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;;; ***** BEGIN LICENSE BLOCK *****
;;; Version: MPL 1.1/GPL 2.0/LGPL 2.1
;;;
;;; The contents of this file are subject to the Mozilla Public License Version
;;; 1.1 (the "License"); you may not use this file except in compliance with
;;; the License. You may obtain a copy of the License at
;;; http://www.mozilla.org/MPL/
;;;
;;; Software distributed under the License is distributed on an "AS IS" basis,
;;; WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
;;; for the specific language governing rights and limitations under the
;;; License.
;;;
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;;; The Original Code is the Language Design and Prototyping Environment.
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;;;
;;; The Initial Developer of the Original Code is
;;; Netscape Communications Corporation.
;;; Portions created by the Initial Developer are Copyright (C) 1999-2002
;;; the Initial Developer. All Rights Reserved.
;;;
;;; Contributor(s):
;;; Waldemar Horwat <waldemar@acm.org>
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;;;
;;; Alternatively, the contents of this file may be used under the terms of
;;; either the GNU General Public License Version 2 or later (the "GPL"), or
;;; the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
;;; in which case the provisions of the GPL or the LGPL are applicable instead
;;; of those above. If you wish to allow use of your version of this file only
;;; under the terms of either the GPL or the LGPL, and not to allow others to
;;; use your version of this file under the terms of the MPL, indicate your
;;; decision by deleting the provisions above and replace them with the notice
;;; and other provisions required by the GPL or the LGPL. If you do not delete
;;; the provisions above, a recipient may use your version of this file under
;;; the terms of any one of the MPL, the GPL or the LGPL.
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;;;
;;; ***** END LICENSE BLOCK *****
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;;;
;;; ECMAScript semantic calculus
;;;
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;;; Waldemar Horwat (waldemar@acm.org)
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;;;
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( declaim ( optimize ( debug 3 ) ) ) ;*****
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( defvar *trace-variables* nil )
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; Different Common Lisp implementations map their floating-point types to Common Lisp types differently.
; Change the code below to encode which ones correspond to IEEE single (float32) and double (float64) values.
( defconstant *float32-type* #+ mcl 'short-float #- mcl 'single-float )
( deftype float32 ( )
' ( or
#+ mcl ( and short-float ( not ( eql 0.0s0 ) ) ( not ( eql -0.0s0 ) ) )
#- mcl ( and single-float ( not ( eql 0.0f0 ) ) ( not ( eql -0.0f0 ) ) )
( member :+zero32 :-zero32 :+infinity32 :-infinity32 :nan32 ) ) )
; The exponent character emitted by (with-standard-io-syntax (format "~E" x)) when printing an IEEE single value
( defconstant *float32-exponent-char* #+ mcl #\S #- mcl #\f )
( defconstant *float64-type* 'double-float )
( deftype float64 ( )
' ( or
( and double-float ( not ( eql 0.0 ) ) ( not ( eql -0.0 ) ) )
( member :+zero64 :-zero64 :+infinity64 :-infinity64 :nan64 ) ) )
; The exponent character emitted by (with-standard-io-syntax (format "~E" x)) when printing an IEEE double value
( defconstant *float64-exponent-char* #+ mcl #\E #- mcl #\d )
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#+ mcl ( dolist ( indent-spec ' ( ( ? . 1 ) ( /*/ . 1 ) ( lisp-call . 3 ) ( throw-error . 1 ) ( apply . 1 ) ( funcall . 1 ) ( declare-action . 5 ) ( production . 3 ) ( rule . 2 ) ( function . 2 )
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( define . 2 ) ( deftag . 1 ) ( defrecord . 1 ) ( deftype . 1 ) ( tag . 1 ) ( %text . 1 )
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( assert . 1 ) ( var . 2 ) ( const . 2 ) ( rwhen . 1 ) ( while . 1 ) ( for-each . 2 )
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( new . 1 ) ( set-field . 1 ) ( list-set-of . 1 ) ( %list-set-of . 1 ) ( :narrow . 1 ) ( :select . 1 ) ) )
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( pushnew indent-spec ccl:*fred-special-indent-alist* :test #' equal ) )
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; Return x/y, ensuring that it is an integer.
( defun int/ ( x y )
( let ( ( q ( / x y ) ) )
( if ( integerp q )
q
( error "int/ must produce an integer" ) ) ) )
; Return the floor of log10 of rational value r
( defun floor-log10 ( r )
( cond
( ( or ( not ( rationalp r ) ) ( <= r 0 ) ) ( error "Bad argument ~S to floor-log10" r ) )
( ( >= r 1 )
( do ( ( result 0 ( 1+ result ) ) )
( ( < r 10 ) result )
( setq r ( floor r 10 ) ) ) )
( t
( do ( ( result 0 ( 1- result ) ) )
( ( >= r 1 ) result )
( setq r ( * r 10 ) ) ) ) ) )
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; Return the boolean exclusive or of the arguments.
( defun xor ( &rest as )
( let ( ( result nil ) )
( dolist ( a as )
( when a
( setq result ( not result ) ) ) )
result ) )
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; A boolean version of = that works on any nil/non-nil values.
( declaim ( inline boolean= ) )
( defun boolean= ( a b )
( eq ( not a ) ( not b ) ) )
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; Complement of eq.
( declaim ( inline not-eq ) )
( defun not-eq ( a b )
( not ( eq a b ) ) )
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( defun digit-char-36 ( char )
( assert-non-null ( digit-char-p char 36 ) ) )
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; Call map on each element of the list l. If map returns true, call filter on that element. Gather the results
; of the calls to filter into a new list and return that list.
( defun filter-map-list ( filter map l )
( let ( ( results nil ) )
( dolist ( e l )
( when ( funcall filter e )
( push ( funcall map e ) results ) ) )
( nreverse results ) ) )
; Call map on each element of the sequence s. If map returns true, call filter on that element. Gather the results
; of the calls to filter into a new sequence of type result-type and return that sequence.
( defun filter-map ( result-type filter map s )
( let ( ( results nil ) )
( map nil
#' ( lambda ( e )
( when ( funcall filter e )
( push ( funcall map e ) results ) ) )
s )
( coerce result-type ( nreverse results ) ) ) )
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; Return the same symbol in the keyword package.
( defun find-keyword ( symbol )
( assert-non-null ( find-symbol ( string symbol ) ( find-package :keyword ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; DOUBLE-PRECISION FLOATING-POINT NUMBERS
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( declaim ( inline finite64? ) )
( defun finite64? ( n )
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( and ( typep n *float64-type* ) ( not ( zerop n ) ) ) )
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( defun float64? ( n )
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( or ( finite64? n ) ( member n ' ( :+zero64 :-zero64 :+infinity64 :-infinity64 :nan64 ) ) ) )
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; Evaluate expr. If it evaluates successfully, return its value except if it evaluates to
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; +0.0 or -0.0, in which case return :+zero64 (but not :-zero64).
; If evaluating expr overflows, evaluate sign; if it returns a positive value, return :+infinity64;
; otherwise return :-infinity64. sign should not return zero.
( defmacro handle-overflow64 ( expr &body sign )
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( let ( ( x ( gensym ) ) )
` ( handler-case ( let ( ( , x , expr ) )
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( if ( zerop , x ) :+zero64 , x ) )
( floating-point-overflow ( ) ( if ( minusp ( progn ,@ sign ) ) :-infinity64 :+infinity64 ) ) ) ) )
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( defun rational-to-float64 ( r )
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( let ( ( f ( handle-overflow64 ( coerce r *float64-type* )
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r ) ) )
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( if ( eq f :+zero64 )
( if ( minusp r ) :-zero64 :+zero64 )
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f ) ) )
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( defun float32-to-float64 ( x )
( case x
( :+zero32 :+zero64 )
( :-zero32 :-zero64 )
( :+infinity32 :+infinity64 )
( :-infinity32 :-infinity64 )
( :nan32 :nan64 )
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( t ( coerce x *float64-type* ) ) ) )
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; Return true if n is +0 or -0 and false otherwise.
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( declaim ( inline float64-is-zero ) )
( defun float64-is-zero ( n )
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( or ( eq n :+zero64 ) ( eq n :-zero64 ) ) )
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; Return true if n is NaN and false otherwise.
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( declaim ( inline float64-is-nan ) )
( defun float64-is-nan ( n )
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( eq n :nan64 ) )
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; Return true if n is :+infinity64 or :-infinity64 and false otherwise.
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( declaim ( inline float64-is-infinite ) )
( defun float64-is-infinite ( n )
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( or ( eq n :+infinity64 ) ( eq n :-infinity64 ) ) )
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; Truncate n to the next lower integer. Signal an error if n isn't finite.
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( defun truncate-finite-float64 ( n )
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( if ( float64-is-zero n )
0
( truncate n ) ) )
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; Return:
; :less if n<m;
; :equal if n=m;
; :greater if n>m.
( defun rational-compare ( n m )
( cond
( ( < n m ) :less )
( ( > n m ) :greater )
( t :equal ) ) )
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; Return:
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; :less if n<m;
; :equal if n=m;
; :greater if n>m;
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; :unordered if either n or m is :nan64.
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( defun float64-compare ( n m )
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( when ( float64-is-zero n )
( setq n 0.0 ) )
( when ( float64-is-zero m )
( setq m 0.0 ) )
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( cond
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( ( or ( float64-is-nan n ) ( float64-is-nan m ) ) :unordered )
( ( eql n m ) :equal )
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( ( or ( eq n :+infinity64 ) ( eq m :-infinity64 ) ) :greater )
( ( or ( eq m :+infinity64 ) ( eq n :-infinity64 ) ) :less )
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( ( < n m ) :less )
( ( > n m ) :greater )
( t :equal ) ) )
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; Return
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; 1 if n is +0.0, :+infinity64, or any positive floating-point number;
; -1 if n is -0.0, :-infinity64, or any positive floating-point number;
; 0 if n is :nan64.
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( defun float64-sign ( n )
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( case n
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( ( :+zero64 :+infinity64 ) 1 )
( ( :-zero64 :-infinity64 ) -1 )
( :nan64 0 )
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( t ( round ( float-sign n ) ) ) ) )
; Return
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; 0 if either n or m is :nan64;
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; 1 if n and m have the same float64-sign;
; -1 if n and m have different float64-signs.
( defun float64-sign-xor ( n m )
( * ( float64-sign n ) ( float64-sign m ) ) )
; Return d truncated towards zero into a 32-bit integer. Overflows wrap around.
( defun float64-to-uint32 ( d )
( case d
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( ( :+zero64 :-zero64 :+infinity64 :-infinity64 :nan64 ) 0 )
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( t ( mod ( truncate d ) #x100000000 ) ) ) )
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; Return the absolute value of n.
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( defun float64-abs ( n )
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( case n
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( ( :+zero64 :-zero64 ) :+zero64 )
( ( :+infinity64 :-infinity64 ) :+infinity64 )
( :nan64 :nan64 )
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( t ( abs n ) ) ) )
; Return -n.
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( defun float64-neg ( n )
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( case n
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( :+zero64 :-zero64 )
( :-zero64 :+zero64 )
( :+infinity64 :-infinity64 )
( :-infinity64 :+infinity64 )
( :nan64 :nan64 )
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( t ( - n ) ) ) )
; Return n+m.
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( defun float64-add ( n m )
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( case n
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( :+zero64 ( if ( eq m :-zero64 ) :+zero64 m ) )
( :-zero64 m )
( :+infinity64 ( case m
( ( :-infinity64 :nan64 ) :nan64 )
( t :+infinity64 ) ) )
( :-infinity64 ( case m
( ( :+infinity64 :nan64 ) :nan64 )
( t :-infinity64 ) ) )
( :nan64 :nan64 )
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( t ( case m
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( ( :+zero64 :-zero64 ) n )
( :+infinity64 :+infinity64 )
( :-infinity64 :-infinity64 )
( :nan64 :nan64 )
( t ( handle-overflow64 ( + n m )
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( let ( ( n-sign ( float-sign n ) )
( m-sign ( float-sign m ) ) )
( assert-true ( = n-sign m-sign ) ) ;If the signs are opposite, we can't overflow.
n-sign ) ) ) ) ) ) )
; Return n-m.
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( defun float64-subtract ( n m )
( float64-add n ( float64-neg m ) ) )
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; Return n*m.
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( defun float64-multiply ( n m )
( let ( ( sign ( float64-sign-xor n m ) )
( n ( float64-abs n ) )
( m ( float64-abs m ) ) )
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( let ( ( result ( cond
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( ( zerop sign ) :nan64 )
( ( eq n :+infinity64 ) ( if ( eq m :+zero64 ) :nan64 :+infinity64 ) )
( ( eq m :+infinity64 ) ( if ( eq n :+zero64 ) :nan64 :+infinity64 ) )
( ( or ( eq n :+zero64 ) ( eq m :+zero64 ) ) :+zero64 )
( t ( handle-overflow64 ( * n m ) 1 ) ) ) ) )
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( if ( minusp sign )
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( float64-neg result )
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result ) ) ) )
; Return n/m.
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( defun float64-divide ( n m )
( let ( ( sign ( float64-sign-xor n m ) )
( n ( float64-abs n ) )
( m ( float64-abs m ) ) )
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( let ( ( result ( cond
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( ( zerop sign ) :nan64 )
( ( eq n :+infinity64 ) ( if ( eq m :+infinity64 ) :nan64 :+infinity64 ) )
( ( eq m :+infinity64 ) :+zero64 )
( ( eq m :+zero64 ) ( if ( eq n :+zero64 ) :nan64 :+infinity64 ) )
( ( eq n :+zero64 ) :+zero64 )
( t ( handle-overflow64 ( / n m ) 1 ) ) ) ) )
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( if ( minusp sign )
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( float64-neg result )
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result ) ) ) )
; Return n%m, using the ECMAScript definition of %.
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( defun float64-remainder ( n m )
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( cond
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( ( or ( float64-is-nan n ) ( float64-is-nan m ) ( float64-is-infinite n ) ( float64-is-zero m ) ) :nan64 )
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( ( or ( float64-is-infinite m ) ( float64-is-zero n ) ) n )
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( t ( let ( ( result ( float ( rem ( rational n ) ( rational m ) ) ) ) )
( if ( zerop result )
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( if ( minusp n ) :-zero64 :+zero64 )
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result ) ) ) ) )
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; s should be a string of decimal digits optionally preceded by a plus or minus sign. Return s's
; value as an integer.
( defun string-to-integer ( s )
( let ( ( p 0 )
( sign 1 )
( n 0 )
( length ( length s ) ) )
( case ( char s 0 )
( #\+ ( setq p 1 ) )
( #\- ( setq sign -1 ) ( setq p 1 ) ) )
( assert ( < p length ) )
( do ( )
( ( = p length ) )
( setq n ( + ( * n 10 ) ( digit-char-p ( char s p ) ) ) )
( incf p ) )
( * sign n ) ) )
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; The number x should be a positive floating-point number that uses the given exponent-char when
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; printed in exponential notation.
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; Return two values:
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; A significand s, expressed as a string of decimal digits, the last of which is nonzero;
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; An exponent e, such that s*10^(e+1-length(s)), when converted to x's type, is the original number x.
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;
; ***** Assumes that Common Lisp implements proper rounding and round-tripping when formatting a floating-point number.
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( defun decompose-positive-float ( x exponent-char )
( unless ( > x 0 )
( error "decompose-positive-float can only be called on a positive number" ) )
( cond
( ( eql x 5e-324 ) ( values "5" -324 ) )
( ( eql x #+ mcl 1s-45 #- mcl 1f-45 ) ( values "1" -45 ) )
( t
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( let* ( ( str ( format nil "~E" x ) )
( p ( position exponent-char str ) ) )
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( unless ( and p ( eql ( char str 1 ) #\. ) )
( error "Internal problem in decompose-float. Check the settings of *float32-exponent-char* and *float64-exponent-char* for your platform." ) )
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( let ( ( s-first ( subseq str 0 1 ) )
( s-rest ( subseq str 2 p ) ) )
( values
( if ( string= s-rest "0" ) s-first ( concatenate 'string s-first s-rest ) )
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( string-to-integer ( subseq str ( 1+ p ) ) ) ) ) ) ) ) )
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; The number x should be a positive floating-point number that uses the given exponent-char when
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; printed in exponential notation.
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; Return two values:
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; A significand s, expressed as a string of decimal digits possibly containing a decimal point;
; An exponent e, such that s*10^e is the absolute value of the original number. e is nil if it would be zero.
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; The number is expressed with e being nil if its absolute value is between 1e-6 inclusive and 1e21 exclusive
; unless always-show-exponent is true.
; If always-show-point is true, then s always contains either an exponent or a decimal point with at least one digit after it.
( defun positive-float-to-string-components ( x exponent-char always-show-point always-show-exponent )
( multiple-value-bind ( s e ) ( decompose-positive-float x exponent-char )
( let ( ( k ( length s ) ) )
( cond
( ( and ( <= k ( 1+ e ) 21 ) ( not always-show-exponent ) )
( setq s ( concatenate 'string s ( make-string ( - ( 1+ e ) k ) :initial-element #\0 ) ) )
( when always-show-point
( setq s ( concatenate 'string s ".0" ) ) )
( setq e nil ) )
( ( and ( <= 0 e 20 ) ( not always-show-exponent ) )
( setq s ( concatenate 'string ( subseq s 0 ( 1+ e ) ) "." ( subseq s ( 1+ e ) ) ) )
( setq e nil ) )
( ( and ( <= -6 e -1 ) ( not always-show-exponent ) )
( setq s ( concatenate 'string "0." ( make-string ( - ( 1+ e ) ) :initial-element #\0 ) s ) )
( setq e nil ) )
( ( = k 1 ) )
( t ( setq s ( concatenate 'string ( subseq s 0 1 ) "." ( subseq s 1 ) ) ) ) )
( values s e ) ) ) )
; The number x should be a positive finite64.
; Return two values:
; A significand s, expressed as a string of decimal digits, the last of which is nonzero;
; An exponent e, such that s*10^(e+1-length(s)), when converted to a float64, is the original number x.
( defun decompose-positive-float64 ( x )
( decompose-positive-float x *float64-exponent-char* ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; SINGLE-PRECISION FLOATING-POINT NUMBERS
( declaim ( inline finite32? ) )
( defun finite32? ( n )
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( and ( typep n *float32-type* ) ( not ( zerop n ) ) ) )
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( defun float32? ( n )
( or ( finite32? n ) ( member n ' ( :+zero32 :-zero32 :+infinity32 :-infinity32 :nan32 ) ) ) )
; Evaluate expr. If it evaluates successfully, return its value except if it evaluates to
; +0.0 or -0.0, in which case return :+zero32 (but not :-zero32).
; If evaluating expr overflows, evaluate sign; if it returns a positive value, return :+infinity32;
; otherwise return :-infinity32. sign should not return zero.
( defmacro handle-overflow32 ( expr &body sign )
( let ( ( x ( gensym ) ) )
` ( handler-case ( let ( ( , x , expr ) )
( if ( zerop , x ) :+zero32 , x ) )
( floating-point-overflow ( ) ( if ( minusp ( progn ,@ sign ) ) :-infinity32 :+infinity32 ) ) ) ) )
( defun rational-to-float32 ( r )
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( let ( ( f ( handle-overflow32 ( coerce r *float32-type* )
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r ) ) )
( if ( eq f :+zero32 )
( if ( minusp r ) :-zero32 :+zero32 )
f ) ) )
; Return true if n is +0 or -0 and false otherwise.
( declaim ( inline float32-is-zero ) )
( defun float32-is-zero ( n )
( or ( eq n :+zero32 ) ( eq n :-zero32 ) ) )
; Return true if n is NaN and false otherwise.
( declaim ( inline float32-is-nan ) )
( defun float32-is-nan ( n )
( eq n :nan32 ) )
; Return true if n is :+infinity32 or :-infinity32 and false otherwise.
( declaim ( inline float32-is-infinite ) )
( defun float32-is-infinite ( n )
( or ( eq n :+infinity32 ) ( eq n :-infinity32 ) ) )
; Truncate n to the next lower integer. Signal an error if n isn't finite.
( defun truncate-finite-float32 ( n )
( if ( float32-is-zero n )
0
( truncate n ) ) )
; Return:
; :less if n<m;
; :equal if n=m;
; :greater if n>m;
; :unordered if either n or m is :nan32.
( defun float32-compare ( n m )
( when ( float32-is-zero n )
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( setq n ( coerce 0.0 *float32-type* ) ) )
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( when ( float32-is-zero m )
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( setq m ( coerce 0.0 *float32-type* ) ) )
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( cond
( ( or ( float32-is-nan n ) ( float32-is-nan m ) ) :unordered )
( ( eql n m ) :equal )
( ( or ( eq n :+infinity32 ) ( eq m :-infinity32 ) ) :greater )
( ( or ( eq m :+infinity32 ) ( eq n :-infinity32 ) ) :less )
( ( < n m ) :less )
( ( > n m ) :greater )
( t :equal ) ) )
; Return
; 1 if n is +0.0, :+infinity32, or any positive floating-point number;
; -1 if n is -0.0, :-infinity32, or any positive floating-point number;
; 0 if n is :nan32.
( defun float32-sign ( n )
( case n
( ( :+zero32 :+infinity32 ) 1 )
( ( :-zero32 :-infinity32 ) -1 )
( :nan32 0 )
( t ( round ( float-sign n ) ) ) ) )
; Return
; 0 if either n or m is :nan32;
; 1 if n and m have the same float32-sign;
; -1 if n and m have different float32-signs.
( defun float32-sign-xor ( n m )
( * ( float32-sign n ) ( float32-sign m ) ) )
; Return the absolute value of n.
( defun float32-abs ( n )
( case n
( ( :+zero32 :-zero32 ) :+zero32 )
( ( :+infinity32 :-infinity32 ) :+infinity32 )
( :nan32 :nan32 )
( t ( abs n ) ) ) )
; Return -n.
( defun float32-neg ( n )
( case n
( :+zero32 :-zero32 )
( :-zero32 :+zero32 )
( :+infinity32 :-infinity32 )
( :-infinity32 :+infinity32 )
( :nan32 :nan32 )
( t ( - n ) ) ) )
; Return n+m.
( defun float32-add ( n m )
( case n
( :+zero32 ( if ( eq m :-zero32 ) :+zero32 m ) )
( :-zero32 m )
( :+infinity32 ( case m
( ( :-infinity32 :nan32 ) :nan32 )
( t :+infinity32 ) ) )
( :-infinity32 ( case m
( ( :+infinity32 :nan32 ) :nan32 )
( t :-infinity32 ) ) )
( :nan32 :nan32 )
( t ( case m
( ( :+zero32 :-zero32 ) n )
( :+infinity32 :+infinity32 )
( :-infinity32 :-infinity32 )
( :nan32 :nan32 )
( t ( handle-overflow32 ( + n m )
( let ( ( n-sign ( float-sign n ) )
( m-sign ( float-sign m ) ) )
( assert-true ( = n-sign m-sign ) ) ;If the signs are opposite, we can't overflow.
n-sign ) ) ) ) ) ) )
; Return n-m.
( defun float32-subtract ( n m )
( float32-add n ( float32-neg m ) ) )
; Return n*m.
( defun float32-multiply ( n m )
( let ( ( sign ( float32-sign-xor n m ) )
( n ( float32-abs n ) )
( m ( float32-abs m ) ) )
( let ( ( result ( cond
( ( zerop sign ) :nan32 )
( ( eq n :+infinity32 ) ( if ( eq m :+zero32 ) :nan32 :+infinity32 ) )
( ( eq m :+infinity32 ) ( if ( eq n :+zero32 ) :nan32 :+infinity32 ) )
( ( or ( eq n :+zero32 ) ( eq m :+zero32 ) ) :+zero32 )
( t ( handle-overflow32 ( * n m ) 1 ) ) ) ) )
( if ( minusp sign )
( float32-neg result )
result ) ) ) )
; Return n/m.
( defun float32-divide ( n m )
( let ( ( sign ( float32-sign-xor n m ) )
( n ( float32-abs n ) )
( m ( float32-abs m ) ) )
( let ( ( result ( cond
( ( zerop sign ) :nan32 )
( ( eq n :+infinity32 ) ( if ( eq m :+infinity32 ) :nan32 :+infinity32 ) )
( ( eq m :+infinity32 ) :+zero32 )
( ( eq m :+zero32 ) ( if ( eq n :+zero32 ) :nan32 :+infinity32 ) )
( ( eq n :+zero32 ) :+zero32 )
( t ( handle-overflow32 ( / n m ) 1 ) ) ) ) )
( if ( minusp sign )
( float32-neg result )
result ) ) ) )
; Return n%m, using the ECMAScript definition of %.
( defun float32-remainder ( n m )
( cond
( ( or ( float32-is-nan n ) ( float32-is-nan m ) ( float32-is-infinite n ) ( float32-is-zero m ) ) :nan32 )
( ( or ( float32-is-infinite m ) ( float32-is-zero n ) ) n )
( t ( let ( ( result ( float ( rem ( rational n ) ( rational m ) ) ) ) )
( if ( zerop result )
( if ( minusp n ) :-zero32 :+zero32 )
result ) ) ) ) )
; s should be a string of decimal digits optionally preceded by a plus or minus sign. Return s's
; value as an integer.
( defun string-to-integer ( s )
( let ( ( p 0 )
( sign 1 )
( n 0 )
( length ( length s ) ) )
( case ( char s 0 )
( #\+ ( setq p 1 ) )
( #\- ( setq sign -1 ) ( setq p 1 ) ) )
( assert ( < p length ) )
( do ( )
( ( = p length ) )
( setq n ( + ( * n 10 ) ( digit-char-p ( char s p ) ) ) )
( incf p ) )
( * sign n ) ) )
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; The number x should be a positive finite32.
; Return two values:
; A significand s, expressed as a string of decimal digits, the last of which is nonzero;
; An exponent e, such that s*10^(e+1-length(s)), when converted to a float32, is the original number x.
( defun decompose-positive-float32 ( x )
( decompose-positive-float x *float32-exponent-char* ) )
;;; ------------------------------------------------------------------------------------------------------
;;; CHARACTER UTILITIES
( defun integer-to-supplementary-char ( code-point )
( unless ( <= #x10000 code-point #x10FFFF )
( error "Bad Unicode supplementary-char code point ~S" code-point ) )
( cons :supplementary-char code-point ) )
( defun integer-to-char21 ( code-point )
( unless ( <= 0 code-point #x10FFFF )
( error "Bad Unicode code point ~S" code-point ) )
( if ( <= code-point #xFFFF )
( code-char code-point )
( cons :supplementary-char code-point ) ) )
( defun char21-to-integer ( ch )
( cond
( ( characterp ch ) ( char-code ch ) )
( ( eq ( car ch ) :supplementary-char ) ( cdr ch ) ) ) )
( defun char21< ( a b )
( < ( char21-to-integer a ) ( char21-to-integer b ) ) )
( defun char21<= ( a b )
( <= ( char21-to-integer a ) ( char21-to-integer b ) ) )
( defun char21> ( a b )
( > ( char21-to-integer a ) ( char21-to-integer b ) ) )
( defun char21>= ( a b )
( >= ( char21-to-integer a ) ( char21-to-integer b ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; SET UTILITIES
( defun integer-set-min ( intset )
( or ( intset-min intset )
( error "min of empty integer-set" ) ) )
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( defun char16-set-min ( intset )
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( code-char ( or ( intset-min intset )
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( error "min of empty char16-set" ) ) ) )
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( defun integer-set-max ( intset )
( or ( intset-max intset )
( error "max of empty integer-set" ) ) )
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( defun char16-set-max ( intset )
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( code-char ( or ( intset-max intset )
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( error "max of empty char16-set" ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; CODE GENERATION
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#+ mcl ( defvar *deferred-functions* )
( defun quiet-compile ( name definition )
#- mcl ( compile name definition )
#+ mcl ( handler-bind ( ( ccl::undefined-function-reference
#' ( lambda ( condition )
( setq *deferred-functions* ( append ( slot-value condition 'ccl::args ) *deferred-functions* ) )
( muffle-warning condition ) ) ) )
( compile name definition ) ) )
( defmacro defer-mcl-warnings ( &body body )
#- mcl ` ( with-compilation-unit ( ) ,@ body )
#+ mcl ` ( let ( ( *deferred-functions* nil ) )
( multiple-value-prog1
( with-compilation-unit ( ) ,@ body )
( let ( ( missing-functions ( remove-if #' fboundp *deferred-functions* ) ) )
( when missing-functions
( warn "Undefined functions: ~S" missing-functions ) ) ) ) ) )
; If args has no elements, return the value of empty.
; If args has one element, return that element.
; If args has two or more elements, return (op . args).
( defun gen-poly-op ( op empty args )
( cond
( ( endp args ) empty )
( ( endp ( cdr args ) ) ( car args ) )
( t ( cons op args ) ) ) )
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; Return `(progn ,@statements), optimizing where possible.
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( defun gen-progn ( statements )
( cond
( ( endp statements ) nil )
( ( and ( endp ( cdr statements ) )
( let ( ( first-statement ( first statements ) ) )
( not ( and ( consp first-statement )
( eq ( first first-statement ) 'declare ) ) ) ) )
( first statements ) )
( t ( cons 'progn statements ) ) ) )
; Return (nth <n> <code>), optimizing if possible.
( defun gen-nth-code ( n code )
( let ( ( abbrev ( assoc n ' ( ( 0 . first ) ( 1 . second ) ( 2 . third ) ( 3 . fourth ) ( 4 . fifth ) ( 5 . sixth ) ( 6 . seventh ) ( 7 . eighth ) ( 8 . ninth ) ( 9 . tenth ) ) ) ) )
( if abbrev
( list ( cdr abbrev ) code )
( list 'nth n code ) ) ) )
; Return code that tests whether the result of evaluating code is a member of the given
; list of symbols using the test eq.
( defun gen-member-test ( code symbols )
( assert-true symbols )
( if ( cdr symbols )
( list 'member code ( list 'quote symbols ) :test ' #' eq )
( list 'eq code ( let ( ( symbol ( car symbols ) ) )
( if ( constantp symbol )
symbol
( list 'quote symbol ) ) ) ) ) )
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; Return `(funcall ,function-value ,@arg-values), optimizing where possible.
( defun gen-apply ( function-value &rest arg-values )
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( let ( ( stripped-function-value ( simple-strip-function function-value ) ) )
( cond
( stripped-function-value
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( if ( and ( consp stripped-function-value )
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( eq ( first stripped-function-value ) 'lambda )
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( listp ( second stripped-function-value ) )
( cddr stripped-function-value )
( every #' ( lambda ( arg )
( and ( identifier? arg )
( not ( eql ( first-symbol-char arg ) #\& ) ) ) )
( second stripped-function-value ) ) )
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( let ( ( function-args ( second stripped-function-value ) )
( function-body ( cddr stripped-function-value ) ) )
( assert-true ( = ( length function-args ) ( length arg-values ) ) )
( if function-args
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( list* 'let
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( mapcar #' list function-args arg-values )
function-body )
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( gen-progn function-body ) ) )
( cons stripped-function-value arg-values ) ) )
( ( and ( consp function-value )
( eq ( first function-value ) 'symbol-function )
( null ( cddr function-value ) )
( consp ( cadr function-value ) )
( eq ( caadr function-value ) 'quote )
( identifier? ( cadadr function-value ) )
( null ( cddadr function-value ) ) )
( cons ( cadadr function-value ) arg-values ) )
( t ( list* 'funcall function-value arg-values ) ) ) ) )
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; Return `#'(lambda ,args (declare (ignore-if-unused ,@args)) ,body-code), optimizing
; where possible.
( defun gen-lambda ( args body-code )
( if args
` #' ( lambda , args ( declare ( ignore-if-unused . , args ) ) , body-code )
` #' ( lambda ( ) , body-code ) ) )
; If expr is a lambda-expression, return an equivalent expression that has
; the given name (which may be a symbol or a string; if it's a string, it is interned
; in the given package). Otherwise, return expr unchanged.
; Attaching a name to lambda-expressions helps in debugging code by identifying
; functions in debugger backtraces.
( defun name-lambda ( expr name &optional package )
( if ( and ( consp expr )
( eq ( first expr ) 'function )
( consp ( rest expr ) )
( consp ( second expr ) )
( eq ( first ( second expr ) ) 'lambda )
( null ( cddr expr ) ) )
( let ( ( name ( if ( symbolp name )
name
( intern name package ) ) ) )
;Avoid trouble when name is a lisp special form like if or lambda.
( when ( special-form-p name )
( setq name ( gensym name ) ) )
` ( flet ( ( , name ,@ ( rest ( second expr ) ) ) )
#' , name ) )
expr ) )
; Intern n symbols in the current package with names <prefix>0, <prefix>1, ...,
; <prefix>n-1, where <prefix> is the value of the prefix string.
; Return a list of these n symbols concatenated to the front of rest.
( defun intern-n-vars-with-prefix ( prefix n rest )
( if ( zerop n )
rest
( intern-n-vars-with-prefix prefix ( 1- n ) ( cons ( intern ( format nil "~A~D" prefix n ) ) rest ) ) ) )
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; Make a new function with the given name. The function takes n-args arguments and applies them to the
; function whose source code is in expr. Return the source code for the function.
( defun gen-defun ( expr name n-args )
( when ( special-form-p name )
( error "Can't call make-defun on ~S" name ) )
( if ( and ( consp expr )
( eq ( first expr ) 'function )
( consp ( rest expr ) )
( second expr )
( null ( cddr expr ) )
( let ( ( stripped-expr ( second expr ) ) )
( and ( consp stripped-expr )
( eq ( first stripped-expr ) 'lambda )
( listp ( second stripped-expr ) )
( cddr stripped-expr )
( every #' ( lambda ( arg )
( and ( identifier? arg )
( not ( eql ( first-symbol-char arg ) #\& ) ) ) )
( second stripped-expr ) ) ) ) )
( let* ( ( stripped-expr ( second expr ) )
( function-args ( second stripped-expr ) )
( function-body ( cddr stripped-expr ) ) )
( assert-true ( = ( length function-args ) n-args ) )
( list* 'defun name function-args function-body ) )
( let ( ( args ( intern-n-vars-with-prefix "_" n-args nil ) ) )
( list 'defun name args ( apply #' gen-apply expr args ) ) ) ) )
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; If code has the form (function <expr>), return <expr>; otherwise, return nil.
( defun simple-strip-function ( code )
( when ( and ( consp code )
( eq ( first code ) 'function )
( consp ( rest code ) )
( second code )
( null ( cddr code ) ) )
( assert-non-null ( second code ) ) ) )
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; Strip the (function ...) covering from expr, leaving only a plain lambda expression.
( defun strip-function ( expr name n-args )
( when ( special-form-p name )
( error "Can't call make-defun on ~S" name ) )
( if ( and ( consp expr )
( eq ( first expr ) 'function )
( consp ( rest expr ) )
( second expr )
( null ( cddr expr ) )
( let ( ( stripped-expr ( second expr ) ) )
( and ( consp stripped-expr )
( eq ( first stripped-expr ) 'lambda )
( listp ( second stripped-expr ) )
( cddr stripped-expr ) ) ) )
( second expr )
( let ( ( args ( intern-n-vars-with-prefix "_" n-args nil ) ) )
( list 'lambda args ( apply #' gen-apply expr args ) ) ) ) )
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; Generate a local variable for holding the value of expr. Optimize the case where expr
; is an identifier or a number.
( defun gen-local-var ( expr )
( if ( or ( symbolp expr ) ( numberp expr ) )
expr
( gensym "L" ) ) )
; var should have been obtained from calling gen-local-var on expr. Return
; `(let ((,var ,expr)) ,body-code),
; optimizing the cases that gen-local-var optimizes.
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( defmacro let-local-var ( var expr &body body-code )
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( let ( ( body ( gensym "BODY" ) ) )
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` ( let ( ( , body ( list ,@ body-code ) ) )
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( if ( eql , var , expr )
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( gen-progn , body )
( list* 'let ( list ( list , var , expr ) ) , body ) ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; LF TOKENS
;;; Each symbol in the LF package is a variant of a terminal that represents that terminal preceded by one
;;; or more line breaks.
( defvar *lf-package* ( make-package "LF" :use nil ) )
( defun make-lf-terminal ( terminal )
( assert-true ( not ( lf-terminal? terminal ) ) )
( multiple-value-bind ( lf-terminal present ) ( intern ( symbol-name terminal ) *lf-package* )
( unless ( eq present :external )
( export lf-terminal *lf-package* )
( setf ( get lf-terminal :sort-key ) ( concatenate 'string ( symbol-name terminal ) " " ) )
( setf ( get lf-terminal :origin ) terminal )
( setf ( get terminal :lf-terminal ) lf-terminal ) )
lf-terminal ) )
( defun lf-terminal? ( terminal )
( eq ( symbol-package terminal ) *lf-package* ) )
( declaim ( inline terminal-lf-terminal lf-terminal-terminal ) )
( defun terminal-lf-terminal ( terminal )
( get terminal :lf-terminal ) )
( defun lf-terminal-terminal ( lf-terminal )
( get lf-terminal :origin ) )
; Ensure that for each transition on a LF: terminal in the grammar there exists a corresponding transition
; on a non-LF: terminal.
( defun ensure-lf-subset ( grammar )
( all-state-transitions
#' ( lambda ( state transitions-hash )
( dolist ( transition-pair ( state-transitions state ) )
( let ( ( terminal ( car transition-pair ) ) )
( when ( lf-terminal? terminal )
( unless ( equal ( cdr transition-pair ) ( gethash ( lf-terminal-terminal terminal ) transitions-hash ) )
( format *error-output* "State ~S: transition on ~S differs from transition on ~S~%"
state terminal ( lf-terminal-terminal terminal ) ) ) ) ) ) )
grammar ) )
; Print a list of transitions on non-LF: terminals that do not have corresponding LF: transitions.
; Return a list of non-LF: terminals which behave identically to the corresponding LF: terminals.
( defun show-non-lf-only-transitions ( grammar )
( let ( ( invariant-terminalset ( make-full-terminalset grammar ) )
( terminals-vector ( grammar-terminals grammar ) ) )
( dotimes ( n ( length terminals-vector ) )
( let ( ( terminal ( svref terminals-vector n ) ) )
( when ( lf-terminal? terminal )
( terminalset-difference-f invariant-terminalset ( make-terminalset grammar terminal ) ) ) ) )
( all-state-transitions
#' ( lambda ( state transitions-hash )
( dolist ( transition-pair ( state-transitions state ) )
( let ( ( terminal ( car transition-pair ) ) )
( unless ( lf-terminal? terminal )
( let ( ( lf-terminal ( terminal-lf-terminal terminal ) ) )
( when lf-terminal
( let ( ( lf-terminal-transition ( gethash lf-terminal transitions-hash ) ) )
( cond
( ( null lf-terminal-transition )
( terminalset-difference-f invariant-terminalset ( make-terminalset grammar terminal ) )
( format *error-output* "State ~S has transition on ~S but not on ~S~%"
state terminal lf-terminal ) )
( ( not ( equal ( cdr transition-pair ) lf-terminal-transition ) )
( terminalset-difference-f invariant-terminalset ( make-terminalset grammar terminal ) )
( format *error-output* "State ~S transition on ~S differs from transition on ~S~%"
state terminal lf-terminal ) ) ) ) ) ) ) ) ) )
grammar )
( terminalset-list grammar invariant-terminalset ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; GRAMMAR-INFO
( defstruct ( grammar-info ( :constructor make-grammar-info ( name grammar &optional lexer ) )
( :copier nil )
( :predicate grammar-info? ) )
( name nil :type symbol :read-only t ) ;The name of this grammar
( grammar nil :type grammar :read-only t ) ;This grammar
( lexer nil :type ( or null lexer ) :read-only t ) ) ;This grammar's lexer if this is a lexer grammar; nil if not
; Return the charclass that defines the given lexer nonterminal or nil if none.
( defun grammar-info-charclass ( grammar-info nonterminal )
( let ( ( lexer ( grammar-info-lexer grammar-info ) ) )
( and lexer ( lexer-charclass lexer nonterminal ) ) ) )
; Return the charclass or partition that defines the given lexer nonterminal or nil if none.
( defun grammar-info-charclass-or-partition ( grammar-info nonterminal )
( let ( ( lexer ( grammar-info-lexer grammar-info ) ) )
( and lexer ( or ( lexer-charclass lexer nonterminal )
( gethash nonterminal ( lexer-partitions lexer ) ) ) ) ) )
;;; ------------------------------------------------------------------------------------------------------
;;; WORLDS
( defstruct ( world ( :constructor allocate-world )
( :copier nil )
( :predicate world? ) )
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( conditionals nil :type list ) ;Assoc list of (conditional . highlight), where highlight can be a style keyword, nil (no style), or 'delete
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( package nil :type ( or null package ) ) ;The package in which this world's identifiers are interned
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( next-type-serial-number 0 :type integer ) ;Serial number to be used for the next type defined
( types-reverse nil :type ( or null hash-table ) ) ;Hash table of (kind tag parameters) -> type; nil if invalid
( false-tag nil :type ( or null tag ) ) ;Tag used for false
( true-tag nil :type ( or null tag ) ) ;Tag used for true
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( finite32-tag nil :type ( or null tag ) ) ;Pseudo-tag used for accessing the value field of a finite32
( finite64-tag nil :type ( or null tag ) ) ;Pseudo-tag used for accessing the value field of a finite64
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( bottom-type nil :type ( or null type ) ) ;Subtype of all types used for nonterminating computations
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( void-type nil :type ( or null type ) ) ;Type used for placeholders
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( false-type nil :type ( or null type ) ) ;Type used for false
( true-type nil :type ( or null type ) ) ;Type used for true
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( boolean-type nil :type ( or null type ) ) ;Type used for booleans
( integer-type nil :type ( or null type ) ) ;Type used for integers
( rational-type nil :type ( or null type ) ) ;Type used for rational numbers
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( finite32-type nil :type ( or null type ) ) ;Type used for nonzero finite single-precision floating-point numbers
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( finite64-type nil :type ( or null type ) ) ;Type used for nonzero finite double-precision floating-point numbers
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( char16-type nil :type ( or null type ) ) ;Type used for Unicode code units and BMP code points
( supplementary-char-type nil :type ( or null type ) ) ;Type used for Unicode supplementary code points
( char21-type nil :type ( or null type ) ) ;Type used for Unicode code points
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( string-type nil :type ( or null type ) ) ;Type used for strings (vectors of char16s)
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( denormalized-false-type nil :type ( or null type ) ) ;Type (denormalized-tag false)
( denormalized-true-type nil :type ( or null type ) ) ;Type (denormalized-tag true)
( boxed-boolean-type nil :type ( or null type ) ) ;Union type (union (tag true) (tag false))
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( grammar-infos nil :type list ) ;List of grammar-info
( commands-source nil :type list ) ) ;List of source code of all commands applied to this world
; Return the name of the world.
( defun world-name ( world )
( package-name ( world-package world ) ) )
; Return a symbol in the given package whose value is that package's world structure.
( defun world-access-symbol ( package )
( find-symbol "*WORLD*" package ) )
; Return the world that created the given package.
( declaim ( inline package-world ) )
( defun package-world ( package )
( symbol-value ( world-access-symbol package ) ) )
; Return the world that contains the given symbol.
( defun symbol-world ( symbol )
( package-world ( symbol-package symbol ) ) )
; Delete the world and its package.
( defun delete-world ( world )
( let ( ( package ( world-package world ) ) )
( when package
( delete-package package ) ) )
( setf ( world-package world ) nil ) )
; Create a world using a package with the given name.
; If the package is already used for another world, its contents
; are erased and the other world deleted.
( defun make-world ( name )
( assert-type name string )
( let ( ( p ( find-package name ) ) )
( when p
( let* ( ( access-symbol ( world-access-symbol p ) )
( p-world ( and ( boundp access-symbol ) ( symbol-value access-symbol ) ) ) )
( unless p-world
( error "Package ~A already in use" name ) )
( assert-true ( eq ( world-package p-world ) p ) )
( delete-world p-world ) ) ) )
( let* ( ( p ( make-package name :use nil ) )
( world ( allocate-world
:package p
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:types-reverse ( make-hash-table :test #' equal ) ) )
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( access-symbol ( intern "*WORLD*" p ) ) )
( set access-symbol world )
( export access-symbol p )
world ) )
; Intern s (which should be a symbol or a string) in this world's
; package and return the resulting symbol.
( defun world-intern ( world s )
( intern ( string s ) ( world-package world ) ) )
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; Same as world-intern except that return nil if s is not already interned.
( defun world-find-symbol ( world s )
( find-symbol ( string s ) ( world-package world ) ) )
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; Export symbol in its package, which must belong to some world.
( defun export-symbol ( symbol )
( assert-true ( symbol-in-any-world symbol ) )
( export symbol ( symbol-package symbol ) ) )
; Call f on each external symbol defined in the world's package.
( declaim ( inline each-world-external-symbol ) )
( defun each-world-external-symbol ( world f )
( each-package-external-symbol ( world-package world ) f ) )
; Call f on each external symbol defined in the world's package that has
; a property with the given name.
; f takes two arguments:
; the symbol
; the value of the property
( defun each-world-external-symbol-with-property ( world property f )
( each-world-external-symbol
world
#' ( lambda ( symbol )
( let ( ( value ( get symbol property *get2-nonce* ) ) )
( unless ( eq value *get2-nonce* )
( funcall f symbol value ) ) ) ) ) )
; Return a list of all external symbols defined in the world's package that have
; a property with the given name.
; The list is sorted by symbol names.
( defun all-world-external-symbols-with-property ( world property )
( let ( ( list nil ) )
( each-world-external-symbol
world
#' ( lambda ( symbol )
( let ( ( value ( get symbol property *get2-nonce* ) ) )
( unless ( eq value *get2-nonce* )
( push symbol list ) ) ) ) )
( sort list #' string< ) ) )
; Return true if s is a symbol that is defined in this world's package.
( declaim ( inline symbol-in-world ) )
( defun symbol-in-world ( world s )
( and ( symbolp s ) ( eq ( symbol-package s ) ( world-package world ) ) ) )
; Return true if s is a symbol that is defined in any world's package.
( defun symbol-in-any-world ( s )
( and ( symbolp s )
( let* ( ( package ( symbol-package s ) )
( access-symbol ( world-access-symbol package ) ) )
( and ( boundp access-symbol ) ( typep ( symbol-value access-symbol ) 'world ) ) ) ) )
; Return a list of grammars in the world
( defun world-grammars ( world )
( mapcar #' grammar-info-grammar ( world-grammar-infos world ) ) )
; Return the grammar-info with the given name in the world
( defun world-grammar-info ( world name )
( find name ( world-grammar-infos world ) :key #' grammar-info-name ) )
; Return the grammar with the given name in the world
( defun world-grammar ( world name )
( let ( ( grammar-info ( world-grammar-info world name ) ) )
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( assert-non-null
( and grammar-info ( grammar-info-grammar grammar-info ) ) ) ) )
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; Return the lexer with the given name in the world
( defun world-lexer ( world name )
( let ( ( grammar-info ( world-grammar-info world name ) ) )
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( assert-non-null
( and grammar-info ( grammar-info-lexer grammar-info ) ) ) ) )
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; Return a list of highlights allowed in this world.
( defun world-highlights ( world )
( let ( ( highlights nil ) )
( dolist ( c ( world-conditionals world ) )
( let ( ( highlight ( cdr c ) ) )
( unless ( or ( null highlight ) ( eq highlight 'delete ) )
( pushnew highlight highlights ) ) ) )
( nreverse highlights ) ) )
; Return the highlight to which the given conditional maps.
; Return 'delete if the conditional should be omitted.
( defun resolve-conditional ( world conditional )
( let ( ( h ( assoc conditional ( world-conditionals world ) ) ) )
( if h
( cdr h )
( error "Bad conditional ~S" conditional ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; SYMBOLS
;;; The following properties are attached to exported symbols in the world:
;;;
;;; :preprocess preprocessor function ((preprocessor-state id . form-arg-list) -> form-list re-preprocess) if this identifier
;;; is a preprocessor command like 'grammar, 'lexer, or 'production
;;;
;;; :command expression code generation function ((world grammar-info-var . form-arg-list) -> void) if this identifier
;;; is a command like 'deftype or 'define
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;;; :statement expression code generation function ((world type-env rest last id . form-arg-list) -> codes, live, annotated-stmts)
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;;; if this identifier is a statement like 'if or 'catch.
;;; codes is a list of generated statements.
;;; live is :dead if the statement cannot complete or a list of the symbols of :uninitialized variables that are initialized
;;; if the statement can complete.
;;; annotated-stmts is a list of generated annotated statements.
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;;; :special-form expression code generation function ((world type-env id . form-arg-list) -> code, type, annotated-expr)
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;;; if this identifier is a special form like 'tag or 'in
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;;; :condition boolean condition code generation function ((world type-env id . form-arg-list) -> code, annotated-expr, true-type-env, false-type-env)
;;; if this identifier is a condition form like 'and or 'in
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;;;
;;; :primitive primitive structure if this identifier is a primitive
;;;
;;; :type-constructor expression code generation function ((world allow-forward-references . form-arg-list) -> type) if this
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;;; identifier is a type constructor like '->, 'vector, 'range-set, 'tag, or 'union
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;;; :deftype type if this identifier is a type; nil if this identifier is a forward-referenced type
;;;
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;;; :non-reserved true if this symbol is usable as an identifier despite being a :special-form, :condition, :primitive, or :type-constructor
;;;
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;;; <value> value of this identifier if it is a variable of type other than ->
;;; <function> value of this identifier if it is a variable of type ->
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;;; :value-expr unparsed expression defining the value of this identifier if it is a variable
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;;; :lisp-value-expr unparsed lisp expression defining the value of this identifier; overrides :value-expr
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;;; :mutable if present and non-nil, this identifier is a mutable variable
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;;; :type type of this identifier if it is a variable
;;; :type-expr unparsed expression defining the type of this identifier if it is a variable
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;;; :tag tag structure if this identifier is a tag
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;;; :tag-hidden a flag that, if true, indicates that this tag's name should not be visible
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;;; :tag= a two-argument function that takes two values with this tag and compares them
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;;;
;;; :action list of (grammar-info . grammar-symbol) that declare this action if this identifier is an action name
;;;
;;; :depict-command depictor function ((markup-stream world depict-env . form-arg-list) -> void)
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;;; :depict-statement depictor function ((markup-stream world semicolon last-paragraph-style . form-annotated-arg-list) -> void)
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;;; :depict-special-form depictor function ((markup-stream world level . form-annotated-arg-list) -> void)
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;;; :depict-type-constructor depictor function ((markup-stream world level . form-arg-list) -> void)
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;;;
; Return the preprocessor action associated with the given symbol or nil if none.
; This macro is appropriate for use with setf.
( defmacro symbol-preprocessor-function ( symbol )
` ( get , symbol :preprocess ) )
; Return the primitive definition associated with the given symbol or nil if none.
; This macro is appropriate for use with setf.
( defmacro symbol-primitive ( symbol )
` ( get , symbol :primitive ) )
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; Return the tag definition associated with the given symbol or nil if none.
; This macro is appropriate for use with setf.
( defmacro symbol-tag ( symbol )
` ( get , symbol :tag ) )
; Call f on each tag definition in the world.
; f takes two arguments:
; the name
; the tag structure
( defun each-tag-definition ( world f )
( each-world-external-symbol-with-property world :tag f ) )
; Return a sorted list of the names of all tag definitions in the world.
( defun world-tag-definitions ( world )
( all-world-external-symbols-with-property world :tag ) )
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; Return the type definition associated with the given symbol.
; Return nil if the symbol is a forward-referenced type.
; If the symbol has no type definition at all, return default
; (or nil if not specified).
; This macro is appropriate for use with setf.
( defmacro symbol-type-definition ( symbol &optional default )
` ( get , symbol :deftype ,@ ( and default ( list default ) ) ) )
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; Return true if this symbol's symbol-type-definition is user-defined.
; This macro is appropriate for use with setf.
( defmacro symbol-type-user-defined ( symbol )
` ( get , symbol 'type-user-defined ) )
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; Call f on each type definition, including forward-referenced types, in the world.
; f takes two arguments:
; the symbol
; the type (nil if forward-referenced)
( defun each-type-definition ( world f )
( each-world-external-symbol-with-property world :deftype f ) )
; Return a sorted list of the names of all type definitions, including
; forward-referenced types, in the world.
( defun world-type-definitions ( world )
( all-world-external-symbols-with-property world :deftype ) )
; Return the type of the variable associated with the given symbol or nil if none.
; This macro is appropriate for use with setf.
( defmacro symbol-type ( symbol )
` ( get , symbol :type ) )
; Return a list of (grammar-info . grammar-symbol) pairs that each indicate
; a grammar and a grammar-symbol in that grammar that has an action named by the given symbol.
; This macro is appropriate for use with setf.
( defmacro symbol-action ( symbol )
` ( get , symbol :action ) )
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; Return an unused name for a new function in the world. The given string is a suggested name.
; The returned value is a symbol.
( defun unique-function-name ( world string )
( let ( ( f ( world-intern world string ) ) )
( if ( fboundp f )
( gentemp string ( world-package world ) )
f ) ) )
;;; ------------------------------------------------------------------------------------------------------
;;; TAGS
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( defstruct ( field ( :type list ) ( :constructor make-field ( label type mutable optional ) ) )
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label ;This field's name (not interned in the world)
type ;This field's type
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mutable ;True if this field is mutable
optional ) ;True if this field can be in an uninitialized state
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( defstruct ( tag ( :constructor make-tag ( name keyword mutable fields =-name link base ) ) ( :predicate tag? ) )
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( name nil :type symbol :read-only t ) ;This tag's world-interned name
( keyword nil :type ( or null keyword ) :read-only t ) ;This tag's keyword (non-null only when the tag is immutable and has no fields)
( mutable nil :type bool :read-only t ) ;True if this tag's equality is based on identity, in which case the tag's values have a hidden serial-number field
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( fields nil :type list :read-only t ) ;List of fields after eval-tags-types or (field-name field-type-expression [:const|:var|:opt-const|:opt-var]) before eval-tags-types
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( =-name nil :type symbol ) ;Lazily computed name of a function that compares two values of this tag for equality; nil if not known yet
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( link nil :type ( or null keyword ) :read-only t ) ;:reference if this is a local tag, :external if it's a predefined tag, or nil for no cross-references to this tag
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( base nil :type integer :read-only t ) ;Position of first field in the list; -1 if it's special
( appearance nil ) ) ;One of the following:
; ; nil to display the constructor normally
; ; (:suffix . markup) to display the constructor as a suffix (the constructor must be unary)
; ; (:infix . markup) to display the constructor as an infix (the constructor must be binary)
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; Return four values:
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; the one-based position of the tag's field corresponding to the given label or nil if the label is not present;
; the type the field;
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; true if the field is mutable;
; true if the field is optional.
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( defun tag-find-field ( tag label )
( do ( ( fields ( tag-fields tag ) ( cdr fields ) )
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( n ( tag-base tag ) ( 1+ n ) ) )
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( ( endp fields ) ( values nil nil nil nil ) )
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( let ( ( field ( car fields ) ) )
( when ( eq label ( field-label field ) )
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( return ( values n ( field-type field ) ( field-mutable field ) ( field-optional field ) ) ) ) ) ) )
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; Define a new tag. Signal an error if the name is already used. Return the tag.
; Do not evaluate the field and type expressions yet; that will be done by eval-tags-types.
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; If hidden is true, mark the tag as hidden so that its name cannot be used to access it.
( defun add-tag ( world name mutable fields link hidden )
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( assert-true ( member link ' ( nil :reference :external ) ) )
( let ( ( name ( scan-name world name ) ) )
( when ( symbol-tag name )
( error "Attempt to redefine tag ~A" name ) )
( let ( ( keyword nil )
( =-name nil ) )
( unless ( or mutable fields )
( setq keyword ( intern ( string name ) :keyword ) ) )
( when ( or mutable ( null fields ) )
( setq =-name 'eq )
( setf ( get name :tag= ) #' eq ) )
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( let ( ( tag ( make-tag name keyword mutable ( copy-list fields ) =-name link ( if mutable 2 1 ) ) ) )
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( setf ( symbol-tag name ) tag )
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( when hidden
( setf ( get name :tag-hidden ) t ) )
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( export-symbol name )
tag ) ) ) )
; Evaluate the type expressions in the tag's fields.
( defun eval-tag-types ( world tag )
( do ( ( fields ( tag-fields tag ) ( cdr fields ) )
( labels nil ) )
( ( endp fields ) )
( let ( ( field ( first fields ) ) )
( unless ( and ( consp field ) ( identifier? ( first field ) )
( consp ( cdr field ) ) ( second field )
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( member ( third field ) ' ( nil :const :var :opt-const :opt-var ) )
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( null ( cdddr field ) ) )
( error "Bad field ~S" field ) )
( let ( ( label ( first field ) )
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( mutable ( member ( third field ) ' ( :var :opt-var ) ) )
( optional ( member ( third field ) ' ( :opt-const :opt-var ) ) ) )
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( when ( member label labels )
( error "Duplicate label ~S" label ) )
( push label labels )
( when ( and mutable ( not ( tag-mutable tag ) ) )
( error "Tag ~S is immutable but contains a mutable field ~S" ( tag-name tag ) label ) )
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( setf ( first fields ) ( make-field label ( scan-type world ( second field ) ) mutable optional ) ) ) ) ) )
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; Evaluate the type expressions in all of the world's tag's fields.
( defun eval-tags-types ( world )
( each-tag-definition
world
#' ( lambda ( name tag )
( declare ( ignore name ) )
( eval-tag-types world tag ) ) ) )
; Return the tag with the given un-world-interned name. Signal an error if one wasn't found.
( defun scan-tag ( world tag-name )
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( let* ( ( name ( world-find-symbol world tag-name ) )
( tag ( symbol-tag name ) )
( hidden ( get name :tag-hidden ) ) )
( unless tag
( error "No tag ~A defined" tag-name ) )
( if hidden nil tag ) ) )
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; Scan label to produce a label that is present in the given tag.
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; Return:
; the label's position;
; its field type;
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; a flag indicating whether the field is mutable;
; a flag indicating whether the field is optional.
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( defun scan-label ( tag label )
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( multiple-value-bind ( position field-type mutable optional ) ( tag-find-field tag label )
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( unless position
( error "Label ~S not present in ~A" label ( tag-name tag ) ) )
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( values position field-type mutable optional ) ) )
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; Print the tag nicely on the given stream.
( defun print-tag ( tag &optional ( stream t ) )
( pprint-logical-block ( stream ( tag-fields tag ) :prefix "(" :suffix ")" )
( pprint-exit-if-list-exhausted )
( loop
( let ( ( field ( pprint-pop ) ) )
( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( write ( field-label field ) :stream stream )
( format stream " ~@_" )
( print-type ( field-type field ) stream )
( when ( field-mutable field )
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( format stream " ~@_:var" ) )
( when ( field-optional field )
( format stream " ~@_:opt" ) ) )
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( pprint-exit-if-list-exhausted )
( format stream " ~:_" ) ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; TYPES
( deftype typekind ( )
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' ( member ;tag ;parameters
:bottom ;nil ;nil
:void ;nil ;nil
:boolean ;nil ;nil
:integer ;nil ;nil
:rational ;nil ;nil
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:finite32 ;nil ;nil ;All non-zero finite 32-bit single-precision floating-point numbers
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:finite64 ;nil ;nil ;All non-zero finite 64-bit double-precision floating-point numbers
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:char16 ;nil ;nil
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:supplementary-char ;nil ;nil
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:-> ;nil ;(result-type arg1-type arg2-type ... argn-type)
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:string ;nil ;(char16)
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:vector ;nil ;(element-type)
:list-set ;nil ;(element-type)
:range-set ;nil ;(element-type)
:bit-set ;(tag ... tag) ;(element-type) ;element-type is the type of the union of the tags
:restricted-set ;(n ... n) ;(bit-set-type) ;n's are in ascending numerical order; use :bottom or :bit-set insetad for the trivial cases
:tag ;tag ;nil
:denormalized-tag ;tag ;nil
:union ;nil ;(type ... type) sorted by ascending serial numbers
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:writable-cell ;nil ;(element-type)
:delay ) ) ;nil ;(type)
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;A denormalized-tag is a singleton tag type whose value carries no meaning.
;
;All types are normalized except for those with kind :denormalized-tag and the boxed-boolean union type of tags true and false.
;
;A union type must have:
; at least two types
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; only types with kinds :integer, :rational, :finite32, :finite64, :char16, :supplementary-char, :->, :string, :vector, :list-set, or :tag
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; no type that is a duplicate or subtype of another type in the union
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; at most one type each with kind :->
; at most one type each with kind :vector or :list-set; furthermore, if such a type is present, then only keyword :tag types may be present
; types sorted by ascending type-serial-number, except that :-> is given the serial number -1 and :vector and :list-set -2.
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;
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;Note that types with the above kinds (not including :->, :vector, or :list-set) never change their serial-numbers during unite-types, so
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;unite-types does not need to worry about unions differing only in the order of their parameters.
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( defstruct ( type ( :constructor allocate-type ( serial-number kind tag parameters =-name /=-name ) ) ( :predicate type? ) )
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( name nil :type symbol ) ;This type's name; nil if this type is anonymous
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( serial-number nil :type integer ) ;This type's unique serial number
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( kind nil :type typekind :read-only t ) ;This type's kind
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( tag nil :read-only t ) ;This type's tag; ordered list of tags for bit-set;
; ; set of included subsets represented as a sorted list of integers for restricted-set
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( parameters nil :type list :read-only t ) ;List of parameter types (either types or symbols if forward-referenced) describing a compound type
( =-name nil :type symbol ) ;Lazily computed name of a function that compares two values of this type for equality; nil if not known yet
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( /=-name nil :type symbol ) ;Name of a function that complements = or nil if none
( order-alist nil ) ;Either nil or an association list ((< . t<) (> . t>) (<= . t<=) (>= . t>=)) where the t's are order functions for this type
( range-set-encode nil :type symbol ) ;Either nil or the name of a function that converts an instance of this type to an integer for storage in a range-set
( range-set-decode nil :type symbol ) ) ;Either nil or the name of a function that reverses the range-set-encode conversion
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( declaim ( inline make-->-type ) )
( defun make-->-type ( world argument-types result-type )
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( make-type world :-> nil ( cons result-type argument-types ) nil nil ) )
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( declaim ( inline ->-argument-types ) )
( defun ->-argument-types ( type )
( assert-true ( eq ( type-kind type ) :-> ) )
( cdr ( type-parameters type ) ) )
( declaim ( inline ->-result-type ) )
( defun ->-result-type ( type )
( assert-true ( eq ( type-kind type ) :-> ) )
( car ( type-parameters type ) ) )
( declaim ( inline make-vector-type ) )
( defun make-vector-type ( world element-type )
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( if ( eq element-type ( world-char16-type world ) )
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( world-string-type world )
( make-type world :vector nil ( list element-type ) nil nil ) ) )
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( declaim ( inline vector-element-type ) )
( defun vector-element-type ( type )
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( assert-true ( member ( type-kind type ) ' ( :vector :string ) ) )
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( car ( type-parameters type ) ) )
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( declaim ( inline make-list-set-type ) )
( defun make-list-set-type ( world element-type )
( make-type world :list-set nil ( list element-type ) nil nil ) )
( declaim ( inline make-range-set-type ) )
( defun make-range-set-type ( world element-type )
( make-type world :range-set nil ( list element-type ) intset=-name nil ) )
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( defun make-bit-set-type ( world tags )
( let ( ( element-type ( make-union-type world ( mapcar #' ( lambda ( tag ) ( make-tag-type world tag ) ) tags ) ) ) )
( make-type world :bit-set tags ( list element-type ) '= '/= ) ) )
; values must be sorted in ascending numerical order.
( defun make-restricted-set-type ( world bit-set-type values )
( assert-true ( bit-set-type? bit-set-type ) )
( if ( endp values )
( world-bottom-type world )
( progn
( when *value-asserts*
( let ( ( prev -1 ) )
( dolist ( v values )
( unless ( and ( integerp v ) ( > v prev ) )
( error "Bad restricted-set set of values: ~S" values ) )
( setq prev v ) )
( unless ( < prev ( ash 1 ( length ( type-tag bit-set-type ) ) ) )
( error "Bad restricted-set set of values: ~S" values ) ) ) )
( if ( = ( length values ) ( ash 1 ( length ( type-tag bit-set-type ) ) ) )
bit-set-type
( make-type world :restricted-set values ( list bit-set-type ) '= '/= ) ) ) ) )
; Return the bit-set type underlying a bit-set or restricted-set.
( defun underlying-bit-set-type ( type )
( ecase ( type-kind type )
( :bit-set type )
( :restricted-set ( first ( type-parameters type ) ) ) ) )
; Return the ordered list of keywords in a bit-set or restricted-set type.
( defun set-type-keywords ( type )
( ecase ( type-kind type )
( :bit-set ( mapcar #' tag-name ( type-tag type ) ) )
( :restricted-set ( set-type-keywords ( first ( type-parameters type ) ) ) ) ) )
( defun bit-set-type? ( v )
( and ( type? v ) ( eq ( type-kind v ) :bit-set ) ) )
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( defun set-element-type ( type )
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( ecase ( type-kind type )
( ( :list-set :range-set :bit-set ) ( first ( type-parameters type ) ) )
( :restricted-set ( set-element-type ( first ( type-parameters type ) ) ) ) ) )
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( defun collection-element-type ( type )
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( ecase ( type-kind type )
( ( :vector :string :list-set :range-set :bit-set ) ( first ( type-parameters type ) ) )
( :restricted-set ( set-element-type ( first ( type-parameters type ) ) ) ) ) )
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( declaim ( inline make-tag-type ) )
( defun make-tag-type ( world tag )
( make-type world :tag tag nil ( tag-=-name tag ) nil ) )
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( declaim ( inline always-true ) )
( defun always-true ( a b )
( declare ( ignore a b ) )
t )
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( declaim ( inline always-false ) )
( defun always-false ( a b )
( declare ( ignore a b ) )
nil )
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( declaim ( inline make-denormalized-tag-type ) )
( defun make-denormalized-tag-type ( world tag )
( assert-true ( tag-keyword tag ) )
( make-type world :denormalized-tag tag nil 'always-true 'always-false ) )
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( declaim ( inline make-writable-cell-type ) )
( defun make-writable-cell-type ( world element-type )
( make-type world :writable-cell nil ( list element-type ) nil nil ) )
( declaim ( inline writable-cell-element-type ) )
( defun writable-cell-element-type ( type )
( assert-true ( eq ( type-kind type ) :writable-cell ) )
( car ( type-parameters type ) ) )
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( declaim ( inline make-delay-type ) )
( defun make-delay-type ( world type )
( make-type world :delay nil ( list type ) nil nil ) )
( declaim ( inline delay-element-type ) )
( defun delay-element-type ( type )
( assert-true ( eq ( type-kind type ) :delay ) )
( car ( type-parameters type ) ) )
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; Return the type's tag if it has one.
; The types float32 and float64 are considered to have fake tags that have one field, named "value", at position -1.
; Return nil if the type is not one of the above.
( defun type-pseudo-tag ( world type )
( case ( type-kind type )
( :tag ( type-tag type ) )
( :finite32 ( world-finite32-tag world ) )
( :finite64 ( world-finite64-tag world ) ) ) )
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; Return true if the type is a tag type or a union of tag types all of which have a field with
; the given label.
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( defun type-has-field ( world type label )
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( flet ( ( test ( type )
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( let ( ( tag ( type-pseudo-tag world type ) ) )
( and tag ( tag-find-field tag label ) ) ) ) )
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( case ( type-kind type )
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( ( :tag :finite32 :finite64 ) ( test type ) )
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( :union ( every #' test ( type-parameters type ) ) ) ) ) )
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; Equivalent types are guaranteed to be eq to each other.
( declaim ( inline type= ) )
( defun type= ( type1 type2 )
( eq type1 type2 ) )
; code is a lisp expression that evaluates to either :true or :false.
; Return a lisp expression that evaluates code and returns either t or nil.
( defun bool-unboxing-code ( code )
( if ( constantp code )
( ecase code
( :true t )
( :false nil ) )
( list 'eq code :true ) ) )
; code is a lisp expression that evaluates to either non-nil or nil.
; Return a lisp expression that evaluates code and returns either :true or :false.
( defun bool-boxing-code ( code )
( if ( constantp code )
( ecase code
( ( t ) :true )
( ( nil ) :false ) )
( list 'if code :true :false ) ) )
; code is a lisp expression that evaluates to a value of type type.
; If type is the same or more specific (i.e. a subtype) than supertype, return code that evaluates code
; and returns its value coerced to supertype.
; Signal an error if type is not a subtype of supertype. expr contains the source code that generated code
; and is used for error reporting only.
;
; Coercions from :denormalized-tag types are not implemented, but they should not be necessary in practice.
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; Coercions from vectors to strings or from strings to vectors are not implemented either.
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( defun widening-coercion-code ( world supertype type code expr )
( if ( type= type supertype )
code
( flet ( ( type-mismatch ( )
( error "Expected type ~A for ~:W but got type ~A"
( print-type-to-string supertype )
expr
( print-type-to-string type ) ) ) )
( let ( ( kind ( type-kind type ) ) )
( if ( eq kind :bottom )
code
( case ( type-kind supertype )
( :boolean
( if ( or ( type= type ( world-false-type world ) )
( type= type ( world-true-type world ) )
( type= type ( world-boxed-boolean-type world ) ) )
( bool-unboxing-code code )
( type-mismatch ) ) )
( :rational
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( if ( eq kind :integer )
code
( type-mismatch ) ) )
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( :union
( let ( ( supertype-types ( type-parameters supertype ) ) )
( case kind
( :boolean
( if ( and ( member ( world-false-type world ) supertype-types ) ( member ( world-true-type world ) supertype-types ) )
( bool-boxing-code code )
( type-mismatch ) ) )
( :integer
( if ( or ( member type supertype-types ) ( member ( world-rational-type world ) supertype-types ) )
code
( type-mismatch ) ) )
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( ( :rational :finite32 :finite64 :char16 :supplementary-char :-> :string :tag )
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( if ( member type supertype-types )
code
( type-mismatch ) ) )
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( ( :vector :list-set )
( let ( ( super-collection-type ( find kind supertype-types :key #' type-kind ) ) )
( if super-collection-type
( widening-coercion-code world super-collection-type type code expr )
( type-mismatch ) ) ) )
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( :union
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( dolist ( type-type ( type-parameters type ) )
( unless ( case ( type-kind type-type )
( :integer ( or ( member type-type supertype-types ) ( member ( world-rational-type world ) supertype-types ) ) )
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( ( :rational :finite32 :finite64 :char16 :supplementary-char :-> :string :tag :vector :list-set ) ( member type-type supertype-types ) ) )
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( type-mismatch ) ) )
code )
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( t ( type-mismatch ) ) ) ) )
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( ( :vector :list-set )
( unless ( eq kind ( type-kind supertype ) )
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( type-mismatch ) )
( let* ( ( par ( gensym "PAR" ) )
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( element-coercion-code ( widening-coercion-code world ( collection-element-type supertype ) ( collection-element-type type ) par expr ) ) )
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( if ( eq element-coercion-code par )
code
` ( mapcar #' ( lambda ( , par ) , element-coercion-code ) code ) ) ) )
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( :->
( unless ( eq kind :-> )
( type-mismatch ) )
( let ( ( supertype-arguments ( ->-argument-types supertype ) )
( type-arguments ( ->-argument-types type ) ) )
( unless ( = ( length supertype-arguments ) ( length type-arguments ) )
( type-mismatch ) )
( mapc #' ( lambda ( supertype-argument type-argument )
( unless ( eq ( widening-coercion-code world type-argument supertype-argument 'test 'test ) 'test )
( error "Nontrivial type coercions of -> arguments are not supported yet" ) ) )
supertype-arguments type-arguments )
( unless ( eq ( widening-coercion-code world ( ->-result-type supertype ) ( ->-result-type type ) 'test 'test ) 'test )
( error "Nontrivial type coercion of -> result is not supported yet" ) ) )
code )
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( :delay
( if ( eq kind :delay )
( let ( ( code2 ( widening-coercion-code world ( delay-element-type supertype ) ( delay-element-type type ) code expr ) ) )
( unless ( equal code code2 )
( error "Nontrivial type coercion of delay result is not supported yet" ) )
code2 )
( widening-coercion-code world ( delay-element-type supertype ) type code expr ) ) )
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( t ( type-mismatch ) ) ) ) ) ) ) )
; Return the list of constituent types that the given type would have if it were a union.
; The result is sorted by ascending serial numbers and contains no duplicates.
( defun type-to-union ( world type )
( ecase ( type-kind type )
( :boolean ( type-parameters ( world-boxed-boolean-type world ) ) )
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( ( :integer :rational :finite32 :finite64 :char16 :supplementary-char :-> :string :vector :list-set :tag ) ( list type ) )
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( :denormalized-tag ( make-tag-type world ( type-tag type ) ) )
( :union ( type-parameters type ) ) ) )
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; Return the type's serial number, except that types with kind :-> are given the serial number -1
; and :vector and :list-set -2.
( defun type-union-serial-number ( type )
( or ( cdr ( assoc ( type-kind type ) ' ( ( :-> . -1 ) ( :vector . -2 ) ( :list-set . -2 ) ) ) )
( type-serial-number type ) ) )
; Merge the two lists of types sorted by ascending serial numbers, except that types with kind :-> are given the serial number -1
; and :vector and :list-set -2.
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; The result is also sorted by ascending serial numbers and contains no duplicates.
( defun merge-type-lists ( types1 types2 )
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( cond
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( ( endp types1 ) types2 )
( ( endp types2 ) types1 )
( t ( let ( ( type1 ( first types1 ) )
( type2 ( first types2 ) ) )
( if ( type= type1 type2 )
( cons type1 ( merge-type-lists ( rest types1 ) ( rest types2 ) ) )
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( let ( ( serial-number1 ( type-union-serial-number type1 ) )
( serial-number2 ( type-union-serial-number type2 ) ) )
( when ( = serial-number1 serial-number2 )
( error "Duplicate function, vector, or set subtype of union: ~S ~S" type1 type2 ) )
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( if ( < serial-number1 serial-number2 )
( cons type1 ( merge-type-lists ( rest types1 ) types2 ) )
( cons type2 ( merge-type-lists types1 ( rest types2 ) ) ) ) ) ) ) ) ) )
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; Intersect the two lists of types sorted by ascending serial numbers, except that types with kind :-> are given the serial number -1
; and :vector and :list-set -2.
; The result is also sorted by ascending serial numbers and contains no duplicates.
( defun intersect-type-lists ( types1 types2 )
( remove-if-not #' ( lambda ( type1 ) ( member type1 types2 ) ) types1 ) )
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; Return true if the list of types is sorted by serial number, except that types with kind :-> are given the serial number -1
; and :vector and :list-set -2.
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( defun type-list-sorted ( types )
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( let ( ( n ( type-union-serial-number ( first types ) ) ) )
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( dolist ( type ( rest types ) t )
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( let ( ( n2 ( type-union-serial-number type ) ) )
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( unless ( < n n2 )
( return nil ) )
( setq n n2 ) ) ) ) )
( defun coercable-to-union-kind ( kind )
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( member kind ' ( :boolean :integer :rational :finite32 :finite64 :char16 :supplementary-char :-> :string :vector :list-set :tag :denormalized-tag :union ) ) )
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; types is a list of distinct, non-overlapping types appropriate for inclusion in a union and
; sorted by increasing serial numbers. Return the union type for holding types, reducing it to
; a simpler type as necessary. If normalize is nil, don't change the representation of the destination type.
( defun reduce-union-type ( world types normalize )
( cond
( ( endp types ) ( world-bottom-type world ) )
( ( endp ( cdr types ) ) ( car types ) )
( ( and ( endp ( cddr types ) ) ( member ( world-true-type world ) types ) ( member ( world-false-type world ) types ) )
( if normalize
( world-boolean-type world )
( world-boxed-boolean-type world ) ) )
( ( every #' ( lambda ( type ) ( eq ( type-=-name type ) 'eq ) ) types )
( make-type world :union nil types 'eq nil ) )
( ( every #' ( lambda ( type ) ( member ( type-=-name type ) ' ( eq eql = char= ) ) ) types )
( make-type world :union nil types 'eql nil ) )
( t ( make-type world :union nil types nil nil ) ) ) )
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; Return the union U of type1 and type2. Note that a value of type1 or type2 might need to be coerced to
; be treated as a member of type U.
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( defun type-union ( world type1 type2 )
( labels
( ( numeric-kind ( kind )
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( member kind ' ( :integer :rational ) ) )
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( numeric-type ( type )
( numeric-kind ( type-kind type ) ) ) )
( if ( type= type1 type2 )
type1
( let ( ( kind1 ( type-kind type1 ) )
( kind2 ( type-kind type2 ) ) )
( cond
( ( eq kind1 :bottom ) type2 )
( ( eq kind2 :bottom ) type1 )
( ( and ( numeric-kind kind1 ) ( numeric-kind kind2 ) ) ( world-rational-type world ) )
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( ( and ( eq kind1 :vector ) ( eq kind2 :vector ) )
( make-vector-type world ( type-union world ( vector-element-type type1 ) ( vector-element-type type2 ) ) ) )
( ( and ( eq kind1 :list-set ) ( eq kind2 :list-set ) )
( make-list-set-type world ( type-union world ( set-element-type type1 ) ( set-element-type type2 ) ) ) )
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( ( and ( coercable-to-union-kind kind1 ) ( coercable-to-union-kind kind2 ) )
( let ( ( types ( merge-type-lists ( type-to-union world type1 ) ( type-to-union world type2 ) ) ) )
( when ( > ( count-if #' numeric-type types ) 1 )
;Currently the union of any two or more different numeric types is always rational.
( setq types ( merge-type-lists ( remove-if #' numeric-type types ) ( list ( world-rational-type world ) ) ) ) )
( assert-true ( type-list-sorted types ) )
( reduce-union-type world types t ) ) )
( t ( error "No union of types ~A and ~A" ( print-type-to-string type1 ) ( print-type-to-string type2 ) ) ) ) ) ) ) )
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; Return the most specific common supertype of the types. Note that a value of one of the given types may need to be
; coerced to be treated as a member of type U.
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; If any of the types is not a type structure, then return a nested list of two-element unions like '(union <type1> <type2>).
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( defun make-union-type ( world &rest types )
( if types
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( reduce #' ( lambda ( type1 type2 )
( if ( and ( type? type1 ) ( type? type2 ) )
( type-union world type1 type2 )
( list 'union type1 type2 ) ) )
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types )
( world-bottom-type world ) ) )
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; Return the intersection I of type1 and type2. Note that a value of type I might need to be coerced to
; be treated as a member of type1 or type2.
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; Not all intersections have been implemented yet, and some are too conservative, returning a smaller type than the exact intersection.
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( defun type-intersection ( world type1 type2 )
( if ( type= type1 type2 )
type1
( let ( ( kind1 ( type-kind type1 ) )
( kind2 ( type-kind type2 ) ) )
( cond
( ( eq kind1 :bottom ) type1 )
( ( eq kind2 :bottom ) type2 )
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( ( and ( or ( eq kind1 :union ) ( eq kind2 :union ) )
( coercable-to-union-kind kind1 ) ( coercable-to-union-kind kind2 ) )
( reduce-union-type world ( intersect-type-lists ( type-to-union world type1 ) ( type-to-union world type2 ) ) t ) )
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( t ( error "No intersection of types ~A and ~A" ( print-type-to-string type1 ) ( print-type-to-string type2 ) ) ) ) ) ) )
; Return the most specific common supertype of the types. Note that a value of the intersection type may need to be
; coerced to be treated as a member of one of the given types.
( defun make-intersection-type ( world &rest types )
( assert-true types )
( reduce #' ( lambda ( type1 type2 ) ( type-intersection world type1 type2 ) )
types ) )
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; Ensure that subtype is a subtype of type. subtype must not be the bottom type.
; Return two values:
; subtype1, a type that is equivalent to subtype but may be denormalized.
; subtype2, the type containing the instances of type but not subtype.
; Any concrete value of type will have either subtype1 or subtype2 without needing coercion.
; subtype1 and subtype2 may be denormalized in the following cases:
; type is boolean and subtype is (tag true) or (tag false);
; type is a union and subtype is boolean.
; Signal an error if there is no subtype2.
( defun type-difference ( world type subtype )
( flet ( ( type-mismatch ( )
( error "Cannot subtract type ~A from type ~A" ( print-type-to-string subtype ) ( print-type-to-string type ) ) ) )
( if ( type= type subtype )
( if ( type= subtype ( world-bottom-type world ) )
( type-mismatch )
( values type ( world-bottom-type world ) ) )
( case ( type-kind type )
( :boolean
( cond
( ( or ( type= subtype ( world-false-type world ) ) ( type= subtype ( world-denormalized-false-type world ) ) )
( values ( world-denormalized-false-type world ) ( world-denormalized-true-type world ) ) )
( ( or ( type= subtype ( world-true-type world ) ) ( type= subtype ( world-denormalized-true-type world ) ) )
( values ( world-denormalized-true-type world ) ( world-denormalized-false-type world ) ) )
( ( type= subtype ( world-boxed-boolean-type world ) )
( values type ( world-bottom-type world ) ) )
( t ( type-mismatch ) ) ) )
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( :rational
( if ( type= subtype ( world-integer-type world ) )
( values subtype 'fractional )
( type-mismatch ) ) )
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( :tag
( if ( and ( eq ( type-kind subtype ) :denormalized-tag ) ( eq ( type-tag type ) ( type-tag subtype ) ) )
( values type ( world-bottom-type world ) )
( type-mismatch ) ) )
( :denormalized-tag
( if ( and ( eq ( type-kind subtype ) :tag ) ( eq ( type-tag type ) ( type-tag subtype ) ) )
( values type ( world-bottom-type world ) )
( type-mismatch ) ) )
( :union
( let ( ( types ( type-parameters type ) ) )
( flet
( ( remove-subtype ( subtype )
( unless ( member subtype types )
( type-mismatch ) )
( setq types ( remove subtype types ) ) ) )
( case ( type-kind subtype )
( :boolean
( remove-subtype ( world-false-type world ) )
( remove-subtype ( world-true-type world ) )
( setq subtype ( world-boxed-boolean-type world ) ) )
( :union
( mapc #' remove-subtype ( type-parameters subtype ) ) )
( :denormalized-tag
( remove-subtype ( make-tag-type world ( type-tag subtype ) ) ) )
( t ( remove-subtype subtype ) ) )
( values subtype ( reduce-union-type world types nil ) ) ) ) )
( t ( type-mismatch ) ) ) ) ) )
; types must be a list of types suitable for inclusion in a :union type's parameters. Return the following values:
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; a list of integerp, rationalp, finite32?, finite64?, characterp, functionp, stringp, and/or listp depending on whether types include the
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; :integer, :rational, :finite32, :finite64, :char16, :->, :string and/or :vector or :list-set member kinds;
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; a list of keywords used by non-list tags in the types;
; a list of tag names used by list tags in the types
( defun analyze-union-types ( types )
( let ( ( atom-tests nil )
( keywords nil )
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( list-tag-names nil )
( has-listp nil ) )
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( dolist ( type types )
( ecase ( type-kind type )
( :integer ( push 'integerp atom-tests ) )
( :rational ( push 'rationalp atom-tests ) )
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( :finite32 ( push 'finite32? atom-tests ) )
( :finite64 ( push 'finite64? atom-tests ) )
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( :char16 ( push 'characterp atom-tests ) )
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( :-> ( push 'functionp atom-tests ) )
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( :string ( push 'stringp atom-tests ) )
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( ( :vector :list-set )
( when has-listp
( error "Unable to discriminate among the constituents in the union ~S" types ) )
( setq has-listp t )
( push 'listp atom-tests ) )
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( :tag ( let* ( ( tag ( type-tag type ) )
( keyword ( tag-keyword tag ) ) )
( if keyword
( push keyword keywords )
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( push ( tag-name tag ) list-tag-names ) ) ) )
( :supplementary-char ( push :supplementary-char list-tag-names ) ) ) )
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( when ( and has-listp list-tag-names )
( error "Unable to discriminate among the constituents in the union ~S" types ) )
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( values
( nreverse atom-tests )
( nreverse keywords )
( nreverse list-tag-names ) ) ) )
; code is a lisp expression that evaluates to a value of type type. subtype is a subtype of type, which
; has already been verified by calling type-difference.
; Return a lisp expression that may evaluate code and returns non-nil if the value is a member of the subtype.
; The expression may evaluate code more than once or not at all.
( defun type-member-test-code ( world subtype type code )
( if ( type= type subtype )
t
( ecase ( type-kind type )
( :boolean
( cond
( ( or ( type= subtype ( world-false-type world ) ) ( type= subtype ( world-denormalized-false-type world ) ) )
( list 'not code ) )
( ( or ( type= subtype ( world-true-type world ) ) ( type= subtype ( world-denormalized-true-type world ) ) )
code )
( t ( error "Bad type-member-test-code" ) ) ) )
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( :rational
( if ( type= subtype ( world-integer-type world ) )
( list 'integerp code )
( error "Bad type-member-test-code" ) ) )
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( ( :tag :denormalized-tag ) t )
( :union
( multiple-value-bind ( type-atom-tests type-keywords type-list-tag-names ) ( analyze-union-types ( type-parameters type ) )
( multiple-value-bind ( subtype-atom-tests subtype-keywords subtype-list-tag-names )
( case ( type-kind subtype )
( :boolean ( values nil ( list :false :true ) nil ) )
( :union ( analyze-union-types ( type-parameters subtype ) ) )
( :denormalized-tag ( analyze-union-types ( list ( make-tag-type world ( type-tag subtype ) ) ) ) )
( t ( analyze-union-types ( list subtype ) ) ) )
( assert-true ( and ( subsetp subtype-atom-tests type-atom-tests )
( subsetp subtype-keywords type-keywords )
( subsetp subtype-list-tag-names type-list-tag-names ) ) )
( gen-poly-op 'or nil
( nconc
( mapcar #' ( lambda ( atom-test ) ( list atom-test code ) ) subtype-atom-tests )
( and subtype-keywords ( list ( gen-member-test code subtype-keywords ) ) )
( and subtype-list-tag-names
( list ( gen-poly-op 'and t
( nconc
( and ( or type-atom-tests type-keywords ) ( list ( list 'consp code ) ) )
( list ( gen-member-test ( list 'car code ) subtype-list-tag-names ) ) ) ) ) ) ) ) ) ) ) ) ) )
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; Print the type nicely on the given stream. If expand1 is true then print
; the type's top level even if it has a name. In all other cases expand
; anonymous types but abbreviate named types by their names.
( defun print-type ( type &optional ( stream t ) expand1 )
( if ( and ( type-name type ) ( not expand1 ) )
( write-string ( symbol-name ( type-name type ) ) stream )
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( case ( type-kind type )
( :bottom ( write-string "bottom" stream ) )
( :void ( write-string "void" stream ) )
( :boolean ( write-string "boolean" stream ) )
( :integer ( write-string "integer" stream ) )
( :rational ( write-string "rational" stream ) )
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( :finite32 ( write-string "finite32" stream ) )
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( :finite64 ( write-string "finite64" stream ) )
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( :char16 ( write-string "char16" stream ) )
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( :supplementary-char ( write-string "supplementary-char" stream ) )
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( :-> ( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( format stream "-> ~@_" )
( pprint-indent :current 0 stream )
( pprint-logical-block ( stream ( ->-argument-types type ) :prefix "(" :suffix ")" )
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( pprint-exit-if-list-exhausted )
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( loop
( print-type ( pprint-pop ) stream )
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( pprint-exit-if-list-exhausted )
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( format stream " ~:_" ) ) )
( format stream " ~_" )
( print-type ( ->-result-type type ) stream ) ) )
( :string ( write-string "string" stream ) )
( :vector ( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( format stream "vector ~@_" )
( print-type ( vector-element-type type ) stream ) ) )
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( :list-set ( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( format stream "list-set ~@_" )
( print-type ( set-element-type type ) stream ) ) )
( :range-set ( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( format stream "range-set ~@_" )
( print-type ( set-element-type type ) stream ) ) )
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( :bit-set ( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( format stream "bit-set" )
( dolist ( keyword ( set-type-keywords type ) )
( format stream " ~:_~A" keyword ) ) ) )
( :restricted-set ( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( format stream "restricted-set" )
( dolist ( keyword ( set-type-keywords type ) )
( format stream " ~:_~A" keyword ) )
( format stream " ~_" )
( pprint-logical-block ( stream ( type-tag type ) :prefix "{" :suffix "}" )
( pprint-exit-if-list-exhausted )
( loop
( print-value ( pprint-pop ) type stream )
( pprint-exit-if-list-exhausted )
( format stream " ~:_" ) ) ) ) )
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( :tag ( let ( ( tag ( type-tag type ) ) )
( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( format stream "tag ~@_~A" ( tag-name tag ) ) ) ) )
( :union ( pprint-logical-block ( stream ( type-parameters type ) :prefix "(" :suffix ")" )
( write-string "union" stream )
( pprint-exit-if-list-exhausted )
( format stream " ~@_" )
( pprint-indent :current 0 stream )
( loop
( print-type ( pprint-pop ) stream )
( pprint-exit-if-list-exhausted )
( format stream " ~:_" ) ) ) )
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( :writable-cell ( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( format stream "writable-cell ~@_" )
( print-type ( writable-cell-element-type type ) stream ) ) )
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( :delay ( pprint-logical-block ( stream nil :prefix "(" :suffix ")" )
( format stream "delay ~@_" )
( print-type ( delay-element-type type ) stream ) ) )
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( t ( error "Bad typekind ~S" ( type-kind type ) ) ) ) ) )
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; Same as print-type except that accumulates the output in a string
; and returns that string.
( defun print-type-to-string ( type &optional expand1 )
( with-output-to-string ( stream )
( print-type type stream expand1 ) ) )
( defmethod print-object ( ( type type ) stream )
( print-unreadable-object ( type stream )
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( format stream "type~D ~@_" ( type-serial-number type ) )
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( let ( ( name ( type-name type ) ) )
( when name
( format stream "~A = ~@_" name ) ) )
( print-type type stream t ) ) )
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; Create or reuse a type with the given kind, tag, and parameters.
; A type is reused if one already exists with equal kind, tag, and parameters.
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; Return the type.
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( defun make-type ( world kind tag parameters =-name /=-name )
( let ( ( reverse-key ( list kind tag parameters ) ) )
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( or ( gethash reverse-key ( world-types-reverse world ) )
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( let ( ( type ( allocate-type ( world-next-type-serial-number world ) kind tag parameters =-name /=-name ) ) )
( incf ( world-next-type-serial-number world ) )
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( setf ( gethash reverse-key ( world-types-reverse world ) ) type ) ) ) ) )
; Provide a new symbol for the type. A type can have zero or more names.
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; If forward-referenced, type may be a symbol or a list of the form (union <type> <type>).
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; Signal an error if the name is already used.
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; user-defined is true if this is a user-defined type rather than a predefined type.
( defun add-type-name ( world type symbol user-defined )
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( assert-true ( symbol-in-world world symbol ) )
( when ( symbol-type-definition symbol )
( error "Attempt to redefine type ~A" symbol ) )
;If the old type was anonymous, give it this name.
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( when ( and ( type? type ) ( not ( type-name type ) ) )
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( setf ( type-name type ) symbol ) )
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( setf ( symbol-type-definition symbol ) type )
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( when user-defined
( setf ( symbol-type-user-defined symbol ) t ) )
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( export-symbol symbol ) )
; Return an existing type with the given symbol, which must be interned in a world's package.
; Signal an error if there isn't an existing type. If allow-forward-references is true and
; symbol is an undefined type identifier, allow it, create a forward-referenced type, and return symbol.
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( defun get-type ( symbol allow-forward-references )
( let ( ( type ( symbol-type-definition symbol ) ) )
( cond
( ( type? type ) type )
( ( not allow-forward-references ) ( error "Undefined type ~A with value ~S" symbol type ) )
( t ( unless type
( setf ( symbol-type-definition symbol ) nil ) )
symbol ) ) ) )
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; Scan a type-expr to produce a type. Return that type.
; If allow-forward-references is true and type-expr is an undefined type identifier,
; allow it, create a forward-referenced type in the world, and return type-expr unchanged.
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; If allow-forward-references is true, also allow undefined type identifiers deeper within type-expr.
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; If type-expr is already a type, return it unchanged.
( defun scan-type ( world type-expr &optional allow-forward-references )
( cond
( ( identifier? type-expr )
( get-type ( world-intern world type-expr ) allow-forward-references ) )
( ( type? type-expr )
type-expr )
( t ( let ( ( type-constructor ( and ( consp type-expr )
( symbolp ( first type-expr ) )
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( get ( world-find-symbol world ( first type-expr ) ) :type-constructor ) ) ) )
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( if type-constructor
( apply type-constructor world allow-forward-references ( rest type-expr ) )
( error "Bad type ~S" type-expr ) ) ) ) ) )
; Same as scan-type except that ensure that the type has the expected kind.
; Return the type.
( defun scan-kinded-type ( world type-expr expected-type-kind )
( let ( ( type ( scan-type world type-expr ) ) )
( unless ( eq ( type-kind type ) expected-type-kind )
( error "Expected ~(~A~) but got ~A" expected-type-kind ( print-type-to-string type ) ) )
type ) )
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; (integer-list <value> ... <value>)
; Each <value> must be a constant expression.
; ***** Currently the lists are not checked, so this type is equivalent to integer except for display purposes.
( defun scan-integer-list ( world allow-forward-references &rest value-exprs )
( declare ( ignore allow-forward-references ) )
( when ( endp value-exprs )
( error "Integer list type must have at least one element" ) )
( let* ( ( integer-type ( world-integer-type world ) )
( values ( mapcar #' ( lambda ( value-expr ) ( eval ( scan-typed-value world ( make-type-env nil nil ) value-expr integer-type ) ) )
value-exprs ) ) )
( unless ( every #' integerp values )
( error "Bad integer list ~S" value-exprs ) )
integer-type ) )
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; (integer-range <low-limit> <high-limit>)
; <low-limit> and <high-limit> must be constant expressions.
; ***** Currently the ranges are not checked, so this type is equivalent to integer except for display purposes.
( defun scan-integer-range ( world allow-forward-references low-limit-expr high-limit-expr )
( declare ( ignore allow-forward-references ) )
( let* ( ( integer-type ( world-integer-type world ) )
( low-limit ( eval ( scan-typed-value world ( make-type-env nil nil ) low-limit-expr integer-type ) ) )
( high-limit ( eval ( scan-typed-value world ( make-type-env nil nil ) high-limit-expr integer-type ) ) ) )
( unless ( and ( integerp low-limit ) ( integerp high-limit ) ( <= low-limit high-limit ) )
( error "Bad integer range ~S .. ~S" low-limit-expr high-limit-expr ) )
integer-type ) )
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; (exclude-zero <type>)
; ***** Currently the exclusion is not checked, so this type is equivalent to <type> except for display purposes.
( defun scan-exclude-zero ( world allow-forward-references type-expr )
( scan-type world type-expr allow-forward-references ) )
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; (-> (<arg-type1> ... <arg-typen>) <result-type>)
( defun scan--> ( world allow-forward-references arg-type-exprs result-type-expr )
( unless ( listp arg-type-exprs )
( error "Bad -> argument type list ~S" arg-type-exprs ) )
( make-->-type world
( mapcar #' ( lambda ( te ) ( scan-type world te allow-forward-references ) ) arg-type-exprs )
( scan-type world result-type-expr allow-forward-references ) ) )
; (vector <element-type>)
( defun scan-vector ( world allow-forward-references element-type )
( make-vector-type world ( scan-type world element-type allow-forward-references ) ) )
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; (list-set <element-type>)
( defun scan-list-set ( world allow-forward-references element-type )
( make-list-set-type world ( scan-type world element-type allow-forward-references ) ) )
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; (range-set <element-type>)
( defun scan-range-set ( world allow-forward-references element-type )
( make-range-set-type world ( scan-type world element-type allow-forward-references ) ) )
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; (bit-set <tag> ... <tag>)
( defun scan-bit-set ( world allow-forward-references &rest tag-names )
( declare ( ignore allow-forward-references ) )
( make-bit-set-type world ( mapcar #' ( lambda ( tag-name )
( let ( ( tag ( scan-tag world tag-name ) ) )
( unless ( tag-keyword tag )
( error "Only singleton tags may be part of a bit-set" ) )
tag ) )
tag-names ) ) )
; (restricted-set <bit-set-type> <value-expr> ... <value-expr>)
( defun scan-restricted-set ( world allow-forward-references bit-set-type-expr &rest value-exprs )
( let ( ( bit-set-type ( scan-type world bit-set-type-expr allow-forward-references ) ) )
( unless ( bit-set-type? bit-set-type )
( error "~S must be a bit-set" bit-set-type-expr ) )
( let ( ( values ( mapcar #' ( lambda ( value-expr )
( assert-type ( eval-typed-value world value-expr bit-set-type ) integer ) )
value-exprs ) ) )
( setq values ( sort values #' < ) )
( let ( ( length1 ( length values ) ) )
( delete-adjacent-duplicates values :test #' = )
( unless ( = ( length values ) length1 )
( error "Duplicate restricted-set value in ~S" value-exprs ) ) )
( make-restricted-set-type world bit-set-type values ) ) ) )
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; (tag <tag> ... <tag>)
( defun scan-tag-type ( world allow-forward-references tag-name &rest tag-names )
( if tag-names
( apply #' make-union-type world ( mapcar #' ( lambda ( tag-name )
( scan-tag-type world allow-forward-references tag-name ) )
( cons tag-name tag-names ) ) )
( make-tag-type world ( scan-tag world tag-name ) ) ) )
; (union <type1> ... <typen>)
( defun scan-union ( world allow-forward-references &rest type-exprs )
( apply #' make-union-type world ( mapcar #' ( lambda ( type-expr )
( scan-type world type-expr allow-forward-references ) )
type-exprs ) ) )
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; (type-diff <type1> <type2>)
; Does not allow forward references in either operand.
( defun scan-type-diff ( world allow-forward-references type-expr1 type-expr2 )
( declare ( ignore allow-forward-references ) )
( let ( ( type1 ( scan-type world type-expr1 nil ) )
( type2 ( scan-type world type-expr2 nil ) ) )
( multiple-value-bind ( subtype1 subtype2 ) ( type-difference world type1 type2 )
( declare ( ignore subtype1 ) )
subtype2 ) ) )
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; (writable-cell <element-type>)
( defun scan-writable-cell ( world allow-forward-references element-type )
( make-writable-cell-type world ( scan-type world element-type allow-forward-references ) ) )
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; (delay <element-type>)
( defun scan-delay ( world allow-forward-references type )
( make-delay-type world ( scan-type world type allow-forward-references ) ) )
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; Resolve all forward type references to refer to their target types.
; Signal an error if any unresolved type references remain.
; Only types reachable from some type name are affected. It is the caller's
; responsibility to make sure that these are the only types that exist.
; Return a list of all type structures encountered.
( defun resolve-forward-types ( world )
( let ( ( visited-types ( make-hash-table :test #' eq ) ) )
( labels
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( ( resolve-type-symbol ( symbol type symbol-stack )
( cond
( ( type? type ) type )
( ( null type ) ( error "Undefined type ~A" symbol ) )
( ( member symbol symbol-stack )
( error "Recursive type forward reference ~S ~S" symbol symbol-stack ) )
( t ( let ( ( type ( resolve-type-expr type ( cons symbol symbol-stack ) ) ) )
( assert-true ( type? type ) )
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;If the old type was anonymous, give it this name.
( unless ( type-name type )
( setf ( type-name type ) symbol ) )
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( setf ( symbol-type-definition symbol ) type )
type ) ) ) )
( resolve-type-expr ( type symbol-stack )
( cond
( ( type? type ) type )
( ( symbolp type )
( resolve-type-symbol type ( symbol-type-definition type ) symbol-stack ) )
( ( structured-type? type ' ( tuple ( eql union ) t t ) )
( let ( ( type1 ( resolve-type-expr ( second type ) symbol-stack ) )
( type2 ( resolve-type-expr ( third type ) symbol-stack ) ) )
( type-union world type1 type2 ) ) )
( t ( error "Bad forward-referenced type ~S" type ) ) ) )
( resolve-type-parameters ( type )
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( unless ( gethash type visited-types )
( setf ( gethash type visited-types ) t )
( do ( ( parameter-types ( type-parameters type ) ( cdr parameter-types ) ) )
( ( endp parameter-types ) )
( let ( ( parameter-type ( car parameter-types ) ) )
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( unless ( type? parameter-type )
( setq parameter-type ( resolve-type-expr parameter-type nil ) )
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( setf ( car parameter-types ) parameter-type ) )
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( resolve-type-parameters parameter-type ) ) ) ) ) )
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( each-type-definition
world
#' ( lambda ( symbol type )
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( unless ( type? type )
( setq type ( resolve-type-symbol symbol type nil ) ) )
( resolve-type-parameters type ) ) ) )
( setf ( world-types-reverse world ) nil )
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( hash-table-keys visited-types ) ) )
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; Recompute the types-reverse hash table from the types in the types hash table and their constituents.
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( defun recompute-type-caches ( world )
( let ( ( types-reverse ( make-hash-table :test #' equal ) ) )
( labels
( ( visit-type ( type )
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( let ( ( reverse-key ( list ( type-kind type ) ( type-tag type ) ( type-parameters type ) ) ) )
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( assert-true ( eq ( gethash reverse-key types-reverse type ) type ) )
( unless ( gethash reverse-key types-reverse )
( setf ( gethash reverse-key types-reverse ) type )
( mapc #' visit-type ( type-parameters type ) ) ) ) ) )
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( visit-type ( world-denormalized-false-type world ) )
( visit-type ( world-denormalized-true-type world ) )
( visit-type ( world-boxed-boolean-type world ) )
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( each-type-definition
world
#' ( lambda ( symbol type )
( declare ( ignore symbol ) )
( visit-type type ) ) ) )
( setf ( world-types-reverse world ) types-reverse ) ) )
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; Return true if type1's serial-number is less than type2's serial-number;
; however, unnamed types' serial numbers are considered to be positive infinity.
( defun type-named-serial-number-< ( type1 type2 )
( let ( ( name1 ( if ( type-name type1 ) 0 1 ) )
( name2 ( if ( type-name type2 ) 0 1 ) ) )
( or ( < name1 name2 )
( and ( = name1 name2 )
( < ( type-serial-number type1 ) ( type-serial-number type2 ) ) ) ) ) )
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; Make all equivalent types be eq. Only types reachable from some type name
; are affected, and names may be redirected to different type structures than
; the ones to which they currently point. It is the caller's responsibility
; to make sure that there are no current outstanding references to types other
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; than via type names (except for types for which it can be guaranteed that
; their type structures are defined only once; this applies to types such as
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; integer and char16 but not (vector integer)).
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;
; This function calls resolve-forward-types before making equivalent types be eq
; and recompute-type-caches just before returning.
;
; This function works by initially assuming that all types with the same kind
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; and tag are the same type and then iterately determining which ones must be
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; different because they contain different parameter types.
( defun unite-types ( world )
( let* ( ( types ( resolve-forward-types world ) )
( n-types ( length types ) ) )
( labels
( ( gen-cliques-1 ( get-key )
( let ( ( types-to-cliques ( make-hash-table :test #' eq :size n-types ) )
( keys-to-cliques ( make-hash-table :test #' equal ) )
( n-cliques 0 ) )
( dolist ( type types )
( let* ( ( key ( funcall get-key type ) )
( clique ( gethash key keys-to-cliques ) ) )
( unless clique
( setq clique n-cliques )
( incf n-cliques )
( setf ( gethash key keys-to-cliques ) clique ) )
( setf ( gethash type types-to-cliques ) clique ) ) )
( values n-cliques types-to-cliques ) ) )
( gen-cliques ( n-old-cliques types-to-old-cliques )
( labels
( ( get-old-clique ( type )
( assert-non-null ( gethash type types-to-old-cliques ) ) )
( get-type-key ( type )
( cons ( get-old-clique type )
( mapcar #' get-old-clique ( type-parameters type ) ) ) ) )
( multiple-value-bind ( n-new-cliques types-to-new-cliques ) ( gen-cliques-1 #' get-type-key )
( assert-true ( >= n-new-cliques n-old-cliques ) )
( if ( /= n-new-cliques n-old-cliques )
( gen-cliques n-new-cliques types-to-new-cliques )
( translate-types n-new-cliques types-to-new-cliques ) ) ) ) )
( translate-types ( n-cliques types-to-cliques )
( let ( ( clique-representatives ( make-array n-cliques :initial-element nil ) ) )
( maphash #' ( lambda ( type clique )
( let ( ( representative ( svref clique-representatives clique ) ) )
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( when ( or ( null representative ) ( type-named-serial-number-< type representative ) )
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( setf ( svref clique-representatives clique ) type ) ) ) )
types-to-cliques )
( assert-true ( every #' identity clique-representatives ) )
( labels
( ( map-type ( type )
( svref clique-representatives ( gethash type types-to-cliques ) ) ) )
( dolist ( type types )
( do ( ( parameter-types ( type-parameters type ) ( cdr parameter-types ) ) )
( ( endp parameter-types ) )
( setf ( car parameter-types ) ( map-type ( car parameter-types ) ) ) ) )
( each-type-definition
world
#' ( lambda ( symbol type )
( setf ( symbol-type-definition symbol ) ( map-type type ) ) ) ) ) ) ) )
( multiple-value-call
#' gen-cliques
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( gen-cliques-1 #' ( lambda ( type ) ( cons ( type-kind type ) ( type-tag type ) ) ) ) )
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( recompute-type-caches world ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; COMPARISONS
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; Return (:test <type-equality-function>), simplifying to nil if the equality function is eql.
( defun element-test ( world type )
( let ( ( test ( get-type-=-name world type ) ) )
( if ( eq test 'eql )
nil
` ( :test #' , test ) ) ) )
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; Return non-nil if the values are equal. value1 and value2 must both belong to a union type.
( defun union= ( value1 value2 )
( or ( eql value1 value2 )
( and ( consp value1 ) ( consp value2 )
( let ( ( tag-name1 ( car value1 ) )
( tag-name2 ( car value2 ) ) )
( and ( eq tag-name1 tag-name2 )
( funcall ( get tag-name1 :tag= ) value1 value2 ) ) ) ) ) )
; Create an equality comparison function for elements of the given :vector type.
; Return the name of the function and also set it in the type.
( defun compute-vector-type-=-name ( world type )
( let ( ( element-type ( vector-element-type type ) ) )
( case ( type-kind element-type )
( ( :integer :rational ) ( setf ( type-=-name type ) 'equal ) )
( t ( let ( ( =-name ( gentemp ( format nil "~A_VECTOR_=" ( type-name element-type ) ) ( world-package world ) ) ) )
( setf ( type-=-name type ) =-name ) ;Must do this now to prevent runaway recursion.
( quiet-compile =-name ` ( lambda ( a b )
( and ( = ( length a ) ( length b ) )
( every #' , ( get-type-=-name world element-type ) a b ) ) ) )
=-name ) ) ) ) )
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; Create an equality comparison function for elements of the given :list-set type.
; Return the name of the function and also set it in the type.
( defun compute-list-set-type-=-name ( world type )
( let* ( ( element-type ( set-element-type type ) )
( =-name ( gentemp ( format nil "~A_LISTSET_=" ( type-name element-type ) ) ( world-package world ) ) ) )
( setf ( type-=-name type ) =-name ) ;Must do this now to prevent runaway recursion.
( quiet-compile =-name ` ( lambda ( a b )
( and ( = ( length a ) ( length b ) )
( subsetp a b ,@ ( element-test world element-type ) ) ) ) )
=-name ) )
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; Create an equality comparison function for elements of the given :tag type.
; Return the name of the function and also set it in the type, the tag, and the :tag= property of the tag-name.
( defun compute-tag-type-=-name ( world type )
( let ( ( tag ( type-tag type ) ) )
( assert-true ( null ( tag-=-name tag ) ) )
( labels
( ( fields-=-code ( fields )
( assert-true fields )
( let ( ( field-=-code ( cons ( get-type-=-name world ( field-type ( car fields ) ) ) ' ( ( car a ) ( car b ) ) ) ) )
( if ( cdr fields )
` ( and , field-=-code
( let ( ( a ( cdr a ) )
( b ( cdr b ) ) )
, ( fields-=-code ( cdr fields ) ) ) )
field-=-code ) ) ) )
( let* ( ( name ( tag-name tag ) )
( =-name ( world-intern world ( concatenate 'string ( string name ) "_=" ) ) ) )
( setf ( type-=-name type ) =-name ) ;Must do this now to prevent runaway recursion.
( let ( ( =-code ` ( lambda ( a b )
( let ( ( a ( cdr a ) )
( b ( cdr b ) ) )
, ( fields-=-code ( tag-fields tag ) ) ) ) ) )
( assert-true ( not ( fboundp =-name ) ) )
( quiet-compile =-name =-code )
( setf ( get name :tag= ) ( symbol-function =-name ) )
( setf ( tag-=-name tag ) =-name ) ) ) ) ) )
; Return the name of a function that compares two instances of this type and returns non-nil if they are equal.
; Signal an error if there is no such function.
; If the type is a tag, also set the :tag= property of the tag.
( defun get-type-=-name ( world type )
( or ( type-=-name type )
( case ( type-kind type )
( :vector ( compute-vector-type-=-name world type ) )
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( :list-set ( compute-list-set-type-=-name world type ) )
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( :tag ( compute-tag-type-=-name world type ) )
( :union
( setf ( type-=-name type ) 'union= ) ;Must do this now to prevent runaway recursion.
( dolist ( subtype ( type-parameters type ) )
( get-type-=-name world subtype ) ) ;Set the :tag= symbol properties.
'union= )
( t ( error "Can't apply = to instances of type ~S" ( print-type-to-string type ) ) ) ) ) )
; Return the name of a function that compares two instances of this type and returns non-nil if they satisfy the given
; order, which should be one of the symbols =, /=, <, >, <=, >=.
; Signal an error if there is no such function except for /=, in which case return nil.
( defun get-type-order-name ( world type order )
( ecase order
( = ( get-type-=-name world type ) )
( /= ( type-/=-name type ) )
( ( < > <= >= )
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( or ( cdr ( assoc order ( type-order-alist type ) ) )
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( error "Can't apply ~A to instances of type ~A" order ( print-type-to-string type ) ) ) ) ) )
; Return code to compare code expression a against b using the given order, which should be one of
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; the symbols =, /=, <, >, <=, >=, set<=.
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; Signal an error if this is not possible.
( defun get-type-order-code ( world type order a b )
( flet ( ( simple-constant? ( code )
( or ( keywordp code ) ( numberp code ) ( characterp code ) ) ) )
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( cond
( ( eq order 'set<= )
( unless ( eq ( type-kind type ) :list-set )
( error "set<= not implemented on type ~S" type ) )
( list* 'subsetp a b ( element-test world ( set-element-type type ) ) ) )
( t
( let ( ( order-name ( get-type-order-name world type order ) ) )
( cond
( ( null order-name )
( assert-true ( eq order '/= ) )
( list 'not ( get-type-order-code world type '= a b ) ) )
( ( and ( eq order-name 'union= ) ( or ( simple-constant? a ) ( simple-constant? b ) ) )
;Optimize union= comparisons against a non-list constant.
( list 'eql a b ) )
( t ( list order-name a b ) ) ) ) ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; SPECIALS
( defun checked-callable ( f )
( let ( ( fun ( callable f ) ) )
( unless fun
( warn "Undefined function ~S" f ) )
fun ) )
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; Add a command or special form definition. symbol is a symbol that names the
; preprocessor directive, command, or special form. When a semantic form
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; (id arg1 arg2 ... argn)
; is encountered and id is a symbol with the same name as symbol, the form is
; replaced by the result of calling one of:
; (expander preprocessor-state id arg1 arg2 ... argn) if property is :preprocess
; (expander world grammar-info-var arg1 arg2 ... argn) if property is :command
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; (expander world type-env rest last id arg1 arg2 ... argn) if property is :statement
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; (expander world type-env id arg1 arg2 ... argn) if property is :special-form or :condition
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; (expander world allow-forward-references arg1 arg2 ... argn) if property is :type-constructor
; expander must be a function or a function symbol.
;
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; In the case of the statement expander only, rest is a list of the remaining statements in the block;
; the statement expander should recursively expand the statements in rest.
; last is non-nil if this statement+rest's return value would pass through as the return value of the function;
; last allows optimization of lisp code to eliminate extraneous return-from statements.
;
; depictor is used instead of expander when emitting markup for the command or special form.
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; depictor is called via:
; (depictor markup-stream world depict-env arg1 arg2 ... argn) if property is :command
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; (depictor markup-stream world arg1 arg2 ... argn) if property is :statement
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; (depictor markup-stream world level arg1 arg2 ... argn) if property is :special-form
; (depictor markup-stream world level arg1 arg2 ... argn) if property is :type-constructor
;
( defun add-special ( property symbol expander &optional depictor )
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( let ( ( emit-property ( cdr ( assoc property ' ( ( :command . :depict-command )
( :statement . :depict-statement )
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( :special-form . :depict-special-form )
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( :condition )
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( :type-constructor . :depict-type-constructor ) ) ) ) ) )
( assert-true ( or emit-property ( not depictor ) ) )
( assert-type symbol identifier )
( when *value-asserts*
( checked-callable expander )
( when depictor ( checked-callable depictor ) ) )
( when ( or ( get symbol property ) ( and emit-property ( get symbol emit-property ) ) )
( error "Attempt to redefine ~A ~A" property symbol ) )
( setf ( get symbol property ) expander )
( when emit-property
( if depictor
( setf ( get symbol emit-property ) depictor )
( remprop symbol emit-property ) ) )
( export-symbol symbol ) ) )
;;; ------------------------------------------------------------------------------------------------------
;;; PRIMITIVES
( defstruct ( primitive ( :constructor make-primitive ( type-expr value-code appearance &key markup1 markup2 level level1 level2 ) )
( :predicate primitive? ) )
( type nil :type ( or null type ) ) ;Type of this primitive; nil if not computed yet
( type-expr nil :read-only t ) ;Source type expression that designates the type of this primitive
( value-code nil :read-only t ) ;Lisp expression that computes the value of this primitive
( appearance nil :read-only t ) ;One of the possible primitive appearances (see below)
( markup1 nil :read-only t ) ;Markup (item or list) for this primitive
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( markup2 nil :read-only t ) ;:global primitives: name to use for an external reference
; ;:unary primitives: markup (item or list) for this primitive's closer
; ;:infix primitives: true if spaces should be put around primitive
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( level nil :read-only t ) ;Precedence level of markup for this primitive
( level1 nil :read-only t ) ;Precedence level required for first argument of this primitive
( level2 nil :read-only t ) ) ;Precedence level required for second argument of this primitive
;appearance is one of the following:
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; :global The primitive appears as a regular, global function or constant; its markup is in markup1.
; If this primitive should generate an external reference, markup2 contains the name to use for the reference
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; :infix The primitive is an infix binary primitive; its markup is in markup1; if markup2 is true, put spaces around markup1
; :unary The primitive is a prefix and/or suffix unary primitive; the prefix is in markup1 and suffix in markup2
; :phantom The primitive disappears when emitting markup for it
; Call this to declare all primitives when initially constructing a world,
; before types have been constructed.
( defun declare-primitive ( symbol type-expr value-code appearance &rest key-args )
( when ( symbol-primitive symbol )
( error "Attempt to redefine primitive ~A" symbol ) )
( setf ( symbol-primitive symbol ) ( apply #' make-primitive type-expr value-code appearance key-args ) )
( export-symbol symbol ) )
; Call this to compute the primitive's type from its type-expr.
( defun define-primitive ( world primitive )
( setf ( primitive-type primitive ) ( scan-type world ( primitive-type-expr primitive ) ) ) )
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; If name is an identifier not already used by a special form, command, or primitive,
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; return it interened into the world's package. If not, generate an error.
( defun scan-name ( world name )
( unless ( identifier? name )
( error "~S should be an identifier" name ) )
( let ( ( symbol ( world-intern world name ) ) )
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( when ( and ( get-properties ( symbol-plist symbol ) ' ( :special-form :condition :primitive :type-constructor ) )
( not ( get symbol :non-reserved ) ) )
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( error "~A is reserved" symbol ) )
symbol ) )
;;; ------------------------------------------------------------------------------------------------------
;;; TYPE ENVIRONMENTS
;;; A type environment is an alist that associates bound variables with their types.
;;; A variable may be bound multiple times; the first binding in the environment list
;;; shadows ones further in the list.
;;; The following kinds of bindings are allowed in a type environment:
;;;
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;;; <type-env-local> (see below)
;;; Normal local variable
;;;
;;; <type-env-action> (see below)
;;; Action variable
;;;
;;; (:return . type)
;;; The function's return type
;;;
;;; (:return-block-name . symbol-or-nil)
;;; The name of the lisp return-from block to be used for returning from this function or nil if not needed yet.
;;; This binding's symbol-or-nil is mutated in place as needed.
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;;;
;;; (:lhs-symbol . symbol)
;;; The lhs nonterminal's symbol if this is a type environment for an action function.
;;;
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( defstruct ( type-env-local ( :type list ) ( :constructor make-type-env-local ( name type mode ) ) )
name ;World-interned name of the local variable
type ;That variable's type
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mode ) ;:const if the variable is read-only;
; ;:var if it's writable;
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; ;:uninitialized if it's writable but not initialized unless the name also appears in the type-env's live list;
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; ;:function if it's bound by flet;
; ;:reserved if it's bound by reserve;
; ;:unused if it's defined but shouldn't be used
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( defstruct ( type-env-action ( :type list ) ( :constructor make-type-env-action ( key local-symbol type general-grammar-symbol ) ) )
key ;(action symbol . index)
; ; action is a world-interned symbol denoting the action function being called
; ; symbol is a terminal or nonterminal's symbol on which the action is called
; ; index is the one-based index used to distinguish among identical
; ; symbols in the rhs of a production. The first occurrence of this
; ; symbol has index 1, the second has index 2, and so on.
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; ; The occurrence of symbol on the left side of the production has index 0.
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local-symbol ;A unique local variable name used to represent the action function's value in the generated lisp code
type ;Type of the action function's value
general-grammar-symbol ) ;The general-grammar-symbol corresponding to the index-th instance of symbol in the production's rhs
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( defstruct ( type-env ( :constructor make-type-env ( bindings live ) ) )
( bindings nil :type list ) ;List of bindings
( live nil :type list ) ) ;List of symbols of :uninitialized variables that have been initialized
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( defparameter *null-type-env* ( make-type-env nil nil ) )
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( defconstant *type-env-flags* ' ( :return :return-block-name :lhs-symbol ) )
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; If symbol is a local variable, return its binding; if not, return nil.
; symbol must already be world-interned.
( defun type-env-get-local ( type-env symbol )
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( assoc symbol ( type-env-bindings type-env ) :test #' eq ) )
; name must be the name of an :uninitialized variable in this type-env. Return true if this variable
; has been initialized.
( defun type-env-initialized ( type-env name )
( member name ( type-env-live type-env ) :test #' eq ) )
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; If the currently generated function is an action for a rule with at least index
; instances of the given grammar-symbol's symbol on the right-hand side, and if action is
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; a legal action for that symbol, return the type-env-action; otherwise, return nil.
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; action must already be world-interned.
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( defun type-env-get-action ( type-env action symbol index )
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( assoc ( list* action symbol index ) ( type-env-bindings type-env ) :test #' equal ) )
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; Nondestructively append the binding to the front of the type-env and return the new type-env.
; If shadow is true, the binding may shadow an existing local variable with the same name.
( defun type-env-add-binding ( type-env name type mode &optional shadow )
( assert-true ( and
( symbolp name )
( type? type )
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( member mode ' ( :const :var :uninitialized :function :reserved :unused ) ) ) )
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( unless shadow
( let ( ( binding ( type-env-get-local type-env name ) ) )
( when binding
( error "Local variable ~A:~A shadows an existing local variable ~A:~A"
name ( print-type-to-string type )
( type-env-local-name binding ) ( print-type-to-string ( type-env-local-type binding ) ) ) ) ) )
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( make-type-env
( cons ( make-type-env-local name type mode ) ( type-env-bindings type-env ) )
( type-env-live type-env ) ) )
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; Define the reserved name as a :const binding.
( defun type-env-unreserve-binding ( type-env name type )
( let ( ( binding ( type-env-get-local type-env name ) ) )
( unless ( and binding ( eq ( type-env-local-mode binding ) :reserved ) )
( error "Local variable ~A:~A needs to be reserved first" name ( print-type-to-string type ) ) )
( type-env-add-binding type-env name type :const t ) ) )
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; Nondestructively shadow the type of the binding of name in type-env and return the new type-env.
( defun type-env-narrow-binding ( type-env name type )
( let ( ( binding ( assert-non-null ( type-env-get-local type-env name ) ) ) )
( type-env-add-binding type-env name type ( type-env-local-mode binding ) t ) ) )
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; Nondestructively unshadow the type of the binding of name in type-env and return two values:
; the previous binding of name;
; the new type-env.
( defun type-env-unnarrow-binding ( type-env name )
( let* ( ( bindings ( type-env-bindings type-env ) )
( shadow-tail ( assert-non-null ( member name bindings :test #' eq :key #' car ) ) )
( tail ( cdr shadow-tail ) )
( old-binding ( assoc name tail :test #' eq ) ) )
( unless old-binding
( error "Can't unshadow ~S" name ) )
( let ( ( unshadowed-bindings ( nconc ( ldiff bindings shadow-tail ) tail ) ) )
( values
old-binding
( make-type-env unshadowed-bindings ( type-env-live type-env ) ) ) ) ) )
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; Mark name as an initialized variable. It should have been declared as :uninitialized.
( defun type-env-initialize-var ( type-env name )
( if ( type-env-initialized type-env name )
type-env
( make-type-env
( type-env-bindings type-env )
( cons name ( type-env-live type-env ) ) ) ) )
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; Create new bindings for the function's return type and return block name and return the new type-env.
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( defun type-env-init-function ( type-env return-type )
( set-type-env-flag
( set-type-env-flag type-env :return return-type )
:return-block-name
nil ) )
; Either reuse or generate a name for return-from statements exiting this function.
( defun gen-type-env-return-block-name ( type-env )
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( let ( ( return-block-binding ( assert-non-null ( assoc :return-block-name ( type-env-bindings type-env ) ) ) ) )
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( or ( cdr return-block-binding )
( setf ( cdr return-block-binding ) ( gensym "RETURN" ) ) ) ) )
; Return an environment obtained from the type-env by adding a binding of flag to value.
( defun set-type-env-flag ( type-env flag value )
( assert-true ( member flag *type-env-flags* ) )
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( make-type-env
( acons flag value ( type-env-bindings type-env ) )
( type-env-live type-env ) ) )
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; Return the value bound to the given flag.
( defun get-type-env-flag ( type-env flag )
( assert-true ( member flag *type-env-flags* ) )
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( cdr ( assoc flag ( type-env-bindings type-env ) ) ) )
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; Ensure that sub-type-env is derived from base-type-env.
( defun ensure-narrowed-type-env ( base-type-env sub-type-env )
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( unless ( and ( tailp ( type-env-bindings base-type-env ) ( type-env-bindings sub-type-env ) )
( equal ( type-env-live base-type-env ) ( type-env-live sub-type-env ) ) )
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( error "The type environment ~S isn't narrower than ~S" sub-type-env base-type-env ) ) )
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; live1 and live2 are either :dead or lists of :uninitialized variables that have been initialized.
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; Return :dead if both live1 and live2 are dead or a list of initialized variables that would be valid
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; on a merge point between code paths resulting in live1 and live2.
( defun merge-live-lists ( live1 live2 )
( cond
( ( eq live1 :dead ) live2 )
( ( eq live2 :dead ) live1 )
( t ( intersection live1 live2 :test #' eq ) ) ) )
; If live is :dead, return nil; otherwise, return type-env with live substituted for type-env's old live list.
( defun substitute-live ( type-env live )
( cond
( ( eq live :dead ) nil )
( ( equal live ( type-env-live type-env ) ) type-env )
( t ( make-type-env ( type-env-bindings type-env ) live ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; VALUES
;;; A value is one of the following:
;;; A void value (represented by nil)
;;; A boolean (nil for false; non-nil for true)
;;; An integer
;;; A rational number
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;;; A *float32-type* (or :+zero32, :-zero32, :+infinity32, :-infinity32, or :nan32)
;;; A *float64-type* (or :+zero64, :-zero64, :+infinity64, :-infinity64, or :nan64)
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;;; A character
;;; A function (represented by a lisp function)
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;;; A string
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;;; A vector (represented by a list)
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;;; A list-set (represented by an unordered list of its elements)
;;; A range-set of integers or characters (represented by an intset of its elements converted to integers)
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;;; A bit-set (represented by an integer with 1's in bits corresponding to present tags) ***** Not implemented yet *****
;;; A restricted-set (represented by an integer with 1's in bits corresponding to present tags) ***** Not implemented yet *****
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;;; A tag (represented by either a keyword or a list (keyword [serial-num] field-value1 ... field-value n));
;;; serial-num is a unique integer present only on mutable tag instances.
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;;; A writable-cell (represented by a cons whose car is a flag that is true if the cell is initialized
;;; and cdr is nil or the value)
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;;; A delayed-value structure
( defstruct ( delayed-value ( :constructor make-delayed-value ( symbol ) ) ( :predicate delayed-value? ) )
( symbol nil :type symbol :read-only t ) ) ;Global variable name
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; Return the bit-set value as a list of tag keywords.
( defun bit-set-to-list ( value bit-set-type )
( assert-true ( and ( bit-set-type? bit-set-type ) ( integerp value ) ( >= value 0 ) ( < value ( ash 1 ( length ( type-tag bit-set-type ) ) ) ) ) )
( let ( ( tags-present nil ) )
( dolist ( tag ( type-tag bit-set-type ) )
( when ( oddp value )
( push ( assert-non-null ( tag-keyword tag ) ) tags-present ) )
( setq value ( ash value -1 ) ) )
( nreverse tags-present ) ) )
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; Return true if the value appears to have the given tag. This function
; may return false positives (return true when the value doesn't actually
; have the given type) but never false negatives.
; If shallow is true, only test at the top level.
( defun value-has-tag ( value tag &optional shallow )
( labels
( ( check-fields ( fields values )
( if ( endp fields )
( null values )
( and ( consp values )
( or shallow ( value-has-type ( car values ) ( field-type ( car fields ) ) ) )
( check-fields ( cdr fields ) ( cdr values ) ) ) ) ) )
( let ( ( keyword ( tag-keyword tag ) ) )
( if keyword
( eq value keyword )
( and ( consp value )
( eq ( car value ) ( tag-name tag ) )
( let ( ( values ( cdr value ) )
( fields ( tag-fields tag ) ) )
( if ( tag-mutable tag )
( and ( consp values ) ( integerp ( car values ) ) ( check-fields fields ( cdr values ) ) )
( check-fields fields values ) ) ) ) ) ) ) )
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; Return true if the value appears to have the given type. This function
; may return false positives (return true when the value doesn't actually
; have the given type) but never false negatives.
; If shallow is true, only test at the top level.
( defun value-has-type ( value type &optional shallow )
( case ( type-kind type )
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( :bottom nil )
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( :void t )
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( :boolean t )
( :integer ( integerp value ) )
( :rational ( rationalp value ) )
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( :finite32 ( and ( finite32? value ) ( not ( zerop value ) ) ) )
( :finite64 ( and ( finite64? value ) ( not ( zerop value ) ) ) )
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( :char16 ( characterp value ) )
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( :supplementary-char ( and ( consp value ) ( eq ( car value ) :supplementary-char ) ( integerp ( cdr value ) ) ( <= #x10000 ( cdr value ) #x10FFFF ) ) )
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( :-> ( functionp value ) )
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( :string ( stringp value ) )
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( :vector ( value-list-has-type value ( vector-element-type type ) shallow ) )
( :list-set ( value-list-has-type value ( set-element-type type ) shallow ) )
( :range-set ( valid-intset? value ) )
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( :bit-set ( and ( integerp value ) ( <= 0 value ) ( < value ( ash 1 ( length ( type-tag type ) ) ) ) ) )
( :restricted-set ( member value ( type-tag type ) ) )
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( :tag ( value-has-tag value ( type-tag type ) shallow ) )
( :union ( some #' ( lambda ( subtype ) ( value-has-type value subtype shallow ) )
( type-parameters type ) ) )
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( :writable-cell ( and ( consp value )
( if ( car value )
( or shallow ( value-has-type ( cdr value ) ( writable-cell-element-type type ) ) )
( null ( cdr value ) ) ) ) )
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( :delay ( or ( delayed-value? value ) ( value-has-type value ( delay-element-type type ) ) ) )
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( t ( error "Bad typekind ~S" ( type-kind type ) ) ) ) )
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; Return true if the value is a list of elements that appear to have the given type. This function
; may return false positives (return true when the value doesn't actually
; have the given type) but never false negatives.
; If shallow is true, only check the list structure -- don't test that the elements have the given type.
( defun value-list-has-type ( values type shallow )
( or ( null values )
( and ( consp values )
( or shallow ( value-has-type ( car values ) type ) )
( value-list-has-type ( cdr values ) type shallow ) ) ) )
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; Print the values list using set notation.
( defun print-set-of-values ( values element-type stream )
( pprint-logical-block ( stream values :prefix "{" :suffix "}" )
( pprint-exit-if-list-exhausted )
( loop
( print-value ( pprint-pop ) element-type stream )
( pprint-exit-if-list-exhausted )
( format stream " ~:_" ) ) ) )
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; Print the value nicely on the given stream. type is the value's type.
( defun print-value ( value type &optional ( stream t ) )
( assert-true ( value-has-type value type t ) )
( case ( type-kind type )
( :void ( assert-true ( null value ) )
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( write-string "empty" stream ) )
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( :boolean ( write-string ( if value "true" "false" ) stream ) )
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( ( :integer :rational :char16 :supplementary-char :-> ) ( write value :stream stream ) )
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( ( :finite32 :finite64 ) ( write value :stream stream ) )
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( :string ( prin1 value stream ) )
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( :vector ( let ( ( element-type ( vector-element-type type ) ) )
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( pprint-logical-block ( stream value :prefix "(" :suffix ")" )
( pprint-exit-if-list-exhausted )
( loop
( print-value ( pprint-pop ) element-type stream )
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( pprint-exit-if-list-exhausted )
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( format stream " ~:_" ) ) ) ) )
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( :list-set ( print-set-of-values value ( set-element-type type ) stream ) )
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( :range-set ( let ( ( converter ( range-set-decode-function ( set-element-type type ) ) ) )
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( pprint-logical-block ( stream value :prefix "{" :suffix "}" )
( pprint-exit-if-list-exhausted )
( loop
( let* ( ( values ( pprint-pop ) )
( value1 ( car values ) )
( value2 ( cdr values ) ) )
( if ( = value1 value2 )
( write ( funcall converter value1 ) :stream stream )
( write ( list ( funcall converter value1 ) ( funcall converter value2 ) ) :stream stream ) ) ) )
( pprint-exit-if-list-exhausted )
( format stream " ~:_" ) ) ) )
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( ( :bit-set :restricted-set ) ( print-set-of-values ( bit-set-to-list value ( underlying-bit-set-type type ) ) ( set-element-type type ) stream ) )
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( :tag ( let ( ( tag ( type-tag type ) ) )
( if ( tag-keyword tag )
( write value :stream stream )
( pprint-logical-block ( stream ( tag-fields tag ) :prefix "[" :suffix "]" )
( write ( pop value ) :stream stream )
( when ( tag-mutable tag )
( format stream " ~:_~D" ( pop value ) ) )
( loop
( pprint-exit-if-list-exhausted )
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( format stream " ~:_" )
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( print-value ( pop value ) ( field-type ( pprint-pop ) ) stream ) ) ) ) ) )
( :union ( dolist ( subtype ( type-parameters type )
( error "~S is not an instance of ~A" value ( print-type-to-string type ) ) )
( when ( value-has-type value subtype t )
( print-value value subtype stream )
( return ) ) ) )
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( :writable-cell ( if ( car value )
( print-value ( cdr value ) ( writable-cell-element-type type ) stream )
( write-string "uninitialized" stream ) ) )
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( :delay ( if ( delayed-value? value )
( write value :stream stream )
( print-value value ( delay-element-type type ) stream ) ) )
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( t ( error "Bad typekind ~S" ( type-kind type ) ) ) ) )
; Print a list of values nicely on the given stream. types is the list of the
; values' types (and should have the same length as the list of values).
; If prefix and/or suffix are non-null, use them as beginning and ending
; delimiters of the printed list.
( defun print-values ( values types &optional ( stream t ) &key prefix suffix )
( assert-true ( = ( length values ) ( length types ) ) )
( pprint-logical-block ( stream values :prefix prefix :suffix suffix )
( pprint-exit-if-list-exhausted )
( dolist ( type types )
( print-value ( pprint-pop ) type stream )
( pprint-exit-if-list-exhausted )
( format stream " ~:_" ) ) ) )
;;; ------------------------------------------------------------------------------------------------------
;;; VALUE EXPRESSIONS
;;; Expressions are annotated to avoid having to duplicate the expression scanning logic when
;;; emitting markup for expressions. Expression forms are prefixed with an expr-annotation symbol
;;; to indicate their kinds. These symbols are in their own package to avoid potential confusion
;;; with keywords, variable names, terminals, etc.
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;;;
;;; Some special forms are extended to include parsed type information for the benefit of markup logic.
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( eval-when ( :compile-toplevel :load-toplevel :execute )
( defpackage "EXPR-ANNOTATION"
( :use )
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( :export "CONSTANT" ;(expr-annotation:constant <constant>)
"PRIMITIVE" ;(expr-annotation:primitive <interned-id>)
"TAG" ;(expr-annotation:tag <tag>)
"LOCAL" ;(expr-annotation:local <interned-id>) ;Local or lexically scoped variable
"GLOBAL" ;(expr-annotation:global <interned-id>) ;Global variable
"CALL" ;(expr-annotation:call <function-expr> <arg-expr> ... <arg-expr>)
"ACTION" ;(expr-annotation:action <action> <general-grammar-symbol> <optional-index>)
"BEGIN" ;(expr-annotation:begin <statement> ... <statement>)
"SPECIAL-FORM" ) ) ) ;(expr-annotation:special-form <interned-form> ...)
; Return true if the annotated-stmt is a statement with the given special-form, which must be a symbol
; but does not have to be interned in the world's package.
( defun special-form-annotated-stmt? ( world special-form annotated-stmt )
( eq ( first annotated-stmt ) ( world-find-symbol world special-form ) ) )
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; Return true if the annotated-expr is a special form annotated expression with
; the given special-form. special-form must be a symbol but does not have to be interned
; in the world's package.
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( defun special-form-annotated-expr? ( world special-form annotated-expr )
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( and ( eq ( first annotated-expr ) 'expr-annotation:special-form )
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( eq ( second annotated-expr ) ( world-find-symbol world special-form ) ) ) )
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; Return the value of the global variable with the given symbol.
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; Compute the value if the variable was unbound.
; Use the *busy-variables* list to prevent infinite recursion while computing variable values.
( defmacro fetch-value ( symbol )
` ( if ( boundp ',symbol )
( symbol-value ',symbol )
( compute-variable-value ',symbol ) ) )
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; Store the value into the global variable with the given symbol.
( defmacro store-global-value ( symbol value )
` ( if ( boundp ',symbol )
( setf ( symbol-value ',symbol ) , value )
( error "Unbound variable ~S" ',symbol ) ) )
; Generate a lisp expression that will call the given action on the grammar symbol.
; type-env is the type environment.
; Return three values:
; The expression's value (a lisp expression)
; The expression's type
; The annotated value-expr
( defun scan-action-call ( type-env action symbol &optional ( index 1 index-supplied ) )
( unless ( integerp index )
( error "Production rhs grammar symbol index ~S must be an integer" index ) )
( let ( ( symbol-action ( type-env-get-action type-env action symbol index ) ) )
( unless symbol-action
( error "Action ~S not found" ( list action symbol index ) ) )
( let ( ( multiple-symbols ( type-env-get-action type-env action symbol ( if ( = index 0 ) 1 2 ) ) ) )
( when ( and ( not index-supplied ) multiple-symbols )
( error "Ambiguous index in action ~S" ( list action symbol ) ) )
( when ( and ( = index 1 )
( not multiple-symbols )
( grammar-symbol-= symbol ( assert-non-null ( get-type-env-flag type-env :lhs-symbol ) ) ) )
( setq multiple-symbols t ) )
( values ( type-env-action-local-symbol symbol-action )
( type-env-action-type symbol-action )
( list* 'expr-annotation:action action ( type-env-action-general-grammar-symbol symbol-action )
( and multiple-symbols ( list index ) ) ) ) ) ) )
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; Generate a lisp expression that will compute the value of value-expr.
; type-env is the type environment. The expression may refer to free variables
; present in the type-env.
; Return three values:
; The expression's value (a lisp expression)
; The expression's type
; The annotated value-expr
( defun scan-value ( world type-env value-expr )
( labels
( ( syntax-error ( )
( error "Syntax error: ~S" value-expr ) )
;Scan a function call. The function has already been scanned into its value and type,
;but the arguments are still unprocessed.
( scan-call ( function-value function-type function-annotated-expr arg-exprs )
( let ( ( arg-values nil )
( arg-types nil )
( arg-annotated-exprs nil ) )
( dolist ( arg-expr arg-exprs )
( multiple-value-bind ( arg-value arg-type arg-annotated-expr ) ( scan-value world type-env arg-expr )
( push arg-value arg-values )
( push arg-type arg-types )
( push arg-annotated-expr arg-annotated-exprs ) ) )
( let ( ( arg-values ( nreverse arg-values ) )
( arg-types ( nreverse arg-types ) )
( arg-annotated-exprs ( nreverse arg-annotated-exprs ) ) )
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( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
( format *error-output*
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"~@<In ~S: ~_Function of type ~A called with arguments of types~:_~{ ~A~}~:>~%"
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value-expr
( print-type-to-string function-type )
( mapcar #' print-type-to-string arg-types ) ) ) ) )
( unless ( eq ( type-kind function-type ) :-> )
( error "Non-function called" ) )
( let ( ( parameter-types ( ->-argument-types function-type ) ) )
( unless ( = ( length arg-types ) ( length parameter-types ) )
( error "Argument count mismatch" ) )
( let ( ( arg-values ( mapcar #' ( lambda ( arg-expr arg-value arg-type parameter-type )
( widening-coercion-code world parameter-type arg-type arg-value arg-expr ) )
arg-exprs arg-values arg-types parameter-types ) ) )
( values ( apply #' gen-apply function-value arg-values )
( ->-result-type function-type )
( list* 'expr-annotation:call function-annotated-expr arg-annotated-exprs ) ) ) ) ) ) ) )
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;Scan an interned identifier
( scan-identifier ( symbol )
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( let ( ( symbol-binding ( type-env-get-local type-env symbol ) ) )
( if symbol-binding
( ecase ( type-env-local-mode symbol-binding )
( ( :const :var )
( values ( type-env-local-name symbol-binding )
( type-env-local-type symbol-binding )
( list 'expr-annotation:local symbol ) ) )
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( :uninitialized
( if ( type-env-initialized type-env symbol )
( values ( type-env-local-name symbol-binding )
( type-env-local-type symbol-binding )
( list 'expr-annotation:local symbol ) )
( error "Uninitialized variable ~A referenced" symbol ) ) )
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( :function
( values ( list 'function ( type-env-local-name symbol-binding ) )
( type-env-local-type symbol-binding )
( list 'expr-annotation:local symbol ) ) )
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( ( :reserved :unused ) ( error "Unused variable ~A referenced" symbol ) ) )
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( let ( ( primitive ( symbol-primitive symbol ) ) )
( if primitive
( values ( primitive-value-code primitive ) ( primitive-type primitive ) ( list 'expr-annotation:primitive symbol ) )
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( let ( ( tag ( symbol-tag symbol ) ) )
( if ( and tag ( tag-keyword tag ) )
( values ( tag-keyword tag )
( make-tag-type world tag )
( list 'expr-annotation:tag tag ) )
( let ( ( type ( symbol-type symbol ) ) )
( if type
( values ( if ( eq ( type-kind type ) :-> )
( list 'symbol-function ( list 'quote symbol ) )
( list 'fetch-value symbol ) )
type
( list 'expr-annotation:global symbol ) )
( syntax-error ) ) ) ) ) ) ) ) ) )
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;Scan a call or special form
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( scan-cons ( first rest )
( if ( identifier? first )
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( let ( ( symbol ( world-intern world first ) ) )
( let ( ( handler ( get symbol :special-form ) ) )
( if handler
( apply handler world type-env symbol rest )
( if ( and ( symbol-action symbol )
( let ( ( local ( type-env-get-local type-env symbol ) ) )
( not ( and local ( eq ( type-kind ( type-env-local-type local ) ) :-> ) ) ) ) )
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( multiple-value-bind ( action-value action-type action-annotated-expr ) ( apply #' scan-action-call type-env symbol rest )
( if ( eq ( type-kind action-type ) :writable-cell )
( progn
( assert-true ( symbolp action-value ) )
( values
` ( if ( car , action-value )
( cdr , action-value )
( error "Uninitialized writable-cell" ) )
( writable-cell-element-type action-type )
action-annotated-expr ) )
( values action-value action-type action-annotated-expr ) ) )
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( multiple-value-call #' scan-call ( scan-identifier symbol ) rest ) ) ) ) )
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( multiple-value-call #' scan-call ( scan-value world type-env first ) rest ) ) )
( scan-constant ( value-expr type )
( values value-expr type ( list 'expr-annotation:constant value-expr ) ) ) )
( assert-three-values
( cond
( ( consp value-expr ) ( scan-cons ( first value-expr ) ( rest value-expr ) ) )
( ( identifier? value-expr ) ( scan-identifier ( world-intern world value-expr ) ) )
( ( integerp value-expr ) ( scan-constant value-expr ( world-integer-type world ) ) )
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( ( typep value-expr *float64-type* )
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( if ( zerop value-expr )
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( error "Use +zero64 or -zero64 instead of 0.0" )
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( scan-constant value-expr ( world-finite64-type world ) ) ) )
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( ( characterp value-expr ) ( scan-constant value-expr ( world-char16-type world ) ) )
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( ( stringp value-expr ) ( scan-constant value-expr ( world-string-type world ) ) )
( t ( syntax-error ) ) ) ) ) )
; Same as scan-value except that ensure that the value has the expected type.
; Return two values:
; The expression's value (a lisp expression)
; The annotated value-expr
( defun scan-typed-value ( world type-env value-expr expected-type )
( multiple-value-bind ( value type annotated-expr ) ( scan-value world type-env value-expr )
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( values ( widening-coercion-code world expected-type type value value-expr ) annotated-expr ) ) )
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( defun eval-typed-value ( world value-expr expected-type )
( eval ( scan-typed-value world *null-type-env* value-expr expected-type ) ) )
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; Same as scan-value except that ensure that the value has type bottom or void.
; Return three values:
; The expression's value (a lisp expression)
; True if value has type void
; The annotated value-expr
( defun scan-void-value ( world type-env value-expr )
( multiple-value-bind ( value type annotated-expr ) ( scan-value world type-env value-expr )
( values
value
( case ( type-kind type )
( :bottom nil )
( :void t )
( t ( error "Value ~S:~A should be void" value-expr ( print-type-to-string type ) ) ) )
annotated-expr ) ) )
; Same as scan-value except that ensure that the value is a vector type.
; Return three values:
; The expression's value (a lisp expression)
; The expression's type
; The annotated value-expr
( defun scan-vector-value ( world type-env value-expr )
( multiple-value-bind ( value type annotated-expr ) ( scan-value world type-env value-expr )
( unless ( member ( type-kind type ) ' ( :string :vector ) )
( error "Value ~S:~A should be a vector" value-expr ( print-type-to-string type ) ) )
( values value type annotated-expr ) ) )
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; Same as scan-value except that ensure that the value is a set type.
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; Return three values:
; The expression's value (a lisp expression)
; The expression's type
; The annotated value-expr
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( defun scan-set-value ( world type-env value-expr )
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( multiple-value-bind ( value type annotated-expr ) ( scan-value world type-env value-expr )
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( unless ( member ( type-kind type ) ' ( :list-set :range-set :bit-set :restricted-set ) )
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( error "Value ~S:~A should be a set" value-expr ( print-type-to-string type ) ) )
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( values value type annotated-expr ) ) )
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; Same as scan-value except that ensure that the value is a vector or set type.
; Return three values:
; The expression's value (a lisp expression)
; The expression's type kind
; The expression's element type
; The annotated value-expr
( defun scan-collection-value ( world type-env value-expr )
( multiple-value-bind ( value type annotated-expr ) ( scan-value world type-env value-expr )
( let ( ( kind ( type-kind type ) ) )
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( unless ( member kind ' ( :string :vector :list-set :range-set :bit-set :restricted-set ) )
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( error "Value ~S:~A should be a vector or a set" value-expr ( print-type-to-string type ) ) )
( values value kind ( collection-element-type type ) annotated-expr ) ) ) )
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; Same as scan-value except that ensure that the value is a tag type, float32, float64, or a union of these types.
; The types float32 and float64 are converted into fake tags that have one field, named "value", at position -1.
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; Return four values:
; The expression's value (a lisp expression)
; The expression's type
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; A list of tags in the expression's type (includes pseudo-tags with a value field at offset -1 for :finite32 and :finite64 if these types are present)
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; The annotated value-expr
( defun scan-union-tag-value ( world type-env value-expr )
( multiple-value-bind ( value type annotated-expr ) ( scan-value world type-env value-expr )
( flet ( ( bad-type ( )
( error "Value ~S:~A should be a tag or union of tags" value-expr ( print-type-to-string type ) ) ) )
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( values
value
type
( case ( type-kind type )
( ( :tag :finite32 :finite64 ) ( list ( type-pseudo-tag world type ) ) )
( :union ( mapcar #' ( lambda ( type2 )
( or ( type-pseudo-tag world type2 )
( bad-type ) ) )
( type-parameters type ) ) )
( t ( bad-type ) ) )
annotated-expr ) ) ) )
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; Generate a lisp expression that will compute the boolean condition expression in condition-expr.
; type-env is the type environment. The expression may refer to free variables present in the type-env.
; Return four values:
; The code for the condition;
; The annotated code for the condition;
; A type-env to use if the condition is true;
; A type-env to use if the condition is false.
( defun scan-condition ( world type-env condition-expr )
( when ( consp condition-expr )
( let ( ( first ( first condition-expr ) ) )
( when ( identifier? first )
( let* ( ( symbol ( world-intern world first ) )
( handler ( get symbol :condition ) ) )
( when handler
( return-from scan-condition ( assert-four-values ( apply handler world type-env symbol ( rest condition-expr ) ) ) ) ) ) ) ) )
( multiple-value-bind ( condition-code condition-annotated-expr )
( scan-typed-value world type-env condition-expr ( world-boolean-type world ) )
( values condition-code condition-annotated-expr type-env type-env ) ) )
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; Return the code for computing value-expr, which will be assigned to the symbol. Check that the
; value has the given type.
( defun scan-global-value ( symbol value-expr type )
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( scan-typed-value ( symbol-world symbol ) *null-type-env* value-expr type ) )
; Same as scan-typed-value except that also allow the form (begin . <statements>); in this case
; return can be used to return the expression's value.
; Return two values:
; The expression's value (a lisp expression)
; The annotated value-expr
( defun scan-typed-value-or-begin ( world type-env value-expr expected-type )
( if ( and ( consp value-expr ) ( eq ( first value-expr ) 'begin ) )
( let* ( ( result-type ( scan-type world expected-type ) )
( local-type-env ( type-env-init-function type-env result-type ) ) )
( multiple-value-bind ( body-codes body-annotated-stmts ) ( finish-function-code world local-type-env result-type ( cdr value-expr ) )
( values ( gen-progn body-codes )
( cons 'expr-annotation:begin body-annotated-stmts ) ) ) )
( scan-typed-value world type-env value-expr expected-type ) ) )
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; Generate the defun code for the world's variable named by symbol.
; The variable's type must be ->.
( defun compute-variable-function ( symbol value-expr type )
( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
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( format *error-output* "~&~@<~2IWhile computing ~A: ~_~:W~:>~%" symbol value-expr ) ) ) )
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( assert-true ( not ( or ( boundp symbol ) ( fboundp symbol ) ) ) )
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( let ( ( code ( strip-function ( scan-global-value symbol value-expr type ) symbol ( length ( ->-argument-types type ) ) ) )
( code2 ( get symbol :lisp-value-expr ) ) )
( when code2
( setq code code2 ) )
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( when *trace-variables*
( format *trace-output* "~&~S ::= ~:W~%" symbol code ) )
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( quiet-compile symbol code ) ) ) )
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( defvar *busy-variables* nil )
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; Compute the value of a world's variable named by symbol. Return the variable's value.
; If the variable already has a computed value, return it unchanged. The variable's type must not be ->.
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; If computing the value requires the values of other variables, compute them as well.
; Use the *busy-variables* list to prevent infinite recursion while computing variable values.
( defun compute-variable-value ( symbol )
( cond
( ( member symbol *busy-variables* ) ( error "Definition of ~A refers to itself" symbol ) )
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( ( boundp symbol ) ( symbol-value symbol ) )
( ( fboundp symbol ) ( error "compute-variable-value should be called only once on a function" ) )
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( t ( let* ( ( *busy-variables* ( cons symbol *busy-variables* ) )
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( value-expr ( get symbol :value-expr ) )
( type ( symbol-type symbol ) ) )
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( when ( get symbol :lisp-value-expr )
( error "Can't use defprimitive on non-function ~S" symbol ) )
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( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
( format *error-output* "~&~@<~2IWhile computing ~A: ~_~:W~:>~%"
symbol value-expr ) ) ) )
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( assert-true ( not ( eq ( type-kind type ) :-> ) ) )
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( let ( ( value-code ( scan-global-value symbol value-expr type ) ) )
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( when *trace-variables*
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( format *trace-output* "~&~S := ~:W~%" symbol value-code ) )
( set symbol ( eval value-code ) ) ) ) ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; SPECIAL FORMS
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;;; Constants
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( defun eval-todo ( )
( error "Reached a TODO expression" ) )
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; (todo)
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; Raises an error.
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( defun scan-todo ( world type-env special-form )
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( declare ( ignore type-env ) )
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( values
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' ( eval-todo )
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( world-bottom-type world )
( list 'expr-annotation:special-form special-form ) ) )
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; (bottom)
; Raises an error. Same as todo except that it doesn't carry the connotation of something that
; should be filled in in the future.
( defun scan-bottom-expr ( world type-env special-form )
( declare ( ignore type-env ) )
( values
' ( eval-bottom )
( world-bottom-type world )
( list 'expr-annotation:special-form special-form ) ) )
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; (hex <integer> [<length>])
; Alternative way of writing the integer in hexadecimal. length is the minimum number of digits to write.
( defun scan-hex ( world type-env special-form n &optional ( length 1 ) )
( declare ( ignore type-env ) )
( unless ( and ( integerp n ) ( integerp length ) ( >= length 0 ) )
( error "Bad hex constant ~S [~S]" n length ) )
( values
n
( world-integer-type world )
( list 'expr-annotation:special-form special-form n length ) ) )
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; (float32 <value>)
; Alternative way of writing a finite, nonzero float32 constant.
( defun scan-float32 ( world type-env special-form value )
( declare ( ignore type-env special-form ) )
( unless ( typep value *float64-type* )
( error "Bad float32 constant ~S" value ) )
( let ( ( f32 ( coerce value *float32-type* ) ) )
( when ( zerop f32 )
( error "Use +zero32 or -zero32 instead of (float32 0.0)" ) )
( values
f32
( world-finite32-type world )
( list 'expr-annotation:constant f32 ) ) ) )
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; (supplementary-char <integer>)
; <integer> must be between #x10000 and #x10FFFF.
( defun scan-supplementary-char ( world type-env special-form code-point )
( declare ( ignore type-env ) )
( unless ( and ( integerp code-point ) ( <= #x10000 code-point #x10FFFF ) )
( error "Bad supplementary-char constant ~S" code-point ) )
( values
( list 'quote ( cons :supplementary-char code-point ) )
( world-supplementary-char-type world )
( list 'expr-annotation:special-form special-form code-point ) ) )
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;;; Expressions
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; (/*/ <value-expr> . <styled-text>)
; Evaluate <value-expr>, but depict <styled-text>.
( defun scan-/*/ ( world type-env special-form value-expr &rest text )
( multiple-value-bind ( code type annotated-expr ) ( scan-value world type-env value-expr )
( declare ( ignore annotated-expr ) )
( when ( endp text )
( error "/*/ needs a text comment" ) )
( let ( ( text2 ( scan-expressions-in-comment world type-env text ) ) )
( values
code
type
( list* 'expr-annotation:special-form special-form text2 ) ) ) ) )
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; (/*/ <value-expr> . <styled-text>)
; Evaluate <value-expr>, but depict <styled-text>.
( defun scan-/*/-condition ( world type-env special-form value-expr &rest text )
( multiple-value-bind ( code annotated-expr true-type-env false-type-env )
( scan-condition world type-env value-expr )
( declare ( ignore annotated-expr ) )
( when ( endp text )
( error "/*/ needs a text comment" ) )
( let ( ( text2 ( scan-expressions-in-comment world type-env text ) ) )
( values
code
( list* 'expr-annotation:special-form special-form text2 )
true-type-env
false-type-env ) ) ) )
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; (lisp-call <lisp-function> <arg-exprs> <result-type-expr> . <styled-text>)
; Evaluate <lisp-function> applied to the results of evaluating <arg-exprs>, but depict <styled-text>.
; <styled-text> can contain the entry (:operand <n>) to depict the nth operand, with n starting from 0.
( defun scan-lisp-call ( world type-env special-form lisp-function arg-exprs result-type-expr &rest text )
( let ( ( result-type ( scan-type world result-type-expr ) )
( arg-values nil )
( arg-annotated-exprs nil ) )
( dolist ( arg-expr arg-exprs )
( multiple-value-bind ( arg-value arg-type arg-annotated-expr ) ( scan-value world type-env arg-expr )
( declare ( ignore arg-type ) )
( push arg-value arg-values )
( push arg-annotated-expr arg-annotated-exprs ) ) )
( let ( ( arg-values ( nreverse arg-values ) )
( arg-annotated-exprs ( nreverse arg-annotated-exprs ) ) )
( let ( ( text2 ( scan-expressions-in-comment world type-env text ) ) )
( values
( cons lisp-function arg-values )
result-type
( list* 'expr-annotation:special-form special-form arg-annotated-exprs text2 ) ) ) ) ) )
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( defun semantic-expt ( base exponent )
( assert-true ( and ( rationalp base ) ( integerp exponent ) ) )
( when ( and ( zerop base ) ( not ( plusp exponent ) ) )
( error "0 raised to a nonpositive exponent" ) )
( expt base exponent ) )
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; (expt <base> <exponent>)
; The result is rational unless both base and exponent are integer constants and the result is an integer.
( defun scan-expt ( world type-env special-form base-expr exponent-expr )
( multiple-value-bind ( base-code base-annotated-expr ) ( scan-typed-value world type-env base-expr ( world-rational-type world ) )
( multiple-value-bind ( exponent-code exponent-annotated-expr ) ( scan-typed-value world type-env exponent-expr ( world-integer-type world ) )
( let ( ( code ( list 'semantic-expt base-code exponent-code ) )
( type ( world-rational-type world ) ) )
( when ( and ( constantp base-code ) ( constantp exponent-code ) )
( setq code ( semantic-expt base-code exponent-code ) )
( when ( integerp code )
( setq type ( world-integer-type world ) ) ) )
( values
code
type
( list 'expr-annotation:special-form special-form base-annotated-expr exponent-annotated-expr ) ) ) ) ) )
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; Return the depict name for one of the comparison symbols =, /=, <, >, <=, >=, set<=.
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( defun comparison-name ( order )
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( cdr ( assoc order ' ( ( = . "=" ) ( /= . :not-equal ) ( < . "<" ) ( > . ">" ) ( <= . :less-or-equal ) ( >= . :greater-or-equal ) ( set<= . :subset-eq-10 ) ) ) ) )
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; Both expr1 and expr2 are coerced to the given type and then compared using the given order.
; The result is a boolean. order-name should be suitable for depict.
( defun scan-comparison ( world type-env special-form order expr1 expr2 type-expr )
( let ( ( type ( scan-type world type-expr ) ) )
( multiple-value-bind ( code1 annotated-expr1 ) ( scan-typed-value world type-env expr1 type )
( multiple-value-bind ( code2 annotated-expr2 ) ( scan-typed-value world type-env expr2 type )
( values
( get-type-order-code world type order code1 code2 )
( world-boolean-type world )
( list 'expr-annotation:special-form special-form ( comparison-name order ) annotated-expr1 annotated-expr2 ) ) ) ) ) )
; (= <expr1> <expr2> [<type>])
( defun scan-= ( world type-env special-form expr1 expr2 &optional ( type-expr 'integer ) )
( scan-comparison world type-env special-form '= expr1 expr2 type-expr ) )
; (/= <expr1> <expr2> [<type>])
( defun scan-/= ( world type-env special-form expr1 expr2 &optional ( type-expr 'integer ) )
( scan-comparison world type-env special-form '/= expr1 expr2 type-expr ) )
; (< <expr1> <expr2> [<type>])
( defun scan-< ( world type-env special-form expr1 expr2 &optional ( type-expr 'integer ) )
( scan-comparison world type-env special-form '< expr1 expr2 type-expr ) )
; (> <expr1> <expr2> [<type>])
( defun scan-> ( world type-env special-form expr1 expr2 &optional ( type-expr 'integer ) )
( scan-comparison world type-env special-form '> expr1 expr2 type-expr ) )
; (<= <expr1> <expr2> [<type>])
( defun scan-<= ( world type-env special-form expr1 expr2 &optional ( type-expr 'integer ) )
( scan-comparison world type-env special-form '<= expr1 expr2 type-expr ) )
; (>= <expr1> <expr2> [<type>])
( defun scan->= ( world type-env special-form expr1 expr2 &optional ( type-expr 'integer ) )
( scan-comparison world type-env special-form '>= expr1 expr2 type-expr ) )
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; (set<= <expr1> <expr2> <type>)
( defun scan-set<= ( world type-env special-form expr1 expr2 type-expr )
( scan-comparison world type-env special-form 'set<= expr1 expr2 type-expr ) )
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; (cascade <type> <expr1> <order1> <expr2> <order2> ... <ordern-1> <exprn>)
; Shorthand for (and (<order1> <expr1> <expr2> <type>) (<order1> <expr2> <expr3> <type>) ... (<ordern-1> <exprn-1> <exprn> <type>)),
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; where each order must be one of the symbols =, /=, <, >, <=, >=, set<=.
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; The intermediate expressions are evaluated at most once.
( defun scan-cascade ( world type-env special-form type-expr expr1 &rest orders-and-exprs )
( let ( ( type ( scan-type world type-expr ) ) )
( labels
( ( cascade ( v1 orders-and-exprs )
( unless ( and ( consp orders-and-exprs ) ( consp ( cdr orders-and-exprs ) )
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( member ( first orders-and-exprs ) ' ( = /= < > <= >= set<= ) ) )
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( error "Bad cascade tail: ~S" orders-and-exprs ) )
( let* ( ( order ( first orders-and-exprs ) )
( order-name ( comparison-name order ) )
( expr2 ( second orders-and-exprs ) )
( orders-and-exprs ( cddr orders-and-exprs ) ) )
( multiple-value-bind ( code2 annotated-expr2 ) ( scan-typed-value world type-env expr2 type )
( if orders-and-exprs
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( let ( ( v2 ( gen-local-var code2 ) ) )
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( multiple-value-bind ( codes annotations ) ( cascade v2 orders-and-exprs )
( values
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( let-local-var v2 code2
` ( and , ( get-type-order-code world type order v1 v2 ) , codes ) )
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( list* order-name annotated-expr2 annotations ) ) ) )
( values
( get-type-order-code world type order v1 code2 )
( list order-name annotated-expr2 ) ) ) ) ) ) )
( multiple-value-bind ( code1 annotated-expr1 ) ( scan-typed-value world type-env expr1 type )
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( let ( ( v1 ( gen-local-var code1 ) ) )
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( multiple-value-bind ( codes annotations ) ( cascade v1 orders-and-exprs )
( values
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( let-local-var v1 code1 codes )
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( world-boolean-type world )
( list* 'expr-annotation:special-form special-form annotated-expr1 annotations ) ) ) ) ) ) ) )
; (and <expr> ... <expr>)
; Short-circuiting logical AND.
( defun scan-and ( world type-env special-form expr &rest exprs )
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( multiple-value-bind ( code annotated-expr true-type-env false-type-env )
( apply #' scan-and-condition world type-env special-form expr exprs )
( declare ( ignore true-type-env false-type-env ) )
( values
code
( world-boolean-type world )
annotated-expr ) ) )
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; (or <expr> ... <expr>)
; Short-circuiting logical OR.
( defun scan-or ( world type-env special-form expr &rest exprs )
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( multiple-value-bind ( code annotated-expr true-type-env false-type-env )
( apply #' scan-or-condition world type-env special-form expr exprs )
( declare ( ignore true-type-env false-type-env ) )
( values
code
( world-boolean-type world )
annotated-expr ) ) )
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; (xor <expr> ... <expr>)
; Logical XOR.
( defun scan-xor ( world type-env special-form expr &rest exprs )
( multiple-value-map-bind ( codes annotated-exprs )
#' ( lambda ( expr )
( scan-typed-value world type-env expr ( world-boolean-type world ) ) )
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( ( cons expr exprs ) )
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( values
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( gen-poly-op 'xor nil codes )
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( world-boolean-type world )
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( list* 'expr-annotation:special-form special-form 'xor annotated-exprs ) ) ) )
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; (not <expr>)
( defun scan-not-condition ( world type-env special-form expr )
( multiple-value-bind ( expr-code expr-annotated-expr expr-true-type-env expr-false-type-env )
( scan-condition world type-env expr )
( values
( list 'not expr-code )
( list 'expr-annotation:call ( list 'expr-annotation:primitive special-form ) expr-annotated-expr )
expr-false-type-env
expr-true-type-env ) ) )
; (and <expr> ... <expr>)
; Short-circuiting logical AND.
( defun scan-and-condition ( world type-env special-form expr &rest exprs )
( multiple-value-bind ( code1 annotated-expr1 true-type-env false-type-env )
( scan-condition world type-env expr )
( let ( ( codes ( list code1 ) )
( annotated-exprs ( list annotated-expr1 ) ) )
( dolist ( expr2 exprs )
( multiple-value-bind ( code2 annotated-expr2 true-type-env2 false-type-env2 )
( scan-condition world true-type-env expr2 )
( push code2 codes )
( push annotated-expr2 annotated-exprs )
( setq true-type-env true-type-env2 )
( ensure-narrowed-type-env false-type-env false-type-env2 ) ) )
( values
( gen-poly-op 'and t ( nreverse codes ) )
( list* 'expr-annotation:special-form special-form 'and ( nreverse annotated-exprs ) )
true-type-env
false-type-env ) ) ) )
; (or <expr> ... <expr>)
; Short-circuiting logical OR.
( defun scan-or-condition ( world type-env special-form expr &rest exprs )
( multiple-value-bind ( code1 annotated-expr1 true-type-env false-type-env )
( scan-condition world type-env expr )
( let ( ( codes ( list code1 ) )
( annotated-exprs ( list annotated-expr1 ) ) )
( dolist ( expr2 exprs )
( multiple-value-bind ( code2 annotated-expr2 true-type-env2 false-type-env2 )
( scan-condition world false-type-env expr2 )
( push code2 codes )
( push annotated-expr2 annotated-exprs )
( setq false-type-env false-type-env2 )
( ensure-narrowed-type-env true-type-env true-type-env2 ) ) )
( values
( gen-poly-op 'or nil ( nreverse codes ) )
( list* 'expr-annotation:special-form special-form 'or ( nreverse annotated-exprs ) )
true-type-env
false-type-env ) ) ) )
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; (begin . <statements>)
; Only allowed at the top level of an action.
( defun finish-function-code ( world type-env result-type body-statements )
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( multiple-value-bind ( body-codes body-live body-annotated-stmts ) ( scan-statements world type-env body-statements t )
( assert-true ( or ( listp body-live ) ( eq body-live :dead ) ) )
( when ( and ( listp body-live ) ( not ( or ( type= result-type ( world-void-type world ) )
( type= result-type ( world-bottom-type world ) ) ) ) )
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( error "Execution falls off the end of a function with result type ~A" ( print-type-to-string result-type ) ) )
( let ( ( return-block-name ( get-type-env-flag type-env :return-block-name ) ) )
( values
( if return-block-name
( list ( list* 'block return-block-name body-codes ) )
body-codes )
body-annotated-stmts ) ) ) )
; Scan a local function.
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; arg-binding-exprs should have the form ((<var1> <type1> [:var | :unused]) ... (<varn> <typen> [:var | :unused])).
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; result-type-expr should be a type expression.
; body-statements contains the function's body statements.
; Return three values:
; A list of lisp function bindings followed by the code (i.e. '((a b c) (declare (ignore c)) (* a b)));
; The function's complete type;
; The annotated body statements.
( defun scan-function-or-lambda ( world type-env arg-binding-exprs result-type-expr body-statements )
( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
( format *error-output* "~&~@<~2IWhile processing lambda ~_~S ~_~S ~_~S:~:>~%"
arg-binding-exprs result-type-expr body-statements ) ) ) )
( let* ( ( result-type ( scan-type world result-type-expr ) )
( local-type-env ( type-env-init-function type-env result-type ) )
( args nil )
( arg-types nil )
( unused-args nil ) )
( unless ( listp arg-binding-exprs )
( error "Bad function bindings ~S" arg-binding-exprs ) )
( dolist ( arg-binding-expr arg-binding-exprs )
( unless ( and ( consp arg-binding-expr )
( consp ( cdr arg-binding-expr ) )
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( member ( cddr arg-binding-expr ) ' ( nil ( :var ) ( :unused ) ) :test #' equal ) )
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( error "Bad function binding ~S" arg-binding-expr ) )
( let ( ( arg-symbol ( scan-name world ( first arg-binding-expr ) ) )
( arg-type ( scan-type world ( second arg-binding-expr ) ) )
( arg-mode ( or ( third arg-binding-expr ) :const ) ) )
( setq local-type-env ( type-env-add-binding local-type-env arg-symbol arg-type arg-mode ) )
( push arg-symbol args )
( push arg-type arg-types )
( when ( eq arg-mode :unused )
( push arg-symbol unused-args ) ) ) )
( setq args ( nreverse args ) )
( setq arg-types ( nreverse arg-types ) )
( setq unused-args ( nreverse unused-args ) )
( multiple-value-bind ( body-codes body-annotated-stmts ) ( finish-function-code world local-type-env result-type body-statements )
( when unused-args
( push ( list 'declare ( cons 'ignore unused-args ) ) body-codes ) )
( values ( cons args body-codes )
( make-->-type world arg-types result-type )
body-annotated-stmts ) ) ) ) )
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; (lambda ((<var1> <type1> [:var | :unused]) ... (<varn> <typen> [:var | :unused])) <result-type> . <statements>)
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( defun scan-lambda ( world type-env special-form arg-binding-exprs result-type-expr &rest body-statements )
( multiple-value-bind ( args-and-body-codes type body-annotated-stmts )
( scan-function-or-lambda world type-env arg-binding-exprs result-type-expr body-statements )
( values
( list 'function ( cons 'lambda args-and-body-codes ) )
type
( list* 'expr-annotation:special-form special-form arg-binding-exprs result-type-expr body-annotated-stmts ) ) ) )
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; (coerce-parameters (<type1> ... <typen>) <function-expr>)
; Coerces the function <function-expr> to a function with the same number of parameters but with types
; <type1> through <typen>, which may be more general than <function-expr>'s parameter types. A dynamic check
; ensures that the run-time values belong to <function-expr>'s parameter types.
;*****
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; (if <condition-expr> <true-expr> <false-expr>)
( defun scan-if-expr ( world type-env special-form condition-expr true-expr false-expr )
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( multiple-value-bind ( condition-code condition-annotated-expr true-type-env false-type-env )
( scan-condition world type-env condition-expr )
( multiple-value-bind ( true-code true-type true-annotated-expr ) ( scan-value world true-type-env true-expr )
( multiple-value-bind ( false-code false-type false-annotated-expr ) ( scan-value world false-type-env false-expr )
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( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
( format *error-output* "~&~@<~2IWhile processing if with alternatives~_ ~S: ~A and~_ ~S: ~A:~:>~%"
true-expr ( print-type-to-string true-type )
false-expr ( print-type-to-string false-type ) ) ) ) )
( let ( ( type ( type-union world true-type false-type ) ) )
( values
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( list 'if condition-code
( widening-coercion-code world type true-type true-code condition-expr )
( widening-coercion-code world type false-type false-code condition-expr ) )
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type
( list 'expr-annotation:special-form special-form condition-annotated-expr true-annotated-expr false-annotated-expr ) ) ) ) ) ) ) )
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;;; Vectors
( defmacro non-empty-vector ( v operation-name )
` ( or , v ( error , ( concatenate 'string operation-name " called on empty vector" ) ) ) )
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( defun make-vector-expr ( world special-form element-type element-codes element-annotated-exprs )
( values
( if element-codes
( let ( ( elements-code ( cons 'list element-codes ) ) )
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( if ( eq element-type ( world-char16-type world ) )
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( if ( cdr element-codes )
( list 'coerce elements-code ' 'string )
( list 'string ( car element-codes ) ) )
elements-code ) )
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( if ( eq element-type ( world-char16-type world ) )
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""
nil ) )
( make-vector-type world element-type )
( list* 'expr-annotation:special-form special-form element-annotated-exprs ) ) )
; (vector <element-expr> ... <element-expr>)
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; Makes a vector of one or more elements.
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( defun scan-vector-expr ( world type-env special-form element-expr &rest element-exprs )
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( multiple-value-bind ( element-code element-type element-annotated-expr ) ( scan-value world type-env element-expr )
( multiple-value-map-bind ( rest-codes rest-annotated-exprs )
#' ( lambda ( element-expr )
( scan-typed-value world type-env element-expr element-type ) )
( element-exprs )
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( make-vector-expr world special-form element-type ( cons element-code rest-codes ) ( cons element-annotated-expr rest-annotated-exprs ) ) ) ) )
; (vector-of <element-type> <element-expr> ... <element-expr>)
; Makes a vector of zero or more elements of the given type.
( defun scan-vector-of ( world type-env special-form element-type-expr &rest element-exprs )
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( let ( ( element-type ( scan-type world element-type-expr ) ) )
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( multiple-value-map-bind ( element-codes element-annotated-exprs )
#' ( lambda ( element-expr )
( scan-typed-value world type-env element-expr element-type ) )
( element-exprs )
( make-vector-expr world special-form element-type element-codes element-annotated-exprs ) ) ) )
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; (repeat <element-type> <element-expr> <count-expr>)
; Makes a vector of count-expr copies of element-expr coerced to the given type.
( defun scan-repeat ( world type-env special-form element-type-expr element-expr count-expr )
( let ( ( element-type ( scan-type world element-type-expr ) ) )
( multiple-value-bind ( element-code element-annotated-expr ) ( scan-typed-value world type-env element-expr element-type )
( multiple-value-bind ( count-code count-annotated-expr ) ( scan-typed-value world type-env count-expr ( world-integer-type world ) )
( let ( ( vector-type ( make-vector-type world element-type ) ) )
( values
( if ( eq vector-type ( world-string-type world ) )
` ( make-string , count-code :initial-element , element-code )
` ( make-list , count-code :initial-element , element-code ) )
vector-type
( list 'expr-annotation:special-form special-form element-annotated-expr count-annotated-expr ) ) ) ) ) ) )
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; Same as nth, except that ensures that the element is actually present.
( defun checked-nth ( list n )
( car ( non-empty-vector ( nthcdr n list ) "nth" ) ) )
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; (nth <vector-expr> <n-expr>)
; Returns the nth element of the vector. Throws an error if the vector's length is less than n.
( defun scan-nth ( world type-env special-form vector-expr n-expr )
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( multiple-value-bind ( vector-code vector-type vector-annotated-expr ) ( scan-vector-value world type-env vector-expr )
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( multiple-value-bind ( n-code n-annotated-expr ) ( scan-typed-value world type-env n-expr ( world-integer-type world ) )
( values
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( cond
( ( eq vector-type ( world-string-type world ) )
` ( char , vector-code , n-code ) )
( ( eql n-code 0 )
` ( car ( non-empty-vector , vector-code "first" ) ) )
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( t ` ( checked-nth , vector-code , n-code ) ) )
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( vector-element-type vector-type )
( list 'expr-annotation:special-form special-form vector-annotated-expr n-annotated-expr ) ) ) ) )
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; (subseq <vector-expr> <low-expr> [<high-expr>])
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; Returns a vector containing elements of the given vector from low-expr to high-expr inclusive.
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; high-expr defaults to length-1.
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; It is required that 0 <= low-expr <= high-expr+1 <= length.
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( defun scan-subseq ( world type-env special-form vector-expr low-expr &optional high-expr )
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( let ( ( integer-type ( world-integer-type world ) ) )
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( multiple-value-bind ( vector-code vector-type vector-annotated-expr ) ( scan-vector-value world type-env vector-expr )
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( multiple-value-bind ( low-code low-annotated-expr ) ( scan-typed-value world type-env low-expr integer-type )
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( if high-expr
( multiple-value-bind ( high-code high-annotated-expr ) ( scan-typed-value world type-env high-expr integer-type )
( values
` ( subseq , vector-code , low-code ( 1+ , high-code ) )
vector-type
( list 'expr-annotation:special-form special-form vector-annotated-expr low-annotated-expr high-annotated-expr ) ) )
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( values
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( case low-code
( 0 vector-code )
( 1 ( if ( eq vector-type ( world-string-type world ) )
` ( subseq , vector-code 1 )
` ( cdr ( non-empty-vector , vector-code "rest" ) ) ) )
( t ` ( subseq , vector-code , low-code ) ) )
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vector-type
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( list 'expr-annotation:special-form special-form vector-annotated-expr low-annotated-expr nil ) ) ) ) ) ) )
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; (cons <value-expr> <vector-expr>)
; Returns a vector consisting of <value-expr> followed by all values in <vector-expr>.
( defun scan-cons ( world type-env special-form value-expr vector-expr )
( multiple-value-bind ( vector-code vector-type vector-annotated-expr ) ( scan-vector-value world type-env vector-expr )
( multiple-value-bind ( value-code value-annotated-expr ) ( scan-typed-value world type-env value-expr ( vector-element-type vector-type ) )
( values
( if ( eq vector-type ( world-string-type world ) )
` ( concatenate 'string ( list , value-code ) , vector-code )
( list 'cons value-code vector-code ) )
vector-type
( list 'expr-annotation:special-form special-form value-annotated-expr vector-annotated-expr ) ) ) ) )
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; (append <vector-expr> <vector-expr> ... <vector-expr>)
; Returns a vector contatenating the given vectors, which must have the same element type.
( defun scan-append ( world type-env special-form vector1-expr &rest vector-exprs )
( unless vector-exprs
( error "append requires at least two lists" ) )
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( multiple-value-bind ( vector1-code vector-type vector1-annotated-expr ) ( scan-vector-value world type-env vector1-expr )
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( multiple-value-map-bind ( vector-codes vector-annotated-exprs )
#' ( lambda ( vector-expr ) ( scan-typed-value world type-env vector-expr vector-type ) )
( vector-exprs )
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( values
( if ( eq vector-type ( world-string-type world ) )
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` ( concatenate 'string , vector1-code ,@ vector-codes )
( list* 'append vector1-code vector-codes ) )
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vector-type
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( list* 'expr-annotation:special-form special-form vector1-annotated-expr vector-annotated-exprs ) ) ) ) )
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; (set-nth <vector-expr> <n-expr> <value-expr>)
; Returns a vector containing the same elements of the given vector except that the nth has been replaced
; with value-expr. n must be between 0 and length-1, inclusive.
( defun scan-set-nth ( world type-env special-form vector-expr n-expr value-expr )
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( multiple-value-bind ( vector-code vector-type vector-annotated-expr ) ( scan-vector-value world type-env vector-expr )
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( multiple-value-bind ( n-code n-annotated-expr ) ( scan-typed-value world type-env n-expr ( world-integer-type world ) )
( multiple-value-bind ( value-code value-annotated-expr ) ( scan-typed-value world type-env value-expr ( vector-element-type vector-type ) )
( values
( let ( ( vector ( gensym "V" ) )
( n ( gensym "N" ) ) )
` ( let ( ( , vector , vector-code )
( , n , n-code ) )
( if ( or ( < , n 0 ) ( >= , n ( length , vector ) ) )
( error "Range error" )
, ( if ( eq vector-type ( world-string-type world ) )
` ( progn
( setq , vector ( copy-seq , vector ) )
( setf ( char , vector , n ) , value-code )
, vector )
( let ( ( l ( gensym "L" ) ) )
` ( let ( ( , l ( nthcdr , n , vector ) ) )
( append ( ldiff , vector , l )
( cons , value-code ( cdr , l ) ) ) ) ) ) ) ) )
vector-type
( list 'expr-annotation:special-form special-form vector-annotated-expr n-annotated-expr value-annotated-expr ) ) ) ) ) )
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;;; Sets
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( defun make-list-set-expr ( world special-form element-type element-codes element-annotated-exprs )
( values
( cond
( ( endp element-codes ) nil )
( ( endp ( cdr element-codes ) ) ( cons 'list element-codes ) )
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( ( every #' ( lambda ( element ) ( or ( numberp element ) ( stringp element ) ) ) element-codes )
( list 'quote ( remove-duplicates element-codes :test #' equal ) ) )
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( t ` ( delete-duplicates ( list ,@ element-codes ) ,@ ( element-test world element-type ) ) ) )
( make-list-set-type world element-type )
( list* 'expr-annotation:special-form special-form element-annotated-exprs ) ) )
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; (list-set <element-expr> ... <element-expr>)
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; (%list-set <element-expr> ... <element-expr>)
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; Makes a set of one or more elements.
( defun scan-list-set-expr ( world type-env special-form element-expr &rest element-exprs )
( multiple-value-bind ( element-code element-type element-annotated-expr ) ( scan-value world type-env element-expr )
( multiple-value-map-bind ( rest-codes rest-annotated-exprs )
#' ( lambda ( element-expr )
( scan-typed-value world type-env element-expr element-type ) )
( element-exprs )
( make-list-set-expr world special-form element-type ( cons element-code rest-codes ) ( cons element-annotated-expr rest-annotated-exprs ) ) ) ) )
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; (list-set-of <element-type> <element-expr> ... <element-expr>)
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; (%list-set-of <element-type> <element-expr> ... <element-expr>)
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; Makes a set of zero or more elements of the given type.
( defun scan-list-set-of ( world type-env special-form element-type-expr &rest element-exprs )
( let ( ( element-type ( scan-type world element-type-expr ) ) )
( multiple-value-map-bind ( element-codes element-annotated-exprs )
#' ( lambda ( element-expr )
( scan-typed-value world type-env element-expr element-type ) )
( element-exprs )
( make-list-set-expr world special-form element-type element-codes element-annotated-exprs ) ) ) )
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; expr is the source code of an expression that generates a value of the given element-type. Return
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; the source code of an expression that generates the corresponding integer for storage in a range-set of
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; the given element-type.
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( defun range-set-encode-expr ( element-type expr )
( let ( ( encode ( type-range-set-encode element-type ) ) )
( cond
( ( null encode ) ( error "Values of type ~S cannot be stored in range-sets" element-type ) )
( ( eq encode 'identity ) expr )
( t ( list encode expr ) ) ) ) )
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; expr is the source code of an expression that generates an integer. Return the source code that undoes
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; the transformation done by range-set-encode-expr.
( defun range-set-decode-expr ( element-type expr )
( let ( ( decode ( type-range-set-decode element-type ) ) )
( cond
( ( null decode ) ( error "Values of type ~S cannot be stored in range-sets" element-type ) )
( ( eq decode 'identity ) expr )
( t ( list decode expr ) ) ) ) )
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; Return a function that converts integers to values of the given element-type for retrieval from a range-set.
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( defun range-set-decode-function ( element-type )
( symbol-function ( type-range-set-decode element-type ) ) )
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; (range-set-of <element-type> <element-expr> ... <element-expr>) ==>
; (range-set-of-ranges <element-type> <element-expr> nil ... <element-expr> nil)
( defun scan-range-set-of ( world type-env special-form element-type-expr &rest element-exprs )
( apply #' scan-range-set-of-ranges
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world type-env special-form element-type-expr
( mapcan #' ( lambda ( element-expr )
( list element-expr nil ) )
element-exprs ) ) )
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; (range-set-of-ranges <element-type> <low-expr> <high-expr> ... <low-expr> <high-expr>)
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; Makes a set of zero or more elements or element ranges. Each <high-expr> can be null to indicate a
; one-element range.
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( defun scan-range-set-of-ranges ( world type-env special-form element-type-expr &rest element-exprs )
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( let* ( ( element-type ( scan-type world element-type-expr ) )
( high t ) )
( multiple-value-map-bind ( element-codes element-annotated-exprs )
#' ( lambda ( element-expr )
( setq high ( not high ) )
( if ( and high ( null element-expr ) )
( values nil nil )
( multiple-value-bind ( element-code element-annotated-expr )
( scan-typed-value world type-env element-expr element-type )
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( values ( range-set-encode-expr element-type element-code )
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element-annotated-expr ) ) ) )
( element-exprs )
( unless high
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( error "Odd number of range-set-of-ranges elements: ~S" element-exprs ) )
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( values
( cons 'intset-from-ranges element-codes )
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( make-range-set-type world element-type )
( list* 'expr-annotation:special-form special-form element-annotated-exprs ) ) ) ) )
; (set* <set-expr> <set-expr>)
; Returns the intersection of the two sets, which must have the same kind.
( defun scan-set* ( world type-env special-form set1-expr set2-expr )
( multiple-value-bind ( set1-code set-type set1-annotated-expr ) ( scan-set-value world type-env set1-expr )
( multiple-value-bind ( set2-code set2-annotated-expr ) ( scan-typed-value world type-env set2-expr set-type )
( values
( ecase ( type-kind set-type )
( :list-set ( list* 'intersection set1-code set2-code ( element-test world ( set-element-type set-type ) ) ) )
( :range-set ( list 'intset-intersection set1-code set2-code ) ) )
set-type
( list 'expr-annotation:special-form special-form set1-annotated-expr set2-annotated-expr ) ) ) ) )
; (set+ <set-expr> <set-expr>)
; Returns the union of the two sets, which must have the same kind.
( defun scan-set+ ( world type-env special-form set1-expr set2-expr )
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( multiple-value-bind ( set1-code set1-type set1-annotated-expr ) ( scan-set-value world type-env set1-expr )
( multiple-value-bind ( set2-code set2-type set2-annotated-expr ) ( scan-set-value world type-env set2-expr )
( let* ( ( set-type ( type-union world set1-type set2-type ) )
( set1-coerced-code ( widening-coercion-code world set-type set1-type set1-code set1-expr ) )
( set2-coerced-code ( widening-coercion-code world set-type set2-type set2-code set2-expr ) ) )
( values
( ecase ( type-kind set-type )
( :list-set ( list* 'union set1-coerced-code set2-coerced-code ( element-test world ( set-element-type set-type ) ) ) )
( :range-set ( list 'intset-union set1-coerced-code set2-coerced-code ) ) )
set-type
( list 'expr-annotation:special-form special-form set1-annotated-expr set2-annotated-expr ) ) ) ) ) )
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; (set- <set-expr> <set-expr>)
; Returns the difference of the two sets, which must have the same kind.
( defun scan-set- ( world type-env special-form set1-expr set2-expr )
( multiple-value-bind ( set1-code set-type set1-annotated-expr ) ( scan-set-value world type-env set1-expr )
( multiple-value-bind ( set2-code set2-annotated-expr ) ( scan-typed-value world type-env set2-expr set-type )
( values
( ecase ( type-kind set-type )
( :list-set ( list* 'set-difference set1-code set2-code ( element-test world ( set-element-type set-type ) ) ) )
( :range-set ( list 'intset-difference set1-code set2-code ) ) )
set-type
( list 'expr-annotation:special-form special-form set1-annotated-expr set2-annotated-expr ) ) ) ) )
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( defun bit-set-index-code ( type elt-code )
( let ( ( keywords ( set-type-keywords type ) ) )
( if ( keywordp elt-code )
( position elt-code keywords )
( list 'position elt-code ( list 'quote keywords ) ) ) ) )
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; (set-in <elt-expr> <set-expr>)
; Returns true if <elt-expr> is a member of the set <set-expr>.
( defun scan-set-in ( world type-env special-form elt-expr set-expr )
( multiple-value-bind ( set-code set-type set-annotated-expr ) ( scan-set-value world type-env set-expr )
( let ( ( elt-type ( set-element-type set-type ) ) )
( multiple-value-bind ( elt-code elt-annotated-expr ) ( scan-typed-value world type-env elt-expr elt-type )
( values
( ecase ( type-kind set-type )
( :list-set ( list* 'member elt-code set-code ( element-test world elt-type ) ) )
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( :range-set ( list 'intset-member? ( range-set-encode-expr elt-type elt-code ) set-code ) )
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( ( :bit-set :restricted-set ) ( list 'logbitp ( bit-set-index-code set-type elt-code ) set-code ) ) )
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( world-boolean-type world )
( list 'expr-annotation:special-form special-form :member-10 elt-annotated-expr set-annotated-expr ) ) ) ) ) )
; (set-not-in <elt-expr> <set-expr>)
; Returns true if <elt-expr> is not a member of the set <set-expr>.
( defun scan-set-not-in ( world type-env special-form elt-expr set-expr )
( multiple-value-bind ( set-code set-type set-annotated-expr ) ( scan-set-value world type-env set-expr )
( let ( ( elt-type ( set-element-type set-type ) ) )
( multiple-value-bind ( elt-code elt-annotated-expr ) ( scan-typed-value world type-env elt-expr elt-type )
( values
( ecase ( type-kind set-type )
( :list-set ( list 'not ( list* 'member elt-code set-code ( element-test world elt-type ) ) ) )
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( :range-set ( list 'not ( list 'intset-member? ( range-set-encode-expr elt-type elt-code ) set-code ) ) )
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( ( :bit-set :restricted-set ) ( list 'not ( list 'logbitp ( bit-set-index-code set-type elt-code ) set-code ) ) ) )
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( world-boolean-type world )
( list 'expr-annotation:special-form special-form :not-member-10 elt-annotated-expr set-annotated-expr ) ) ) ) ) )
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( defun elt-of ( set )
( if set
( car set )
( error "elt-of called on empty set" ) ) )
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( defun range-set-elt-of ( set )
( or ( intset-min set )
( error "elt-of called on empty set" ) ) )
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( defun bit-set-elt-of ( set keywords )
( dolist ( keyword keywords )
( when ( oddp set )
( return-from bit-set-elt-of keyword ) )
( setq set ( ash set -1 ) ) )
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( error "elt-of called on empty set" ) )
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; (elt-of <elt-expr>)
; Returns any element of <set-expr>, which must be a nonempty set.
( defun scan-elt-of ( world type-env special-form set-expr )
( multiple-value-bind ( set-code set-type set-annotated-expr ) ( scan-set-value world type-env set-expr )
( let ( ( elt-type ( set-element-type set-type ) ) )
( values
( ecase ( type-kind set-type )
( :list-set ( list 'elt-of set-code ) )
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( :range-set ( range-set-decode-expr elt-type ( list 'range-set-elt-of set-code ) ) )
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( ( :bit-set :restricted-set ) ( list 'bit-set-elt-of set-code ( list 'quote ( set-type-keywords set-type ) ) ) ) )
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elt-type
( list 'expr-annotation:special-form special-form set-annotated-expr ) ) ) ) )
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( defun unique-elt-of ( set )
( if ( and set ( endp ( cdr set ) ) )
( car set )
( error "unique-elt-of called on a set with other than one element" ) ) )
( defun range-set-unique-elt-of ( set )
( unless ( = ( intset-length set ) 1 )
( error "unique-elt-of called on a set with other than one element" ) )
( intset-min set ) )
( defun bit-set-unique-elt-of ( set keywords )
( unless ( = ( logcount set ) 1 )
( error "unique-elt-of called on a set with other than one element" ) )
( assert-non-null ( nth ( integer-length set ) keywords ) ) )
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; (unique-elt-of <elt-expr> [<var> <condition-expr>])
; Returns the one element of <set-expr>, which must have exactly one element. If <var> and <condition-expr> are given,
; then return the one element of <set-expr> that satisfies <condition-expr>; there must be exactly one such element.
; <var> may shadow an existing local variable.
( defun scan-unique-elt-of ( world type-env special-form set-expr &optional var-source condition-expr )
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( multiple-value-bind ( set-code set-type set-annotated-expr ) ( scan-set-value world type-env set-expr )
( let ( ( elt-type ( set-element-type set-type ) ) )
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( if var-source
( let* ( ( var ( scan-name world var-source ) )
( local-type-env ( type-env-add-binding type-env var elt-type :const t ) ) )
( multiple-value-bind ( condition-code condition-annotated-expr ) ( scan-typed-value world local-type-env condition-expr ( world-boolean-type world ) )
( unless ( eq ( type-kind set-type ) :list-set )
( error "Not implemented" ) )
( values
` ( unique-elt-of ( remove-if-not #' ( lambda ( , var ) , condition-code ) , set-code ) )
elt-type
( list 'expr-annotation:special-form special-form set-annotated-expr var condition-annotated-expr ) ) ) )
( values
( ecase ( type-kind set-type )
( :list-set ( list 'unique-elt-of set-code ) )
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( :range-set ( range-set-decode-expr elt-type ( list 'range-set-unique-elt-of set-code ) ) )
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( ( :bit-set :restricted-set ) ( list 'bit-set-unique-elt-of set-code ( list 'quote ( set-type-keywords set-type ) ) ) ) )
elt-type
( list 'expr-annotation:special-form special-form set-annotated-expr ) ) ) ) ) )
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;;; Vectors or Sets
; (empty <vector-or-set-expr>)
; Returns true if the vector or set has zero elements.
; This is equivalent to (= (length <vector-or-set-expr>) 0) but is implemented more efficiently.
( defun scan-empty ( world type-env special-form collection-expr )
( multiple-value-bind ( collection-code collection-kind element-type collection-annotated-expr ) ( scan-collection-value world type-env collection-expr )
( declare ( ignore element-type ) )
( values
( ecase collection-kind
( :string ` ( zerop ( length , collection-code ) ) )
( ( :vector :list-set ) ( list 'endp collection-code ) )
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( :range-set ( list 'intset-empty collection-code ) )
( ( :bit-set :restricted-set ) ( list '= collection-code 0 ) ) )
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( world-boolean-type world )
( list 'expr-annotation:special-form special-form collection-kind collection-annotated-expr ) ) ) )
; (nonempty <vector-or-set-expr>)
; Returns true if the vector or set does not have zero elements.
; This is equivalent to (/= (length <vector-or-set-expr>) 0) but is implemented more efficiently.
( defun scan-nonempty ( world type-env special-form collection-expr )
( multiple-value-bind ( collection-code collection-kind element-type collection-annotated-expr ) ( scan-collection-value world type-env collection-expr )
( declare ( ignore element-type ) )
( values
( ecase collection-kind
( :string ` ( /= ( length , collection-code ) 0 ) )
( ( :vector :list-set ) collection-code )
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( :range-set ` ( not ( intset-empty , collection-code ) ) )
( ( :bit-set :restricted-set ) ( list '/= collection-code 0 ) ) )
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( world-boolean-type world )
( list 'expr-annotation:special-form special-form collection-kind collection-annotated-expr ) ) ) )
; (length <vector-or-set-expr>)
; Returns the number of elements in the vector or set.
( defun scan-length ( world type-env special-form collection-expr )
( multiple-value-bind ( collection-code collection-kind element-type collection-annotated-expr ) ( scan-collection-value world type-env collection-expr )
( declare ( ignore element-type ) )
( values
( ecase collection-kind
( ( :string :vector :list-set ) ( list 'length collection-code ) )
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( :range-set ( list 'intset-length collection-code ) )
( ( :bit-set :restricted-set ) ( list 'logcount collection-code ) ) )
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( world-integer-type world )
( list 'expr-annotation:special-form special-form collection-annotated-expr ) ) ) )
; (some <vector-or-set-expr> <var> <condition-expr>)
; Return true if there exists an element <var> of <vector-or-set-expr> on which <condition-expr> is true.
; Not implemented on range-sets.
( defun scan-some ( world type-env special-form collection-expr var-source condition-expr )
( multiple-value-bind ( code annotated-expr true-type-env false-type-env )
( scan-some-condition world type-env special-form collection-expr var-source condition-expr )
( declare ( ignore true-type-env false-type-env ) )
( values code ( world-boolean-type world ) annotated-expr ) ) )
; (some <vector-or-set-expr> <var> <condition-expr> [:define-true])
; Return true if there exists an element <var> of <vector-or-set-expr> on which <condition-expr> is true.
; If :define-true is given, set <var> to be any such element (the first if in a vector) in the true branch; <var> must have been reserved.
; Not implemented on range-sets.
( defun scan-some-condition ( world type-env special-form collection-expr var-source condition-expr &optional define-true )
( unless ( member define-true ' ( nil :define-true ) )
( error "~S must be :define-true" ) )
( multiple-value-bind ( collection-code collection-kind element-type collection-annotated-expr ) ( scan-collection-value world type-env collection-expr )
( unless ( member collection-kind ' ( :vector :string :list-set ) )
( error "Not implemented" ) )
( let* ( ( var ( scan-name world var-source ) )
( local-type-env ( if define-true
( type-env-unreserve-binding type-env var element-type )
( type-env-add-binding type-env var element-type :const ) ) ) )
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( multiple-value-bind ( condition-code condition-annotated-expr true-type-env false-type-env ) ( scan-condition world local-type-env condition-expr )
( declare ( ignore false-type-env ) )
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( let ( ( result-annotated-expr ( list 'expr-annotation:special-form special-form 'some collection-annotated-expr var condition-annotated-expr ) )
( coerced-collection-code ( if ( eq collection-kind :string ) ` ( coerce , collection-code 'list ) collection-code ) ) )
( if define-true
( values
( let ( ( v ( gensym "V" ) ) )
` ( dolist ( , v , coerced-collection-code )
( when ( let ( ( , var , v ) ) , condition-code )
( setq , var , v )
( return t ) ) ) )
result-annotated-expr
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true-type-env
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type-env )
( values
` ( some #' ( lambda ( , var ) , condition-code ) , coerced-collection-code )
result-annotated-expr
type-env
type-env ) ) ) ) ) ) )
; (every <vector-or-set-expr> <var> <condition-expr>)
; Return true if every element <var> in <vector-or-set-expr> satisfies <condition-expr>.
; Not implemented on range-sets.
( defun scan-every ( world type-env special-form collection-expr var-source condition-expr )
( multiple-value-bind ( collection-code collection-kind element-type collection-annotated-expr ) ( scan-collection-value world type-env collection-expr )
( unless ( member collection-kind ' ( :vector :string :list-set ) )
( error "Not implemented" ) )
( let* ( ( var ( scan-name world var-source ) )
( local-type-env ( type-env-add-binding type-env var element-type :const ) ) )
( multiple-value-bind ( condition-code condition-annotated-expr ) ( scan-typed-value world local-type-env condition-expr ( world-boolean-type world ) )
( let ( ( coerced-collection-code ( if ( eq collection-kind :string ) ` ( coerce , collection-code 'list ) collection-code ) ) )
( values
` ( every #' ( lambda ( , var ) , condition-code ) , coerced-collection-code )
( world-boolean-type world )
( list 'expr-annotation:special-form special-form 'every collection-annotated-expr var condition-annotated-expr ) ) ) ) ) ) )
; (map <vector-or-set-expr> <var> <value-expr> [<condition-expr>])
; Return a vector or set of <value-expr> applied to all elements <var> of <vector-or-set-expr> on which <condition-expr> is true.
; The map produces a vector if given a vector or a list-set if given a list-set.
; Not implemented on range-sets.
( defun scan-map ( world type-env special-form collection-expr var-source value-expr &optional ( condition-expr 'true ) )
( multiple-value-bind ( collection-code collection-kind element-type collection-annotated-expr ) ( scan-collection-value world type-env collection-expr )
( let* ( ( var ( scan-name world var-source ) )
( local-type-env ( type-env-add-binding type-env var element-type :const ) ) )
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( multiple-value-bind ( condition-code condition-annotated-expr true-type-env false-type-env )
( scan-condition world local-type-env condition-expr )
( declare ( ignore false-type-env ) )
( multiple-value-bind ( value-code value-type value-annotated-expr ) ( scan-value world true-type-env value-expr )
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( let* ( ( source-is-vector ( member collection-kind ' ( :string :vector ) ) )
( source-is-string ( eq collection-kind :string ) )
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( destination-is-string ( and source-is-vector ( eq value-type ( world-char16-type world ) ) ) )
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( result-type ( case collection-kind
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( ( :string :vector ) ( make-vector-type world value-type ) )
( :list-set ( make-list-set-type world value-type ) )
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( t ( error "Map not implemented on this kind of a set" ) ) ) )
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( destination-sequence-type ( if destination-is-string 'string 'list ) )
( result-annotated-expr ( list 'expr-annotation:special-form special-form collection-kind collection-annotated-expr var value-annotated-expr condition-annotated-expr ) ) )
( cond
( ( eq condition-code 't )
( values
( let ( ( mapcar-code ` ( mapcar #' ( lambda ( , var ) , value-code ) , collection-code ) ) )
( cond
( ( or source-is-string destination-is-string ) ` ( map ',destination-sequence-type ,@ ( cdr mapcar-code ) ) )
( source-is-vector mapcar-code )
( t ( list* 'delete-duplicates mapcar-code ( element-test world value-type ) ) ) ) )
result-type
( nbutlast result-annotated-expr ) ) )
( ( eq value-expr var-source )
( values
` ( remove-if-not #' ( lambda ( , var ) , condition-code ) , collection-code )
result-type
result-annotated-expr ) )
( t
( values
( let ( ( filter-map-list-code ` ( filter-map-list #' ( lambda ( , var ) , condition-code ) #' ( lambda ( , var ) , value-code ) , collection-code ) ) )
( cond
( ( or source-is-string destination-is-string ) ` ( filter-map ',destination-sequence-type ,@ ( cdr filter-map-list-code ) ) )
( source-is-vector filter-map-list-code )
( t ( list* 'delete-duplicates filter-map-list-code ( element-test world value-type ) ) ) ) )
result-type
result-annotated-expr ) ) ) ) ) ) ) ) )
;;; Tuples and Records
( defparameter *record-counter* 0 )
; (new <type> <field-expr1> ... <field-exprn>)
; Used to create both tuples and records.
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; A <field-expr> should be one of the following:
; an expression
; :uninit to indicate an uninitialized field, which must have kind :opt-const or :opt-var
; (:delay <global-var>) to indicate a field (which must have kind :opt-const or :opt-var) initialized the first time it's read to a global variable
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( defun scan-new ( world type-env special-form type-name &rest value-exprs )
( let* ( ( type ( scan-kinded-type world type-name :tag ) )
( tag ( type-tag type ) )
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( fields ( tag-fields tag ) ) )
( unless ( = ( length value-exprs ) ( length fields ) )
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( error "Wrong number of ~A fields given in constructor: ~S" type-name value-exprs ) )
( when ( tag-keyword tag )
( error "Don't use new to create tag ~A; refer to the tag directly instead" type-name ) )
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( multiple-value-map-bind ( value-codes value-annotated-exprs )
#' ( lambda ( field value-expr )
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( cond
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( ( eq value-expr :uninit )
( if ( field-optional field )
( values :%uninit% value-expr )
( error "Can't leave non-optional field ~S uninitialized" ( field-label field ) ) ) )
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( ( field-optional field )
( scan-typed-value world type-env value-expr ( make-delay-type world ( field-type field ) ) ) )
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( t ( scan-typed-value world type-env value-expr ( field-type field ) ) ) ) )
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( fields value-exprs )
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( values
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( let ( ( name ( tag-name tag ) ) )
( if ( tag-mutable tag )
( list* 'list ( list 'quote name ) ' ( incf *record-counter* ) value-codes )
( list* 'list ( list 'quote name ) value-codes ) ) )
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type
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( list* 'expr-annotation:special-form special-form type type-name value-annotated-exprs ) ) ) ) )
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( defun check-optional-value ( value )
( cond
( ( eq value :%uninit% ) ( error "Uninitialized field read" ) )
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( ( delayed-value? value )
( let ( ( s ( delayed-value-symbol value ) ) )
( if ( boundp s )
( symbol-value s )
( compute-variable-value s ) ) ) )
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( t value ) ) )
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; Return the tuple or record field's value.
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( defun scan-&-maybe-opt ( world type-env special-form label record-expr opt )
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( multiple-value-bind ( record-code record-type tags record-annotated-expr ) ( scan-union-tag-value world type-env record-expr )
( let ( ( position-alist nil )
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( field-types nil )
( any-opt nil ) )
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( dolist ( tag tags )
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( multiple-value-bind ( position field-type mutable optional ) ( scan-label tag label )
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( declare ( ignore mutable ) )
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( when optional
( setq any-opt t ) )
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( let ( ( entry ( assoc position position-alist ) ) )
( unless entry
( setq entry ( cons position nil ) )
( push entry position-alist ) )
( assert-true ( null ( tag-keyword tag ) ) )
( push ( tag-name tag ) ( cdr entry ) )
( push field-type field-types ) ) ) )
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( unless ( eq opt any-opt )
( if any-opt
( error "The field ~S may be uninitialized; use &opt instead" label )
( error "The field ~S is always initialized; use & instead" label ) ) )
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( assert-true position-alist )
( setq position-alist ( sort position-alist #' < :key #' car ) )
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( let ( ( result-type ( apply #' make-union-type world field-types ) ) )
( dolist ( field-type field-types )
( unless ( eq ( widening-coercion-code world result-type field-type 'test 'test ) 'test )
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( error "Nontrivial type coercions in & are not implemented yet" ) ) )
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( let ( ( code ( let ( ( n ( caar position-alist ) ) )
( if ( endp ( cdr position-alist ) )
( if ( = n -1 )
( list 'rational record-code )
( gen-nth-code n record-code ) )
( let ( ( var ( gen-local-var record-code ) ) )
( let-local-var var record-code
( if ( /= n -1 )
` ( case ( car , var )
,@ ( mapcar #' ( lambda ( entry ) ( list ( cdr entry ) ( gen-nth-code ( car entry ) var ) ) )
position-alist ) )
` ( if ( floatp , var )
( rational , var )
, ( if ( endp ( cddr position-alist ) )
( gen-nth-code ( caadr position-alist ) record-code )
` ( case ( car , var )
,@ ( mapcar #' ( lambda ( entry ) ( list ( cdr entry ) ( gen-nth-code ( car entry ) var ) ) )
( cdr position-alist ) ) ) ) ) ) ) ) ) ) ) )
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( values
( if any-opt
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( list 'check-optional-value code )
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code )
result-type
( list 'expr-annotation:special-form special-form record-type label record-annotated-expr ) ) ) ) ) ) )
; (& <label> <record-expr>)
; Return the tuple or record field's value.
( defun scan-& ( world type-env special-form label record-expr )
( scan-&-maybe-opt world type-env special-form label record-expr nil ) )
; (&opt <label> <record-expr>)
; Return the tuple or record field's value. Assert that the value is present.
( defun scan-&opt ( world type-env special-form label record-expr )
( scan-&-maybe-opt world type-env special-form label record-expr t ) )
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; (set-field <expr> <label> <field-expr> ... <label> <field-expr>)
; Return a new tuple or record with its fields the same as in <expr> except for the specified ones.
( defun scan-set-field ( world type-env special-form record-expr &rest labels-and-exprs )
( multiple-value-bind ( record-code record-type record-annotated-expr ) ( scan-value world type-env record-expr )
( let ( ( n-replaced-fields ( length labels-and-exprs ) ) )
( when ( oddp n-replaced-fields )
( error "Label without a field value in set-field" ) )
( setq n-replaced-fields ( / n-replaced-fields 2 ) )
( unless ( eq ( type-kind record-type ) :tag )
( error "Value ~S:~A should be a tuple or a record" record-expr ( print-type-to-string record-type ) ) )
( let* ( ( tag ( type-tag record-type ) )
( mutable ( tag-mutable tag ) )
( fields ( tag-fields tag ) )
( record-var ( gen-local-var record-code ) )
( n-fields ( length fields ) )
( replacements nil )
( annotated-fields nil ) )
( unless ( > n-fields n-replaced-fields )
( error "set-field replaces all fields in the tuple or record" ) )
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( do ( ( i n-fields ( 1- i ) ) )
( ( zerop i ) )
( push ( gen-nth-code ( + i ( if mutable 1 0 ) ) record-var ) replacements ) )
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( when mutable
( push ' ( incf *record-counter* ) replacements ) )
( push ( list 'quote ( tag-name tag ) ) replacements )
( do ( ( replacement-mask 0 ) )
( ( endp labels-and-exprs ) )
( let ( ( label ( pop labels-and-exprs ) )
( field-expr ( pop labels-and-exprs ) ) )
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( multiple-value-bind ( position field-type mutable optional ) ( scan-label tag label )
( declare ( ignore mutable optional ) )
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( when ( logbitp position replacement-mask )
( error "Duplicate set-field label ~S" label ) )
( setq replacement-mask ( dpb 1 ( byte 1 position ) replacement-mask ) )
( multiple-value-bind ( field-code field-annotated-expr )
( scan-typed-value world type-env field-expr field-type )
( setf ( nth position replacements ) field-code )
( push ( list label field-annotated-expr ) annotated-fields ) ) ) ) )
( values
( cons 'list replacements )
record-type
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( list* 'expr-annotation:special-form special-form record-type record-annotated-expr ( nreverse annotated-fields ) ) ) ) ) ) )
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;;; Unions
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; (in <expr> <type>)
( defun scan-in ( world type-env special-form value-expr type-expr )
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( let ( ( type ( scan-type world type-expr ) ) )
( multiple-value-bind ( value-code value-type value-annotated-expr ) ( scan-value world type-env value-expr )
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( type-difference world value-type type )
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( values
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( let ( ( var ( gen-local-var value-code ) ) )
( let-local-var var value-code
( type-member-test-code world type value-type var ) ) )
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( world-boolean-type world )
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( list 'expr-annotation:special-form special-form value-annotated-expr type type-expr ) ) ) ) )
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; (in <var> <type> <criteria>)
; <criteria> is one of:
; nil Don't constrain the type of <var>, which can also be an expression in this case only
; :narrow-true Constrain the type of <var> in the true branch
; :narrow-false Constrain the type of <var> in the false branch
; :narrow-both Constrain the type of <var> in both branches
( defun scan-in-condition ( world type-env special-form var-expr type-expr &optional criteria )
( cond
( ( null criteria )
( multiple-value-bind ( code type annotated-expr ) ( scan-in world type-env special-form var-expr type-expr )
( declare ( ignore type ) )
( values code annotated-expr type-env type-env ) ) )
( ( not ( identifier? var-expr ) )
( error "~S must be a variable" var-expr ) )
( ( not ( member criteria ' ( :narrow-true :narrow-false :narrow-both ) ) )
( error "Bad criteria ~S" criteria ) )
( t ( let ( ( type ( scan-type world type-expr ) ) )
( multiple-value-bind ( var var-type var-annotated-expr ) ( scan-value world type-env var-expr )
( multiple-value-bind ( true-type false-type ) ( type-difference world var-type ( scan-type world type-expr ) )
( assert-true ( symbolp var ) )
( values
( type-member-test-code world type var-type var )
( list 'expr-annotation:special-form special-form var-annotated-expr type type-expr )
( if ( member criteria ' ( :narrow-true :narrow-both ) )
( type-env-narrow-binding type-env var true-type )
type-env )
( if ( member criteria ' ( :narrow-false :narrow-both ) )
( type-env-narrow-binding type-env var false-type )
type-env ) ) ) ) ) ) ) )
; (not-in <expr> <type>)
( defun scan-not-in ( world type-env special-form value-expr type-expr )
( multiple-value-bind ( code type annotated-expr ) ( scan-in world type-env special-form value-expr type-expr )
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( values
( list 'not code )
type
annotated-expr ) ) )
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; (not-in <var> <type> <criteria>)
; <criteria> is one of:
; nil Don't constrain the type of <var>, which can also be an expression in this case only
; :narrow-true Constrain the type of <var> in the true branch
; :narrow-false Constrain the type of <var> in the false branch
; :narrow-both Constrain the type of <var> in both branches
( defun scan-not-in-condition ( world type-env special-form var-expr type-expr &optional criteria )
( let ( ( reverse-criteria ( assoc criteria ' ( ( nil . nil ) ( :narrow-true . :narrow-false ) ( :narrow-false . :narrow-true ) ( :narrow-both . :narrow-both ) ) ) ) )
( unless reverse-criteria
( error "Bad criteria ~S" criteria ) )
( multiple-value-bind ( code annotated-expr true-type-env false-type-env )
( scan-in-condition world type-env special-form var-expr type-expr ( cdr reverse-criteria ) )
( values
( list 'not code )
annotated-expr
false-type-env
true-type-env ) ) ) )
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; (assert-in <expr> <type>)
; Returns the value of <expr>.
( defun scan-assert-in ( world type-env special-form value-expr type-expr )
( let ( ( type ( scan-type world type-expr ) ) )
( multiple-value-bind ( value-code value-type value-annotated-expr ) ( scan-value world type-env value-expr )
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( multiple-value-bind ( true-type false-type ) ( type-difference world value-type type )
( declare ( ignore false-type ) )
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( values
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( let ( ( var ( gen-local-var value-code ) ) )
( let-local-var var value-code
( list 'assert ( type-member-test-code world type value-type var ) )
var ) )
true-type
( list 'expr-annotation:special-form special-form value-annotated-expr type type-expr ) ) ) ) ) )
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; (assert-not-in <expr> <type>)
; Returns the value of <expr>.
( defun scan-assert-not-in ( world type-env special-form value-expr type-expr )
( let ( ( type ( scan-type world type-expr ) ) )
( multiple-value-bind ( value-code value-type value-annotated-expr ) ( scan-value world type-env value-expr )
( multiple-value-bind ( true-type false-type ) ( type-difference world value-type type )
( declare ( ignore true-type ) )
( values
( let ( ( var ( gen-local-var value-code ) ) )
( let-local-var var value-code
( list 'assert ( list 'not ( type-member-test-code world type value-type var ) ) )
var ) )
false-type
( list 'expr-annotation:special-form special-form value-annotated-expr type type-expr ) ) ) ) ) )
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;;; Writable Cells
; (writable-cell-of <element-type>)
; Makes an uninitialized writable cell of the given type.
( defun scan-writable-cell-of ( world type-env special-form element-type-expr )
( declare ( ignore type-env ) )
( let ( ( element-type ( scan-type world element-type-expr ) ) )
( values
' ( cons nil nil )
( make-writable-cell-type world element-type )
( list* 'expr-annotation:special-form special-form ) ) ) )
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;;; Delayed Values
( defun scan-delay-or-delay-of ( world value-expr value-code element-type value-annotated-expr )
( unless ( and ( consp value-code ) ( eq ( first value-code ) 'fetch-value ) ( = ( length value-code ) 2 ) ( symbolp ( second value-code ) ) )
( error "delay expression ~S must refer to a global variable" value-expr ) )
( values
( list 'make-delayed-value ( list 'quote ( second value-code ) ) )
( make-delay-type world element-type )
value-annotated-expr ) )
; (delay <global>)
; Makes a delayed-global-read object for accessing the given global. Such an object can be accessed only by assigning it to
; an :opt-const or :opt-var record field and then reading it.
( defun scan-delay-expr ( world type-env special-form value-expr )
( declare ( ignore special-form ) )
( multiple-value-bind ( value-code element-type value-annotated-expr ) ( scan-value world type-env value-expr )
( scan-delay-or-delay-of world value-expr value-code element-type value-annotated-expr ) ) )
; (delay-of <element-type> <global>)
; Makes a delayed-global-read object for accessing the given global. Such an object can be accessed only by assigning it to
; an :opt-const or :opt-var record field and then reading it.
( defun scan-delay-of-expr ( world type-env special-form element-type-expr value-expr )
( declare ( ignore special-form ) )
( let ( ( element-type ( scan-type world element-type-expr ) ) )
( multiple-value-bind ( value-code value-annotated-expr ) ( scan-typed-value world type-env value-expr element-type )
( scan-delay-or-delay-of world value-expr value-code element-type value-annotated-expr ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; STATEMENT EXPRESSIONS
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; If source is a list that starts with a statement keyword, return that interned keyword;
; otherwise return nil.
( defun statement? ( world source )
( and ( consp source )
( let ( ( id ( first source ) ) )
( and ( identifier? id )
( let ( ( symbol ( world-find-symbol world id ) ) )
( when ( get symbol :statement )
symbol ) ) ) ) ) )
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; Generate a list of lisp expressions that will execute the given statements.
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; type-env is the type environment or nil if these statements are not reachable.
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; last is true if these statements' lisp return value becomes the return value of the function if the function falls through.
;
; Return three values:
; A list of codes (a list of lisp expressions)
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; :dead if the statement cannot complete or a list of the symbols of :uninitialized variables that are initialized if the statement can complete.
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; A list of annotated statements
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( defun scan-statements ( world type-env statements last )
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( if statements
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( if type-env
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( let* ( ( statement ( first statements ) )
( rest-statements ( rest statements ) )
( symbol ( statement? world statement ) ) )
( if symbol
( apply ( get symbol :statement ) world type-env rest-statements last symbol ( rest statement ) )
( multiple-value-bind ( statement-code live statement-annotated-expr )
( scan-void-value world type-env statement )
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( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
( scan-statements world ( and live type-env ) rest-statements last )
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( values ( cons statement-code rest-codes )
rest-live
( cons ( list ( world-intern world 'exec ) statement-annotated-expr ) rest-annotated-stmts ) ) ) ) ) )
( error "Unreachable statements: ~S" statements ) )
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( values nil
( if type-env ( type-env-live type-env ) :dead )
nil ) ) )
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; Compute the initial type-env to use for the given general-production's action code.
; The first cell of the type-env gives the production's lhs nonterminal's symbol;
; the remaining cells give the action arguments in order.
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; If include-lhs is true, include the lhs's actions with index 0 at the beginning of the
; environment.
( defun general-production-action-env ( grammar general-production include-lhs )
( let* ( ( index-override nil )
( current-indices nil )
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( lhs-general-nonterminal ( general-production-lhs general-production ) )
( bound-arguments-alist ( nonterminal-sample-bound-argument-alist grammar lhs-general-nonterminal ) ) )
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( flet ( ( general-symbol-action-env ( general-grammar-symbol )
( let* ( ( symbol ( general-grammar-symbol-symbol general-grammar-symbol ) )
( index ( or index-override ( incf ( getf current-indices symbol 0 ) ) ) )
( grammar-symbol ( instantiate-general-grammar-symbol bound-arguments-alist general-grammar-symbol ) ) )
( mapcar
#' ( lambda ( declaration )
( let* ( ( action-symbol ( car declaration ) )
( action-type ( cdr declaration ) )
( local-symbol ( gensym ( symbol-name action-symbol ) ) ) )
( make-type-env-action
( list* action-symbol symbol index )
local-symbol
action-type
general-grammar-symbol ) ) )
( grammar-symbol-signature grammar grammar-symbol ) ) ) ) )
( let ( ( env ( set-type-env-flag
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( make-type-env ( mapcan #' general-symbol-action-env ( general-production-rhs general-production ) ) nil )
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:lhs-symbol ( general-grammar-symbol-symbol lhs-general-nonterminal ) ) ) )
( when include-lhs
( setq index-override 0 )
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( setq env ( make-type-env ( nconc ( general-symbol-action-env lhs-general-nonterminal ) ( type-env-bindings env ) )
( type-env-live env ) ) ) )
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env ) ) ) )
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; Return the number of arguments that a function returned by compute-action-code
; would expect.
( defun n-action-args ( grammar production )
( let ( ( n-args 0 ) )
( dolist ( grammar-symbol ( production-rhs production ) )
( incf n-args ( length ( grammar-symbol-signature grammar grammar-symbol ) ) ) )
n-args ) )
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; Compute the code for evaluating body-expr to obtain the value of one of the
; production's actions. Verify that the result has the given type and that the
; type is the same as type-expr.
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( defun compute-action-code ( world production action-symbol type-expr body-expr type initial-env )
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( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
( format *error-output* "~&~@<~2IWhile processing action ~A on ~S: ~_~:W~:>~%"
action-symbol ( production-name production ) body-expr ) ) ) )
( let ( ( type2 ( scan-type world type-expr ) ) )
( unless ( type= type type2 )
( error "Action declared using type ~A but defined using ~A"
( print-type-to-string type ) ( print-type-to-string type2 ) ) ) )
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( let ( ( body-code ( scan-typed-value-or-begin world initial-env body-expr type ) ) )
( name-lambda body-code
( concatenate 'string ( symbol-name ( production-name production ) )
"~" ( symbol-name action-symbol ) )
( world-package world ) ) ) ) )
; Compute the body of all grammar actions for this production.
( defun compute-production-code ( world grammar production )
( let* ( ( lhs ( production-lhs production ) )
( n-action-args ( n-action-args grammar production ) )
( initial-env ( general-production-action-env grammar production nil ) )
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( args ( mapcar #' cadr ( cdr ( type-env-bindings initial-env ) ) ) ) )
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( assert-true ( = ( length args ) n-action-args ) )
( let* ( ( result-vars nil )
( code-bindings
( mapcar
#' ( lambda ( action-binding )
( let ( ( action-symbol ( car action-binding ) )
( action ( cdr action-binding ) ) )
( unless action
( error "Missing action ~S for production ~S" ( car action-binding ) ( production-name production ) ) )
( multiple-value-bind ( has-type type ) ( action-declaration grammar ( production-lhs production ) action-symbol )
( declare ( ignore has-type ) )
( let ( ( code ( compute-action-code world production action-symbol ( action-type action ) ( action-expr action ) type initial-env ) )
( result-var ( gensym ( symbol-name action-symbol ) ) ) )
( when *trace-variables*
( format *trace-output* "~&~@<~S[~S] := ~2I~_~:W~:>~%" action-symbol ( production-name production ) code ) )
( push result-var result-vars )
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( setq initial-env
( make-type-env ( cons ( make-type-env-action
( list* action-symbol ( general-grammar-symbol-symbol lhs ) 0 )
result-var
type
lhs )
( type-env-bindings initial-env ) )
( type-env-live initial-env ) ) )
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( list result-var code ) ) ) ) )
( production-actions production ) ) )
( filtered-args ( mapcar #' ( lambda ( arg )
( and ( tree-member arg code-bindings ) arg ) )
args ) )
( production-code
( if code-bindings
` ( lambda ( stack )
( list*-bind , ( nreconc filtered-args ' ( stack-rest ) ) stack
( let* , code-bindings
( list* ,@ result-vars stack-rest ) ) ) )
` ( lambda ( stack )
( nthcdr , n-action-args stack ) ) ) )
( production-code-name ( unique-function-name world ( string ( production-name production ) ) ) ) )
( setf ( production-n-action-args production ) n-action-args )
( when *trace-variables*
( format *trace-output* "~&~@<all[~S] := ~2I~_~:W~:>~%" ( production-name production ) production-code ) )
( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
( format *error-output* "~&While computing production ~S:~%" ( production-name production ) ) ) ) )
( quiet-compile production-code-name production-code )
( setf ( production-evaluator production ) ( symbol-function production-code-name ) ) ) ) ) )
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; Return a list of all grammar symbols' symbols that are present in at least one expr-annotation:action
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; in the annotated expression. The symbols are returned in no particular order.
( defun annotated-expr-grammar-symbols ( annotated-expr )
( let ( ( symbols nil ) )
( labels
( ( scan ( annotated-expr )
( when ( consp annotated-expr )
( if ( eq ( first annotated-expr ) 'expr-annotation:action )
( pushnew ( general-grammar-symbol-symbol ( third annotated-expr ) ) symbols :test *grammar-symbol-=* )
( mapc #' scan annotated-expr ) ) ) ) )
( scan annotated-expr )
symbols ) ) )
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; text is a list of strings and forms intended for a comment. Interpret a few special forms as follows:
; (:expr <result-type> <expr>)
; becomes converted to (:annotated-expr <annotated-expr>)
; (:def-const <name> <type>)
; augments the environment for the rest of the comment with a local variable named <name> with type <type>.
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; (:initialize <name>)
; augments the environment for the rest of the comment by initializing the local variable named <name>.
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( defun scan-expressions-in-comment ( world type-env text )
( mapcan #' ( lambda ( item )
( if ( consp item )
( let ( ( key ( first item ) ) )
( case key
( :expr
( unless ( = ( length item ) 3 )
( error "Bad :expr ~S" item ) )
( let ( ( result-type ( scan-type world ( second item ) ) ) )
( multiple-value-bind ( value-code value-annotated-expr ) ( scan-typed-value world type-env ( third item ) result-type )
( declare ( ignore value-code ) )
( list ( list :annotated-expr value-annotated-expr ) ) ) ) )
( :def-const
( unless ( = ( length item ) 3 )
( error "Bad :expr ~S" item ) )
( let* ( ( symbol ( scan-name world ( second item ) ) )
( type ( scan-type world ( third item ) ) ) )
( setq type-env ( type-env-add-binding type-env symbol type :const ) ) )
nil )
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( :initialize
( unless ( = ( length item ) 2 )
( error "Bad :expr ~S" item ) )
( let ( ( symbol ( scan-name world ( second item ) ) ) )
( setq type-env ( type-env-initialize-var type-env symbol ) ) )
nil )
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( t ( list item ) ) ) )
( list item ) ) )
text ) )
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;;; ------------------------------------------------------------------------------------------------------
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;;; STATEMENTS
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; (// . <styled-text>)
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; (note . <styled-text>)
; A one-paragraph comment using the given <styled-text>. The note form precedes the text with the keyword 'note'.
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( defun scan-// ( world type-env rest-statements last special-form &rest text )
( unless text
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( error "// or note should have non-empty text" ) )
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( let ( ( text2 ( scan-expressions-in-comment world type-env text ) ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts ) ( scan-statements world type-env rest-statements last )
( values rest-codes
rest-live
( cons ( cons special-form text2 ) rest-annotated-stmts ) ) ) ) )
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; (/* . <styled-text>)
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; A one-paragraph comment using the given <styled-text>. The subsequent statements are hidden until the next (*/) statement
; or until the end of the subsequent statements if they cannot fall through.
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; These comments cannot nest.
( defun scan-/* ( world type-env rest-statements last special-form &rest text )
( unless text
( error "/* should have non-empty text" ) )
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( let ( ( text2 ( scan-expressions-in-comment world type-env text ) ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts ) ( scan-statements world type-env rest-statements last )
( let ( ( end-special-form ( assert-non-null ( world-find-symbol world '*/ ) ) ) )
( loop
( when ( endp rest-annotated-stmts )
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( if ( eq rest-live :dead )
( return )
( error "Missing */" ) ) )
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( let* ( ( annotated-stmt ( pop rest-annotated-stmts ) )
( stmt-keyword ( first annotated-stmt ) ) )
( cond
( ( eq stmt-keyword special-form )
( error "/* comments can't nest" ) )
( ( eq stmt-keyword end-special-form )
( return ) ) ) ) ) )
( values rest-codes
rest-live
( cons ( cons special-form text2 ) rest-annotated-stmts ) ) ) ) )
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; (*/)
; Terminates a /* comment.
( defun scan-*/ ( world type-env rest-statements last special-form )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts ) ( scan-statements world type-env rest-statements last )
( values rest-codes
rest-live
( cons ( list special-form ) rest-annotated-stmts ) ) ) )
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( defun eval-bottom ( )
( error "Reached a BOTTOM statement" ) )
; (bottom . <styled-text>)
; Raises an error.
( defun scan-bottom ( world type-env rest-statements last special-form &rest text )
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( let ( ( text2 ( scan-expressions-in-comment world type-env text ) ) )
( scan-statements world nil rest-statements last )
( values
( list ' ( eval-bottom ) )
:dead
( list ( cons special-form text2 ) ) ) ) )
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; (assert <condition-expr> . <styled-text>)
; Used to declare conditions that are known to be true if the semantics function correctly. Don't use this to
; verify user input.
; <styled-text> can contain the entry (:assertion) to depict <condition-expr>.
( defun scan-assert ( world type-env rest-statements last special-form condition-expr &rest text )
( unless text
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( setq text ' ( ( :assertion ) ";" ) ) )
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( let ( ( text2 ( scan-expressions-in-comment world type-env text ) ) )
( multiple-value-bind ( condition-code condition-annotated-expr true-type-env false-type-env )
( scan-condition world type-env condition-expr )
( declare ( ignore false-type-env ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts ) ( scan-statements world true-type-env rest-statements last )
( values ( cons ( list 'assert condition-code ) rest-codes )
rest-live
( cons ( list* special-form condition-annotated-expr text2 ) rest-annotated-stmts ) ) ) ) ) )
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; (quiet-assert <condition-expr>)
; Used to declare conditions that are known to be true if the semantics function correctly. Don't use this to
; verify user input.
; A quiet-assert does not appear in the depicted statements.
( defun scan-quiet-assert ( world type-env rest-statements last special-form condition-expr )
( declare ( ignore special-form ) )
( multiple-value-bind ( condition-code condition-annotated-expr true-type-env false-type-env )
( scan-condition world type-env condition-expr )
( declare ( ignore condition-annotated-expr false-type-env ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts ) ( scan-statements world true-type-env rest-statements last )
( values ( cons ( list 'assert condition-code ) rest-codes )
rest-live
rest-annotated-stmts ) ) ) )
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; (exec <expr>)
( defun scan-exec ( world type-env rest-statements last special-form expr )
( multiple-value-bind ( statement-code statement-type statement-annotated-expr )
( scan-value world type-env expr )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world ( and ( not ( eq ( type-kind statement-type ) :bottom ) ) type-env ) rest-statements last )
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( values ( cons statement-code rest-codes )
rest-live
( cons ( list special-form statement-annotated-expr ) rest-annotated-stmts ) ) ) ) )
; (const <name> <type> <value>)
; (var <name> <type> <value>)
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( defun scan-const ( world type-env rest-statements last special-form name type-expr value-expr )
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( let* ( ( symbol ( scan-name world name ) )
( type ( scan-type world type-expr ) )
( placeholder-type-env ( type-env-add-binding type-env symbol type :unused ) ) )
( multiple-value-bind ( value-code value-annotated-expr ) ( scan-typed-value world placeholder-type-env value-expr type )
( let ( ( local-type-env ( type-env-add-binding type-env symbol type ( find-keyword special-form ) ) ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world local-type-env rest-statements last )
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( values
( list ` ( let ( ( , symbol , value-code ) )
,@ rest-codes ) )
rest-live
( cons ( list special-form name type-expr value-annotated-expr ) rest-annotated-stmts ) ) ) ) ) ) )
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; (var <name> <type> [<value>])
( defun scan-var ( world type-env rest-statements last special-form name type-expr &optional value-expr )
( if value-expr
( scan-const world type-env rest-statements last special-form name type-expr value-expr )
( let* ( ( symbol ( scan-name world name ) )
( type ( scan-type world type-expr ) ) )
( let ( ( local-type-env ( type-env-add-binding type-env symbol type :uninitialized ) ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world local-type-env rest-statements last )
( unless ( eq rest-live :dead )
( setq rest-live ( remove symbol rest-live :test #' eq ) ) )
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( values
( list ` ( let ( , symbol ) ,@ rest-codes ) )
rest-live
( cons ( list special-form name type-expr ) rest-annotated-stmts ) ) ) ) ) ) )
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; (multiple-value-bind ((<name> <type>) ...) <lisp-function> <arg-exprs>)
; Evaluate <lisp-function> applied to the results of evaluating <arg-exprs>. The function should return multiple values,
; which are assigned to new variables with the given names and types.
( defun scan-multiple-value-bind ( world type-env rest-statements last special-form names-and-types lisp-function arg-exprs )
( unless ( structured-type? names-and-types ' ( list ( tuple t t ) ) )
( error "Bad definitions for scan-multiple-value-bind" ) )
( let ( ( arg-values nil ) )
( dolist ( arg-expr arg-exprs )
( multiple-value-bind ( arg-value arg-type arg-annotated-expr ) ( scan-value world type-env arg-expr )
( declare ( ignore arg-type arg-annotated-expr ) )
( push arg-value arg-values ) ) )
( let ( ( arg-values ( nreverse arg-values ) )
( symbols nil ) )
( dolist ( name-and-type names-and-types )
( let* ( ( symbol ( scan-name world ( first name-and-type ) ) )
( type ( scan-type world ( second name-and-type ) ) ) )
( setq type-env ( type-env-add-binding type-env symbol type :var ) )
( push symbol symbols ) ) )
( setq symbols ( nreverse symbols ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
( scan-statements world type-env rest-statements last )
( unless ( eq rest-live :dead )
( dolist ( symbol symbols )
( setq rest-live ( remove symbol rest-live :test #' eq ) ) ) )
( values
( list ` ( multiple-value-bind , symbols ( , lisp-function ,@ arg-values ) ,@ rest-codes ) )
rest-live
( cons ( list special-form names-and-types lisp-function arg-exprs ) rest-annotated-stmts ) ) ) ) ) )
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; (reserve <name>)
; Used to reserve <name> as a variable that can be later defined by a (some <name> ... :define-true) expression.
( defun scan-reserve ( world type-env rest-statements last special-form name )
( declare ( ignore special-form ) )
( let* ( ( symbol ( scan-name world name ) )
( local-type-env ( type-env-add-binding type-env symbol ( world-void-type world ) :reserved ) ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world local-type-env rest-statements last )
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( values
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( list ` ( let ( , symbol ) ,@ rest-codes ) )
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rest-live
rest-annotated-stmts ) ) ) )
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; (function (<name> (<var1> <type1> [:var | :unused]) ... (<varn> <typen> [:var | :unused])) <result-type> . <statements>)
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( defun scan-function ( world type-env rest-statements last special-form name-and-arg-binding-exprs result-type-expr &rest body-statements )
( unless ( consp name-and-arg-binding-exprs )
( error "Bad function name and bindings: ~S" name-and-arg-binding-exprs ) )
( let* ( ( symbol ( scan-name world ( first name-and-arg-binding-exprs ) ) )
( placeholder-type-env ( type-env-add-binding type-env symbol ( world-void-type world ) :unused ) ) )
( multiple-value-bind ( args-and-body-codes type body-annotated-stmts )
( scan-function-or-lambda world placeholder-type-env ( rest name-and-arg-binding-exprs ) result-type-expr body-statements )
( let ( ( local-type-env ( type-env-add-binding type-env symbol type :function ) ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world local-type-env rest-statements last )
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( values
( list ` ( flet ( ( , symbol ,@ args-and-body-codes ) )
,@ rest-codes ) )
rest-live
( cons ( list* special-form name-and-arg-binding-exprs result-type-expr body-annotated-stmts ) rest-annotated-stmts ) ) ) ) ) ) )
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; (<- <name> <value> [:end-narrow])
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; Mutate the local or global variable.
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( defun scan-<- ( world type-env rest-statements last special-form name value-expr &optional end-narrow )
( unless ( member end-narrow ' ( nil :end-narrow ) )
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( error "Bad flag ~S given to <-" end-narrow ) )
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( let* ( ( symbol ( scan-name world name ) )
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( symbol-binding ( type-env-get-local type-env symbol ) )
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( type-env2 type-env )
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type )
( if symbol-binding
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( case ( type-env-local-mode symbol-binding )
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( :var
( when end-narrow
( multiple-value-setq ( symbol-binding type-env2 ) ( type-env-unnarrow-binding type-env symbol ) ) )
( setq type ( type-env-local-type symbol-binding ) ) )
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( :uninitialized
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( when end-narrow
( error ":end-narrow not applicable to uninitialized variables" ) )
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( setq type ( type-env-local-type symbol-binding ) )
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( setq type-env2 ( type-env-initialize-var type-env2 symbol ) ) )
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( t ( error "Local variable ~A not writable" name ) ) )
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( progn
( setq type ( symbol-type symbol ) )
( unless type
( error "Unknown local or global variable ~A" name ) )
( unless ( get symbol :mutable )
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( error "Global variable ~A not writable" name ) )
( when end-narrow
( error ":end-narrow not applicable to global variables" ) ) ) )
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( multiple-value-bind ( value-code value-annotated-expr ) ( scan-typed-value world type-env value-expr type )
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( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world type-env2 rest-statements last )
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( values
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( cons ( if symbol-binding
( list 'setq ( type-env-local-name symbol-binding ) value-code )
( list 'store-global-value symbol value-code ) )
rest-codes )
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rest-live
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( cons ( list special-form name value-annotated-expr ( not symbol-binding ) ) rest-annotated-stmts ) ) ) ) ) )
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; (&= <label> <record-expr> <value-expr>)
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; Writes the value of the field.
( defun scan-&= ( world type-env rest-statements last special-form label record-expr value-expr )
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( multiple-value-bind ( record-code record-type tags record-annotated-expr ) ( scan-union-tag-value world type-env record-expr )
( let ( ( position-alist nil )
( field-types nil ) )
( dolist ( tag tags )
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( multiple-value-bind ( position field-type mutable optional ) ( scan-label tag label )
( declare ( ignore optional ) )
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( unless mutable
( error "Attempt to write to immutable field ~S of ~S" label ( tag-name tag ) ) )
( let ( ( entry ( assoc position position-alist ) ) )
( unless entry
( setq entry ( cons position nil ) )
( push entry position-alist ) )
( assert-true ( null ( tag-keyword tag ) ) )
( push ( tag-name tag ) ( cdr entry ) )
( push field-type field-types ) ) ) )
( assert-true position-alist )
( setq position-alist ( sort position-alist #' < :key #' car ) )
( let ( ( destination-type ( apply #' make-intersection-type world field-types ) ) )
( dolist ( field-type field-types )
( unless ( eq ( widening-coercion-code world field-type destination-type 'test 'test ) 'test )
( error "Type coercions in &= are not implemented yet" ) ) )
( multiple-value-bind ( value-code value-annotated-expr ) ( scan-typed-value world type-env value-expr destination-type )
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( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world type-env rest-statements last )
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( values
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( cons
( if ( endp ( cdr position-alist ) )
( list 'setf ( gen-nth-code ( caar position-alist ) record-code ) value-code )
( let ( ( var ( gen-local-var record-code ) )
( val ( gen-local-var value-code ) ) )
( let-local-var var record-code
( let-local-var val value-code
` ( case ( car , var )
,@ ( mapcar #' ( lambda ( entry ) ( list ( cdr entry ) ( list 'setf ( gen-nth-code ( car entry ) var ) val ) ) )
position-alist ) ) ) ) ) )
rest-codes )
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rest-live
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( cons ( list special-form record-type label record-annotated-expr value-annotated-expr ) rest-annotated-stmts ) ) ) ) ) ) ) )
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; (&const= <label> <record-expr> <value-expr>)
; Initializes the value of an optional constant field.
( defun scan-&const= ( world type-env rest-statements last special-form label record-expr value-expr )
( multiple-value-bind ( record-code record-type tags record-annotated-expr ) ( scan-union-tag-value world type-env record-expr )
( let ( ( position-alist nil )
( field-types nil ) )
( dolist ( tag tags )
( multiple-value-bind ( position field-type mutable optional ) ( scan-label tag label )
( declare ( ignore mutable ) )
( unless optional
( error "Attempt to initialize a non-optional field ~S of ~S" label ( tag-name tag ) ) )
( let ( ( entry ( assoc position position-alist ) ) )
( unless entry
( setq entry ( cons position nil ) )
( push entry position-alist ) )
( assert-true ( null ( tag-keyword tag ) ) )
( push ( tag-name tag ) ( cdr entry ) )
( push field-type field-types ) ) ) )
( assert-true position-alist )
( setq position-alist ( sort position-alist #' < :key #' car ) )
( let ( ( destination-type ( apply #' make-intersection-type world field-types ) ) )
( dolist ( field-type field-types )
( unless ( eq ( widening-coercion-code world field-type destination-type 'test 'test ) 'test )
( error "Type coercions in &const= are not implemented yet" ) ) )
( multiple-value-bind ( value-code value-annotated-expr ) ( scan-typed-value world type-env value-expr destination-type )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
( scan-statements world type-env rest-statements last )
( values
( append
( if ( endp ( cdr position-alist ) )
( list
( list 'assert ( list 'eq ( gen-nth-code ( caar position-alist ) record-code ) :%uninit% ) )
( list 'setf ( gen-nth-code ( caar position-alist ) record-code ) value-code ) )
( let ( ( var ( gen-local-var record-code ) )
( val ( gen-local-var value-code ) ) )
( let-local-var var record-code
( let-local-var val value-code
` ( case ( car , var )
,@ ( mapcar #' ( lambda ( entry ) ( list ( cdr entry )
( list 'assert ( list 'eq ( gen-nth-code ( car entry ) var ) :%uninit% ) )
( list 'setf ( gen-nth-code ( car entry ) var ) val ) ) )
position-alist ) ) ) ) ) )
rest-codes )
rest-live
( cons ( list special-form record-type label record-annotated-expr value-annotated-expr ) rest-annotated-stmts ) ) ) ) ) ) ) )
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; (action<- <action> <value>)
; Mutate the writable action. This can be done only once per action.
( defun scan-action<- ( world type-env rest-statements last special-form action value-expr )
( unless ( and ( consp action ) ( identifier? ( first action ) ) )
( error "Bad action: ~S" action ) )
( let ( ( symbol ( world-intern world ( first action ) ) ) )
( unless ( symbol-action symbol )
( error "~S is not an action name" ( first action ) ) )
( multiple-value-bind ( action-value action-type action-annotated-expr ) ( apply #' scan-action-call type-env symbol ( rest action ) )
( unless ( eq ( type-kind action-type ) :writable-cell )
( error "action<- type ~S must be a writable-cell" action-type ) )
( assert-true ( symbolp action-value ) )
( multiple-value-bind ( value-code value-annotated-expr ) ( scan-typed-value world type-env value-expr ( writable-cell-element-type action-type ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world type-env rest-statements last )
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( values
( if ( or ( symbolp value-code ) ( numberp value-code ) )
( list* ` ( when ( car , action-value )
( error "Attempt to write ~S to an already initialized writable-cell ~S" , value-code , action-value ) )
` ( setf ( car , action-value ) t )
` ( setf ( cdr , action-value ) , value-code )
rest-codes )
( let ( ( v ( gensym "V" ) ) )
( cons ` ( let ( ( , v , value-code ) )
( when ( car , action-value )
( error "Attempt to write ~S to an already initialized writable-cell ~S" , v , action-value ) )
( setf ( car , action-value ) t )
( setf ( cdr , action-value ) , v ) )
rest-codes ) ) )
rest-live
( cons ( list special-form action-annotated-expr value-annotated-expr ) rest-annotated-stmts ) ) ) ) ) ) )
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; (return [<value-expr>])
( defun scan-return ( world type-env rest-statements last special-form &optional value-expr )
( let ( ( value-code nil )
( value-annotated-expr nil )
( type ( get-type-env-flag type-env :return ) ) )
( cond
( value-expr
( multiple-value-setq ( value-code value-annotated-expr )
( scan-typed-value world type-env value-expr type ) ) )
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( ( not ( type= type ( world-void-type world ) ) )
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( error "Return statement needs a value" ) ) )
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( scan-statements world nil rest-statements last )
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( values
( list ( if last
value-code
( list* 'return-from
( gen-type-env-return-block-name type-env )
( and value-code ( list value-code ) ) ) ) )
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:dead
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( list ( list special-form value-annotated-expr ) ) ) ) )
; (rwhen <condition-expr> . <true-statements>)
; Same as when except that checks that true-statements cannot fall through and generates more efficient code.
( defun scan-rwhen ( world type-env rest-statements last special-form condition-expr &rest true-statements )
( multiple-value-bind ( condition-code condition-annotated-expr true-type-env false-type-env )
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( scan-condition world type-env condition-expr )
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( multiple-value-bind ( true-codes true-live true-annotated-stmts ) ( scan-statements world true-type-env true-statements last )
( unless ( eq true-live :dead )
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( error "rwhen statements ~S must not fall through" true-statements ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world false-type-env rest-statements last )
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( values ( list ( list 'if condition-code ( gen-progn true-codes ) ( gen-progn rest-codes ) ) )
rest-live
( cons ( list special-form ( cons condition-annotated-expr true-annotated-stmts ) ) rest-annotated-stmts ) ) ) ) ) )
; (when <condition-expr> . <true-statements>)
( defun scan-when ( world type-env rest-statements last special-form condition-expr &rest true-statements )
( scan-cond world type-env rest-statements last special-form ( cons condition-expr true-statements ) ) )
; (if <condition-expr> <true-statement> <false-statement>)
( defun scan-if-stmt ( world type-env rest-statements last special-form condition-expr true-statement false-statement )
( scan-cond world type-env rest-statements last special-form ( list condition-expr true-statement ) ( list nil false-statement ) ) )
; Generate and optimize a cond statement with the given cases.
( defun gen-cond-code ( cases )
( cond
( ( endp cases ) nil )
( ( endp ( cdr cases ) )
( cons 'when ( car cases ) ) )
( ( and ( endp ( cddr cases ) ) ( eq ( car ( second cases ) ) t ) ( endp ( cddr ( first cases ) ) ) ( endp ( cddr ( second cases ) ) ) )
( list 'if ( first ( first cases ) ) ( second ( first cases ) ) ( second ( second cases ) ) ) )
( t ( cons 'cond cases ) ) ) )
; (cond (<condition-expr> . <statements>) ... (<condition-expr> . <statements>) [(nil . <statements>)])
; <condition-expr> can be one of the following:
; nil Always true; used for an "else" clause
; true Same as nil
; <expr> Condition expression <expr>
( defun scan-cond ( world type-env rest-statements last special-form &rest cases )
( unless cases
( error "Empty cond statement" ) )
( let ( ( local-type-env type-env )
( nested-last ( and last ( null rest-statements ) ) )
( case-codes nil )
( annotated-cases nil )
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( joint-live :dead )
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( found-default-case nil ) )
( dolist ( case cases )
( unless ( consp case )
( error "Bad cond case: ~S" case ) )
( when found-default-case
( error "Cond case follows default case: ~S" cases ) )
( let ( ( condition-expr ( first case ) ) )
( multiple-value-bind ( condition-code condition-annotated-expr true-type-env false-type-env )
( if ( member condition-expr ' ( nil true ) )
( values t nil local-type-env local-type-env )
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( scan-condition world local-type-env condition-expr ) )
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( when ( eq condition-code t )
( if ( cdr cases )
( setq found-default-case t )
( error "Cond statement consisting only of an else case: ~S" cases ) ) )
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( multiple-value-bind ( codes live annotated-stmts ) ( scan-statements world true-type-env ( rest case ) nested-last )
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( push ( cons condition-code codes ) case-codes )
( push ( cons condition-annotated-expr annotated-stmts ) annotated-cases )
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( setq joint-live ( merge-live-lists joint-live live ) ) )
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( setq local-type-env false-type-env ) ) ) )
( unless found-default-case
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( setq joint-live ( merge-live-lists joint-live ( type-env-live type-env ) ) ) )
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( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world ( substitute-live type-env joint-live ) rest-statements last )
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( values ( cons ( gen-cond-code ( nreverse case-codes ) ) rest-codes )
rest-live
( cons ( cons special-form ( nreverse annotated-cases ) ) rest-annotated-stmts ) ) ) ) )
; (while <condition-expr> . <statements>)
( defun scan-while ( world type-env rest-statements last special-form condition-expr &rest loop-statements )
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( multiple-value-bind ( condition-code condition-annotated-expr true-type-env false-type-env )
( scan-condition world type-env condition-expr )
( multiple-value-bind ( loop-codes loop-live loop-annotated-stmts ) ( scan-statements world true-type-env loop-statements nil )
( unless ( listp loop-live )
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( warn "While loop can execute at most once: ~S ~S" condition-expr loop-statements ) )
( let ( ( infinite ( and ( constantp condition-code ) ( symbolp condition-code ) condition-code ) ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world ( and ( not infinite ) false-type-env ) rest-statements last )
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( values
( cons ( if infinite
( cons 'loop loop-codes )
` ( do ( )
( ( not , condition-code ) )
,@ loop-codes ) )
rest-codes )
rest-live
( cons ( list* special-form condition-annotated-expr loop-annotated-stmts ) rest-annotated-stmts ) ) ) ) ) ) )
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; (for-each <vector-or-set-expr> <var> . <statements>)
; Not implemented on range-sets.
( defun scan-for-each ( world type-env rest-statements last special-form collection-expr var-source &rest loop-statements )
( multiple-value-bind ( collection-code collection-kind element-type collection-annotated-expr ) ( scan-collection-value world type-env collection-expr )
( case collection-kind
( ( :vector :list-set ) )
( :string ( setq collection-code ( list 'coerce collection-code ' 'list ) ) )
( t ( error "Not implemented" ) ) )
( let* ( ( var ( scan-name world var-source ) )
( local-type-env ( type-env-add-binding type-env var element-type :const ) ) )
( multiple-value-bind ( loop-codes loop-live loop-annotated-stmts ) ( scan-statements world local-type-env loop-statements nil )
( unless ( listp loop-live )
( warn "For-each loop can execute at most once: ~S ~S" collection-expr var-source loop-statements ) )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts ) ( scan-statements world type-env rest-statements last )
( values
( cons ` ( dolist ( , var , collection-code )
,@ loop-codes )
rest-codes )
rest-live
( cons ( list* special-form collection-annotated-expr var loop-annotated-stmts ) rest-annotated-stmts ) ) ) ) ) ) )
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( defconstant *semantic-exception-type-name* 'semantic-exception )
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; (throw <value-expr> . <styled-text>)
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; <value-expr> must have type *semantic-exception-type-name*, which must be the name of some user-defined type in the environment.
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; If present, <styled-text> is depicted after the throw statement, separated by an em-dash.
( defun scan-throw ( world type-env rest-statements last special-form value-expr &rest text )
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( multiple-value-bind ( value-code value-annotated-expr )
( scan-typed-value world type-env value-expr ( scan-type world *semantic-exception-type-name* ) )
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( scan-statements world type-env rest-statements last )
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( let ( ( text2 ( scan-expressions-in-comment world type-env text ) ) )
( values
( list ( list 'throw :semantic-exception value-code ) )
:dead
( list ( list* special-form value-annotated-expr text2 ) ) ) ) ) )
( defparameter *an-error-list* ' ( -argument-error -attribute-error -eval-error -uninitialized-error ) )
; (throw-error <error> . <styled-text>)
; Syntactic sugar for:
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; (throw (/*/ (system-error <error> <message>) "a[n] " <error> " exception " :m-dash " " . <styled-text>))
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( defun scan-throw-error ( world type-env rest-statements last special-form error-name &rest text )
( declare ( ignore special-form ) )
( scan-statements
world
type-env
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( cons ` ( throw ( /*/ ( system-error , error-name , ( simple-text-to-string text ) )
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, ( if ( member error-name *an-error-list* ) "an" "a" )
:nbsp
( :global , error-name )
:nbsp
"exception"
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,@ ( and text ( list* " " :m-dash " " text ) ) ) )
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rest-statements )
last ) )
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( defun simple-text-to-string ( text )
( if text
( apply #' concatenate 'string
( mapcar #' ( lambda ( text-item )
( cond
( ( stringp text-item ) text-item )
( ( eq text-item :apostrophe ) "'" )
( ( characterp text-item ) ( string text-item ) )
( ( and ( consp text-item ) ( = ( length text-item ) 2 ) ( eq ( first text-item ) :character-literal ) ( stringp ( second text-item ) ) )
( second text-item ) )
( t "*" ) ) )
text ) )
'undefined ) )
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; (catch <body-statements> (<var> [:unused]) . <handler-statements>)
( defun scan-catch ( world type-env rest-statements last special-form body-statements arg-binding-expr &rest handler-statements )
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( multiple-value-bind ( body-codes body-live body-annotated-stmts ) ( scan-statements world type-env body-statements nil )
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( unless ( and ( consp arg-binding-expr )
( member ( cdr arg-binding-expr ) ' ( nil ( :unused ) ) :test #' equal ) )
( error "Bad catch binding ~S" arg-binding-expr ) )
( let* ( ( nested-last ( and last ( null rest-statements ) ) )
( arg-symbol ( scan-name world ( first arg-binding-expr ) ) )
( arg-type ( scan-type world *semantic-exception-type-name* ) )
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( local-type-env ( type-env-add-binding type-env arg-symbol arg-type :const ) ) )
( multiple-value-bind ( handler-codes handler-live handler-annotated-stmts ) ( scan-statements world local-type-env handler-statements nested-last )
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( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world ( substitute-live type-env ( merge-live-lists body-live handler-live ) ) rest-statements last )
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( let ( ( code
` ( block nil
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( let ( ( , arg-symbol ( catch :semantic-exception ,@ body-codes ,@ ( when ( listp body-live ) ' ( ( return ) ) ) ) ) )
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,@ ( and ( eq ( second arg-binding-expr ) :unused ) ` ( ( declare ( ignore , arg-symbol ) ) ) )
,@ handler-codes ) ) ) )
( values ( cons code rest-codes )
rest-live
( cons ( list* special-form body-annotated-stmts arg-binding-expr handler-annotated-stmts ) rest-annotated-stmts ) ) ) ) ) ) ) )
( defun case-error ( )
( error "No case chosen" ) )
; (case <value-expr> (key <type> . <statements>) ... (keyword <type> . <statements>))
; where each key is one of:
; :select No special action
; :narrow Narrow the type of <value-expr>, which must be a variable, to this case's <type>
; :otherwise Catch-all else case; <type> should be either nil or the remaining catch-all type
( defun scan-case ( world type-env rest-statements last special-form value-expr &rest cases )
( multiple-value-bind ( value-code value-type value-annotated-expr ) ( scan-value world type-env value-expr )
( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
( format *error-output* "~@<In case ~S: ~A ~_~S~:>" value-expr ( print-type-to-string value-type ) cases ) ) ) )
( let ( ( var ( if ( symbolp value-code ) value-code ( gensym "CASE" ) ) )
( nested-last ( and last ( null rest-statements ) ) ) )
( labels
( ( process-remaining-cases ( cases remaining-type )
( if cases
( let ( ( case ( car cases ) )
( cases ( cdr cases ) ) )
( unless ( and ( consp case ) ( consp ( cdr case ) ) ( member ( car case ) ' ( :select :narrow :otherwise ) ) )
( error "Bad case ~S" case ) )
( let ( ( key ( first case ) )
( type-expr ( second case ) )
( statements ( cddr case ) ) )
( if ( eq key :otherwise )
( progn
( when cases
( error "Otherwise case must be the last one" ) )
( when type-expr
( let ( ( type ( scan-type world type-expr ) ) )
( unless ( type= type remaining-type )
( error "Otherwise case type ~A given but ~A expected"
( print-type-to-string type ) ( print-type-to-string remaining-type ) ) ) ) )
( when ( type= remaining-type ( world-bottom-type world ) )
( error "Otherwise case not reached" ) )
( multiple-value-bind ( statements-codes statements-live statements-annotated-stmts )
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( scan-statements world type-env statements nested-last )
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( values ( list ( cons t statements-codes ) )
statements-live
( list ( list* key type-expr statements-annotated-stmts ) ) ) ) )
( multiple-value-bind ( type remaining-type ) ( type-difference world remaining-type ( scan-type world type-expr ) )
( let ( ( condition-code ( type-member-test-code world type value-type var ) ) )
( multiple-value-bind ( remaining-code remaining-live remaining-annotated-stmts )
( process-remaining-cases cases remaining-type )
( ecase key
( :select
( multiple-value-bind ( statements-codes statements-live statements-annotated-stmts )
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( scan-statements world type-env statements nested-last )
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( values ( cons ( cons condition-code statements-codes ) remaining-code )
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( merge-live-lists statements-live remaining-live )
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( cons ( list* key type-expr statements-annotated-stmts ) remaining-annotated-stmts ) ) ) )
( :narrow
( unless ( equal var value-code )
( error "const and var cases can only be used when dispatching on a variable" ) )
( multiple-value-bind ( statements-codes statements-live statements-annotated-stmts )
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( scan-statements world ( type-env-narrow-binding type-env var type ) statements nested-last )
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( values ( cons ( cons condition-code statements-codes ) remaining-code )
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( merge-live-lists statements-live remaining-live )
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( cons ( list* key type-expr statements-annotated-stmts ) remaining-annotated-stmts ) ) ) ) ) ) ) ) ) ) )
( if ( type= remaining-type ( world-bottom-type world ) )
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( values ' ( ( t ( case-error ) ) ) :dead nil )
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( error "Type ~A not considered in case" remaining-type ) ) ) ) )
( multiple-value-bind ( cases-code cases-live cases-annotated-stmts ) ( process-remaining-cases cases value-type )
( multiple-value-bind ( rest-codes rest-live rest-annotated-stmts )
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( scan-statements world ( substitute-live type-env cases-live ) rest-statements last )
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( values
( cons ( if ( equal var value-code )
( cons 'cond cases-code )
` ( let ( ( , var , value-code ) )
( cond ,@ cases-code ) ) )
rest-codes )
rest-live
( cons ( list* special-form value-annotated-expr cases-annotated-stmts ) rest-annotated-stmts ) ) ) ) ) ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; COMMANDS
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; (%highlight <highlight> <command> ... <command>)
; Evaluate the given commands. <highlight> is a hint for printing.
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; If <highlight> is :hide, then the commands are evaluated but not printed.
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( defun scan-%highlight ( world grammar-info-var highlight &rest commands )
( declare ( ignore highlight ) )
( scan-commands world grammar-info-var commands ) )
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; (%... ...)
; Ignore any command that starts with a %. These commands are hints for printing.
( defun scan-% ( world grammar-info-var &rest rest )
( declare ( ignore world grammar-info-var rest ) ) )
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; (deftag <name>)
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; Create the immutable tag in the world and set its contents.
; Do not evaluate the field and type expressions yet; that will be done by eval-tags-types.
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( defun scan-deftag ( world grammar-info-var name )
( declare ( ignore grammar-info-var ) )
( add-tag world name nil nil :reference nil ) )
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; Create the tuple or record. Return the type.
( defun scan-deftuple-or-defrecord ( world record name fields user-defined )
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( let* ( ( tag ( add-tag world name record fields :reference t ) )
( symbol ( tag-name tag ) )
( type ( make-tag-type world tag ) ) )
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( add-type-name world type symbol user-defined )
type ) )
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; (deftuple <name> (<name1> <type1>) ... (<namen> <typen>))
; Create the immutable tuple and tag in the world and set its contents.
; Do not evaluate the field and type expressions yet; that will be done by eval-tags-types.
( defun scan-deftuple ( world grammar-info-var name &rest fields )
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( declare ( ignore grammar-info-var ) )
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( unless fields
( error "A tuple must have at least one field; use a tag instead" ) )
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( scan-deftuple-or-defrecord world nil name fields t ) )
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; (defrecord <name> (<name1> <type1> [:const | :var | :opt-const | :opt-var]) ... (<namen> <typen> [:const | :var | :opt-const | :opt-var]))
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; Create the mutable record and tag in the world and set its contents.
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; Do not evaluate the field and type expressions yet; that will be done by eval-tags-types.
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; :const fields are immutable;
; :var fields are mutable;
; :opt-const fields can be left uninitialized but can only be initialized once;
; :opt-var fields are mutable and can be left uninitialized.
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( defun scan-defrecord ( world grammar-info-var name &rest fields )
( declare ( ignore grammar-info-var ) )
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( scan-deftuple-or-defrecord world t name fields t ) )
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; (deftype <name> <type>)
; Create the type in the world and set its contents.
( defun scan-deftype ( world grammar-info-var name type-expr )
( declare ( ignore grammar-info-var ) )
( let* ( ( symbol ( scan-name world name ) )
( type ( scan-type world type-expr t ) ) )
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( add-type-name world type symbol t ) ) )
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; (define <name> <type> <value>)
; (defun <name> (-> (<type1> ... <typen>) <result-type>) (lambda ((<arg1> <type1>) ... (<argn> <typen>)) <result-type> . <statements>))
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; Create the constant in the world but do not evaluate its type or value yet.
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( defun scan-define ( world grammar-info-var name type-expr value-expr )
( declare ( ignore grammar-info-var ) )
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( let ( ( symbol ( scan-name world name ) ) )
( unless ( eq ( get symbol :value-expr *get2-nonce* ) *get2-nonce* )
( error "Attempt to redefine variable ~A" symbol ) )
( setf ( get symbol :value-expr ) value-expr )
( setf ( get symbol :type-expr ) type-expr )
( export-symbol symbol ) ) )
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; (defprimitive <name> <lisp-lambda-expr>)
; Overrides a defun of <name> with the result of compiling <lisp-lambda-expr>.
( defun scan-defprimitive ( world grammar-info-var name lisp-lambda-expr )
( declare ( ignore grammar-info-var ) )
( let ( ( symbol ( scan-name world name ) ) )
( unless ( get symbol :value-expr )
( error "Need to define ~A before using defprimitive on it" symbol ) )
( setf ( get symbol :lisp-value-expr ) lisp-lambda-expr ) ) )
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; (defvar <name> <type> <value>)
; Create the variable in the world but do not evaluate its type or value yet.
( defun scan-defvar ( world grammar-info-var name type-expr value-expr )
( declare ( ignore grammar-info-var ) )
( let ( ( symbol ( scan-name world name ) ) )
( unless ( eq ( get symbol :value-expr *get2-nonce* ) *get2-nonce* )
( error "Attempt to redefine variable ~A" symbol ) )
( setf ( get symbol :value-expr ) value-expr )
( setf ( get symbol :type-expr ) type-expr )
( setf ( get symbol :mutable ) t )
( export-symbol symbol ) ) )
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; (definfix <type> <markup> <param1> <param2>)
; <type> must be a tuple or record tag. Define the syntax for depicting its constructor to be the infix operator
; depicted by <markup>. <param1> and <param2> are used as parameter names for depicting the definfix definition itself.
( defun scan-definfix ( world grammar-info-var type-name markup param1 param2 )
( declare ( ignore grammar-info-var param1 param2 ) )
( let* ( ( symbol ( scan-name world type-name ) )
( type ( get-type symbol nil ) ) )
( unless ( eq ( type-kind type ) :tag )
( error "~A should be a tag type" ( print-type-to-string type ) ) )
( let ( ( tag ( type-tag type ) ) )
( when ( tag-appearance tag )
( error "Duplicate appearance on tag ~S" tag ) )
( setf ( tag-appearance tag ) ( cons :infix markup ) ) ) ) )
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; (set-grammar <name>)
; Set the current grammar to the grammar or lexer with the given name.
( defun scan-set-grammar ( world grammar-info-var name )
( let ( ( grammar-info ( world-grammar-info world name ) ) )
( unless grammar-info
( error "Unknown grammar ~A" name ) )
( setf ( car grammar-info-var ) grammar-info ) ) )
; (clear-grammar)
; Clear the current grammar.
( defun scan-clear-grammar ( world grammar-info-var )
( declare ( ignore world ) )
( setf ( car grammar-info-var ) nil ) )
; Get the grammar-info-var's grammar. Signal an error if there isn't one.
( defun checked-grammar ( grammar-info-var )
( let ( ( grammar-info ( car grammar-info-var ) ) )
( if grammar-info
( grammar-info-grammar grammar-info )
( error "Grammar needed" ) ) ) )
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; (declare-action <action-name> <general-grammar-symbol> <type> <mode> <parameter-list> <command> ... <command>)
; <mode> is one of:
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; :hide Don't depict this action declaration because it's for a hidden production;
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; :forward Depict this action declaration; it forwards to calls to the same action in all nonterminals on the rhs;
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; :singleton Don't depict this action declaration because it contains a singleton production;
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; :action Depict this action declaration; all corresponding actions will be depicted by depict-action;
; :actfun Depict this action declaration; all corresponding actions will be depicted by depict-actfun;
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; :writable Depict this action declaration but not actions.
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; <parameter-list> contains the names of the action parameters when <mode> is :actfun.
( defun scan-declare-action ( world grammar-info-var action-name general-grammar-symbol-source type-expr mode parameter-list &rest commands )
( declare ( ignore parameter-list ) )
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( unless ( member mode ' ( :hide :forward :singleton :action :actfun :writable ) )
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( error "Bad declare-action mode ~S" mode ) )
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( let* ( ( grammar ( checked-grammar grammar-info-var ) )
( action-symbol ( scan-name world action-name ) )
( general-grammar-symbol ( grammar-parametrization-intern grammar general-grammar-symbol-source ) ) )
( declare-action grammar general-grammar-symbol action-symbol type-expr )
( dolist ( grammar-symbol ( general-grammar-symbol-instances grammar general-grammar-symbol ) )
( push ( cons ( car grammar-info-var ) grammar-symbol ) ( symbol-action action-symbol ) ) )
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( export-symbol action-symbol ) )
( scan-commands world grammar-info-var commands ) )
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; (action <action-name> <production-name> <type> <mode> <value>)
; (actfun <action-name> <production-name> <type> <mode> <value>)
; <mode> is one of:
; :hide Don't depict this action;
; :singleton Depict this action along with its declaration;
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; :first Depict this action, which is the first in the rule;
; :middle Depict this action, which is neither the first nor the last in the rule;
; :last Depict this action, which is the last in the rule.
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( defun scan-action ( world grammar-info-var action-name production-name type-expr mode value-expr )
( unless ( member mode ' ( :hide :singleton :first :middle :last ) )
( error "Bad action mode ~S" mode ) )
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( let ( ( grammar ( checked-grammar grammar-info-var ) )
( action-symbol ( world-intern world action-name ) ) )
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( define-action grammar production-name action-symbol type-expr value-expr ) ) )
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; (terminal-action <action-name> <terminal> <lisp-function>)
( defun scan-terminal-action ( world grammar-info-var action-name terminal function )
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( let ( ( grammar ( checked-grammar grammar-info-var ) )
( action-symbol ( world-intern world action-name ) ) )
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( define-terminal-action grammar terminal action-symbol ( symbol-function function ) ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; INITIALIZATION
( defparameter *default-specials*
' ( ( :preprocess
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( ? preprocess-? )
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( declare-action preprocess-declare-action )
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( define preprocess-define )
( action preprocess-action )
( grammar preprocess-grammar )
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( line-grammar preprocess-line-grammar )
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( lexer preprocess-lexer )
( grammar-argument preprocess-grammar-argument )
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( production preprocess-production )
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( rule preprocess-rule )
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( exclude preprocess-exclude ) )
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( :command
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( %highlight scan-%highlight depict-%highlight ) ;For internal use only; use ? instead.
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( %heading scan-% depict-%heading )
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( %text scan-% depict-%text )
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( grammar-argument scan-% depict-grammar-argument )
( %rule scan-% depict-%rule )
( %charclass scan-% depict-%charclass )
( %print-actions scan-% depict-%print-actions )
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( deftag scan-deftag depict-deftag )
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( deftuple scan-deftuple depict-deftuple )
( defrecord scan-defrecord depict-deftuple )
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( deftype scan-deftype depict-deftype )
( define scan-define depict-define )
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( defun scan-define depict-defun ) ;Occurs from desugaring a function define
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( defprimitive scan-defprimitive depict-defprimitive )
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( defvar scan-defvar depict-defvar )
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( definfix scan-definfix depict-definfix )
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( set-grammar scan-set-grammar depict-set-grammar )
( clear-grammar scan-clear-grammar depict-clear-grammar )
( declare-action scan-declare-action depict-declare-action )
( action scan-action depict-action )
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( actfun scan-action depict-actfun )
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( terminal-action scan-terminal-action depict-terminal-action ) )
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( :statement
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( // scan-// depict-// )
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( note scan-// depict-note )
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( /* scan-/* depict-// )
( */ scan-*/ depict-*/ )
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( bottom scan-bottom depict-bottom )
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( assert scan-assert depict-assert )
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( quiet-assert scan-quiet-assert nil )
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( exec scan-exec depict-exec )
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( const scan-const depict-var )
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( var scan-var depict-var )
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( multiple-value-bind scan-multiple-value-bind depict-multiple-value-bind )
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( reserve scan-reserve nil )
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( function scan-function depict-function )
( <- scan-<- depict-<- )
( &= scan-&= depict-&= )
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( &const= scan-&const= depict-&= )
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( action<- scan-action<- depict-action<- )
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( return scan-return depict-return )
( rwhen scan-rwhen depict-cond )
( when scan-when depict-cond )
( if scan-if-stmt depict-cond )
( cond scan-cond depict-cond )
( while scan-while depict-while )
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( for-each scan-for-each depict-for-each )
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( throw scan-throw depict-throw )
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( throw-error scan-throw-error nil )
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( catch scan-catch depict-catch )
( case scan-case depict-case ) )
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( :special-form
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;;Constants
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( todo scan-todo depict-todo )
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( bottom scan-bottom-expr depict-bottom-expr )
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( hex scan-hex depict-hex )
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( float32 scan-float32 nil )
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( supplementary-char scan-supplementary-char depict-supplementary-char )
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;;Expressions
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( /*/ scan-/*/ depict-/*/ )
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( lisp-call scan-lisp-call depict-lisp-call )
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( expt scan-expt depict-expt )
( = scan-= depict-comparison )
( /= scan-/= depict-comparison )
( < scan-< depict-comparison )
( > scan-> depict-comparison )
( <= scan-<= depict-comparison )
( >= scan->= depict-comparison )
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( set<= scan-set<= depict-comparison )
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( cascade scan-cascade depict-cascade )
( and scan-and depict-and-or-xor )
( or scan-or depict-and-or-xor )
( xor scan-xor depict-and-or-xor )
( lambda scan-lambda depict-lambda )
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( if scan-if-expr depict-if-expr )
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;;Vectors
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( vector scan-vector-expr depict-vector-expr )
( vector-of scan-vector-of depict-vector-expr )
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( repeat scan-repeat depict-repeat )
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( nth scan-nth depict-nth )
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( subseq scan-subseq depict-subseq )
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( cons scan-cons depict-cons )
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( append scan-append depict-append )
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( set-nth scan-set-nth depict-set-nth )
;;Sets
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( list-set scan-list-set-expr depict-list-set-expr )
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( %list-set scan-list-set-expr depict-%list-set-expr )
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( list-set-of scan-list-set-of depict-list-set-expr )
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( %list-set-of scan-list-set-of depict-%list-set-expr )
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( range-set-of scan-range-set-of depict-range-set-of-ranges )
( range-set-of-ranges scan-range-set-of-ranges depict-range-set-of-ranges )
( set* scan-set* depict-set* )
( set+ scan-set+ depict-set+ )
( set- scan-set- depict-set- )
( set-in scan-set-in depict-set-in )
( set-not-in scan-set-not-in depict-set-in )
( elt-of scan-elt-of depict-elt-of )
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( unique-elt-of scan-unique-elt-of depict-unique-elt-of )
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;;Vectors or Sets
( empty scan-empty depict-empty )
( nonempty scan-nonempty depict-nonempty )
( length scan-length depict-length )
( some scan-some depict-some )
( every scan-every depict-some )
( map scan-map depict-map )
;;Tuples and Records
( new scan-new depict-new )
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( & scan-& depict-& )
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( &opt scan-&opt depict-& )
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( set-field scan-set-field depict-set-field )
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;;Unions
( in scan-in depict-in )
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( not-in scan-not-in depict-not-in )
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( assert-in scan-assert-in depict-assert-in )
( assert-not-in scan-assert-not-in depict-assert-in )
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;;Writable Cells
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( writable-cell-of scan-writable-cell-of depict-writable-cell-of ) ;For internal use only
;;Delayed Values
( delay scan-delay-expr nil )
( delay-of scan-delay-of-expr nil ) )
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( :condition
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( /*/ scan-/*/-condition )
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( not scan-not-condition )
( and scan-and-condition )
( or scan-or-condition )
( some scan-some-condition )
( in scan-in-condition )
( not-in scan-not-in-condition ) )
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( :type-constructor
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( integer-list scan-integer-list depict-integer-list )
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( integer-range scan-integer-range depict-integer-range )
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( exclude-zero scan-exclude-zero depict-exclude-zero )
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( -> scan--> depict--> )
( vector scan-vector depict-vector )
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( list-set scan-list-set depict-set )
( range-set scan-range-set depict-set )
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( tag scan-tag-type depict-tag-type )
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( union scan-union depict-union )
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( type-diff scan-type-diff depict-type-diff )
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( writable-cell scan-writable-cell depict-writable-cell )
( delay scan-delay depict-delay ) ) ) )
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( defparameter *default-non-reserved* ' ( length ) )
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( defparameter *default-primitives*
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' ( ( neg ( -> ( integer ) integer ) #' - :unary :minus nil %prefix% %prefix% )
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( abs ( -> ( integer ) integer ) #' abs :unary "|" "|" %primary% %expr% )
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( * ( -> ( integer integer ) integer ) #' * :infix :cartesian-product-10 nil %factor% %factor% %factor% )
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( int/ ( -> ( integer integer ) integer ) #' int/ :infix "/" nil %factor% %factor% %prefix% )
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( mod ( -> ( integer integer ) integer ) #' mod :infix ( ( :semantic-keyword "mod" ) ) t %factor% %factor% %prefix% )
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( + ( -> ( integer integer ) integer ) #' + :infix "+" t %term% %term% %term% )
( - ( -> ( integer integer ) integer ) #' - :infix :minus t %term% %term% %factor% )
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;(rational-compare (-> (rational rational) order) #'rational-compare)
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( rat-neg ( -> ( rational ) rational ) #' - :unary :minus nil %prefix% %prefix% )
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( rat-abs ( -> ( rational ) rational ) #' abs :unary "|" "|" %primary% %expr% )
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( rat* ( -> ( rational rational ) rational ) #' * :infix :cartesian-product-10 nil %factor% %factor% %factor% )
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( rat/ ( -> ( rational rational ) rational ) #' / :infix "/" nil %factor% %factor% %prefix% )
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( rat+ ( -> ( rational rational ) rational ) #' + :infix "+" t %term% %term% %term% )
( rat- ( -> ( rational rational ) rational ) #' - :infix :minus t %term% %term% %factor% )
( floor ( -> ( rational ) integer ) #' floor :unary :left-floor-10 :right-floor-10 %primary% %expr% )
( ceiling ( -> ( rational ) integer ) #' ceiling :unary :left-ceiling-10 :right-ceiling-10 %primary% %expr% )
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( floor-log10 ( -> ( rational ) integer ) #' floor-log10 :unary ( :left-floor-10 "log" ( :subscript "10" ) "(" ) ( ")" :right-floor-10 ) %primary% %expr% )
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( not ( -> ( boolean ) boolean ) #' not :unary ( ( :semantic-keyword "not" ) " " ) nil %not% %not% )
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( bitwise-and ( -> ( integer integer ) integer ) #' logand )
( bitwise-or ( -> ( integer integer ) integer ) #' logior )
( bitwise-xor ( -> ( integer integer ) integer ) #' logxor )
( bitwise-shift ( -> ( integer integer ) integer ) #' ash )
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( real-to-float32 ( -> ( rational ) float32 ) #' rational-to-float32 :unary nil ( ( :subscript "f32" ) ) %term% %primary% )
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( truncate-finite-float32 ( -> ( finite-float32 ) integer ) #' truncate-finite-float32 )
;(float32-compare (-> (float32 float32) order) #'float32-compare)
( float32-abs ( -> ( float32 float32 ) float32 ) #' float32-abs )
( float32-negate ( -> ( float32 ) float32 ) #' float32-neg )
( float32-add ( -> ( float32 float32 ) float32 ) #' float32-add )
( float32-subtract ( -> ( float32 float32 ) float32 ) #' float32-subtract )
( float32-multiply ( -> ( float32 float32 ) float32 ) #' float32-multiply )
( float32-divide ( -> ( float32 float32 ) float32 ) #' float32-divide )
( float32-remainder ( -> ( float32 float32 ) float32 ) #' float32-remainder )
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( real-to-float64 ( -> ( rational ) float64 ) #' rational-to-float64 :unary nil ( ( :subscript "f64" ) ) %term% %primary% )
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( float32-to-float64 ( -> ( float32 ) float64 ) #' float32-to-float64 )
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( truncate-finite-float64 ( -> ( finite-float64 ) integer ) #' truncate-finite-float64 )
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;(float64-compare (-> (float64 float64) order) #'float64-compare)
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( float64-abs ( -> ( float64 float64 ) float64 ) #' float64-abs )
( float64-negate ( -> ( float64 ) float64 ) #' float64-neg )
( float64-add ( -> ( float64 float64 ) float64 ) #' float64-add )
( float64-subtract ( -> ( float64 float64 ) float64 ) #' float64-subtract )
( float64-multiply ( -> ( float64 float64 ) float64 ) #' float64-multiply )
( float64-divide ( -> ( float64 float64 ) float64 ) #' float64-divide )
( float64-remainder ( -> ( float64 float64 ) float64 ) #' float64-remainder )
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( integer-to-char16 ( -> ( integer ) char16 ) #' code-char )
( char16-to-integer ( -> ( char16 ) integer ) #' char-code )
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( integer-to-supplementary-char ( -> ( integer ) supplementary-char ) #' integer-to-supplementary-char )
( integer-to-char21 ( -> ( integer ) char21 ) #' integer-to-char21 )
( char21-to-integer ( -> ( char21 ) integer ) #' char21-to-integer )
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;(integer-set-min (-> (integer-set) integer) #'integer-set-min :unary ((:semantic-keyword "min") " ") nil %min-max% %prefix%)
;(integer-set-max (-> (integer-set) integer) #'integer-set-max :unary ((:semantic-keyword "max") " ") nil %min-max% %prefix%)
;(char16-set-min (-> (char16-set) char16) #'char16-set-min :unary ((:semantic-keyword "min") " ") nil %min-max% %prefix%)
;(char16-set-max (-> (char16-set) char16) #'char16-set-max :unary ((:semantic-keyword "max") " ") nil %min-max% %prefix%)
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( digit-value ( -> ( char16 ) integer ) #' digit-char-36 ) ) )
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; \#boolean is a boxed version of boolean. Use it as a return type of a function that returns boolean if the entire function type
; will be coerced to the type of a function that returns a union including boolean.
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;;; Partial order of primitives for deciding when to depict parentheses.
( defparameter *primitive-level* ( make-partial-order ) )
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( def-partial-order-element *primitive-level* %primary% ) ;id, constant, (e), tag<...>, |e|
( def-partial-order-element *primitive-level* %suffix% %primary% ) ;f(...), a[i], a[i...j], a[i<-v], a.l, action
( def-partial-order-element *primitive-level* %prefix% %suffix% ) ;-e, new tag<...>, a^b
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( def-partial-order-element *primitive-level* %min-max% %prefix% ) ;min, max
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( def-partial-order-element *primitive-level* %not% %prefix% ) ;not
( def-partial-order-element *primitive-level* %factor% %prefix% ) ;/, *, intersection, tuple-infix
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( def-partial-order-element *primitive-level* %term% %factor% ) ;+, -, append, union, set difference
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( def-partial-order-element *primitive-level* %relational% %term% %min-max% %not% ) ;<, <=, >, >=, =, /=, is, member, ...
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( def-partial-order-element *primitive-level* %logical% %relational% ) ;and, or, xor
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( def-partial-order-element *primitive-level* %expr% %logical% ) ;?:, some, every, elt-of, unique-elt-of
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; Return the tail end of the lambda list for make-primitive. The returned list always starts with
; an appearance constant and is followed by additional keywords as appropriate for that appearance.
( defun process-primitive-spec-appearance ( name primitive-spec-appearance )
( if primitive-spec-appearance
( let ( ( appearance ( first primitive-spec-appearance ) )
( args ( rest primitive-spec-appearance ) ) )
( cons
appearance
( ecase appearance
( :global
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( assert-type args ( tuple t symbol ) )
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( list :markup1 ( first args ) :level ( symbol-value ( second args ) ) ) )
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( :infix
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( assert-type args ( tuple t bool symbol symbol symbol ) )
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( list :markup1 ( first args ) :markup2 ( second args ) :level ( symbol-value ( third args ) )
:level1 ( symbol-value ( fourth args ) ) :level2 ( symbol-value ( fifth args ) ) ) )
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( :unary
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( assert-type args ( tuple t t symbol symbol ) )
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( list :markup1 ( first args ) :markup2 ( second args ) :level ( symbol-value ( third args ) )
:level1 ( symbol-value ( fourth args ) ) ) )
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( :phantom
( assert-true ( null args ) )
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( list :level %primary% ) ) ) ) )
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( let ( ( name ( symbol-lower-mixed-case-name name ) ) )
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` ( :global :markup1 ( ( :global-variable , name ) ) :markup2 , name :level , %suffix% ) ) ) )
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; Create a world with the given name and set up the built-in properties of its symbols.
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; conditionals is an association list of (conditional . highlight), where conditional is a symbol
; and highlight is either:
; a style keyword: Use that style to highlight the contents of any (? conditional ...) commands
; nil: Include the contents of any (? conditional ...) commands without highlighting them
; delete: Don't include the contents of (? conditional ...) commands
( defun init-world ( name conditionals )
( assert-type conditionals ( list ( cons symbol ( or null keyword ( eql delete ) ) ) ) )
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( let ( ( world ( make-world name ) ) )
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( setf ( world-conditionals world ) conditionals )
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( dolist ( specials-list *default-specials* )
( let ( ( property ( car specials-list ) ) )
( dolist ( special-spec ( cdr specials-list ) )
( apply #' add-special
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property
( world-intern world ( first special-spec ) )
( rest special-spec ) ) ) ) )
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( dolist ( non-reserved *default-non-reserved* )
( let ( ( symbol ( world-intern world non-reserved ) ) )
( assert ( get-properties ( symbol-plist symbol ) ' ( :special-form :condition :primitive :type-constructor ) ) )
( setf ( get symbol :non-reserved ) t )
( export-symbol symbol ) ) )
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( dolist ( primitive-spec *default-primitives* )
( let ( ( name ( world-intern world ( first primitive-spec ) ) ) )
( apply #' declare-primitive
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name
( second primitive-spec )
( third primitive-spec )
( process-primitive-spec-appearance name ( cdddr primitive-spec ) ) ) ) )
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;Define simple types
( add-type-name world
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( setf ( world-false-type world ) ( make-tag-type world ( setf ( world-false-tag world ) ( add-tag world 'false nil nil nil nil ) ) ) )
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( world-intern world 'false-type )
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nil )
( add-type-name world
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( setf ( world-true-type world ) ( make-tag-type world ( setf ( world-true-tag world ) ( add-tag world 'true nil nil nil nil ) ) ) )
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( world-intern world 'true-type )
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nil )
( setf ( world-denormalized-false-type world ) ( make-denormalized-tag-type world ( world-false-tag world ) ) )
( setf ( world-denormalized-true-type world ) ( make-denormalized-tag-type world ( world-true-tag world ) ) )
( assert-true ( < ( type-serial-number ( world-false-type world ) ) ( type-serial-number ( world-true-type world ) ) ) )
( setf ( world-boxed-boolean-type world )
( make-type world :union nil ( list ( world-false-type world ) ( world-true-type world ) ) 'eq nil ) )
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( add-type-name world ( world-boxed-boolean-type world ) ( world-intern world '\#boolean ) nil )
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( flet ( ( make-simple-type ( name kind =-name /=-name )
( let ( ( type ( make-type world kind nil nil =-name /=-name ) ) )
( add-type-name world type ( world-intern world name ) nil )
type ) ) )
( setf ( world-bottom-type world ) ( make-simple-type 'bottom-type :bottom nil nil ) )
( setf ( world-void-type world ) ( make-simple-type 'void :void nil nil ) )
( setf ( world-boolean-type world ) ( make-simple-type 'boolean :boolean 'boolean= nil ) )
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( let ( ( integer-type ( make-simple-type 'integer :integer '= '/= ) ) )
( setf ( world-integer-type world ) integer-type )
( setf ( type-order-alist integer-type ) ' ( ( < . < ) ( > . > ) ( <= . <= ) ( >= . >= ) ) )
( setf ( type-range-set-encode integer-type ) 'identity )
( setf ( type-range-set-decode integer-type ) 'identity ) )
( let ( ( rational-type ( make-simple-type 'rational :rational '= '/= ) ) )
( setf ( world-rational-type world ) rational-type )
( setf ( type-order-alist rational-type ) ' ( ( < . < ) ( > . > ) ( <= . <= ) ( >= . >= ) ) ) )
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( setf ( world-finite32-type world ) ( make-simple-type 'nonzero-finite-float32 :finite32 '= '/= ) )
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( setf ( world-finite64-type world ) ( make-simple-type 'nonzero-finite-float64 :finite64 '= '/= ) )
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( setf ( world-finite32-tag world ) ( make-tag :finite32 nil nil ( list ( make-field 'value ( world-rational-type world ) nil nil ) ) '= nil -1 ) )
( setf ( world-finite64-tag world ) ( make-tag :finite64 nil nil ( list ( make-field 'value ( world-rational-type world ) nil nil ) ) '= nil -1 ) )
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( let* ( ( char16-type ( make-simple-type 'char16 :char16 'char= 'char/= ) )
( supplementary-char-type ( make-simple-type 'supplementary-char :supplementary-char 'equal nil ) )
( char21-type ( make-union-type world char16-type supplementary-char-type ) ) )
( setf ( type-order-alist char16-type ) ' ( ( < . char< ) ( > . char> ) ( <= . char<= ) ( >= . char>= ) ) )
( setf ( type-range-set-encode char16-type ) 'char-code )
( setf ( type-range-set-decode char16-type ) 'code-char )
( setf ( type-order-alist supplementary-char-type ) ' ( ( < . char21< ) ( > . char21> ) ( <= . char21<= ) ( >= . char21>= ) ) )
( setf ( type-range-set-encode supplementary-char-type ) 'char21-to-integer )
( setf ( type-range-set-decode supplementary-char-type ) 'integer-to-char21 )
( setf ( type-order-alist char21-type ) ' ( ( < . char21< ) ( > . char21> ) ( <= . char21<= ) ( >= . char21>= ) ) )
( setf ( type-=-name char21-type ) 'equal )
( setf ( type-range-set-encode char21-type ) 'char21-to-integer )
( setf ( type-range-set-decode char21-type ) 'integer-to-char21 )
( add-type-name world char21-type ( world-intern world 'char21 ) nil )
( setf ( world-char16-type world ) char16-type )
( setf ( world-supplementary-char-type world ) supplementary-char-type )
( setf ( world-char21-type world ) char21-type ) )
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( let ( ( string-type ( make-type world :string nil ( list ( world-char16-type world ) ) 'string= 'string/= ) ) )
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( setf ( type-order-alist string-type ) ' ( ( < . string< ) ( > . string> ) ( <= . string<= ) ( >= . string>= ) ) )
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( add-type-name world string-type ( world-intern world 'string ) nil )
( setf ( world-string-type world ) string-type ) ) )
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( add-type-name world ( make-range-set-type world ( world-integer-type world ) ) ( world-intern world 'integer-set ) nil )
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( add-type-name world ( make-range-set-type world ( world-char16-type world ) ) ( world-intern world 'char16-set ) nil )
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( add-type-name world ( make-range-set-type world ( world-char21-type world ) ) ( world-intern world 'char21-set ) nil )
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;Define order, floating-point, and long integer types
( let ( ;(order-types (mapcar
; #'(lambda (tag-name)
; (make-tag-type world (add-tag world tag-name nil nil nil nil)))
; '(less equal greater unordered)))
( float32-tag-types ( mapcar
#' ( lambda ( tag-name )
( make-tag-type world ( add-tag world tag-name nil nil nil nil ) ) )
' ( +zero32 -zero32 +infinity32 -infinity32 nan32 ) ) )
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( float64-tag-types ( mapcar
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#' ( lambda ( tag-name )
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( make-tag-type world ( add-tag world tag-name nil nil nil nil ) ) )
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' ( +zero64 -zero64 +infinity64 -infinity64 nan64 ) ) ) )
;(add-type-name world (apply #'make-union-type world order-types) (world-intern world 'order) nil)
( let ( ( float32-type ( apply #' make-union-type world ( world-finite32-type world ) float32-tag-types ) )
( float64-type ( apply #' make-union-type world ( world-finite64-type world ) float64-tag-types ) )
( finite-float32-type ( make-union-type world ( world-finite32-type world ) ( first float32-tag-types ) ( second float32-tag-types ) ) )
( finite-float64-type ( make-union-type world ( world-finite64-type world ) ( first float64-tag-types ) ( second float64-tag-types ) ) ) )
( add-type-name world float32-type ( world-intern world 'float32 ) nil )
( add-type-name world float64-type ( world-intern world 'float64 ) nil )
( add-type-name world finite-float32-type ( world-intern world 'finite-float32 ) nil )
( add-type-name world finite-float64-type ( world-intern world 'finite-float64 ) nil )
( let ( ( long-type ( scan-deftuple-or-defrecord world nil 'long ' ( ( value ( integer-range ( neg ( expt 2 63 ) ) ( - ( expt 2 63 ) 1 ) ) ) ) nil ) )
( u-long-type ( scan-deftuple-or-defrecord world nil 'u-long ' ( ( value ( integer-range 0 ( - ( expt 2 64 ) 1 ) ) ) ) nil ) ) )
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( setf ( tag-appearance ( type-tag long-type ) ) ' ( :suffix ( :subscript ( :tag-name "long" ) ) ) )
( setf ( tag-appearance ( type-tag u-long-type ) ) ' ( :suffix ( :subscript ( :tag-name "ulong" ) ) ) )
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( add-type-name world ( make-union-type world float32-type float64-type long-type u-long-type ) ( world-intern world 'general-number ) nil )
( add-type-name world ( make-union-type world finite-float32-type finite-float64-type long-type u-long-type )
( world-intern world 'finite-general-number ) nil ) ) ) )
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world ) )
( defun print-world ( world &optional ( stream t ) ( all t ) )
( pprint-logical-block ( stream nil )
( labels
( ( default-print-contents ( symbol value stream )
( declare ( ignore symbol ) )
( write value :stream stream ) )
( print-symbols-and-contents ( property title separator print-contents )
( let ( ( symbols ( all-world-external-symbols-with-property world property ) ) )
( when symbols
( pprint-logical-block ( stream symbols )
( write-string title stream )
( pprint-indent :block 2 stream )
( pprint-newline :mandatory stream )
( loop
( let ( ( symbol ( pprint-pop ) ) )
( pprint-logical-block ( stream nil )
( if separator
( format stream "~A ~@_~:I~A " symbol separator )
( format stream "~A " symbol ) )
( funcall print-contents symbol ( get symbol property ) stream ) ) )
( pprint-exit-if-list-exhausted )
( pprint-newline :mandatory stream ) ) )
( pprint-newline :mandatory stream )
( pprint-newline :mandatory stream ) ) ) ) )
( when all
( print-symbols-and-contents
:preprocess "Preprocessor actions:" "::" #' default-print-contents )
( print-symbols-and-contents
:command "Commands:" "::" #' default-print-contents )
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( print-symbols-and-contents
:statement "Special Forms:" "::" #' default-print-contents )
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( print-symbols-and-contents
:special-form "Special Forms:" "::" #' default-print-contents )
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( print-symbols-and-contents
:condition "Conditions:" "::" #' default-print-contents )
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( print-symbols-and-contents
:primitive "Primitives:" ":"
#' ( lambda ( symbol primitive stream )
( declare ( ignore symbol ) )
( let ( ( type ( primitive-type primitive ) ) )
( if type
( print-type type stream )
( format stream "~@<<<~;~W~;>>~:>" ( primitive-type-expr primitive ) ) ) )
( format stream " ~_= ~@<<~;~W~;>~:>" ( primitive-value-code primitive ) ) ) )
( print-symbols-and-contents
:type-constructor "Type Constructors:" "::" #' default-print-contents ) )
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( print-symbols-and-contents
:tag "Tags:" "=="
#' ( lambda ( symbol tag stream )
( declare ( ignore symbol ) )
( print-tag tag stream ) ) )
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( print-symbols-and-contents
:deftype "Types:" "=="
#' ( lambda ( symbol type stream )
( if type
( print-type type stream ( eq symbol ( type-name type ) ) )
( format stream "<forward-referenced>" ) ) ) )
( print-symbols-and-contents
:value-expr "Values:" ":"
#' ( lambda ( symbol value-expr stream )
( let ( ( type ( symbol-type symbol ) ) )
( if type
( print-type type stream )
( format stream "~@<<<~;~W~;>>~:>" ( get symbol :type-expr ) ) )
( format stream " ~_= " )
( if ( boundp symbol )
( print-value ( symbol-value symbol ) type stream )
( format stream "~@<<<~;~W~;>>~:>" value-expr ) ) ) ) )
( print-symbols-and-contents
:action "Actions:" nil
#' ( lambda ( action-symbol grammar-info-and-symbols stream )
( pprint-newline :miser stream )
( pprint-logical-block ( stream ( reverse grammar-info-and-symbols ) )
( pprint-exit-if-list-exhausted )
( loop
( let* ( ( grammar-info-and-symbol ( pprint-pop ) )
( grammar-info ( car grammar-info-and-symbol ) )
( grammar ( grammar-info-grammar grammar-info ) )
( grammar-symbol ( cdr grammar-info-and-symbol ) ) )
( write-string ": " stream )
( multiple-value-bind ( has-type type ) ( action-declaration grammar grammar-symbol action-symbol )
( declare ( ignore has-type ) )
( pprint-logical-block ( stream nil )
( print-type type stream )
( format stream " ~_{~S ~S}" ( grammar-info-name grammar-info ) grammar-symbol ) ) ) )
( pprint-exit-if-list-exhausted )
( pprint-newline :mandatory stream ) ) ) ) ) ) ) )
( defmethod print-object ( ( world world ) stream )
( print-unreadable-object ( world stream )
( format stream "world ~A" ( world-name world ) ) ) )
;;; ------------------------------------------------------------------------------------------------------
;;; EVALUATION
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; Scan a command. Create types and variables in the world but do not evaluate variables' types or values yet.
; grammar-info-var is a cons cell whose car is either nil or a grammar-info for the grammar currently being defined.
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( defun scan-command ( world grammar-info-var command )
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( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
( format *error-output* "~&~@<~2IWhile processing: ~_~:W~:>~%" command ) ) ) )
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( let ( ( handler ( and ( consp command )
( identifier? ( first command ) )
( get ( world-intern world ( first command ) ) :command ) ) ) )
( if handler
( apply handler world grammar-info-var ( rest command ) )
( error "Bad command" ) ) ) ) )
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; Scan a list of commands. See scan-command above.
( defun scan-commands ( world grammar-info-var commands )
( dolist ( command commands )
( scan-command world grammar-info-var command ) ) )
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; Compute the primitives' types from their type-exprs.
( defun define-primitives ( world )
( each-world-external-symbol-with-property
world
:primitive
#' ( lambda ( symbol primitive )
( declare ( ignore symbol ) )
( define-primitive world primitive ) ) ) )
; Compute the types and values of all variables accumulated by scan-command.
( defun eval-variables ( world )
;Compute the variables' types first.
( each-world-external-symbol-with-property
world
:type-expr
#' ( lambda ( symbol type-expr )
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( when ( symbol-tag symbol )
( error "~S is both a tag and a variable" symbol ) )
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( setf ( get symbol :type ) ( scan-type world type-expr ) ) ) )
;Then compute the variables' values.
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( let ( ( vars nil ) )
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( each-world-external-symbol-with-property
world
:value-expr
#' ( lambda ( symbol value-expr )
( let ( ( type ( symbol-type symbol ) ) )
( if ( eq ( type-kind type ) :-> )
( compute-variable-function symbol value-expr type )
( push symbol vars ) ) ) ) )
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( mapc #' compute-variable-value vars ) ) )
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; Compute the types of all grammar declarations accumulated by scan-declare-action.
( defun eval-action-declarations ( world )
( dolist ( grammar ( world-grammars world ) )
( each-action-declaration
grammar
#' ( lambda ( grammar-symbol action-declaration )
( declare ( ignore grammar-symbol ) )
( setf ( cdr action-declaration ) ( scan-type world ( cdr action-declaration ) ) ) ) ) ) )
; Compute the bodies of all grammar actions accumulated by scan-action.
( defun eval-action-definitions ( world )
( dolist ( grammar ( world-grammars world ) )
( maphash
#' ( lambda ( terminal action-bindings )
( dolist ( action-binding action-bindings )
( unless ( cdr action-binding )
( error "Missing action ~S for terminal ~S" ( car action-binding ) terminal ) ) ) )
( grammar-terminal-actions grammar ) )
( each-grammar-production
grammar
#' ( lambda ( production )
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( compute-production-code world grammar production ) ) ) ) )
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; Evaluate the given commands in the world.
; This method can only be called once.
( defun eval-commands ( world commands )
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( defer-mcl-warnings
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( define-primitives world )
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( ensure-proper-form commands )
( assert-true ( null ( world-commands-source world ) ) )
( setf ( world-commands-source world ) commands )
( let ( ( grammar-info-var ( list nil ) ) )
( scan-commands world grammar-info-var commands ) )
( unite-types world )
( eval-tags-types world )
( eval-action-declarations world )
( eval-variables world )
( eval-action-definitions world ) ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; PREPROCESSING
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( defstruct ( preprocessor-state ( :constructor make-preprocessor-state ( world ) ) )
( world nil :type world :read-only t ) ;The world into which preprocessed symbols are interned
( highlight nil :type symbol ) ;The current highlight style or nil if none
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( kind nil :type ( member nil :grammar :lexer ) ) ;The kind of grammar being accumulated or nil if none
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( kind2 nil :type ( member nil :lalr-1 :lr-1 :canonical-lr-1 ) ) ;The kind of parser
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( name nil :type symbol ) ;Name of the grammar being accumulated or nil if none
( parametrization nil :type ( or null grammar-parametrization ) ) ;Parametrization of the grammar being accumulated or nil if none
( start-symbol nil :type symbol ) ;Start symbol of the grammar being accumulated or nil if none
( grammar-source-reverse nil :type list ) ;List of productions in the grammar being accumulated (in reverse order)
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( excluded-nonterminals-source nil :type list ) ;List of nonterminals to be excluded from the grammar
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( grammar-options nil :type list ) ;List of other options for make-grammar
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( charclasses-source nil ) ;List of charclasses in the lexical grammar being accumulated
( lexer-actions-source nil ) ;List of lexer actions in the lexical grammar being accumulated
( grammar-infos-reverse nil :type list ) ) ;List of grammar-infos already completed (in reverse order)
; Ensure that the preprocessor-state is accumulating a grammar or a lexer.
( defun preprocess-ensure-grammar ( preprocessor-state )
( unless ( preprocessor-state-kind preprocessor-state )
( error "No active grammar at this point" ) ) )
; Finish generating the current grammar-info if one is in progress.
; Return any extra commands needed for this grammar-info.
; The result list can be mutated using nconc.
( defun preprocessor-state-finish-grammar ( preprocessor-state )
( let ( ( kind ( preprocessor-state-kind preprocessor-state ) ) )
( and kind
( let ( ( parametrization ( preprocessor-state-parametrization preprocessor-state ) )
( start-symbol ( preprocessor-state-start-symbol preprocessor-state ) )
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( grammar-source ( nreverse ( preprocessor-state-grammar-source-reverse preprocessor-state ) ) )
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( excluded-nonterminals-source ( preprocessor-state-excluded-nonterminals-source preprocessor-state ) )
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( grammar-options ( preprocessor-state-grammar-options preprocessor-state ) )
( highlights ( world-highlights ( preprocessor-state-world preprocessor-state ) ) ) )
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( multiple-value-bind ( grammar lexer extra-commands )
( ecase kind
( :grammar
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( values ( apply #' make-and-compile-grammar
( preprocessor-state-kind2 preprocessor-state )
parametrization
start-symbol
grammar-source
:excluded-nonterminals excluded-nonterminals-source
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:highlights highlights
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grammar-options )
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nil
nil ) )
( :lexer
( multiple-value-bind ( lexer extra-commands )
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( apply #' make-lexer-and-grammar
( preprocessor-state-kind2 preprocessor-state )
( preprocessor-state-charclasses-source preprocessor-state )
( preprocessor-state-lexer-actions-source preprocessor-state )
parametrization
start-symbol
grammar-source
:excluded-nonterminals excluded-nonterminals-source
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:highlights highlights
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grammar-options )
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( values ( lexer-grammar lexer ) lexer extra-commands ) ) ) )
( let ( ( grammar-info ( make-grammar-info ( preprocessor-state-name preprocessor-state ) grammar lexer ) ) )
( setf ( preprocessor-state-kind preprocessor-state ) nil )
( setf ( preprocessor-state-kind2 preprocessor-state ) nil )
( setf ( preprocessor-state-name preprocessor-state ) nil )
( setf ( preprocessor-state-parametrization preprocessor-state ) nil )
( setf ( preprocessor-state-start-symbol preprocessor-state ) nil )
( setf ( preprocessor-state-grammar-source-reverse preprocessor-state ) nil )
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( setf ( preprocessor-state-excluded-nonterminals-source preprocessor-state ) nil )
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( setf ( preprocessor-state-grammar-options preprocessor-state ) nil )
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( setf ( preprocessor-state-charclasses-source preprocessor-state ) nil )
( setf ( preprocessor-state-lexer-actions-source preprocessor-state ) nil )
( push grammar-info ( preprocessor-state-grammar-infos-reverse preprocessor-state ) )
( append extra-commands ( list ' ( clear-grammar ) ) ) ) ) ) ) ) )
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; Helper function for preprocess-source.
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; source is a list of preprocessor directives and commands. Preprocess these commands
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; using the given preprocessor-state and return the resulting list of commands.
( defun preprocess-list ( preprocessor-state source )
( let ( ( world ( preprocessor-state-world preprocessor-state ) ) )
( flet
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( ( preprocess-one ( form )
( when ( consp form )
( let ( ( first ( car form ) ) )
( when ( identifier? first )
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( let ( ( action ( symbol-preprocessor-function ( world-intern world first ) ) ) )
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( when action
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( handler-bind ( ( ( or error warning )
#' ( lambda ( condition )
( declare ( ignore condition ) )
( format *error-output* "~&~@<~2IWhile preprocessing: ~_~:W~:>~%" form ) ) ) )
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( multiple-value-bind ( preprocessed-form re-preprocess ) ( apply action preprocessor-state form )
( return-from preprocess-one
( if re-preprocess
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( preprocess-list preprocessor-state preprocessed-form )
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preprocessed-form ) ) ) ) ) ) ) ) )
( list form ) ) )
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( mapcan #' preprocess-one source ) ) ) )
; source is a list of preprocessor directives and commands. Preprocess these commands
; and return the following results:
; a list of preprocessed commands;
; a list of grammar-infos extracted from preprocessor directives.
( defun preprocess-source ( world source )
( let* ( ( preprocessor-state ( make-preprocessor-state world ) )
( commands ( preprocess-list preprocessor-state source ) )
( commands ( nconc commands ( preprocessor-state-finish-grammar preprocessor-state ) ) ) )
( values commands ( nreverse ( preprocessor-state-grammar-infos-reverse preprocessor-state ) ) ) ) )
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; Create a new world with the given name and preprocess and evaluate the given
; source commands in it.
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; conditionals is an association list of (conditional . highlight), where conditional is a symbol
; and highlight is either:
; a style keyword: Use that style to highlight the contents of any (? conditional ...) commands
; nil: Include the contents of any (? conditional ...) commands without highlighting them
; delete: Don't include the contents of (? conditional ...) commands
( defun generate-world ( name source &optional conditionals )
( let ( ( world ( init-world name conditionals ) ) )
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( multiple-value-bind ( commands grammar-infos ) ( preprocess-source world source )
( dolist ( grammar-info grammar-infos )
( clear-actions ( grammar-info-grammar grammar-info ) ) )
( setf ( world-grammar-infos world ) grammar-infos )
( eval-commands world commands )
world ) ) )
;;; ------------------------------------------------------------------------------------------------------
;;; PREPROCESSOR ACTIONS
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; (? <conditional> <command> ... <command>)
; ==>
; (%highlight <highlight> <command> ... <command>)
; or
; <empty>
( defun preprocess-? ( preprocessor-state command conditional &rest commands )
( declare ( ignore command ) )
( let ( ( highlight ( resolve-conditional ( preprocessor-state-world preprocessor-state ) conditional ) )
( saved-highlight ( preprocessor-state-highlight preprocessor-state ) ) )
( cond
( ( eq highlight 'delete ) ( values nil nil ) )
( ( eq highlight saved-highlight ) ( values commands t ) )
( t ( values
( unwind-protect
( progn
( setf ( preprocessor-state-highlight preprocessor-state ) highlight )
( list ( list* '%highlight highlight ( preprocess-list preprocessor-state commands ) ) ) )
( setf ( preprocessor-state-highlight preprocessor-state ) saved-highlight ) )
nil ) ) ) ) )
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; (declare-action <action-name> <general-grammar-symbol> <type> <mode> <parameter-list> <command> ... <command>)
; ==>
; (declare-action <action-name> <general-grammar-symbol> <type> <mode> <parameter-list> <command> ... <command>)
( defun preprocess-declare-action ( preprocessor-state command action-name general-grammar-symbol-source type-expr mode parameter-list &rest commands )
( declare ( ignore command ) )
( values
( list ( list* 'declare-action action-name general-grammar-symbol-source type-expr mode parameter-list
( preprocess-list preprocessor-state commands ) ) )
nil ) )
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; commands is a list of commands and/or (? <conditional> ...), where the ... is a list of commands.
; Call f on each non-deleted command, passing it that command and the current value of highlight.
; f returns a list of preprocessed commands; return the destructive concatenation of these lists.
( defun each-preprocessed-command ( f preprocessor-state commands highlight )
( mapcan
#' ( lambda ( command )
( if ( and ( consp command ) ( eq ( car command ) '? ) )
( progn
( assert-type command ( cons t cons t ( list t ) ) )
( let* ( ( commands ( cddr command ) )
( new-highlight ( resolve-conditional ( preprocessor-state-world preprocessor-state ) ( second command ) ) ) )
( cond
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( ( eq new-highlight 'delete ) nil )
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( ( eq new-highlight highlight ) ( each-preprocessed-command f preprocessor-state commands new-highlight ) )
( t ( list ( list* '? ( second command ) ( each-preprocessed-command f preprocessor-state commands new-highlight ) ) ) ) ) ) )
( funcall f command highlight ) ) )
commands ) )
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; (define <name> <type> <value>)
; ==>
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; (define <name> <type> <value>)
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;
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; (define (<name> (<arg1> <type1>) ... (<argn> <typen>)) <result-type> . <statements>)
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; ==>
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; (defun <name> (-> (<type1> ... <typen>) <result-type>)
; (lambda ((<arg1> <type1>) ... (<argn> <typen>)) <result-type> . <statements>))
( defun preprocess-define ( preprocessor-state command name type &rest value-or-statements )
( declare ( ignore command preprocessor-state ) )
( values
( list
( if ( consp name )
( let ( ( bindings ( rest name ) ) )
( list 'defun
( first name )
( list '-> ( mapcar #' second bindings ) type )
( list* 'lambda bindings type value-or-statements ) ) )
( list* 'define name type value-or-statements ) ) )
nil ) )
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; (action <action-name> <production-name> <type> <mode> <value>)
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; ==>
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; (action <action-name> <production-name> <type> <mode> <value>)
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;
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; (action (<action-name> (<arg1>) ... (<argn>)) <production-name> (-> (<type1> ... <typen>) <result-type>) <mode> . <statements>)
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; ==>
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; (actfun <action-name> <production-name> (-> (<type1> ... <typen>) <result-type>) <mode>
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; (lambda ((<arg1> <type1>) ... (<argn> <typen>)) <result-type> . <statements>))
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( defun preprocess-action ( preprocessor-state command action-name production-name type mode &rest value-or-statements )
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( declare ( ignore command preprocessor-state ) )
( values
( list
( if ( consp action-name )
( let ( ( action-name ( first action-name ) )
( abbreviated-bindings ( rest action-name ) ) )
( unless ( and ( consp type ) ( eq ( first type ) '-> ) )
( error "Destructuring requires ~S to be a -> type" type ) )
( let ( ( ->-parameters ( second type ) )
( ->-result ( third type ) ) )
( unless ( = ( length ->-parameters ) ( length abbreviated-bindings ) )
( error "Parameter count mistmatch: ~S and ~S" ->-parameters abbreviated-bindings ) )
( let ( ( bindings ( mapcar #' ( lambda ( binding type )
( if ( consp binding )
( list* ( first binding ) type ( rest binding ) )
( list binding type ) ) )
abbreviated-bindings
->-parameters ) ) )
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( list 'actfun action-name production-name type mode ( list* 'lambda bindings ->-result value-or-statements ) ) ) ) )
( list* 'action action-name production-name type mode value-or-statements ) ) )
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nil ) )
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( defun preprocess-grammar-or-lexer ( preprocessor-state kind kind2 name start-symbol &rest grammar-options )
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( assert-type name identifier )
( let ( ( commands ( preprocessor-state-finish-grammar preprocessor-state ) ) )
( when ( find name ( preprocessor-state-grammar-infos-reverse preprocessor-state ) :key #' grammar-info-name )
( error "Duplicate grammar ~S" name ) )
( setf ( preprocessor-state-kind preprocessor-state ) kind )
( setf ( preprocessor-state-kind2 preprocessor-state ) kind2 )
( setf ( preprocessor-state-name preprocessor-state ) name )
( setf ( preprocessor-state-parametrization preprocessor-state ) ( make-grammar-parametrization ) )
( setf ( preprocessor-state-start-symbol preprocessor-state ) start-symbol )
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( setf ( preprocessor-state-grammar-options preprocessor-state ) grammar-options )
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( values
( nconc commands ( list ( list 'set-grammar name ) ) )
nil ) ) )
; (grammar <name> <kind> <start-symbol>)
; ==>
; grammar:
; Begin accumulating a grammar with the given name and start symbol;
; commands:
; (set-grammar <name>)
( defun preprocess-grammar ( preprocessor-state command name kind2 start-symbol )
( declare ( ignore command ) )
( preprocess-grammar-or-lexer preprocessor-state :grammar kind2 name start-symbol ) )
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( defun generate-line-break-constraints ( terminal )
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( assert-type terminal user-terminal )
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( list
( list terminal :line-break )
( list ( make-lf-terminal terminal ) :no-line-break ) ) )
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; (line-grammar <name> <kind> <start-symbol>)
; ==>
; grammar:
; Begin accumulating a grammar with the given name and start symbol.
; Allow :no-line-break constraints.
; commands:
; (set-grammar <name>)
( defun preprocess-line-grammar ( preprocessor-state command name kind2 start-symbol )
( declare ( ignore command ) )
( preprocess-grammar-or-lexer preprocessor-state :grammar kind2 name start-symbol
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:variant-constraint-names ' ( :line-break :no-line-break )
:variant-generator #' generate-line-break-constraints ) )
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; (lexer <name> <kind> <start-symbol> <charclasses-source> <lexer-actions-source>)
; ==>
; grammar:
; Begin accumulating a lexer with the given name, start symbol, charclasses, and lexer actions;
; commands:
; (set-grammar <name>)
( defun preprocess-lexer ( preprocessor-state command name kind2 start-symbol charclasses-source lexer-actions-source )
( declare ( ignore command ) )
( multiple-value-prog1
( preprocess-grammar-or-lexer preprocessor-state :lexer kind2 name start-symbol )
( setf ( preprocessor-state-charclasses-source preprocessor-state ) charclasses-source )
( setf ( preprocessor-state-lexer-actions-source preprocessor-state ) lexer-actions-source ) ) )
; (grammar-argument <argument> <attribute> <attribute> ... <attribute>)
; ==>
; grammar parametrization:
; (<argument> <attribute> <attribute> ... <attribute>)
; commands:
; (grammar-argument <argument> <attribute> <attribute> ... <attribute>)
( defun preprocess-grammar-argument ( preprocessor-state command argument &rest attributes )
( preprocess-ensure-grammar preprocessor-state )
( grammar-parametrization-declare-argument ( preprocessor-state-parametrization preprocessor-state ) argument attributes )
( values ( list ( list* command argument attributes ) )
nil ) )
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; (production <lhs> <rhs> <name>)
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; ==>
; grammar:
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; (<lhs> <rhs> <name> <current-highlight>)
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; commands:
; (%rule <lhs>)
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( defun preprocess-production ( preprocessor-state command lhs rhs name )
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( declare ( ignore command ) )
( preprocess-ensure-grammar preprocessor-state )
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( push ( list lhs rhs name ( preprocessor-state-highlight preprocessor-state ) )
( preprocessor-state-grammar-source-reverse preprocessor-state ) )
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( values ( list ( list '%rule lhs ) )
t ) )
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; (rule <general-grammar-symbol>
; ((<action-name-1> <type-1>) ... (<action-name-n> <type-n>))
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; (production <lhs-1> <rhs-1> <name-1> (<action-spec-1-1> . <body-1-1>) ... (<action-spec-1-n> . <body-1-n>))
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; ...
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; (production <lhs-m> <rhs-m> <name-m> (<action-spec-m-1> . <body-m-1>) ... (<action-spec-m-n> . <body-m-n>)))
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; ==>
; grammar:
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; (<lhs-1> <rhs-1> <name-1> <current-highlight>)
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; ...
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; (<lhs-m> <rhs-m> <name-m> <current-highlight>)
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; commands:
; (%rule <lhs-1>)
; ...
; (%rule <lhs-m>)
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; (declare-action <action-name-1> <general-grammar-symbol> <type-1> <mode> <parameter-list>)
; (action <action-spec-1-1> <name-1> <type-1> <mode> . <body-1-1>)
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; ...
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; (action <action-spec-m-1> <name-m> <type-1> <mode> . <body-m-1>)
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; ...
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; (declare-action <action-name-n> <general-grammar-symbol> <type-n> <mode> <parameter-list>)
; (action <action-spec-1-n> <name-1> <type-n> <mode> . <body-1-n>)
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; ...
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; (action <action-spec-m-n> <name-m> <type-n> <mode> . <body-m-n>)
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;
; The productions may be enclosed by (? <conditional> ...) preprocessor actions.
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;
; If one of the <body-x-y> is :forward, then the action must be a function action and the corresponding action's
; <body-z-y> must also be :forward in every other production. This action expands into a function that calls
; actions with the same name in every nonterminal on the right side of the grammar production, passing them the
; same parameters as the action received.
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;
; If one of the <body-x-y> is :forward-result, then the action must be a function action and the corresponding action's
; <body-z-y> must also be :forward-result in every other production. This action expands into a function that calls
; actions with the same name in every nonterminal on the right side of the grammar production, passing them the
; same parameters as the action received and returns the result. Each production must have exactly one nonterminal.
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( defun preprocess-rule ( preprocessor-state command general-grammar-symbol action-declarations &rest productions )
( declare ( ignore command ) )
( assert-type action-declarations ( list ( tuple symbol t ) ) )
( preprocess-ensure-grammar preprocessor-state )
( labels
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( ( writable-action ( action-declaration )
( let ( ( type ( second action-declaration ) ) )
( and ( consp type )
( eq ( first type ) 'writable-cell ) ) ) )
( actions-match ( action-declarations parameter-lists actions )
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( or ( and ( endp action-declarations ) ( endp parameter-lists ) ( endp actions ) )
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( let ( ( action-declaration ( first action-declarations ) ) )
( if ( writable-action action-declaration )
( progn
( when ( eq ( first parameter-lists ) t )
( setf ( first parameter-lists ) :value ) )
( actions-match ( rest action-declarations ) ( rest parameter-lists ) actions ) )
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( let* ( ( declared-action-name ( first action-declaration ) )
( action ( first actions ) )
( action-name ( first action ) )
( action-body ( rest action ) )
( parameter-list :value ) )
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( when ( consp action-name )
( setq parameter-list ( mapcar #' ( lambda ( arg )
( if ( consp arg )
( first arg )
arg ) )
( rest action-name ) ) )
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( setq action-name ( first action-name ) )
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( cond
( ( equal action-body ' ( :forward ) )
( setq parameter-list ( cons :forward parameter-list ) ) )
( ( equal action-body ' ( :forward-result ) )
( setq parameter-list ( cons :forward-result parameter-list ) ) ) ) )
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( when ( eq ( first parameter-lists ) t )
( setf ( first parameter-lists ) parameter-list ) )
( and ( eq declared-action-name action-name )
( equal ( first parameter-lists ) parameter-list )
( actions-match ( rest action-declarations ) ( rest parameter-lists ) ( rest actions ) ) ) ) ) ) ) ) )
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( let* ( ( n-productions 0 )
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( parameter-lists ( make-list ( length action-declarations ) :initial-element t ) )
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( commands-reverse
( nreverse
( each-preprocessed-command
#' ( lambda ( production highlight )
( assert-true ( eq ( first production ) 'production ) )
( let ( ( lhs ( second production ) )
( rhs ( third production ) )
( name ( assert-type ( fourth production ) symbol ) )
( actions ( assert-type ( cddddr production ) ( list ( cons t t ) ) ) ) )
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( unless ( actions-match action-declarations parameter-lists actions )
( error "Action name or parameter list mismatch: ~S vs. ~S" action-declarations actions ) )
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( push ( list lhs rhs name highlight ) ( preprocessor-state-grammar-source-reverse preprocessor-state ) )
( incf n-productions )
( list ( list '%rule lhs ) ) ) )
preprocessor-state
productions
( preprocessor-state-highlight preprocessor-state ) ) ) ) )
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( when ( = n-productions 0 )
( error "Empty rule" ) )
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( let ( ( i 4 ) )
( dolist ( action-declaration action-declarations )
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( let* ( ( action-name ( first action-declaration ) )
( parameter-list ( pop parameter-lists ) )
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( writable ( writable-action action-declaration ) )
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( forward-mode ( if ( and ( consp parameter-list ) ( member ( first parameter-list ) ' ( :forward :forward-result ) ) )
( first parameter-list )
nil ) )
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( declare-mode ( cond
( writable :writable )
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( forward-mode :forward )
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( ( = n-productions 1 ) :singleton )
( ( eq parameter-list :value ) :action )
( t ( assert-true ( listp parameter-list ) ) :actfun ) ) )
( j 0 ) )
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( when forward-mode
( setq parameter-list ( cdr parameter-list ) ) )
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( push ( list*
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'declare-action action-name general-grammar-symbol ( second action-declaration ) declare-mode parameter-list
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( each-preprocessed-command
#' ( lambda ( production highlight )
( declare ( ignore highlight ) )
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( let* ( ( name ( fourth production ) )
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( action ( cond
( writable
( list action-name ( list 'writable-cell-of ( second ( second action-declaration ) ) ) ) )
( ( eq forward-mode :forward )
( let ( ( forwarded-calls ( generate-forwarded-calls action-name ( third production ) parameter-list ) ) )
( if forwarded-calls
( cons ( cons action-name parameter-list ) forwarded-calls )
( list ( cons action-name ( mapcar #' ( lambda ( parameter ) ( list parameter :unused ) ) parameter-list ) ) ) ) ) )
( ( eq forward-mode :forward-result )
( let ( ( forwarded-calls ( generate-forwarded-calls action-name ( third production ) parameter-list ) ) )
( unless ( = ( length forwarded-calls ) 1 )
( error ":forward-result productions must have exactly one nonterminal" ) )
( list ( cons action-name parameter-list ) ( cons 'return forwarded-calls ) ) ) )
( t ( nth i production ) ) ) )
( mode ( cond
( ( = n-productions 1 ) :singleton )
( ( = j 0 ) :first )
( ( = j ( 1- n-productions ) ) :last )
( t :middle ) ) ) )
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( incf j )
( list ( list* 'action ( first action ) name ( second action-declaration ) mode ( rest action ) ) ) ) )
preprocessor-state
productions
( preprocessor-state-highlight preprocessor-state ) ) )
commands-reverse )
( assert-true ( = j n-productions ) )
( unless writable
( incf i ) ) ) )
( values ( nreverse commands-reverse ) t ) ) ) ) )
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( defun generate-forwarded-calls ( action-name rhs arguments )
( let ( ( counts nil ) )
( labels
( ( process-grammar-symbol ( general-grammar-symbol )
( cond
( ( and ( keywordp general-grammar-symbol ) ( not ( member general-grammar-symbol ' ( :- :line-break :no-line-break ) ) ) )
( let ( ( count ( incf ( getf counts general-grammar-symbol 0 ) ) ) )
( list ( cons ( list action-name general-grammar-symbol count ) arguments ) ) ) )
( ( consp general-grammar-symbol )
( process-grammar-symbol ( first general-grammar-symbol ) ) )
( t nil ) ) ) )
( mapcan #' process-grammar-symbol rhs ) ) ) )
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; (exclude <lhs> ... <lhs>)
; ==>
; grammar excluded nonterminals:
; <lhs> ... <lhs>;
( defun preprocess-exclude ( preprocessor-state command &rest excluded-nonterminals-source )
( declare ( ignore command ) )
( preprocess-ensure-grammar preprocessor-state )
( setf ( preprocessor-state-excluded-nonterminals-source preprocessor-state )
( append excluded-nonterminals-source ( preprocessor-state-excluded-nonterminals-source preprocessor-state ) ) )
( values nil nil ) )
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;;; ------------------------------------------------------------------------------------------------------
;;; DEBUGGING
( defmacro fsource ( name )
` ( function-lambda-expression #' , name ) )
( defmacro =source ( name )
` ( function-lambda-expression ( get ',name :tag= ) ) )
#|
( defun test ( )
( handler-bind ( ( ccl::undefined-function-reference
#' ( lambda ( condition )
( break )
( muffle-warning condition ) ) ) )
( let ( ( s1 ( gentemp "TEMP" ) )
( s2 ( gentemp "TEMP" ) ) )
( compile s1 ` ( lambda ( x ) ( , s2 x y ) ) )
( compile s2 ` ( lambda ( x ) ( , s1 x ) ) ) ) ) )
| #