ruby/compile.c

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C
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/**********************************************************************
compile.c - ruby node tree -> VM instruction sequence
$Author$
created at: 04/01/01 03:42:15 JST
Copyright (C) 2004-2007 Koichi Sasada
**********************************************************************/
#include "internal.h"
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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#include "ruby/re.h"
#include "encindex.h"
#include <math.h>
#define USE_INSN_STACK_INCREASE 1
#include "vm_core.h"
#include "iseq.h"
#include "insns.inc"
#include "insns_info.inc"
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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#include "gc.h"
#ifdef HAVE_DLADDR
# include <dlfcn.h>
#endif
#undef RUBY_UNTYPED_DATA_WARNING
#define RUBY_UNTYPED_DATA_WARNING 0
#define FIXNUM_INC(n, i) ((n)+(INT2FIX(i)&~FIXNUM_FLAG))
#define FIXNUM_OR(n, i) ((n)|INT2FIX(i))
typedef struct iseq_link_element {
enum {
ISEQ_ELEMENT_NONE,
ISEQ_ELEMENT_LABEL,
ISEQ_ELEMENT_INSN,
ISEQ_ELEMENT_ADJUST
} type;
struct iseq_link_element *next;
struct iseq_link_element *prev;
} LINK_ELEMENT;
typedef struct iseq_link_anchor {
LINK_ELEMENT anchor;
LINK_ELEMENT *last;
} LINK_ANCHOR;
typedef struct iseq_label_data {
LINK_ELEMENT link;
int label_no;
int position;
int sc_state;
int sp;
int refcnt;
unsigned int set: 1;
} LABEL;
typedef struct iseq_insn_data {
LINK_ELEMENT link;
enum ruby_vminsn_type insn_id;
unsigned int line_no;
int operand_size;
int sc_state;
VALUE *operands;
} INSN;
typedef struct iseq_adjust_data {
LINK_ELEMENT link;
LABEL *label;
int line_no;
} ADJUST;
struct ensure_range {
LABEL *begin;
LABEL *end;
struct ensure_range *next;
};
struct iseq_compile_data_ensure_node_stack {
NODE *ensure_node;
struct iseq_compile_data_ensure_node_stack *prev;
struct ensure_range *erange;
};
/**
* debug function(macro) interface depend on CPDEBUG
* if it is less than 0, runtime option is in effect.
*
* debug level:
* 0: no debug output
* 1: show node type
* 2: show node important parameters
* ...
* 5: show other parameters
* 10: show every AST array
*/
#ifndef CPDEBUG
#define CPDEBUG 0
#endif
#if CPDEBUG >= 0
#define compile_debug CPDEBUG
#else
#define compile_debug ISEQ_COMPILE_DATA(iseq)->option->debug_level
#endif
#if CPDEBUG
#define compile_debug_print_indent(level) \
ruby_debug_print_indent((level), compile_debug, gl_node_level * 2)
#define debugp(header, value) (void) \
(compile_debug_print_indent(1) && \
ruby_debug_print_value(1, compile_debug, (header), (value)))
#define debugi(header, id) (void) \
(compile_debug_print_indent(1) && \
ruby_debug_print_id(1, compile_debug, (header), (id)))
#define debugp_param(header, value) (void) \
(compile_debug_print_indent(1) && \
ruby_debug_print_value(1, compile_debug, (header), (value)))
#define debugp_verbose(header, value) (void) \
(compile_debug_print_indent(2) && \
ruby_debug_print_value(2, compile_debug, (header), (value)))
#define debugp_verbose_node(header, value) (void) \
(compile_debug_print_indent(10) && \
ruby_debug_print_value(10, compile_debug, (header), (value)))
#define debug_node_start(node) ((void) \
(compile_debug_print_indent(1) && \
(ruby_debug_print_node(1, CPDEBUG, "", (NODE *)(node)), gl_node_level)), \
gl_node_level++)
#define debug_node_end() gl_node_level --
#else
static inline ID
r_id(ID id)
{
return id;
}
static inline VALUE
r_value(VALUE value)
{
return value;
}
#define debugi(header, id) r_id(id)
#define debugp(header, value) r_value(value)
#define debugp_verbose(header, value) r_value(value)
#define debugp_verbose_node(header, value) r_value(value)
#define debugp_param(header, value) r_value(value)
#define debug_node_start(node) ((void)0)
#define debug_node_end() ((void)0)
#endif
#if CPDEBUG > 1 || CPDEBUG < 0
#define printf ruby_debug_printf
#define debugs if (compile_debug_print_indent(1)) ruby_debug_printf
#define debug_compile(msg, v) ((void)(compile_debug_print_indent(1) && fputs((msg), stderr)), (v))
#else
#define debugs if(0)printf
#define debug_compile(msg, v) (v)
#endif
/* create new label */
#define NEW_LABEL(l) new_label_body(iseq, (l))
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#define iseq_path(iseq) ((iseq)->body->location.path)
#define iseq_absolute_path(iseq) ((iseq)->body->location.absolute_path)
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#define NEW_ISEQ(node, name, type, line_no) \
new_child_iseq(iseq, (node), rb_fstring(name), 0, (type), (line_no))
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#define NEW_CHILD_ISEQ(node, name, type, line_no) \
new_child_iseq(iseq, (node), rb_fstring(name), iseq, (type), (line_no))
/* add instructions */
#define ADD_SEQ(seq1, seq2) \
APPEND_LIST((seq1), (seq2))
/* add an instruction */
#define ADD_INSN(seq, line, insn) \
ADD_ELEM((seq), (LINK_ELEMENT *) new_insn_body(iseq, (line), BIN(insn), 0))
/* insert an instruction before prev */
#define INSERT_BEFORE_INSN(prev, line, insn) \
INSERT_ELEM_PREV(&(prev)->link, (LINK_ELEMENT *) new_insn_body(iseq, (line), BIN(insn), 0))
/* add an instruction with some operands (1, 2, 3, 5) */
#define ADD_INSN1(seq, line, insn, op1) \
ADD_ELEM((seq), (LINK_ELEMENT *) \
new_insn_body(iseq, (line), BIN(insn), 1, (VALUE)(op1)))
/* insert an instruction with some operands (1, 2, 3, 5) before prev */
#define INSERT_BEFORE_INSN1(prev, line, insn, op1) \
INSERT_ELEM_PREV(&(prev)->link, (LINK_ELEMENT *) \
new_insn_body(iseq, (line), BIN(insn), 1, (VALUE)(op1)))
#define LABEL_REF(label) ((label)->refcnt++)
/* add an instruction with label operand (alias of ADD_INSN1) */
#define ADD_INSNL(seq, line, insn, label) (ADD_INSN1(seq, line, insn, label), LABEL_REF(label))
#define ADD_INSN2(seq, line, insn, op1, op2) \
ADD_ELEM((seq), (LINK_ELEMENT *) \
new_insn_body(iseq, (line), BIN(insn), 2, (VALUE)(op1), (VALUE)(op2)))
#define ADD_INSN3(seq, line, insn, op1, op2, op3) \
ADD_ELEM((seq), (LINK_ELEMENT *) \
new_insn_body(iseq, (line), BIN(insn), 3, (VALUE)(op1), (VALUE)(op2), (VALUE)(op3)))
/* Specific Insn factory */
#define ADD_SEND(seq, line, id, argc) \
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ADD_SEND_R((seq), (line), (id), (argc), NULL, (VALUE)INT2FIX(0), NULL)
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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#define ADD_SEND_WITH_FLAG(seq, line, id, argc, flag) \
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ADD_SEND_R((seq), (line), (id), (argc), NULL, (VALUE)(flag), NULL)
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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#define ADD_SEND_WITH_BLOCK(seq, line, id, argc, block) \
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ADD_SEND_R((seq), (line), (id), (argc), (block), (VALUE)INT2FIX(0), NULL)
#define ADD_CALL_RECEIVER(seq, line) \
ADD_INSN((seq), (line), putself)
#define ADD_CALL(seq, line, id, argc) \
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ADD_SEND_R((seq), (line), (id), (argc), NULL, (VALUE)INT2FIX(VM_CALL_FCALL), NULL)
#define ADD_CALL_WITH_BLOCK(seq, line, id, argc, block) \
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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ADD_SEND_R((seq), (line), (id), (argc), (block), (VALUE)INT2FIX(VM_CALL_FCALL), NULL)
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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#define ADD_SEND_R(seq, line, id, argc, block, flag, keywords) \
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ADD_ELEM((seq), (LINK_ELEMENT *) new_insn_send(iseq, (line), (id), (VALUE)(argc), (block), (VALUE)(flag), (keywords)))
#define ADD_TRACE(seq, line, event) \
do { \
if ((event) == RUBY_EVENT_LINE && ISEQ_COVERAGE(iseq) && \
(line) != ISEQ_COMPILE_DATA(iseq)->last_coverable_line) { \
RARRAY_ASET(ISEQ_COVERAGE(iseq), (line) - 1, INT2FIX(0)); \
ISEQ_COMPILE_DATA(iseq)->last_coverable_line = (line); \
ADD_INSN1((seq), (line), trace, INT2FIX(RUBY_EVENT_COVERAGE)); \
} \
if (ISEQ_COMPILE_DATA(iseq)->option->trace_instruction) { \
ADD_INSN1((seq), (line), trace, INT2FIX(event)); \
} \
} while (0)
/* add label */
#define ADD_LABEL(seq, label) \
ADD_ELEM((seq), (LINK_ELEMENT *) (label))
#define APPEND_LABEL(seq, before, label) \
APPEND_ELEM((seq), (before), (LINK_ELEMENT *) (label))
#define ADD_ADJUST(seq, line, label) \
ADD_ELEM((seq), (LINK_ELEMENT *) new_adjust_body(iseq, (label), (line)))
#define ADD_ADJUST_RESTORE(seq, label) \
ADD_ELEM((seq), (LINK_ELEMENT *) new_adjust_body(iseq, (label), -1))
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#define ADD_CATCH_ENTRY(type, ls, le, iseqv, lc) do { \
VALUE _e = rb_ary_new3(5, (type), \
(VALUE)(ls) | 1, (VALUE)(le) | 1, \
(VALUE)(iseqv), (VALUE)(lc) | 1); \
if (ls) LABEL_REF(ls); \
if (le) LABEL_REF(le); \
if (lc) LABEL_REF(lc); \
rb_ary_push(ISEQ_COMPILE_DATA(iseq)->catch_table_ary, freeze_hide_obj(_e)); \
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} while (0)
/* compile node */
#define COMPILE(anchor, desc, node) \
(debug_compile("== " desc "\n", \
iseq_compile_each(iseq, (anchor), (node), 0)))
/* compile node, this node's value will be popped */
#define COMPILE_POPED(anchor, desc, node) \
(debug_compile("== " desc "\n", \
iseq_compile_each(iseq, (anchor), (node), 1)))
/* compile node, which is popped when 'poped' is true */
#define COMPILE_(anchor, desc, node, poped) \
(debug_compile("== " desc "\n", \
iseq_compile_each(iseq, (anchor), (node), (poped))))
#define COMPILE_RECV(anchor, desc, node) \
(private_recv_p(node) ? \
(ADD_INSN(anchor, nd_line(node), putself), VM_CALL_FCALL) : \
(COMPILE(anchor, desc, node->nd_recv), 0))
#define OPERAND_AT(insn, idx) \
(((INSN*)(insn))->operands[(idx)])
#define INSN_OF(insn) \
(((INSN*)(insn))->insn_id)
/* error */
typedef void (*compile_error_func)(VALUE, int, const char *, ...);
static void
append_compile_error(VALUE file, int line, const char *fmt, ...)
{
VALUE err_info = rb_errinfo();
VALUE str = rb_attr_get(err_info, idMesg);
va_list args;
if (RSTRING_LEN(str)) rb_str_cat2(str, "\n");
if (file) {
rb_str_concat(str, file);
if (line) rb_str_catf(str, ":%d", line);
rb_str_cat2(str, ": ");
}
va_start(args, fmt);
rb_str_vcatf(str, fmt, args);
va_end(args);
}
NOINLINE(static compile_error_func prepare_compile_error(rb_iseq_t *iseq));
static compile_error_func
prepare_compile_error(rb_iseq_t *iseq)
{
VALUE err_info = ISEQ_COMPILE_DATA(iseq)->err_info;
if (compile_debug) return rb_compile_bug_str;
if (NIL_P(err_info)) {
err_info = rb_exc_new_cstr(rb_eSyntaxError, "");
RB_OBJ_WRITE(iseq, &ISEQ_COMPILE_DATA(iseq)->err_info, err_info);
}
rb_set_errinfo(err_info);
return append_compile_error;
}
#define COMPILE_ERROR prepare_compile_error(iseq)
#define ERROR_ARGS_AT(n) ruby_sourcefile_string, nd_line(n),
#define ERROR_ARGS ERROR_ARGS_AT(node)
#define EXPECT_NODE(prefix, node, ndtype) \
do { \
NODE *error_node = (node); \
enum node_type error_type = nd_type(error_node); \
if (error_type != (ndtype)) { \
rb_compile_bug_str(ERROR_ARGS_AT(error_node) \
prefix ": " #ndtype " is expected, but %s", \
ruby_node_name(error_type)); \
} \
} while (0)
#define EXPECT_NODE_NONULL(prefix, parent, ndtype) \
do { \
rb_compile_bug_str(ERROR_ARGS_AT(parent) \
prefix ": must be " #ndtype ", but 0"); \
} while (0)
#define UNKNOWN_NODE(prefix, node) \
do { \
NODE *error_node = (node); \
rb_compile_bug_str(ERROR_ARGS_AT(error_node) prefix ": unknown node (%s)", \
ruby_node_name(nd_type(error_node))); \
} while (0)
#define COMPILE_OK 1
#define COMPILE_NG 0
/* leave name uninitialized so that compiler warn if INIT_ANCHOR is
* missing */
#define DECL_ANCHOR(name) \
LINK_ANCHOR *name, name##_body__ = {{0,},}
#define INIT_ANCHOR(name) \
(name##_body__.last = &name##_body__.anchor, name = &name##_body__)
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static inline VALUE
freeze_hide_obj(VALUE obj)
{
OBJ_FREEZE(obj);
RBASIC_CLEAR_CLASS(obj);
return obj;
}
#include "optinsn.inc"
#if OPT_INSTRUCTIONS_UNIFICATION
#include "optunifs.inc"
#endif
/* for debug */
#if CPDEBUG < 0
#define ISEQ_ARG iseq,
#define ISEQ_ARG_DECLARE rb_iseq_t *iseq,
#else
#define ISEQ_ARG
#define ISEQ_ARG_DECLARE
#endif
#if CPDEBUG
#define gl_node_level ISEQ_COMPILE_DATA(iseq)->node_level
#endif
static void dump_disasm_list(LINK_ELEMENT *elem);
static int insn_data_length(INSN *iobj);
static int calc_sp_depth(int depth, INSN *iobj);
static INSN *new_insn_body(rb_iseq_t *iseq, int line_no, enum ruby_vminsn_type insn_id, int argc, ...);
static LABEL *new_label_body(rb_iseq_t *iseq, long line);
static ADJUST *new_adjust_body(rb_iseq_t *iseq, LABEL *label, int line);
static int iseq_compile_each(rb_iseq_t *iseq, LINK_ANCHOR *anchor, NODE * n, int);
static int iseq_setup(rb_iseq_t *iseq, LINK_ANCHOR *anchor);
static int iseq_optimize(rb_iseq_t *iseq, LINK_ANCHOR *anchor);
static int iseq_insns_unification(rb_iseq_t *iseq, LINK_ANCHOR *anchor);
static int iseq_set_local_table(rb_iseq_t *iseq, const ID *tbl);
static int iseq_set_exception_local_table(rb_iseq_t *iseq);
static int iseq_set_arguments(rb_iseq_t *iseq, LINK_ANCHOR *anchor, NODE * node);
static int iseq_set_sequence_stackcaching(rb_iseq_t *iseq, LINK_ANCHOR *anchor);
static int iseq_set_sequence(rb_iseq_t *iseq, LINK_ANCHOR *anchor);
static int iseq_set_exception_table(rb_iseq_t *iseq);
static int iseq_set_optargs_table(rb_iseq_t *iseq);
/*
* To make Array to LinkedList, use link_anchor
*/
static void
verify_list(ISEQ_ARG_DECLARE const char *info, LINK_ANCHOR *anchor)
{
#if CPDEBUG
int flag = 0;
LINK_ELEMENT *list, *plist;
if (!compile_debug) return;
list = anchor->anchor.next;
plist = &anchor->anchor;
while (list) {
if (plist != list->prev) {
flag += 1;
}
plist = list;
list = list->next;
}
if (anchor->last != plist && anchor->last != 0) {
flag |= 0x70000;
}
if (flag != 0) {
rb_bug("list verify error: %08x (%s)", flag, info);
}
#endif
}
#if CPDEBUG < 0
#define verify_list(info, anchor) verify_list(iseq, (info), (anchor))
#endif
/*
* elem1, elem2 => elem1, elem2, elem
*/
static void
ADD_ELEM(ISEQ_ARG_DECLARE LINK_ANCHOR *anchor, LINK_ELEMENT *elem)
{
elem->prev = anchor->last;
anchor->last->next = elem;
anchor->last = elem;
verify_list("add", anchor);
}
/*
* elem1, before, elem2 => elem1, before, elem, elem2
*/
static void
APPEND_ELEM(ISEQ_ARG_DECLARE LINK_ANCHOR *anchor, LINK_ELEMENT *before, LINK_ELEMENT *elem)
{
elem->prev = before;
elem->next = before->next;
elem->next->prev = elem;
before->next = elem;
if (before == anchor->last) anchor->last = elem;
verify_list("add", anchor);
}
#if CPDEBUG < 0
#define ADD_ELEM(anchor, elem) ADD_ELEM(iseq, (anchor), (elem))
#define APPEND_ELEM(anchor, before, elem) APPEND_ELEM(iseq, (anchor), (before), (elem))
#endif
static int
iseq_add_mark_object(const rb_iseq_t *iseq, VALUE v)
{
if (!SPECIAL_CONST_P(v)) {
rb_iseq_add_mark_object(iseq, v);
}
return COMPILE_OK;
}
#define ruby_sourcefile_string (iseq->body->location.path)
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#define ruby_sourcefile RSTRING_PTR(iseq->body->location.path)
static int
iseq_add_mark_object_compile_time(const rb_iseq_t *iseq, VALUE v)
{
if (!SPECIAL_CONST_P(v)) {
rb_ary_push(ISEQ_COMPILE_DATA(iseq)->mark_ary, v);
}
return COMPILE_OK;
}
static int
validate_label(st_data_t name, st_data_t label, st_data_t arg)
{
rb_iseq_t *iseq = (rb_iseq_t *)arg;
LABEL *lobj = (LABEL *)label;
if (!lobj->link.next) {
do {
COMPILE_ERROR(ruby_sourcefile_string, lobj->position,
"%"PRIsVALUE": undefined label",
rb_id2str((ID)name));
} while (0);
}
return ST_CONTINUE;
}
static void
validate_labels(rb_iseq_t *iseq, st_table *labels_table)
{
st_foreach(labels_table, validate_label, (st_data_t)iseq);
st_free_table(labels_table);
if (!NIL_P(ISEQ_COMPILE_DATA(iseq)->err_info)) {
rb_exc_raise(ISEQ_COMPILE_DATA(iseq)->err_info);
}
}
VALUE
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rb_iseq_compile_node(rb_iseq_t *iseq, NODE *node)
{
DECL_ANCHOR(ret);
INIT_ANCHOR(ret);
if (node == 0) {
COMPILE(ret, "nil", node);
iseq_set_local_table(iseq, 0);
}
else if (nd_type(node) == NODE_SCOPE) {
/* iseq type of top, method, class, block */
iseq_set_local_table(iseq, node->nd_tbl);
iseq_set_arguments(iseq, ret, node->nd_args);
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switch (iseq->body->type) {
case ISEQ_TYPE_BLOCK:
{
LABEL *start = ISEQ_COMPILE_DATA(iseq)->start_label = NEW_LABEL(0);
LABEL *end = ISEQ_COMPILE_DATA(iseq)->end_label = NEW_LABEL(0);
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ADD_TRACE(ret, FIX2INT(iseq->body->location.first_lineno), RUBY_EVENT_B_CALL);
ADD_LABEL(ret, start);
COMPILE(ret, "block body", node->nd_body);
ADD_LABEL(ret, end);
ADD_TRACE(ret, nd_line(node), RUBY_EVENT_B_RETURN);
/* wide range catch handler must put at last */
ADD_CATCH_ENTRY(CATCH_TYPE_REDO, start, end, 0, start);
ADD_CATCH_ENTRY(CATCH_TYPE_NEXT, start, end, 0, end);
break;
}
case ISEQ_TYPE_CLASS:
{
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ADD_TRACE(ret, FIX2INT(iseq->body->location.first_lineno), RUBY_EVENT_CLASS);
COMPILE(ret, "scoped node", node->nd_body);
ADD_TRACE(ret, nd_line(node), RUBY_EVENT_END);
break;
}
case ISEQ_TYPE_METHOD:
{
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ADD_TRACE(ret, FIX2INT(iseq->body->location.first_lineno), RUBY_EVENT_CALL);
COMPILE(ret, "scoped node", node->nd_body);
ADD_TRACE(ret, nd_line(node), RUBY_EVENT_RETURN);
break;
}
default: {
COMPILE(ret, "scoped node", node->nd_body);
break;
}
}
}
else if (RB_TYPE_P((VALUE)node, T_IMEMO)) {
const struct vm_ifunc *ifunc = (struct vm_ifunc *)node;
/* user callback */
(*ifunc->func)(iseq, ret, ifunc->data);
}
else {
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switch (iseq->body->type) {
case ISEQ_TYPE_METHOD:
case ISEQ_TYPE_CLASS:
case ISEQ_TYPE_BLOCK:
case ISEQ_TYPE_EVAL:
case ISEQ_TYPE_MAIN:
case ISEQ_TYPE_TOP:
COMPILE_ERROR(ERROR_ARGS "compile/should not be reached: %s:%d",
__FILE__, __LINE__);
return COMPILE_NG;
case ISEQ_TYPE_RESCUE:
iseq_set_exception_local_table(iseq);
COMPILE(ret, "rescue", node);
break;
case ISEQ_TYPE_ENSURE:
iseq_set_exception_local_table(iseq);
COMPILE_POPED(ret, "ensure", node);
break;
case ISEQ_TYPE_DEFINED_GUARD:
iseq_set_exception_local_table(iseq);
COMPILE(ret, "defined guard", node);
break;
default:
rb_compile_bug_str(ERROR_ARGS "unknown scope");
}
}
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if (iseq->body->type == ISEQ_TYPE_RESCUE || iseq->body->type == ISEQ_TYPE_ENSURE) {
ADD_INSN2(ret, 0, getlocal, INT2FIX(2), INT2FIX(0));
ADD_INSN1(ret, 0, throw, INT2FIX(0) /* continue throw */ );
}
else {
ADD_INSN(ret, ISEQ_COMPILE_DATA(iseq)->last_line, leave);
}
#if SUPPORT_JOKE
if (ISEQ_COMPILE_DATA(iseq)->labels_table) {
st_table *labels_table = ISEQ_COMPILE_DATA(iseq)->labels_table;
ISEQ_COMPILE_DATA(iseq)->labels_table = 0;
validate_labels(iseq, labels_table);
}
#endif
return iseq_setup(iseq, ret);
}
int
rb_iseq_translate_threaded_code(rb_iseq_t *iseq)
{
#if OPT_DIRECT_THREADED_CODE || OPT_CALL_THREADED_CODE
const void * const *table = rb_vm_get_insns_address_table();
unsigned int i;
VALUE *encoded = (VALUE *)iseq->body->iseq_encoded;
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for (i = 0; i < iseq->body->iseq_size; /* */ ) {
int insn = (int)iseq->body->iseq_encoded[i];
int len = insn_len(insn);
encoded[i] = (VALUE)table[insn];
i += len;
}
#endif
return COMPILE_OK;
}
#if OPT_DIRECT_THREADED_CODE || OPT_CALL_THREADED_CODE
static int
rb_vm_insn_addr2insn(const void *addr) /* cold path */
{
int insn;
const void * const *table = rb_vm_get_insns_address_table();
for (insn = 0; insn < VM_INSTRUCTION_SIZE; insn++) {
if (table[insn] == addr) {
return insn;
}
}
rb_bug("rb_vm_insn_addr2insn: invalid insn address: %p", addr);
}
#endif
VALUE *
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rb_iseq_original_iseq(const rb_iseq_t *iseq) /* cold path */
{
VALUE *original_code;
if (ISEQ_ORIGINAL_ISEQ(iseq)) return ISEQ_ORIGINAL_ISEQ(iseq);
original_code = ISEQ_ORIGINAL_ISEQ_ALLOC(iseq, iseq->body->iseq_size);
MEMCPY(original_code, iseq->body->iseq_encoded, VALUE, iseq->body->iseq_size);
#if OPT_DIRECT_THREADED_CODE || OPT_CALL_THREADED_CODE
{
unsigned int i;
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for (i = 0; i < iseq->body->iseq_size; /* */ ) {
const void *addr = (const void *)original_code[i];
const int insn = rb_vm_insn_addr2insn(addr);
original_code[i] = insn;
i += insn_len(insn);
}
}
#endif
return original_code;
}
/*********************************************/
/* definition of data structure for compiler */
/*********************************************/
/*
* On 32-bit SPARC, GCC by default generates SPARC V7 code that may require
* 8-byte word alignment. On the other hand, Oracle Solaris Studio seems to
* generate SPARCV8PLUS code with unaligned memory access instructions.
* That is why the STRICT_ALIGNMENT is defined only with GCC.
*/
#if defined(__sparc) && SIZEOF_VOIDP == 4 && defined(__GNUC__)
#define STRICT_ALIGNMENT
#endif
#ifdef STRICT_ALIGNMENT
#if defined(HAVE_TRUE_LONG_LONG) && SIZEOF_LONG_LONG > SIZEOF_VALUE
#define ALIGNMENT_SIZE SIZEOF_LONG_LONG
#else
#define ALIGNMENT_SIZE SIZEOF_VALUE
#endif
#define PADDING_SIZE_MAX ((size_t)((ALIGNMENT_SIZE) - 1))
#define ALIGNMENT_SIZE_MASK PADDING_SIZE_MAX
/* Note: ALIGNMENT_SIZE == (2 ** N) is expected. */
#else
#define PADDING_SIZE_MAX 0
#endif /* STRICT_ALIGNMENT */
#ifdef STRICT_ALIGNMENT
/* calculate padding size for aligned memory access */
static size_t
calc_padding(void *ptr, size_t size)
{
size_t mis;
size_t padding = 0;
mis = (size_t)ptr & ALIGNMENT_SIZE_MASK;
if (mis > 0) {
padding = ALIGNMENT_SIZE - mis;
}
/*
* On 32-bit sparc or equivalents, when a single VALUE is requested
* and padding == sizeof(VALUE), it is clear that no padding is needed.
*/
#if ALIGNMENT_SIZE > SIZEOF_VALUE
if (size == sizeof(VALUE) && padding == sizeof(VALUE)) {
padding = 0;
}
#endif
return padding;
}
#endif /* STRICT_ALIGNMENT */
static void *
compile_data_alloc(rb_iseq_t *iseq, size_t size)
{
void *ptr = 0;
struct iseq_compile_data_storage *storage =
ISEQ_COMPILE_DATA(iseq)->storage_current;
#ifdef STRICT_ALIGNMENT
size_t padding = calc_padding((void *)&storage->buff[storage->pos], size);
#else
const size_t padding = 0; /* expected to be optimized by compiler */
#endif /* STRICT_ALIGNMENT */
if (size >= INT_MAX - padding) rb_memerror();
if (storage->pos + size + padding > storage->size) {
unsigned int alloc_size = storage->size;
while (alloc_size < size + PADDING_SIZE_MAX) {
if (alloc_size >= INT_MAX / 2) rb_memerror();
alloc_size *= 2;
}
storage->next = (void *)ALLOC_N(char, alloc_size +
SIZEOF_ISEQ_COMPILE_DATA_STORAGE);
storage = ISEQ_COMPILE_DATA(iseq)->storage_current = storage->next;
storage->next = 0;
storage->pos = 0;
storage->size = alloc_size;
#ifdef STRICT_ALIGNMENT
padding = calc_padding((void *)&storage->buff[storage->pos], size);
#endif /* STRICT_ALIGNMENT */
}
#ifdef STRICT_ALIGNMENT
storage->pos += (int)padding;
#endif /* STRICT_ALIGNMENT */
ptr = (void *)&storage->buff[storage->pos];
storage->pos += (int)size;
return ptr;
}
static INSN *
compile_data_alloc_insn(rb_iseq_t *iseq)
{
return (INSN *)compile_data_alloc(iseq, sizeof(INSN));
}
static LABEL *
compile_data_alloc_label(rb_iseq_t *iseq)
{
return (LABEL *)compile_data_alloc(iseq, sizeof(LABEL));
}
static ADJUST *
compile_data_alloc_adjust(rb_iseq_t *iseq)
{
return (ADJUST *)compile_data_alloc(iseq, sizeof(ADJUST));
}
/*
* elem1, elemX => elem1, elem2, elemX
*/
static void
INSERT_ELEM_NEXT(LINK_ELEMENT *elem1, LINK_ELEMENT *elem2)
{
elem2->next = elem1->next;
elem2->prev = elem1;
elem1->next = elem2;
if (elem2->next) {
elem2->next->prev = elem2;
}
}
/*
* elem1, elemX => elemX, elem2, elem1
*/
static void
INSERT_ELEM_PREV(LINK_ELEMENT *elem1, LINK_ELEMENT *elem2)
{
elem2->prev = elem1->prev;
elem2->next = elem1;
elem1->prev = elem2;
if (elem2->prev) {
elem2->prev->next = elem2;
}
}
/*
* elemX, elem1, elemY => elemX, elem2, elemY
*/
static void
REPLACE_ELEM(LINK_ELEMENT *elem1, LINK_ELEMENT *elem2)
{
elem2->prev = elem1->prev;
elem2->next = elem1->next;
if (elem1->prev) {
elem1->prev->next = elem2;
}
if (elem1->next) {
elem1->next->prev = elem2;
}
}
static void
REMOVE_ELEM(LINK_ELEMENT *elem)
{
elem->prev->next = elem->next;
if (elem->next) {
elem->next->prev = elem->prev;
}
}
static LINK_ELEMENT *
FIRST_ELEMENT(LINK_ANCHOR *anchor)
{
return anchor->anchor.next;
}
static LINK_ELEMENT *
LAST_ELEMENT(LINK_ANCHOR *anchor)
{
return anchor->last;
}
static LINK_ELEMENT *
POP_ELEMENT(ISEQ_ARG_DECLARE LINK_ANCHOR *anchor)
{
LINK_ELEMENT *elem = anchor->last;
anchor->last = anchor->last->prev;
anchor->last->next = 0;
verify_list("pop", anchor);
return elem;
}
#if CPDEBUG < 0
#define POP_ELEMENT(anchor) POP_ELEMENT(iseq, (anchor))
#endif
static int
LIST_SIZE_ZERO(LINK_ANCHOR *anchor)
{
if (anchor->anchor.next == 0) {
return 1;
}
else {
return 0;
}
}
/*
* anc1: e1, e2, e3
* anc2: e4, e5
*#=>
* anc1: e1, e2, e3, e4, e5
* anc2: e4, e5 (broken)
*/
static void
APPEND_LIST(ISEQ_ARG_DECLARE LINK_ANCHOR *anc1, LINK_ANCHOR *anc2)
{
if (anc2->anchor.next) {
anc1->last->next = anc2->anchor.next;
anc2->anchor.next->prev = anc1->last;
anc1->last = anc2->last;
}
verify_list("append", anc1);
}
#if CPDEBUG < 0
#define APPEND_LIST(anc1, anc2) APPEND_LIST(iseq, (anc1), (anc2))
#endif
/*
* anc1: e1, e2, e3
* anc2: e4, e5
*#=>
* anc1: e4, e5, e1, e2, e3
* anc2: e4, e5 (broken)
*/
static void
INSERT_LIST(ISEQ_ARG_DECLARE LINK_ANCHOR *anc1, LINK_ANCHOR *anc2)
{
if (anc2->anchor.next) {
LINK_ELEMENT *first = anc1->anchor.next;
anc1->anchor.next = anc2->anchor.next;
anc1->anchor.next->prev = &anc1->anchor;
anc2->last->next = first;
if (first) {
first->prev = anc2->last;
}
else {
anc1->last = anc2->last;
}
}
verify_list("append", anc1);
}
#if CPDEBUG < 0
#define INSERT_LIST(anc1, anc2) INSERT_LIST(iseq, (anc1), (anc2))
#endif
#if CPDEBUG && 0
static void
debug_list(ISEQ_ARG_DECLARE LINK_ANCHOR *anchor)
{
LINK_ELEMENT *list = FIRST_ELEMENT(anchor);
printf("----\n");
printf("anch: %p, frst: %p, last: %p\n", &anchor->anchor,
anchor->anchor.next, anchor->last);
while (list) {
printf("curr: %p, next: %p, prev: %p, type: %d\n", list, list->next,
list->prev, FIX2INT(list->type));
list = list->next;
}
printf("----\n");
dump_disasm_list(anchor->anchor.next);
verify_list("debug list", anchor);
}
#if CPDEBUG < 0
#define debug_list(anc) debug_list(iseq, (anc))
#endif
#endif
static LABEL *
new_label_body(rb_iseq_t *iseq, long line)
{
LABEL *labelobj = compile_data_alloc_label(iseq);
labelobj->link.type = ISEQ_ELEMENT_LABEL;
labelobj->link.next = 0;
labelobj->label_no = ISEQ_COMPILE_DATA(iseq)->label_no++;
labelobj->sc_state = 0;
labelobj->sp = -1;
labelobj->refcnt = 0;
return labelobj;
}
static ADJUST *
new_adjust_body(rb_iseq_t *iseq, LABEL *label, int line)
{
ADJUST *adjust = compile_data_alloc_adjust(iseq);
adjust->link.type = ISEQ_ELEMENT_ADJUST;
adjust->link.next = 0;
adjust->label = label;
adjust->line_no = line;
if (label) LABEL_REF(label);
return adjust;
}
static INSN *
new_insn_core(rb_iseq_t *iseq, int line_no,
int insn_id, int argc, VALUE *argv)
{
INSN *iobj = compile_data_alloc_insn(iseq);
/* printf("insn_id: %d, line: %d\n", insn_id, line_no); */
iobj->link.type = ISEQ_ELEMENT_INSN;
iobj->link.next = 0;
iobj->insn_id = insn_id;
iobj->line_no = line_no;
iobj->operands = argv;
iobj->operand_size = argc;
iobj->sc_state = 0;
return iobj;
}
static INSN *
new_insn_body(rb_iseq_t *iseq, int line_no, enum ruby_vminsn_type insn_id, int argc, ...)
{
VALUE *operands = 0;
va_list argv;
if (argc > 0) {
int i;
va_init_list(argv, argc);
operands = (VALUE *)compile_data_alloc(iseq, sizeof(VALUE) * argc);
for (i = 0; i < argc; i++) {
VALUE v = va_arg(argv, VALUE);
operands[i] = v;
}
va_end(argv);
}
return new_insn_core(iseq, line_no, insn_id, argc, operands);
}
static struct rb_call_info *
new_callinfo(rb_iseq_t *iseq, ID mid, int argc, unsigned int flag, struct rb_call_info_kw_arg *kw_arg, int has_blockiseq)
{
size_t size = kw_arg != NULL ? sizeof(struct rb_call_info_with_kwarg) : sizeof(struct rb_call_info);
struct rb_call_info *ci = (struct rb_call_info *)compile_data_alloc(iseq, size);
struct rb_call_info_with_kwarg *ci_kw = (struct rb_call_info_with_kwarg *)ci;
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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ci->mid = mid;
ci->flag = flag;
ci->orig_argc = argc;
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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if (kw_arg) {
ci->flag |= VM_CALL_KWARG;
ci_kw->kw_arg = kw_arg;
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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ci->orig_argc += kw_arg->keyword_len;
iseq->body->ci_kw_size++;
}
else {
iseq->body->ci_size++;
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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}
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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if (!(ci->flag & (VM_CALL_ARGS_SPLAT | VM_CALL_ARGS_BLOCKARG)) &&
kw_arg == NULL && !has_blockiseq) {
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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ci->flag |= VM_CALL_ARGS_SIMPLE;
}
return ci;
}
static INSN *
new_insn_send(rb_iseq_t *iseq, int line_no, ID id, VALUE argc, const rb_iseq_t *blockiseq, VALUE flag, struct rb_call_info_kw_arg *keywords)
{
VALUE *operands = (VALUE *)compile_data_alloc(iseq, sizeof(VALUE) * 3);
operands[0] = (VALUE)new_callinfo(iseq, id, FIX2INT(argc), FIX2INT(flag), keywords, blockiseq != NULL);
operands[1] = Qfalse; /* cache */
operands[2] = (VALUE)blockiseq;
return new_insn_core(iseq, line_no, BIN(send), 3, operands);
}
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static rb_iseq_t *
new_child_iseq(rb_iseq_t *iseq, NODE *node,
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VALUE name, const rb_iseq_t *parent, enum iseq_type type, int line_no)
{
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rb_iseq_t *ret_iseq;
debugs("[new_child_iseq]> ---------------------------------------\n");
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ret_iseq = rb_iseq_new_with_opt(node, name,
iseq_path(iseq), iseq_absolute_path(iseq),
INT2FIX(line_no), parent, type, ISEQ_COMPILE_DATA(iseq)->option);
debugs("[new_child_iseq]< ---------------------------------------\n");
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iseq_add_mark_object(iseq, (VALUE)ret_iseq);
return ret_iseq;
}
static int
iseq_setup(rb_iseq_t *iseq, LINK_ANCHOR *anchor)
{
/* debugs("[compile step 2] (iseq_array_to_linkedlist)\n"); */
if (compile_debug > 5)
dump_disasm_list(FIRST_ELEMENT(anchor));
debugs("[compile step 3.1 (iseq_optimize)]\n");
iseq_optimize(iseq, anchor);
if (compile_debug > 5)
dump_disasm_list(FIRST_ELEMENT(anchor));
if (ISEQ_COMPILE_DATA(iseq)->option->instructions_unification) {
debugs("[compile step 3.2 (iseq_insns_unification)]\n");
iseq_insns_unification(iseq, anchor);
if (compile_debug > 5)
dump_disasm_list(FIRST_ELEMENT(anchor));
}
if (ISEQ_COMPILE_DATA(iseq)->option->stack_caching) {
debugs("[compile step 3.3 (iseq_set_sequence_stackcaching)]\n");
iseq_set_sequence_stackcaching(iseq, anchor);
if (compile_debug > 5)
dump_disasm_list(FIRST_ELEMENT(anchor));
}
debugs("[compile step 4.1 (iseq_set_sequence)]\n");
if (!iseq_set_sequence(iseq, anchor)) return COMPILE_NG;
if (compile_debug > 5)
dump_disasm_list(FIRST_ELEMENT(anchor));
debugs("[compile step 4.2 (iseq_set_exception_table)]\n");
if (!iseq_set_exception_table(iseq)) return COMPILE_NG;
debugs("[compile step 4.3 (set_optargs_table)] \n");
if (!iseq_set_optargs_table(iseq)) return COMPILE_NG;
debugs("[compile step 5 (iseq_translate_threaded_code)] \n");
if (!rb_iseq_translate_threaded_code(iseq)) return COMPILE_NG;
if (compile_debug > 1) {
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VALUE str = rb_iseq_disasm(iseq);
printf("%s\n", StringValueCStr(str));
}
debugs("[compile step: finish]\n");
return COMPILE_OK;
}
static int
iseq_set_exception_local_table(rb_iseq_t *iseq)
{
/* TODO: every id table is same -> share it.
* Current problem is iseq_free().
*/
ID id_dollar_bang;
ID *ids = (ID *)ALLOC_N(ID, 1);
CONST_ID(id_dollar_bang, "#$!");
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iseq->body->local_table_size = 1;
iseq->body->local_size = iseq->body->local_table_size + 1;
ids[0] = id_dollar_bang;
iseq->body->local_table = ids;
return COMPILE_OK;
}
static int
get_lvar_level(const rb_iseq_t *iseq)
{
int lev = 0;
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while (iseq != iseq->body->local_iseq) {
lev++;
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iseq = iseq->body->parent_iseq;
}
return lev;
}
static int
get_dyna_var_idx_at_raw(const rb_iseq_t *iseq, ID id)
{
unsigned int i;
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for (i = 0; i < iseq->body->local_table_size; i++) {
if (iseq->body->local_table[i] == id) {
return (int)i;
}
}
return -1;
}
static int
get_local_var_idx(const rb_iseq_t *iseq, ID id)
{
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int idx = get_dyna_var_idx_at_raw(iseq->body->local_iseq, id);
if (idx < 0) {
rb_bug("get_local_var_idx: %d", idx);
}
return idx;
}
static int
get_dyna_var_idx(const rb_iseq_t *iseq, ID id, int *level, int *ls)
{
int lv = 0, idx = -1;
while (iseq) {
idx = get_dyna_var_idx_at_raw(iseq, id);
if (idx >= 0) {
break;
}
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iseq = iseq->body->parent_iseq;
lv++;
}
if (idx < 0) {
rb_bug("get_dyna_var_idx: -1");
}
*level = lv;
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*ls = iseq->body->local_size;
return idx;
}
static void
iseq_calc_param_size(rb_iseq_t *iseq)
{
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if (iseq->body->param.flags.has_opt ||
iseq->body->param.flags.has_post ||
iseq->body->param.flags.has_rest ||
iseq->body->param.flags.has_block ||
iseq->body->param.flags.has_kw ||
iseq->body->param.flags.has_kwrest) {
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if (iseq->body->param.flags.has_block) {
iseq->body->param.size = iseq->body->param.block_start + 1;
}
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else if (iseq->body->param.flags.has_kwrest) {
iseq->body->param.size = iseq->body->param.keyword->rest_start + 1;
}
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else if (iseq->body->param.flags.has_kw) {
iseq->body->param.size = iseq->body->param.keyword->bits_start + 1;
}
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else if (iseq->body->param.flags.has_post) {
iseq->body->param.size = iseq->body->param.post_start + iseq->body->param.post_num;
}
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else if (iseq->body->param.flags.has_rest) {
iseq->body->param.size = iseq->body->param.rest_start + 1;
}
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else if (iseq->body->param.flags.has_opt) {
iseq->body->param.size = iseq->body->param.lead_num + iseq->body->param.opt_num;
}
else {
rb_bug("unreachable");
}
}
else {
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iseq->body->param.size = iseq->body->param.lead_num;
}
}
static void
iseq_set_arguments_keywords(rb_iseq_t *iseq, LINK_ANCHOR *optargs, const struct rb_args_info *args)
{
NODE *node = args->kw_args;
struct rb_iseq_param_keyword *keyword;
const VALUE default_values = rb_ary_tmp_new(1);
const VALUE complex_mark = rb_str_tmp_new(0);
int kw = 0, rkw = 0, di = 0, i;
iseq->body->param.flags.has_kw = TRUE;
iseq->body->param.keyword = keyword = ZALLOC_N(struct rb_iseq_param_keyword, 1);
keyword->bits_start = get_dyna_var_idx_at_raw(iseq, args->kw_rest_arg->nd_vid);
while (node) {
NODE *val_node = node->nd_body->nd_value;
VALUE dv;
if (val_node == (NODE *)-1) {
++rkw;
}
else {
switch (nd_type(val_node)) {
case NODE_LIT:
dv = val_node->nd_lit;
iseq_add_mark_object(iseq, dv);
break;
case NODE_NIL:
dv = Qnil;
break;
case NODE_TRUE:
dv = Qtrue;
break;
case NODE_FALSE:
dv = Qfalse;
break;
default:
COMPILE_POPED(optargs, "kwarg", node); /* nd_type(node) == NODE_KW_ARG */
dv = complex_mark;
}
keyword->num = ++di;
rb_ary_push(default_values, dv);
}
kw++;
node = node->nd_next;
}
keyword->num = kw;
if (args->kw_rest_arg->nd_cflag != 0) {
keyword->rest_start = get_dyna_var_idx_at_raw(iseq, args->kw_rest_arg->nd_cflag);
iseq->body->param.flags.has_kwrest = TRUE;
}
keyword->required_num = rkw;
keyword->table = &iseq->body->local_table[keyword->bits_start - keyword->num];
{
VALUE *dvs = ALLOC_N(VALUE, RARRAY_LEN(default_values));
for (i = 0; i < RARRAY_LEN(default_values); i++) {
VALUE dv = RARRAY_AREF(default_values, i);
if (dv == complex_mark) dv = Qundef;
dvs[i] = dv;
}
keyword->default_values = dvs;
}
}
static int
iseq_set_arguments(rb_iseq_t *iseq, LINK_ANCHOR *optargs, NODE *node_args)
{
debugs("iseq_set_arguments: %s\n", node_args ? "" : "0");
if (node_args) {
struct rb_args_info *args = node_args->nd_ainfo;
ID rest_id = 0;
int last_comma = 0;
ID block_id = 0;
EXPECT_NODE("iseq_set_arguments", node_args, NODE_ARGS);
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iseq->body->param.lead_num = (int)args->pre_args_num;
if (iseq->body->param.lead_num > 0) iseq->body->param.flags.has_lead = TRUE;
debugs(" - argc: %d\n", iseq->body->param.lead_num);
rest_id = args->rest_arg;
if (rest_id == 1) {
last_comma = 1;
rest_id = 0;
}
block_id = args->block_arg;
if (args->first_post_arg) {
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iseq->body->param.post_start = get_dyna_var_idx_at_raw(iseq, args->first_post_arg);
iseq->body->param.post_num = args->post_args_num;
iseq->body->param.flags.has_post = TRUE;
}
if (args->opt_args) {
NODE *node = args->opt_args;
LABEL *label;
VALUE labels = rb_ary_tmp_new(1);
VALUE *opt_table;
int i = 0, j;
while (node) {
label = NEW_LABEL(nd_line(node));
rb_ary_push(labels, (VALUE)label | 1);
ADD_LABEL(optargs, label);
COMPILE_POPED(optargs, "optarg", node->nd_body);
node = node->nd_next;
i += 1;
}
/* last label */
label = NEW_LABEL(nd_line(node_args));
rb_ary_push(labels, (VALUE)label | 1);
ADD_LABEL(optargs, label);
opt_table = ALLOC_N(VALUE, i+1);
MEMCPY(opt_table, RARRAY_CONST_PTR(labels), VALUE, i+1);
for (j = 0; j < i+1; j++) {
opt_table[j] &= ~1;
}
rb_ary_clear(labels);
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iseq->body->param.flags.has_opt = TRUE;
iseq->body->param.opt_num = i;
iseq->body->param.opt_table = opt_table;
}
if (args->kw_args) {
iseq_set_arguments_keywords(iseq, optargs, args);
}
else if (args->kw_rest_arg) {
struct rb_iseq_param_keyword *keyword = ZALLOC_N(struct rb_iseq_param_keyword, 1);
keyword->rest_start = get_dyna_var_idx_at_raw(iseq, args->kw_rest_arg->nd_vid);
iseq->body->param.keyword = keyword;
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iseq->body->param.flags.has_kwrest = TRUE;
}
if (args->pre_init) { /* m_init */
COMPILE_POPED(optargs, "init arguments (m)", args->pre_init);
}
if (args->post_init) { /* p_init */
COMPILE_POPED(optargs, "init arguments (p)", args->post_init);
}
if (rest_id) {
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iseq->body->param.rest_start = get_dyna_var_idx_at_raw(iseq, rest_id);
iseq->body->param.flags.has_rest = TRUE;
assert(iseq->body->param.rest_start != -1);
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if (iseq->body->param.post_start == 0) { /* TODO: why that? */
iseq->body->param.post_start = iseq->body->param.rest_start + 1;
}
}
if (block_id) {
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iseq->body->param.block_start = get_dyna_var_idx_at_raw(iseq, block_id);
iseq->body->param.flags.has_block = TRUE;
}
iseq_calc_param_size(iseq);
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if (iseq->body->type == ISEQ_TYPE_BLOCK) {
if (iseq->body->param.flags.has_opt == FALSE &&
iseq->body->param.flags.has_post == FALSE &&
iseq->body->param.flags.has_rest == FALSE &&
iseq->body->param.flags.has_kw == FALSE &&
iseq->body->param.flags.has_kwrest == FALSE) {
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
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if (iseq->body->param.lead_num == 1 && last_comma == 0) {
/* {|a|} */
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iseq->body->param.flags.ambiguous_param0 = TRUE;
}
}
}
}
return COMPILE_OK;
}
static int
iseq_set_local_table(rb_iseq_t *iseq, const ID *tbl)
{
int size;
if (tbl) {
size = (int)*tbl;
tbl++;
}
else {
size = 0;
}
if (size > 0) {
ID *ids = (ID *)ALLOC_N(ID, size);
MEMCPY(ids, tbl, ID, size);
iseq->body->local_table = ids;
}
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iseq->body->local_size = iseq->body->local_table_size = size;
iseq->body->local_size += 1;
/*
if (lfp == dfp ) { // top, class, method
dfp[-1]: svar
else { // block
dfp[-1]: cref
}
*/
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debugs("iseq_set_local_table: %d, %d\n", iseq->body->local_size, iseq->body->local_table_size);
return COMPILE_OK;
}
static int
cdhash_cmp(VALUE val, VALUE lit)
{
if (val == lit) return 0;
if (SPECIAL_CONST_P(lit)) {
return val != lit;
}
if (SPECIAL_CONST_P(val) || BUILTIN_TYPE(val) != BUILTIN_TYPE(lit)) {
return -1;
}
if (BUILTIN_TYPE(lit) == T_STRING) {
return rb_str_hash_cmp(lit, val);
}
return !rb_eql(lit, val);
}
static st_index_t
cdhash_hash(VALUE a)
{
if (SPECIAL_CONST_P(a)) return (st_index_t)a;
if (RB_TYPE_P(a, T_STRING)) return rb_str_hash(a);
{
VALUE hval = rb_hash(a);
return (st_index_t)FIX2LONG(hval);
}
}
static const struct st_hash_type cdhash_type = {
cdhash_cmp,
cdhash_hash,
};
struct cdhash_set_label_struct {
VALUE hash;
int pos;
int len;
};
static int
cdhash_set_label_i(VALUE key, VALUE val, void *ptr)
{
struct cdhash_set_label_struct *data = (struct cdhash_set_label_struct *)ptr;
LABEL *lobj = (LABEL *)(val & ~1);
rb_hash_aset(data->hash, key, INT2FIX(lobj->position - (data->pos+data->len)));
return ST_CONTINUE;
}
/**
ruby insn object list -> raw instruction sequence
*/
static int
iseq_set_sequence(rb_iseq_t *iseq, LINK_ANCHOR *anchor)
{
struct iseq_line_info_entry *line_info_table;
unsigned int last_line = 0;
LINK_ELEMENT *list;
VALUE *generated_iseq;
int insn_num, code_index, line_info_index, sp, stack_max = 0, line = 0;
/* fix label position */
list = FIRST_ELEMENT(anchor);
insn_num = code_index = 0;
while (list) {
switch (list->type) {
case ISEQ_ELEMENT_INSN:
{
INSN *iobj = (INSN *)list;
line = iobj->line_no;
code_index += insn_data_length(iobj);
insn_num++;
break;
}
case ISEQ_ELEMENT_LABEL:
{
LABEL *lobj = (LABEL *)list;
lobj->position = code_index;
lobj->set = TRUE;
break;
}
case ISEQ_ELEMENT_NONE:
{
/* ignore */
break;
}
case ISEQ_ELEMENT_ADJUST:
{
ADJUST *adjust = (ADJUST *)list;
if (adjust->line_no != -1) {
code_index += 2 /* insn + 1 operand */;
insn_num++;
}
break;
}
default:
dump_disasm_list(FIRST_ELEMENT(anchor));
dump_disasm_list(list);
COMPILE_ERROR(ruby_sourcefile_string, line, "error: set_sequence");
return COMPILE_NG;
}
list = list->next;
}
/* make instruction sequence */
generated_iseq = ALLOC_N(VALUE, code_index);
line_info_table = ALLOC_N(struct iseq_line_info_entry, insn_num);
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iseq->body->is_entries = ZALLOC_N(union iseq_inline_storage_entry, iseq->body->is_size);
iseq->body->ci_entries = (struct rb_call_info *)ruby_xmalloc(sizeof(struct rb_call_info) * iseq->body->ci_size +
sizeof(struct rb_call_info_with_kwarg) * iseq->body->ci_kw_size);
iseq->body->cc_entries = ZALLOC_N(struct rb_call_cache, iseq->body->ci_size + iseq->body->ci_kw_size);
ISEQ_COMPILE_DATA(iseq)->ci_index = ISEQ_COMPILE_DATA(iseq)->ci_kw_index = 0;
list = FIRST_ELEMENT(anchor);
line_info_index = code_index = sp = 0;
while (list) {
switch (list->type) {
case ISEQ_ELEMENT_INSN:
{
int j, len, insn;
const char *types;
VALUE *operands;
INSN *iobj = (INSN *)list;
/* update sp */
sp = calc_sp_depth(sp, iobj);
if (sp > stack_max) {
stack_max = sp;
}
/* fprintf(stderr, "insn: %-16s, sp: %d\n", insn_name(iobj->insn_id), sp); */
operands = iobj->operands;
insn = iobj->insn_id;
generated_iseq[code_index] = insn;
types = insn_op_types(insn);
len = insn_len(insn);
/* operand check */
if (iobj->operand_size != len - 1) {
/* printf("operand size miss! (%d, %d)\n", iobj->operand_size, len); */
dump_disasm_list(list);
xfree(generated_iseq);
xfree(line_info_table);
COMPILE_ERROR(ruby_sourcefile_string, iobj->line_no,
"operand size miss! (%d for %d)",
iobj->operand_size, len - 1);
return COMPILE_NG;
}
for (j = 0; types[j]; j++) {
char type = types[j];
/* printf("--> [%c - (%d-%d)]\n", type, k, j); */
switch (type) {
case TS_OFFSET:
{
/* label(destination position) */
LABEL *lobj = (LABEL *)operands[j];
if (!lobj->set) {
COMPILE_ERROR(ruby_sourcefile_string, iobj->line_no,
"unknown label");
return COMPILE_NG;
}
if (lobj->sp == -1) {
lobj->sp = sp;
}
generated_iseq[code_index + 1 + j] = lobj->position - (code_index + len);
break;
}
case TS_CDHASH:
{
VALUE map = operands[j];
struct cdhash_set_label_struct data;
data.hash = map;
data.pos = code_index;
data.len = len;
rb_hash_foreach(map, cdhash_set_label_i, (VALUE)&data);
rb_hash_rehash(map);
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freeze_hide_obj(map);
generated_iseq[code_index + 1 + j] = map;
break;
}
case TS_LINDEX:
case TS_NUM: /* ulong */
generated_iseq[code_index + 1 + j] = FIX2INT(operands[j]);
break;
case TS_ISEQ: /* iseq */
{
VALUE v = operands[j];
generated_iseq[code_index + 1 + j] = v;
break;
}
case TS_VALUE: /* VALUE */
{
VALUE v = operands[j];
generated_iseq[code_index + 1 + j] = v;
/* to mark ruby object */
iseq_add_mark_object(iseq, v);
break;
}
case TS_IC: /* inline cache */
{
unsigned int ic_index = FIX2UINT(operands[j]);
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IC ic = (IC)&iseq->body->is_entries[ic_index];
if (UNLIKELY(ic_index >= iseq->body->is_size)) {
rb_bug("iseq_set_sequence: ic_index overflow: index: %d, size: %d", ic_index, iseq->body->is_size);
}
generated_iseq[code_index + 1 + j] = (VALUE)ic;
break;
}
case TS_CALLINFO: /* call info */
{
struct rb_call_info *base_ci = (struct rb_call_info *)operands[j];
struct rb_call_info *ci;
if (base_ci->flag & VM_CALL_KWARG) {
struct rb_call_info_with_kwarg *ci_kw_entries = (struct rb_call_info_with_kwarg *)&iseq->body->ci_entries[iseq->body->ci_size];
struct rb_call_info_with_kwarg *ci_kw = &ci_kw_entries[ISEQ_COMPILE_DATA(iseq)->ci_kw_index++];
*ci_kw = *((struct rb_call_info_with_kwarg *)base_ci);
ci = (struct rb_call_info *)ci_kw;
assert(ISEQ_COMPILE_DATA(iseq)->ci_kw_index <= iseq->body->ci_kw_size);
}
else {
ci = &iseq->body->ci_entries[ISEQ_COMPILE_DATA(iseq)->ci_index++];
*ci = *base_ci;
assert(ISEQ_COMPILE_DATA(iseq)->ci_index <= iseq->body->ci_size);
}
generated_iseq[code_index + 1 + j] = (VALUE)ci;
break;
}
case TS_CALLCACHE:
{
struct rb_call_cache *cc = &iseq->body->cc_entries[ISEQ_COMPILE_DATA(iseq)->ci_index + ISEQ_COMPILE_DATA(iseq)->ci_kw_index - 1];
generated_iseq[code_index + 1 + j] = (VALUE)cc;
break;
}
case TS_ID: /* ID */
generated_iseq[code_index + 1 + j] = SYM2ID(operands[j]);
break;
case TS_GENTRY:
{
struct rb_global_entry *entry =
(struct rb_global_entry *)(operands[j] & (~1));
generated_iseq[code_index + 1 + j] = (VALUE)entry;
}
break;
case TS_FUNCPTR:
generated_iseq[code_index + 1 + j] = operands[j];
break;
default:
xfree(generated_iseq);
xfree(line_info_table);
COMPILE_ERROR(ruby_sourcefile_string, iobj->line_no,
"unknown operand type: %c", type);
return COMPILE_NG;
}
}
if (last_line != iobj->line_no) {
line_info_table[line_info_index].line_no = last_line = iobj->line_no;
line_info_table[line_info_index].position = code_index;
line_info_index++;
}
code_index += len;
break;
}
case ISEQ_ELEMENT_LABEL:
{
LABEL *lobj = (LABEL *)list;
if (lobj->sp == -1) {
lobj->sp = sp;
}
else {
sp = lobj->sp;
}
break;
}
case ISEQ_ELEMENT_ADJUST:
{
ADJUST *adjust = (ADJUST *)list;
int orig_sp = sp;
if (adjust->label) {
sp = adjust->label->sp;
}
else {
sp = 0;
}
if (adjust->line_no != -1) {
if (orig_sp - sp > 0) {
if (last_line != (unsigned int)adjust->line_no) {
line_info_table[line_info_index].line_no = last_line = adjust->line_no;
line_info_table[line_info_index].position = code_index;
line_info_index++;
}
generated_iseq[code_index++] = BIN(adjuststack);
generated_iseq[code_index++] = orig_sp - sp;
}
else if (orig_sp - sp == 0) {
/* jump to next insn */
if (last_line != (unsigned int)adjust->line_no) {
line_info_table[line_info_index].line_no = last_line = adjust->line_no;
line_info_table[line_info_index].position = code_index;
line_info_index++;
}
generated_iseq[code_index++] = BIN(nop);
generated_iseq[code_index++] = BIN(nop);
}
else {
rb_compile_bug_str(ruby_sourcefile_string, adjust->line_no,
"iseq_set_sequence: adjust bug %d < %d", orig_sp, sp);
}
}
break;
}
default:
/* ignore */
break;
}
list = list->next;
}
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iseq->body->iseq_encoded = (void *)generated_iseq;
iseq->body->iseq_size = code_index;
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iseq->body->stack_max = stack_max;
REALLOC_N(line_info_table, struct iseq_line_info_entry, line_info_index);
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iseq->body->line_info_table = line_info_table;
iseq->body->line_info_size = line_info_index;
return COMPILE_OK;
}
static int
label_get_position(LABEL *lobj)
{
return lobj->position;
}
static int
label_get_sp(LABEL *lobj)
{
return lobj->sp;
}
static int
iseq_set_exception_table(rb_iseq_t *iseq)
{
const VALUE *tptr, *ptr;
unsigned int tlen, i;
struct iseq_catch_table_entry *entry;
tlen = (int)RARRAY_LEN(ISEQ_COMPILE_DATA(iseq)->catch_table_ary);
tptr = RARRAY_CONST_PTR(ISEQ_COMPILE_DATA(iseq)->catch_table_ary);
if (tlen > 0) {
struct iseq_catch_table *table = xmalloc(iseq_catch_table_bytes(tlen));
table->size = tlen;
for (i = 0; i < table->size; i++) {
ptr = RARRAY_CONST_PTR(tptr[i]);
entry = &table->entries[i];
entry->type = (enum catch_type)(ptr[0] & 0xffff);
entry->start = label_get_position((LABEL *)(ptr[1] & ~1));
entry->end = label_get_position((LABEL *)(ptr[2] & ~1));
entry->iseq = (rb_iseq_t *)ptr[3];
/* register iseq as mark object */
if (entry->iseq != 0) {
iseq_add_mark_object(iseq, (VALUE)entry->iseq);
}
/* stack depth */
if (ptr[4]) {
LABEL *lobj = (LABEL *)(ptr[4] & ~1);
entry->cont = label_get_position(lobj);
entry->sp = label_get_sp(lobj);
/* TODO: Dirty Hack! Fix me */
if (entry->type == CATCH_TYPE_RESCUE ||
entry->type == CATCH_TYPE_BREAK ||
entry->type == CATCH_TYPE_NEXT) {
entry->sp--;
}
}
else {
entry->cont = 0;
}
}
iseq->body->catch_table = table;
RB_OBJ_WRITE(iseq, &ISEQ_COMPILE_DATA(iseq)->catch_table_ary, 0); /* free */
}
else {
iseq->body->catch_table = NULL;
}
return COMPILE_OK;
}
/*
* set optional argument table
* def foo(a, b=expr1, c=expr2)
* =>
* b:
* expr1
* c:
* expr2
*/
static int
iseq_set_optargs_table(rb_iseq_t *iseq)
{
int i;
VALUE *opt_table = (VALUE *)iseq->body->param.opt_table;
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if (iseq->body->param.flags.has_opt) {
for (i = 0; i < iseq->body->param.opt_num + 1; i++) {
opt_table[i] = label_get_position((LABEL *)opt_table[i]);
}
}
return COMPILE_OK;
}
static LINK_ELEMENT *
get_destination_insn(INSN *iobj)
{
LABEL *lobj = (LABEL *)OPERAND_AT(iobj, 0);
LINK_ELEMENT *list;
list = lobj->link.next;
while (list) {
if (list->type == ISEQ_ELEMENT_INSN || list->type == ISEQ_ELEMENT_ADJUST) {
break;
}
list = list->next;
}
return list;
}
static LINK_ELEMENT *
get_next_insn(INSN *iobj)
{
LINK_ELEMENT *list = iobj->link.next;
while (list) {
if (list->type == ISEQ_ELEMENT_INSN || list->type == ISEQ_ELEMENT_ADJUST) {
return list;
}
list = list->next;
}
return 0;
}
static LINK_ELEMENT *
get_prev_insn(INSN *iobj)
{
LINK_ELEMENT *list = iobj->link.prev;
while (list) {
if (list->type == ISEQ_ELEMENT_INSN || list->type == ISEQ_ELEMENT_ADJUST) {
return list;
}
list = list->prev;
}
return 0;
}
static void
unref_destination(INSN *iobj, int pos)
{
LABEL *lobj = (LABEL *)OPERAND_AT(iobj, pos);
--lobj->refcnt;
if (!lobj->refcnt) REMOVE_ELEM(&lobj->link);
}
static void
replace_destination(INSN *dobj, INSN *nobj)
{
VALUE n = OPERAND_AT(nobj, 0);
LABEL *dl = (LABEL *)OPERAND_AT(dobj, 0);
LABEL *nl = (LABEL *)n;
--dl->refcnt;
++nl->refcnt;
OPERAND_AT(dobj, 0) = n;
if (!dl->refcnt) REMOVE_ELEM(&dl->link);
}
static int
remove_unreachable_chunk(rb_iseq_t *iseq, LINK_ELEMENT *i)
{
int removed = 0;
while (i) {
if (i->type == ISEQ_ELEMENT_INSN) {
struct rb_iseq_constant_body *body = iseq->body;
VALUE insn = INSN_OF(i);
int pos, len = insn_len(insn);
for (pos = 0; pos < len; ++pos) {
switch (insn_op_types(insn)[pos]) {
case TS_OFFSET:
unref_destination((INSN *)i, pos);
break;
case TS_CALLINFO:
if (((struct rb_call_info *)OPERAND_AT(i, pos))->flag & VM_CALL_KWARG)
--(body->ci_kw_size);
else
--(body->ci_size);
break;
}
}
}
else if (i->type == ISEQ_ELEMENT_LABEL) {
if (((LABEL *)i)->refcnt > 0) break;
}
else break;
REMOVE_ELEM(i);
removed = 1;
i = i->next;
}
return removed;
}
static int
iseq_peephole_optimize(rb_iseq_t *iseq, LINK_ELEMENT *list, const int do_tailcallopt)
{
INSN *iobj = (INSN *)list;
again:
if (iobj->insn_id == BIN(jump)) {
INSN *niobj, *diobj, *piobj;
/*
* useless jump elimination:
* jump LABEL1
* ...
* LABEL1:
* jump LABEL2
*
* => in this case, first jump instruction should jump to
* LABEL2 directly
*/
diobj = (INSN *)get_destination_insn(iobj);
niobj = (INSN *)get_next_insn(iobj);
if (diobj == niobj) {
/*
* jump LABEL
* LABEL:
* =>
* LABEL:
*/
unref_destination(iobj, 0);
REMOVE_ELEM(&iobj->link);
}
else if (iobj != diobj && diobj->insn_id == BIN(jump) &&
OPERAND_AT(iobj, 0) != OPERAND_AT(diobj, 0)) {
replace_destination(iobj, diobj);
remove_unreachable_chunk(iseq, iobj->link.next);
goto again;
}
else if (diobj->insn_id == BIN(leave)) {
/*
* jump LABEL
* ...
* LABEL:
* leave
* =>
* leave
* ...
* LABEL:
* leave
*/
INSN *eiobj = new_insn_core(iseq, iobj->line_no, BIN(leave),
diobj->operand_size, diobj->operands);
INSN *popiobj = new_insn_core(iseq, iobj->line_no,
BIN(pop), 0, 0);
/* replace */
unref_destination(iobj, 0);
REPLACE_ELEM((LINK_ELEMENT *)iobj, (LINK_ELEMENT *)eiobj);
INSERT_ELEM_NEXT((LINK_ELEMENT *)eiobj, (LINK_ELEMENT *)popiobj);
iobj = eiobj;
goto again;
}
/*
* useless jump elimination (if/unless destination):
* if L1
* jump L2
* L1:
* ...
* L2:
*
* ==>
* unless L2
* L1:
* ...
* L2:
*/
else if ((piobj = (INSN *)get_prev_insn(iobj)) != 0 &&
(piobj->insn_id == BIN(branchif) ||
piobj->insn_id == BIN(branchunless))) {
if (niobj == (INSN *)get_destination_insn(piobj)) {
piobj->insn_id = (piobj->insn_id == BIN(branchif))
? BIN(branchunless) : BIN(branchif);
replace_destination(piobj, iobj);
REMOVE_ELEM(&iobj->link);
}
}
else if (remove_unreachable_chunk(iseq, iobj->link.next)) {
goto again;
}
}
if (iobj->insn_id == BIN(leave)) {
remove_unreachable_chunk(iseq, iobj->link.next);
}
if (iobj->insn_id == BIN(branchif) ||
iobj->insn_id == BIN(branchnil) ||
iobj->insn_id == BIN(branchunless)) {
/*
* if L1
* ...
* L1:
* jump L2
* =>
* if L2
*/
INSN *nobj = (INSN *)get_destination_insn(iobj);
INSN *pobj = (INSN *)iobj->link.prev;
int prev_dup = 0;
if (pobj) {
if (pobj->link.type != ISEQ_ELEMENT_INSN)
pobj = 0;
else if (pobj->insn_id == BIN(dup))
prev_dup = 1;
}
for (;;) {
if (nobj->insn_id == BIN(jump)) {
replace_destination(iobj, nobj);
}
else if (prev_dup && nobj->insn_id == BIN(dup) &&
!!(nobj = (INSN *)nobj->link.next) &&
/* basic blocks, with no labels in the middle */
nobj->insn_id == iobj->insn_id) {
/*
* dup
* if L1
* ...
* L1:
* dup
* if L2
* =>
* dup
* if L2
* ...
* L1:
* dup
* if L2
*/
replace_destination(iobj, nobj);
}
else if (pobj) {
/*
* putnil
* if L1
* =>
* # nothing
*
* putobject true
* if L1
* =>
* jump L1
*
* putstring ".."
* if L1
* =>
* jump L1
*
* putstring ".."
* dup
* if L1
* =>
* putstring ".."
* jump L1
*
*/
int cond;
if (prev_dup && pobj->link.prev->type == ISEQ_ELEMENT_INSN) {
pobj = (INSN *)pobj->link.prev;
}
if (pobj->insn_id == BIN(putobject)) {
cond = (iobj->insn_id == BIN(branchif) ?
OPERAND_AT(pobj, 0) != Qfalse :
iobj->insn_id == BIN(branchunless) ?
OPERAND_AT(pobj, 0) == Qfalse :
FALSE);
}
else if (pobj->insn_id == BIN(putstring)) {
cond = iobj->insn_id == BIN(branchif);
}
else if (pobj->insn_id == BIN(putnil)) {
cond = iobj->insn_id != BIN(branchif);
}
else break;
REMOVE_ELEM(iobj->link.prev);
if (cond) {
iobj->insn_id = BIN(jump);
goto again;
}
else {
unref_destination(iobj, 0);
REMOVE_ELEM(&iobj->link);
}
break;
}
else break;
nobj = (INSN *)get_destination_insn(nobj);
}
}
if (iobj->insn_id == BIN(pop)) {
/*
* putself / putnil / putobject obj / putstring "..."
* pop
* =>
* # do nothing
*/
LINK_ELEMENT *prev = iobj->link.prev;
if (prev->type == ISEQ_ELEMENT_INSN) {
enum ruby_vminsn_type previ = ((INSN *)prev)->insn_id;
if (previ == BIN(putobject) || previ == BIN(putnil) ||
previ == BIN(putself) || previ == BIN(putstring)) {
/* just push operand or static value and pop soon, no
* side effects */
REMOVE_ELEM(prev);
REMOVE_ELEM(&iobj->link);
}
}
}
if (do_tailcallopt &&
(iobj->insn_id == BIN(send) ||
iobj->insn_id == BIN(opt_aref_with) ||
iobj->insn_id == BIN(opt_aset_with) ||
iobj->insn_id == BIN(invokesuper))) {
/*
* send ...
* leave
* =>
* send ..., ... | VM_CALL_TAILCALL, ...
* leave # unreachable
*/
INSN *piobj = NULL;
if (iobj->link.next) {
LINK_ELEMENT *next = iobj->link.next;
do {
if (next->type != ISEQ_ELEMENT_INSN) {
next = next->next;
continue;
}
switch (INSN_OF(next)) {
case BIN(nop):
/*case BIN(trace):*/
next = next->next;
break;
case BIN(leave):
piobj = iobj;
default:
next = NULL;
break;
}
} while (next);
}
if (piobj) {
struct rb_call_info *ci = (struct rb_call_info *)piobj->operands[0];
if (piobj->insn_id == BIN(send) || piobj->insn_id == BIN(invokesuper)) {
if (piobj->operands[2] == 0) { /* no blockiseq */
ci->flag |= VM_CALL_TAILCALL;
}
}
else {
ci->flag |= VM_CALL_TAILCALL;
}
}
}
return COMPILE_OK;
}
static int
insn_set_specialized_instruction(rb_iseq_t *iseq, INSN *iobj, int insn_id)
{
iobj->insn_id = insn_id;
iobj->operand_size = insn_len(insn_id) - 1;
if (insn_id == BIN(opt_neq)) {
VALUE *old_operands = iobj->operands;
iobj->operand_size = 4;
iobj->operands = (VALUE *)compile_data_alloc(iseq, iobj->operand_size * sizeof(VALUE));
iobj->operands[0] = old_operands[0];
iobj->operands[1] = Qfalse; /* CALL_CACHE */
iobj->operands[2] = (VALUE)new_callinfo(iseq, idEq, 1, 0, NULL, FALSE);
iobj->operands[3] = Qfalse; /* CALL_CACHE */
}
return COMPILE_OK;
}
static int
iseq_specialized_instruction(rb_iseq_t *iseq, INSN *iobj)
{
if (iobj->insn_id == BIN(newarray) && iobj->link.next &&
iobj->link.next->type == ISEQ_ELEMENT_INSN) {
/*
* [a, b, ...].max/min -> a, b, c, opt_newarray_max/min
*/
INSN *niobj = (INSN *)iobj->link.next;
if (niobj->insn_id == BIN(send)) {
struct rb_call_info *ci = (struct rb_call_info *)OPERAND_AT(niobj, 0);
if ((ci->flag & VM_CALL_ARGS_SIMPLE) && ci->orig_argc == 0) {
switch (ci->mid) {
case idMax:
iobj->insn_id = BIN(opt_newarray_max);
REMOVE_ELEM(&niobj->link);
return COMPILE_OK;
case idMin:
iobj->insn_id = BIN(opt_newarray_min);
REMOVE_ELEM(&niobj->link);
return COMPILE_OK;
}
}
}
}
if (iobj->insn_id == BIN(send)) {
struct rb_call_info *ci = (struct rb_call_info *)OPERAND_AT(iobj, 0);
const rb_iseq_t *blockiseq = (rb_iseq_t *)OPERAND_AT(iobj, 2);
#define SP_INSN(opt) insn_set_specialized_instruction(iseq, iobj, BIN(opt_##opt))
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
if (ci->flag & VM_CALL_ARGS_SIMPLE) {
switch (ci->orig_argc) {
case 0:
switch (ci->mid) {
case idLength: SP_INSN(length); return COMPILE_OK;
case idSize: SP_INSN(size); return COMPILE_OK;
case idEmptyP: SP_INSN(empty_p);return COMPILE_OK;
case idSucc: SP_INSN(succ); return COMPILE_OK;
case idNot: SP_INSN(not); return COMPILE_OK;
}
break;
case 1:
switch (ci->mid) {
case idPLUS: SP_INSN(plus); return COMPILE_OK;
case idMINUS: SP_INSN(minus); return COMPILE_OK;
case idMULT: SP_INSN(mult); return COMPILE_OK;
case idDIV: SP_INSN(div); return COMPILE_OK;
case idMOD: SP_INSN(mod); return COMPILE_OK;
case idEq: SP_INSN(eq); return COMPILE_OK;
case idNeq: SP_INSN(neq); return COMPILE_OK;
case idLT: SP_INSN(lt); return COMPILE_OK;
case idLE: SP_INSN(le); return COMPILE_OK;
case idGT: SP_INSN(gt); return COMPILE_OK;
case idGE: SP_INSN(ge); return COMPILE_OK;
case idLTLT: SP_INSN(ltlt); return COMPILE_OK;
case idAREF: SP_INSN(aref); return COMPILE_OK;
}
break;
case 2:
switch (ci->mid) {
case idASET: SP_INSN(aset); return COMPILE_OK;
}
break;
}
}
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
if ((ci->flag & VM_CALL_ARGS_BLOCKARG) == 0 && blockiseq == NULL) {
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
iobj->insn_id = BIN(opt_send_without_block);
iobj->operand_size = insn_len(iobj->insn_id) - 1;
}
}
#undef SP_INSN
return COMPILE_OK;
}
static int
iseq_optimize(rb_iseq_t *iseq, LINK_ANCHOR *anchor)
{
LINK_ELEMENT *list;
const int do_peepholeopt = ISEQ_COMPILE_DATA(iseq)->option->peephole_optimization;
const int do_tailcallopt = ISEQ_COMPILE_DATA(iseq)->option->tailcall_optimization;
const int do_si = ISEQ_COMPILE_DATA(iseq)->option->specialized_instruction;
const int do_ou = ISEQ_COMPILE_DATA(iseq)->option->operands_unification;
list = FIRST_ELEMENT(anchor);
while (list) {
if (list->type == ISEQ_ELEMENT_INSN) {
if (do_peepholeopt) {
iseq_peephole_optimize(iseq, list, do_tailcallopt);
}
if (do_si) {
iseq_specialized_instruction(iseq, (INSN *)list);
}
if (do_ou) {
insn_operands_unification((INSN *)list);
}
}
list = list->next;
}
return COMPILE_OK;
}
#if OPT_INSTRUCTIONS_UNIFICATION
static INSN *
new_unified_insn(rb_iseq_t *iseq,
int insn_id, int size, LINK_ELEMENT *seq_list)
{
INSN *iobj = 0;
LINK_ELEMENT *list = seq_list;
int i, argc = 0;
VALUE *operands = 0, *ptr = 0;
/* count argc */
for (i = 0; i < size; i++) {
iobj = (INSN *)list;
argc += iobj->operand_size;
list = list->next;
}
if (argc > 0) {
ptr = operands =
(VALUE *)compile_data_alloc(iseq, sizeof(VALUE) * argc);
}
/* copy operands */
list = seq_list;
for (i = 0; i < size; i++) {
iobj = (INSN *)list;
MEMCPY(ptr, iobj->operands, VALUE, iobj->operand_size);
ptr += iobj->operand_size;
list = list->next;
}
return new_insn_core(iseq, iobj->line_no, insn_id, argc, operands);
}
#endif
/*
* This scheme can get more performance if do this optimize with
* label address resolving.
* It's future work (if compile time was bottle neck).
*/
static int
iseq_insns_unification(rb_iseq_t *iseq, LINK_ANCHOR *anchor)
{
#if OPT_INSTRUCTIONS_UNIFICATION
LINK_ELEMENT *list;
INSN *iobj, *niobj;
int id, k;
intptr_t j;
list = FIRST_ELEMENT(anchor);
while (list) {
if (list->type == ISEQ_ELEMENT_INSN) {
iobj = (INSN *)list;
id = iobj->insn_id;
if (unified_insns_data[id] != 0) {
const int *const *entry = unified_insns_data[id];
for (j = 1; j < (intptr_t)entry[0]; j++) {
const int *unified = entry[j];
LINK_ELEMENT *li = list->next;
for (k = 2; k < unified[1]; k++) {
if (li->type != ISEQ_ELEMENT_INSN ||
((INSN *)li)->insn_id != unified[k]) {
goto miss;
}
li = li->next;
}
/* matched */
niobj =
new_unified_insn(iseq, unified[0], unified[1] - 1,
list);
/* insert to list */
niobj->link.prev = (LINK_ELEMENT *)iobj->link.prev;
niobj->link.next = li;
if (li) {
li->prev = (LINK_ELEMENT *)niobj;
}
list->prev->next = (LINK_ELEMENT *)niobj;
list = (LINK_ELEMENT *)niobj;
break;
miss:;
}
}
}
list = list->next;
}
#endif
return COMPILE_OK;
}
#if OPT_STACK_CACHING
#define SC_INSN(insn, stat) sc_insn_info[(insn)][(stat)]
#define SC_NEXT(insn) sc_insn_next[(insn)]
#include "opt_sc.inc"
static int
insn_set_sc_state(rb_iseq_t *iseq, INSN *iobj, int state)
{
int nstate;
int insn_id;
insn_id = iobj->insn_id;
iobj->insn_id = SC_INSN(insn_id, state);
nstate = SC_NEXT(iobj->insn_id);
if (insn_id == BIN(jump) ||
insn_id == BIN(branchif) || insn_id == BIN(branchunless)) {
LABEL *lobj = (LABEL *)OPERAND_AT(iobj, 0);
if (lobj->sc_state != 0) {
if (lobj->sc_state != nstate) {
dump_disasm_list((LINK_ELEMENT *)iobj);
dump_disasm_list((LINK_ELEMENT *)lobj);
printf("\n-- %d, %d\n", lobj->sc_state, nstate);
COMPILE_ERROR(ruby_sourcefile_string, iobj->line_no,
"insn_set_sc_state error\n");
return COMPILE_NG;
}
}
else {
lobj->sc_state = nstate;
}
if (insn_id == BIN(jump)) {
nstate = SCS_XX;
}
}
else if (insn_id == BIN(leave)) {
nstate = SCS_XX;
}
return nstate;
}
static int
label_set_sc_state(LABEL *lobj, int state)
{
if (lobj->sc_state != 0) {
if (lobj->sc_state != state) {
state = lobj->sc_state;
}
}
else {
lobj->sc_state = state;
}
return state;
}
#endif
static int
iseq_set_sequence_stackcaching(rb_iseq_t *iseq, LINK_ANCHOR *anchor)
{
#if OPT_STACK_CACHING
LINK_ELEMENT *list;
int state, insn_id;
/* initialize */
state = SCS_XX;
list = FIRST_ELEMENT(anchor);
/* dump_disasm_list(list); */
/* for each list element */
while (list) {
redo_point:
switch (list->type) {
case ISEQ_ELEMENT_INSN:
{
INSN *iobj = (INSN *)list;
insn_id = iobj->insn_id;
/* dump_disasm_list(list); */
switch (insn_id) {
case BIN(nop):
{
/* exception merge point */
if (state != SCS_AX) {
INSN *rpobj =
new_insn_body(iseq, 0, BIN(reput), 0);
/* replace this insn */
REPLACE_ELEM(list, (LINK_ELEMENT *)rpobj);
list = (LINK_ELEMENT *)rpobj;
goto redo_point;
}
break;
}
case BIN(swap):
{
if (state == SCS_AB || state == SCS_BA) {
state = (state == SCS_AB ? SCS_BA : SCS_AB);
REMOVE_ELEM(list);
list = list->next;
goto redo_point;
}
break;
}
case BIN(pop):
{
switch (state) {
case SCS_AX:
case SCS_BX:
state = SCS_XX;
break;
case SCS_AB:
state = SCS_AX;
break;
case SCS_BA:
state = SCS_BX;
break;
case SCS_XX:
goto normal_insn;
default:
COMPILE_ERROR(ruby_sourcefile_string, iobj->line_no,
"unreachable");
return COMPILE_NG;
}
/* remove useless pop */
REMOVE_ELEM(list);
list = list->next;
goto redo_point;
}
default:;
/* none */
} /* end of switch */
normal_insn:
state = insn_set_sc_state(iseq, iobj, state);
break;
}
case ISEQ_ELEMENT_LABEL:
{
LABEL *lobj;
lobj = (LABEL *)list;
state = label_set_sc_state(lobj, state);
}
default:
break;
}
list = list->next;
}
#endif
return COMPILE_OK;
}
static int
compile_dstr_fragments(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE *node, int *cntp)
{
NODE *list = node->nd_next;
VALUE lit = node->nd_lit;
LINK_ELEMENT *first_lit = 0;
int cnt = 0;
debugp_param("nd_lit", lit);
if (!NIL_P(lit)) {
cnt++;
if (!RB_TYPE_P(lit, T_STRING)) {
rb_compile_bug_str(ERROR_ARGS "dstr: must be string: %s",
rb_builtin_type_name(TYPE(lit)));
}
lit = node->nd_lit = rb_fstring(lit);
ADD_INSN1(ret, nd_line(node), putobject, lit);
if (RSTRING_LEN(lit) == 0) first_lit = LAST_ELEMENT(ret);
}
while (list) {
node = list->nd_head;
if (nd_type(node) == NODE_STR) {
node->nd_lit = rb_fstring(node->nd_lit);
ADD_INSN1(ret, nd_line(node), putobject, node->nd_lit);
lit = Qnil;
}
else {
COMPILE(ret, "each string", node);
}
cnt++;
list = list->nd_next;
}
if (NIL_P(lit) && first_lit) {
REMOVE_ELEM(first_lit);
--cnt;
}
*cntp = cnt;
return COMPILE_OK;
}
static int
compile_dstr(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE * node)
{
int cnt;
compile_dstr_fragments(iseq, ret, node, &cnt);
ADD_INSN1(ret, nd_line(node), concatstrings, INT2FIX(cnt));
return COMPILE_OK;
}
static int
compile_dregx(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE * node)
{
int cnt;
compile_dstr_fragments(iseq, ret, node, &cnt);
ADD_INSN2(ret, nd_line(node), toregexp, INT2FIX(node->nd_cflag), INT2FIX(cnt));
return COMPILE_OK;
}
static int
compile_branch_condition(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE * cond,
LABEL *then_label, LABEL *else_label)
{
switch (nd_type(cond)) {
case NODE_AND:
{
LABEL *label = NEW_LABEL(nd_line(cond));
compile_branch_condition(iseq, ret, cond->nd_1st, label,
else_label);
ADD_LABEL(ret, label);
compile_branch_condition(iseq, ret, cond->nd_2nd, then_label,
else_label);
break;
}
case NODE_OR:
{
LABEL *label = NEW_LABEL(nd_line(cond));
compile_branch_condition(iseq, ret, cond->nd_1st, then_label,
label);
ADD_LABEL(ret, label);
compile_branch_condition(iseq, ret, cond->nd_2nd, then_label,
else_label);
break;
}
case NODE_LIT: /* NODE_LIT is always not true */
case NODE_TRUE:
case NODE_STR:
/* printf("useless condition eliminate (%s)\n", ruby_node_name(nd_type(cond))); */
ADD_INSNL(ret, nd_line(cond), jump, then_label);
break;
case NODE_FALSE:
case NODE_NIL:
/* printf("useless condition eliminate (%s)\n", ruby_node_name(nd_type(cond))); */
ADD_INSNL(ret, nd_line(cond), jump, else_label);
break;
default:
COMPILE(ret, "branch condition", cond);
ADD_INSNL(ret, nd_line(cond), branchunless, else_label);
ADD_INSNL(ret, nd_line(cond), jump, then_label);
break;
}
return COMPILE_OK;
}
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
static int
compile_array_keyword_arg(rb_iseq_t *iseq, LINK_ANCHOR *ret, const NODE * const root_node, struct rb_call_info_kw_arg ** const kw_arg_ptr)
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
{
if (kw_arg_ptr == NULL) return FALSE;
if (nd_type(root_node) == NODE_HASH && root_node->nd_head && nd_type(root_node->nd_head) == NODE_ARRAY) {
NODE *node = root_node->nd_head;
while (node) {
NODE *key_node = node->nd_head;
assert(nd_type(node) == NODE_ARRAY);
if (key_node && nd_type(key_node) == NODE_LIT && RB_TYPE_P(key_node->nd_lit, T_SYMBOL)) {
/* can be keywords */
}
else {
return FALSE;
}
node = node->nd_next; /* skip value node */
node = node->nd_next;
}
/* may be keywords */
node = root_node->nd_head;
{
int len = (int)node->nd_alen / 2;
struct rb_call_info_kw_arg *kw_arg = (struct rb_call_info_kw_arg *)ruby_xmalloc(sizeof(struct rb_call_info_kw_arg) + sizeof(VALUE) * (len - 1));
VALUE *keywords = kw_arg->keywords;
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
int i = 0;
kw_arg->keyword_len = len;
*kw_arg_ptr = kw_arg;
for (i=0; node != NULL; i++, node = node->nd_next->nd_next) {
NODE *key_node = node->nd_head;
NODE *val_node = node->nd_next->nd_head;
keywords[i] = key_node->nd_lit;
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
COMPILE(ret, "keyword values", val_node);
}
assert(i == len);
return TRUE;
}
}
return FALSE;
}
enum compile_array_type_t {
COMPILE_ARRAY_TYPE_ARRAY,
COMPILE_ARRAY_TYPE_HASH,
COMPILE_ARRAY_TYPE_ARGS
};
static int
compile_array_(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE* node_root,
enum compile_array_type_t type, struct rb_call_info_kw_arg **keywords_ptr, int poped)
{
NODE *node = node_root;
int line = (int)nd_line(node);
int len = 0;
if (nd_type(node) == NODE_ZARRAY) {
if (!poped) {
switch (type) {
case COMPILE_ARRAY_TYPE_ARRAY: ADD_INSN1(ret, line, newarray, INT2FIX(0)); break;
case COMPILE_ARRAY_TYPE_HASH: ADD_INSN1(ret, line, newhash, INT2FIX(0)); break;
case COMPILE_ARRAY_TYPE_ARGS: /* do nothing */ break;
}
}
}
else {
int opt_p = 1;
int first = 1, i;
while (node) {
NODE *start_node = node, *end_node;
NODE *kw = 0;
const int max = 0x100;
DECL_ANCHOR(anchor);
INIT_ANCHOR(anchor);
for (i=0; i<max && node; i++, len++, node = node->nd_next) {
if (CPDEBUG > 0) {
EXPECT_NODE("compile_array", node, NODE_ARRAY);
}
if (type != COMPILE_ARRAY_TYPE_ARRAY && !node->nd_head) {
kw = node->nd_next;
node = 0;
if (kw) {
opt_p = 0;
node = kw->nd_next;
kw = kw->nd_head;
}
break;
}
if (opt_p && nd_type(node->nd_head) != NODE_LIT) {
opt_p = 0;
}
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
if (type == COMPILE_ARRAY_TYPE_ARGS && node->nd_next == NULL /* last node */ && compile_array_keyword_arg(iseq, anchor, node->nd_head, keywords_ptr)) {
len--;
}
else {
COMPILE_(anchor, "array element", node->nd_head, poped);
}
}
if (opt_p && type != COMPILE_ARRAY_TYPE_ARGS) {
if (!poped) {
VALUE ary = rb_ary_tmp_new(i);
end_node = node;
node = start_node;
while (node != end_node) {
rb_ary_push(ary, node->nd_head->nd_lit);
node = node->nd_next;
}
while (node && nd_type(node->nd_head) == NODE_LIT &&
node->nd_next && nd_type(node->nd_next->nd_head) == NODE_LIT) {
rb_ary_push(ary, node->nd_head->nd_lit);
node = node->nd_next;
rb_ary_push(ary, node->nd_head->nd_lit);
node = node->nd_next;
len++;
}
OBJ_FREEZE(ary);
iseq_add_mark_object_compile_time(iseq, ary);
if (first) {
first = 0;
if (type == COMPILE_ARRAY_TYPE_ARRAY) {
ADD_INSN1(ret, line, duparray, ary);
}
else { /* COMPILE_ARRAY_TYPE_HASH */
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
ADD_INSN1(ret, line, putobject, ary);
ADD_SEND(ret, line, id_core_hash_from_ary, INT2FIX(1));
}
}
else {
if (type == COMPILE_ARRAY_TYPE_ARRAY) {
ADD_INSN1(ret, line, putobject, ary);
ADD_INSN(ret, line, concatarray);
}
else {
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
ADD_INSN1(ret, line, putobject, ary);
ADD_SEND(ret, line, id_core_hash_merge_ary, INT2FIX(1));
}
}
}
}
else {
if (!poped) {
switch (type) {
case COMPILE_ARRAY_TYPE_ARRAY:
ADD_INSN1(anchor, line, newarray, INT2FIX(i));
if (first) {
first = 0;
}
else {
ADD_INSN(anchor, line, concatarray);
}
APPEND_LIST(ret, anchor);
break;
case COMPILE_ARRAY_TYPE_HASH:
if (i > 0) {
if (first) {
ADD_INSN1(anchor, line, newhash, INT2FIX(i));
APPEND_LIST(ret, anchor);
}
else {
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
ADD_INSN(ret, line, swap);
APPEND_LIST(ret, anchor);
ADD_SEND(ret, line, id_core_hash_merge_ptr, INT2FIX(i + 1));
}
}
if (kw) {
VALUE nhash = (i > 0 || !first) ? INT2FIX(2) : INT2FIX(1);
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
if (i > 0 || !first) ADD_INSN(ret, line, swap);
COMPILE(ret, "keyword splat", kw);
ADD_SEND(ret, line, id_core_hash_merge_kwd, nhash);
if (nhash == INT2FIX(1)) ADD_SEND(ret, line, rb_intern("dup"), INT2FIX(0));
}
first = 0;
break;
case COMPILE_ARRAY_TYPE_ARGS:
APPEND_LIST(ret, anchor);
break;
}
}
else {
/* poped */
APPEND_LIST(ret, anchor);
}
}
}
}
return len;
}
static VALUE
compile_array(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE* node_root, enum compile_array_type_t type)
{
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
return compile_array_(iseq, ret, node_root, type, NULL, 0);
}
static VALUE
case_when_optimizable_literal(NODE * node)
{
switch (nd_type(node)) {
case NODE_LIT: {
VALUE v = node->nd_lit;
double ival;
if (RB_TYPE_P(v, T_FLOAT) &&
modf(RFLOAT_VALUE(v), &ival) == 0.0) {
return FIXABLE(ival) ? LONG2FIX((long)ival) : rb_dbl2big(ival);
}
if (SYMBOL_P(v) || rb_obj_is_kind_of(v, rb_cNumeric)) {
return v;
}
break;
}
case NODE_NIL:
return Qnil;
case NODE_TRUE:
return Qtrue;
case NODE_FALSE:
return Qfalse;
case NODE_STR:
return node->nd_lit = rb_fstring(node->nd_lit);
}
return Qundef;
}
static int
when_vals(rb_iseq_t *iseq, LINK_ANCHOR *cond_seq, NODE *vals, LABEL *l1, int only_special_literals, VALUE literals)
{
while (vals) {
NODE* val = vals->nd_head;
VALUE lit = case_when_optimizable_literal(val);
if (lit == Qundef) {
only_special_literals = 0;
}
else {
if (rb_hash_lookup(literals, lit) != Qnil) {
rb_compile_warning(ruby_sourcefile, nd_line(val),
"duplicated when clause is ignored");
}
else {
rb_hash_aset(literals, lit, (VALUE)(l1) | 1);
}
}
ADD_INSN(cond_seq, nd_line(val), dup); /* dup target */
if (nd_type(val) == NODE_STR) {
val->nd_lit = rb_fstring(val->nd_lit);
debugp_param("nd_lit", val->nd_lit);
ADD_INSN1(cond_seq, nd_line(val), putobject, val->nd_lit);
}
else {
COMPILE(cond_seq, "when cond", val);
}
ADD_INSN1(cond_seq, nd_line(vals), checkmatch, INT2FIX(VM_CHECKMATCH_TYPE_CASE));
ADD_INSNL(cond_seq, nd_line(val), branchif, l1);
vals = vals->nd_next;
}
return only_special_literals;
}
static int
compile_massign_lhs(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE *node)
{
switch (nd_type(node)) {
case NODE_ATTRASGN: {
INSN *iobj;
struct rb_call_info *ci;
VALUE dupidx;
int line = nd_line(node);
COMPILE_POPED(ret, "masgn lhs (NODE_ATTRASGN)", node);
iobj = (INSN *)get_prev_insn((INSN *)LAST_ELEMENT(ret)); /* send insn */
ci = (struct rb_call_info *)iobj->operands[0];
ci->orig_argc += 1;
dupidx = INT2FIX(ci->orig_argc);
INSERT_BEFORE_INSN1(iobj, line, topn, dupidx);
if (ci->flag & VM_CALL_ARGS_SPLAT) {
--ci->orig_argc;
INSERT_BEFORE_INSN1(iobj, line, newarray, INT2FIX(1));
INSERT_BEFORE_INSN(iobj, line, concatarray);
}
ADD_INSN(ret, line, pop); /* result */
break;
}
case NODE_MASGN: {
DECL_ANCHOR(anchor);
INIT_ANCHOR(anchor);
COMPILE_POPED(anchor, "nest masgn lhs", node);
REMOVE_ELEM(FIRST_ELEMENT(anchor));
ADD_SEQ(ret, anchor);
break;
}
default: {
DECL_ANCHOR(anchor);
INIT_ANCHOR(anchor);
COMPILE_POPED(anchor, "masgn lhs", node);
REMOVE_ELEM(FIRST_ELEMENT(anchor));
ADD_SEQ(ret, anchor);
}
}
return COMPILE_OK;
}
static void
compile_massign_opt_lhs(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE *lhsn)
{
if (lhsn) {
compile_massign_opt_lhs(iseq, ret, lhsn->nd_next);
compile_massign_lhs(iseq, ret, lhsn->nd_head);
}
}
static int
compile_massign_opt(rb_iseq_t *iseq, LINK_ANCHOR *ret,
NODE *rhsn, NODE *orig_lhsn)
{
VALUE mem[64];
const int memsize = numberof(mem);
int memindex = 0;
int llen = 0, rlen = 0;
int i;
NODE *lhsn = orig_lhsn;
#define MEMORY(v) { \
int i; \
if (memindex == memsize) return 0; \
for (i=0; i<memindex; i++) { \
if (mem[i] == (v)) return 0; \
} \
mem[memindex++] = (v); \
}
if (rhsn == 0 || nd_type(rhsn) != NODE_ARRAY) {
return 0;
}
while (lhsn) {
NODE *ln = lhsn->nd_head;
switch (nd_type(ln)) {
case NODE_LASGN:
MEMORY(ln->nd_vid);
break;
case NODE_DASGN:
case NODE_DASGN_CURR:
case NODE_IASGN:
case NODE_IASGN2:
case NODE_CVASGN:
MEMORY(ln->nd_vid);
break;
default:
return 0;
}
lhsn = lhsn->nd_next;
llen++;
}
while (rhsn) {
if (llen <= rlen) {
COMPILE_POPED(ret, "masgn val (popped)", rhsn->nd_head);
}
else {
COMPILE(ret, "masgn val", rhsn->nd_head);
}
rhsn = rhsn->nd_next;
rlen++;
}
if (llen > rlen) {
for (i=0; i<llen-rlen; i++) {
ADD_INSN(ret, nd_line(orig_lhsn), putnil);
}
}
compile_massign_opt_lhs(iseq, ret, orig_lhsn);
return 1;
}
static void
adjust_stack(rb_iseq_t *iseq, LINK_ANCHOR *ret, int line, int rlen, int llen)
{
if (rlen < llen) {
do {ADD_INSN(ret, line, putnil);} while (++rlen < llen);
}
else if (rlen > llen) {
do {ADD_INSN(ret, line, pop);} while (--rlen > llen);
}
}
static int
compile_massign(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE *node, int poped)
{
NODE *rhsn = node->nd_value;
NODE *splatn = node->nd_args;
NODE *lhsn = node->nd_head;
int lhs_splat = (splatn && (VALUE)splatn != (VALUE)-1) ? 1 : 0;
if (!poped || splatn || !compile_massign_opt(iseq, ret, rhsn, lhsn)) {
int llen = 0;
int expand = 1;
DECL_ANCHOR(lhsseq);
INIT_ANCHOR(lhsseq);
while (lhsn) {
compile_massign_lhs(iseq, lhsseq, lhsn->nd_head);
llen += 1;
lhsn = lhsn->nd_next;
}
COMPILE(ret, "normal masgn rhs", rhsn);
if (!poped) {
ADD_INSN(ret, nd_line(node), dup);
}
else if (!lhs_splat) {
INSN *last = (INSN*)ret->last;
if (last->link.type == ISEQ_ELEMENT_INSN &&
last->insn_id == BIN(newarray) &&
last->operand_size == 1) {
int rlen = FIX2INT(OPERAND_AT(last, 0));
/* special case: assign to aset or attrset */
if (llen == 2) {
POP_ELEMENT(ret);
adjust_stack(iseq, ret, nd_line(node), rlen, llen);
ADD_INSN(ret, nd_line(node), swap);
expand = 0;
}
else if (llen > 2 && llen != rlen) {
POP_ELEMENT(ret);
adjust_stack(iseq, ret, nd_line(node), rlen, llen);
ADD_INSN1(ret, nd_line(node), reverse, INT2FIX(llen));
expand = 0;
}
else if (llen > 2) {
last->insn_id = BIN(reverse);
expand = 0;
}
}
}
if (expand) {
ADD_INSN2(ret, nd_line(node), expandarray,
INT2FIX(llen), INT2FIX(lhs_splat));
}
ADD_SEQ(ret, lhsseq);
if (lhs_splat) {
if (nd_type(splatn) == NODE_POSTARG) {
/*a, b, *r, p1, p2 */
NODE *postn = splatn->nd_2nd;
NODE *restn = splatn->nd_1st;
int num = (int)postn->nd_alen;
int flag = 0x02 | (((VALUE)restn == (VALUE)-1) ? 0x00 : 0x01);
ADD_INSN2(ret, nd_line(splatn), expandarray,
INT2FIX(num), INT2FIX(flag));
if ((VALUE)restn != (VALUE)-1) {
compile_massign_lhs(iseq, ret, restn);
}
while (postn) {
compile_massign_lhs(iseq, ret, postn->nd_head);
postn = postn->nd_next;
}
}
else {
/* a, b, *r */
compile_massign_lhs(iseq, ret, splatn);
}
}
}
return COMPILE_OK;
}
static int
compile_colon2(rb_iseq_t *iseq, NODE * node,
LINK_ANCHOR *pref, LINK_ANCHOR *body)
{
switch (nd_type(node)) {
case NODE_CONST:
debugi("compile_colon2 - colon", node->nd_vid);
ADD_INSN1(body, nd_line(node), getconstant, ID2SYM(node->nd_vid));
break;
case NODE_COLON3:
debugi("compile_colon2 - colon3", node->nd_mid);
ADD_INSN(body, nd_line(node), pop);
ADD_INSN1(body, nd_line(node), putobject, rb_cObject);
ADD_INSN1(body, nd_line(node), getconstant, ID2SYM(node->nd_mid));
break;
case NODE_COLON2:
compile_colon2(iseq, node->nd_head, pref, body);
debugi("compile_colon2 - colon2", node->nd_mid);
ADD_INSN1(body, nd_line(node), getconstant, ID2SYM(node->nd_mid));
break;
default:
COMPILE(pref, "const colon2 prefix", node);
break;
}
return COMPILE_OK;
}
static VALUE
compile_cpath(LINK_ANCHOR *ret, rb_iseq_t *iseq, NODE *cpath)
{
if (nd_type(cpath) == NODE_COLON3) {
/* toplevel class ::Foo */
ADD_INSN1(ret, nd_line(cpath), putobject, rb_cObject);
return Qfalse;
}
else if (cpath->nd_head) {
/* Bar::Foo */
COMPILE(ret, "nd_else->nd_head", cpath->nd_head);
return Qfalse;
}
else {
/* class at cbase Foo */
ADD_INSN1(ret, nd_line(cpath), putspecialobject,
INT2FIX(VM_SPECIAL_OBJECT_CONST_BASE));
return Qtrue;
}
}
#define private_recv_p(node) (nd_type((node)->nd_recv) == NODE_SELF)
#define defined_expr defined_expr0
static int
defined_expr(rb_iseq_t *iseq, LINK_ANCHOR *ret,
NODE *node, LABEL **lfinish, VALUE needstr)
{
enum defined_type expr_type = 0;
enum node_type type;
switch (type = nd_type(node)) {
/* easy literals */
case NODE_NIL:
expr_type = DEFINED_NIL;
break;
case NODE_SELF:
expr_type = DEFINED_SELF;
break;
case NODE_TRUE:
expr_type = DEFINED_TRUE;
break;
case NODE_FALSE:
expr_type = DEFINED_FALSE;
break;
case NODE_ARRAY:{
NODE *vals = node;
do {
defined_expr(iseq, ret, vals->nd_head, lfinish, Qfalse);
if (!lfinish[1]) {
lfinish[1] = NEW_LABEL(nd_line(node));
}
ADD_INSNL(ret, nd_line(node), branchunless, lfinish[1]);
} while ((vals = vals->nd_next) != NULL);
}
case NODE_STR:
case NODE_LIT:
case NODE_ZARRAY:
case NODE_AND:
case NODE_OR:
default:
expr_type = DEFINED_EXPR;
break;
/* variables */
case NODE_LVAR:
case NODE_DVAR:
expr_type = DEFINED_LVAR;
break;
case NODE_IVAR:
ADD_INSN(ret, nd_line(node), putnil);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_IVAR),
ID2SYM(node->nd_vid), needstr);
return 1;
case NODE_GVAR:
ADD_INSN(ret, nd_line(node), putnil);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_GVAR),
ID2SYM(node->nd_entry->id), needstr);
return 1;
case NODE_CVAR:
ADD_INSN(ret, nd_line(node), putnil);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_CVAR),
ID2SYM(node->nd_vid), needstr);
return 1;
case NODE_CONST:
ADD_INSN(ret, nd_line(node), putnil);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_CONST),
ID2SYM(node->nd_vid), needstr);
return 1;
case NODE_COLON2:
if (!lfinish[1]) {
lfinish[1] = NEW_LABEL(nd_line(node));
}
defined_expr(iseq, ret, node->nd_head, lfinish, Qfalse);
ADD_INSNL(ret, nd_line(node), branchunless, lfinish[1]);
if (rb_is_const_id(node->nd_mid)) {
COMPILE(ret, "defined/colon2#nd_head", node->nd_head);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_CONST),
ID2SYM(node->nd_mid), needstr);
}
else {
COMPILE(ret, "defined/colon2#nd_head", node->nd_head);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_METHOD),
ID2SYM(node->nd_mid), needstr);
}
return 1;
case NODE_COLON3:
ADD_INSN1(ret, nd_line(node), putobject, rb_cObject);
ADD_INSN3(ret, nd_line(node), defined,
INT2FIX(DEFINED_CONST), ID2SYM(node->nd_mid), needstr);
return 1;
/* method dispatch */
case NODE_CALL:
case NODE_VCALL:
case NODE_FCALL:
case NODE_ATTRASGN:{
const int explicit_receiver =
(type == NODE_CALL ||
(type == NODE_ATTRASGN && !private_recv_p(node)));
if (!lfinish[1]) {
lfinish[1] = NEW_LABEL(nd_line(node));
}
if (node->nd_args) {
defined_expr(iseq, ret, node->nd_args, lfinish, Qfalse);
ADD_INSNL(ret, nd_line(node), branchunless, lfinish[1]);
}
if (explicit_receiver) {
defined_expr(iseq, ret, node->nd_recv, lfinish, Qfalse);
ADD_INSNL(ret, nd_line(node), branchunless, lfinish[1]);
COMPILE(ret, "defined/recv", node->nd_recv);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_METHOD),
ID2SYM(node->nd_mid), needstr);
}
else {
ADD_INSN(ret, nd_line(node), putself);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_FUNC),
ID2SYM(node->nd_mid), needstr);
}
return 1;
}
case NODE_YIELD:
ADD_INSN(ret, nd_line(node), putnil);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_YIELD), 0,
needstr);
return 1;
case NODE_BACK_REF:
case NODE_NTH_REF:
ADD_INSN(ret, nd_line(node), putnil);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_REF),
INT2FIX((node->nd_nth << 1) | (type == NODE_BACK_REF)),
needstr);
return 1;
case NODE_SUPER:
case NODE_ZSUPER:
ADD_INSN(ret, nd_line(node), putnil);
ADD_INSN3(ret, nd_line(node), defined, INT2FIX(DEFINED_ZSUPER), 0,
needstr);
return 1;
case NODE_OP_ASGN1:
case NODE_OP_ASGN2:
case NODE_OP_ASGN_OR:
case NODE_OP_ASGN_AND:
case NODE_MASGN:
case NODE_LASGN:
case NODE_DASGN:
case NODE_DASGN_CURR:
case NODE_GASGN:
case NODE_IASGN:
case NODE_CDECL:
case NODE_CVDECL:
case NODE_CVASGN:
expr_type = DEFINED_ASGN;
break;
}
if (expr_type) {
if (needstr != Qfalse) {
VALUE str = rb_iseq_defined_string(expr_type);
ADD_INSN1(ret, nd_line(node), putobject, str);
}
else {
ADD_INSN1(ret, nd_line(node), putobject, Qtrue);
}
return 1;
}
return 0;
}
#undef defined_expr
static int
defined_expr(rb_iseq_t *iseq, LINK_ANCHOR *ret,
NODE *node, LABEL **lfinish, VALUE needstr)
{
LINK_ELEMENT *lcur = ret->last;
int done = defined_expr0(iseq, ret, node, lfinish, needstr);
if (lfinish[1]) {
int line = nd_line(node);
LABEL *lstart = NEW_LABEL(line);
LABEL *lend = NEW_LABEL(line);
2015-07-22 01:52:59 +03:00
const rb_iseq_t *rescue = NEW_CHILD_ISEQ(NEW_NIL(),
rb_str_concat(rb_str_new2
("defined guard in "),
iseq->body->location.label),
ISEQ_TYPE_DEFINED_GUARD, 0);
APPEND_LABEL(ret, lcur, lstart);
ADD_LABEL(ret, lend);
ADD_CATCH_ENTRY(CATCH_TYPE_RESCUE, lstart, lend, rescue, lfinish[1]);
}
return done;
}
static VALUE
2015-07-22 01:52:59 +03:00
make_name_for_block(const rb_iseq_t *orig_iseq)
{
int level = 1;
2015-07-22 01:52:59 +03:00
const rb_iseq_t *iseq = orig_iseq;
2015-07-22 01:52:59 +03:00
if (orig_iseq->body->parent_iseq != 0) {
while (orig_iseq->body->local_iseq != iseq) {
if (iseq->body->type == ISEQ_TYPE_BLOCK) {
level++;
}
2015-07-22 01:52:59 +03:00
iseq = iseq->body->parent_iseq;
}
}
if (level == 1) {
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return rb_sprintf("block in %"PRIsVALUE, iseq->body->location.label);
}
else {
2015-07-22 01:52:59 +03:00
return rb_sprintf("block (%d levels) in %"PRIsVALUE, level, iseq->body->location.label);
}
}
static void
push_ensure_entry(rb_iseq_t *iseq,
struct iseq_compile_data_ensure_node_stack *enl,
struct ensure_range *er, NODE *node)
{
enl->ensure_node = node;
enl->prev = ISEQ_COMPILE_DATA(iseq)->ensure_node_stack; /* prev */
enl->erange = er;
ISEQ_COMPILE_DATA(iseq)->ensure_node_stack = enl;
}
static void
add_ensure_range(rb_iseq_t *iseq, struct ensure_range *erange,
LABEL *lstart, LABEL *lend)
{
struct ensure_range *ne =
compile_data_alloc(iseq, sizeof(struct ensure_range));
while (erange->next != 0) {
erange = erange->next;
}
ne->next = 0;
ne->begin = lend;
ne->end = erange->end;
erange->end = lstart;
erange->next = ne;
}
static void
add_ensure_iseq(LINK_ANCHOR *ret, rb_iseq_t *iseq, int is_return)
{
struct iseq_compile_data_ensure_node_stack *enlp =
ISEQ_COMPILE_DATA(iseq)->ensure_node_stack;
struct iseq_compile_data_ensure_node_stack *prev_enlp = enlp;
DECL_ANCHOR(ensure);
INIT_ANCHOR(ensure);
while (enlp) {
if (enlp->erange != 0) {
DECL_ANCHOR(ensure_part);
LABEL *lstart = NEW_LABEL(0);
LABEL *lend = NEW_LABEL(0);
INIT_ANCHOR(ensure_part);
add_ensure_range(iseq, enlp->erange, lstart, lend);
ISEQ_COMPILE_DATA(iseq)->ensure_node_stack = enlp->prev;
ADD_LABEL(ensure_part, lstart);
COMPILE_POPED(ensure_part, "ensure part", enlp->ensure_node);
ADD_LABEL(ensure_part, lend);
ADD_SEQ(ensure, ensure_part);
}
else {
if (!is_return) {
break;
}
}
enlp = enlp->prev;
}
ISEQ_COMPILE_DATA(iseq)->ensure_node_stack = prev_enlp;
ADD_SEQ(ret, ensure);
}
static VALUE
setup_args(rb_iseq_t *iseq, LINK_ANCHOR *args, NODE *argn, unsigned int *flag, struct rb_call_info_kw_arg **keywords)
{
VALUE argc = INT2FIX(0);
int nsplat = 0;
DECL_ANCHOR(arg_block);
DECL_ANCHOR(args_splat);
INIT_ANCHOR(arg_block);
INIT_ANCHOR(args_splat);
if (argn && nd_type(argn) == NODE_BLOCK_PASS) {
COMPILE(arg_block, "block", argn->nd_body);
*flag |= VM_CALL_ARGS_BLOCKARG;
argn = argn->nd_head;
}
setup_argn:
if (argn) {
switch (nd_type(argn)) {
case NODE_SPLAT: {
COMPILE(args, "args (splat)", argn->nd_head);
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_INSN1(args, nd_line(argn), splatarray, Qfalse);
argc = INT2FIX(1);
nsplat++;
*flag |= VM_CALL_ARGS_SPLAT;
break;
}
case NODE_ARGSCAT:
case NODE_ARGSPUSH: {
int next_is_array = (nd_type(argn->nd_head) == NODE_ARRAY);
DECL_ANCHOR(tmp);
INIT_ANCHOR(tmp);
COMPILE(tmp, "args (cat: splat)", argn->nd_body);
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
if (nd_type(argn) == NODE_ARGSCAT) {
ADD_INSN1(tmp, nd_line(argn), splatarray, Qfalse);
}
else {
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_INSN1(tmp, nd_line(argn), newarray, INT2FIX(1));
}
INSERT_LIST(args_splat, tmp);
nsplat++;
*flag |= VM_CALL_ARGS_SPLAT;
if (next_is_array) {
argc = INT2FIX(compile_array(iseq, args, argn->nd_head, COMPILE_ARRAY_TYPE_ARGS) + 1);
}
else {
argn = argn->nd_head;
goto setup_argn;
}
break;
}
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
case NODE_ARRAY:
{
argc = INT2FIX(compile_array_(iseq, args, argn, COMPILE_ARRAY_TYPE_ARGS, keywords, FALSE));
break;
}
default: {
UNKNOWN_NODE("setup_arg", argn);
}
}
}
if (nsplat > 1) {
int i;
for (i=1; i<nsplat; i++) {
ADD_INSN(args_splat, nd_line(args), concatarray);
}
}
if (!LIST_SIZE_ZERO(args_splat)) {
ADD_SEQ(args, args_splat);
}
if (*flag & VM_CALL_ARGS_BLOCKARG) {
ADD_SEQ(args, arg_block);
}
return argc;
}
static VALUE
build_postexe_iseq(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE *body)
{
int line = nd_line(body);
VALUE argc = INT2FIX(0);
2015-07-22 01:52:59 +03:00
const rb_iseq_t *block = NEW_CHILD_ISEQ(body, make_name_for_block(iseq->body->parent_iseq), ISEQ_TYPE_BLOCK, line);
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
ADD_CALL_WITH_BLOCK(ret, line, id_core_set_postexe, argc, block);
iseq_set_local_table(iseq, 0);
return Qnil;
}
static void
compile_named_capture_assign(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE *node)
{
NODE *vars;
LINK_ELEMENT *last;
int line = nd_line(node);
LABEL *fail_label = NEW_LABEL(line), *end_label = NEW_LABEL(line);
#if !(defined(NAMED_CAPTURE_BY_SVAR) && NAMED_CAPTURE_BY_SVAR-0)
ADD_INSN1(ret, line, getglobal, ((VALUE)rb_global_entry(idBACKREF) | 1));
#else
ADD_INSN2(ret, line, getspecial, INT2FIX(1) /* '~' */, INT2FIX(0));
#endif
ADD_INSN(ret, line, dup);
ADD_INSNL(ret, line, branchunless, fail_label);
for (vars = node; vars; vars = vars->nd_next) {
INSN *cap;
if (vars->nd_next) {
ADD_INSN(ret, line, dup);
}
last = ret->last;
COMPILE_POPED(ret, "capture", vars->nd_head);
last = last->next; /* putobject :var */
cap = new_insn_send(iseq, line, idAREF, INT2FIX(1),
NULL, INT2FIX(0), NULL);
INSERT_ELEM_PREV(last->next, (LINK_ELEMENT *)cap);
#if !defined(NAMED_CAPTURE_SINGLE_OPT) || NAMED_CAPTURE_SINGLE_OPT-0
if (!vars->nd_next && vars == node) {
/* only one name */
DECL_ANCHOR(nom);
INIT_ANCHOR(nom);
ADD_INSNL(nom, line, jump, end_label);
ADD_LABEL(nom, fail_label);
# if 0 /* $~ must be MatchData or nil */
ADD_INSN(nom, line, pop);
ADD_INSN(nom, line, putnil);
# endif
ADD_LABEL(nom, end_label);
(nom->last->next = cap->link.next)->prev = nom->last;
(cap->link.next = nom->anchor.next)->prev = &cap->link;
return;
}
#endif
}
ADD_INSNL(ret, line, jump, end_label);
ADD_LABEL(ret, fail_label);
ADD_INSN(ret, line, pop);
for (vars = node; vars; vars = vars->nd_next) {
last = ret->last;
COMPILE_POPED(ret, "capture", vars->nd_head);
last = last->next; /* putobject :var */
((INSN*)last)->insn_id = BIN(putnil);
((INSN*)last)->operand_size = 0;
}
ADD_LABEL(ret, end_label);
}
/**
compile each node
self: InstructionSequence
node: Ruby compiled node
poped: This node will be poped
*/
static int
iseq_compile_each(rb_iseq_t *iseq, LINK_ANCHOR *ret, NODE * node, int poped)
{
enum node_type type;
LINK_ELEMENT *saved_last_element = 0;
int line;
if (node == 0) {
if (!poped) {
debugs("node: NODE_NIL(implicit)\n");
ADD_INSN(ret, ISEQ_COMPILE_DATA(iseq)->last_line, putnil);
}
return COMPILE_OK;
}
line = (int)nd_line(node);
if (ISEQ_COMPILE_DATA(iseq)->last_line == line) {
/* ignore */
}
else {
if (node->flags & NODE_FL_NEWLINE) {
ISEQ_COMPILE_DATA(iseq)->last_line = line;
ADD_TRACE(ret, line, RUBY_EVENT_LINE);
saved_last_element = ret->last;
}
}
debug_node_start(node);
type = nd_type(node);
switch (type) {
case NODE_BLOCK:{
while (node && nd_type(node) == NODE_BLOCK) {
COMPILE_(ret, "BLOCK body", node->nd_head,
(node->nd_next == 0 && poped == 0) ? 0 : 1);
node = node->nd_next;
}
if (node) {
COMPILE_(ret, "BLOCK next", node->nd_next, poped);
}
break;
}
case NODE_IF:{
DECL_ANCHOR(cond_seq);
DECL_ANCHOR(then_seq);
DECL_ANCHOR(else_seq);
LABEL *then_label, *else_label, *end_label;
INIT_ANCHOR(cond_seq);
INIT_ANCHOR(then_seq);
INIT_ANCHOR(else_seq);
then_label = NEW_LABEL(line);
else_label = NEW_LABEL(line);
end_label = NEW_LABEL(line);
compile_branch_condition(iseq, cond_seq, node->nd_cond,
then_label, else_label);
COMPILE_(then_seq, "then", node->nd_body, poped);
COMPILE_(else_seq, "else", node->nd_else, poped);
ADD_SEQ(ret, cond_seq);
ADD_LABEL(ret, then_label);
ADD_SEQ(ret, then_seq);
ADD_INSNL(ret, line, jump, end_label);
ADD_LABEL(ret, else_label);
ADD_SEQ(ret, else_seq);
ADD_LABEL(ret, end_label);
break;
}
case NODE_CASE:{
NODE *vals;
NODE *tempnode = node;
LABEL *endlabel, *elselabel;
DECL_ANCHOR(head);
DECL_ANCHOR(body_seq);
DECL_ANCHOR(cond_seq);
int only_special_literals = 1;
VALUE literals = rb_hash_new();
INIT_ANCHOR(head);
INIT_ANCHOR(body_seq);
INIT_ANCHOR(cond_seq);
rb_hash_tbl_raw(literals)->type = &cdhash_type;
if (node->nd_head == 0) {
COMPILE_(ret, "when", node->nd_body, poped);
break;
}
COMPILE(head, "case base", node->nd_head);
node = node->nd_body;
type = nd_type(node);
line = nd_line(node);
if (type != NODE_WHEN) {
COMPILE_ERROR(ERROR_ARGS "NODE_CASE: unexpected node. must be NODE_WHEN, but %s", ruby_node_name(type));
debug_node_end();
return COMPILE_NG;
}
endlabel = NEW_LABEL(line);
elselabel = NEW_LABEL(line);
ADD_SEQ(ret, head); /* case VAL */
while (type == NODE_WHEN) {
LABEL *l1;
l1 = NEW_LABEL(line);
ADD_LABEL(body_seq, l1);
ADD_INSN(body_seq, line, pop);
COMPILE_(body_seq, "when body", node->nd_body, poped);
ADD_INSNL(body_seq, line, jump, endlabel);
vals = node->nd_head;
if (vals) {
switch (nd_type(vals)) {
case NODE_ARRAY:
only_special_literals = when_vals(iseq, cond_seq, vals, l1, only_special_literals, literals);
break;
case NODE_SPLAT:
case NODE_ARGSCAT:
case NODE_ARGSPUSH:
only_special_literals = 0;
ADD_INSN (cond_seq, nd_line(vals), dup);
COMPILE(cond_seq, "when/cond splat", vals);
ADD_INSN1(cond_seq, nd_line(vals), checkmatch, INT2FIX(VM_CHECKMATCH_TYPE_CASE | VM_CHECKMATCH_ARRAY));
ADD_INSNL(cond_seq, nd_line(vals), branchif, l1);
break;
default:
UNKNOWN_NODE("NODE_CASE", vals);
}
}
else {
EXPECT_NODE_NONULL("NODE_CASE", node, NODE_ARRAY);
}
node = node->nd_next;
if (!node) {
break;
}
type = nd_type(node);
line = nd_line(node);
}
/* else */
if (node) {
ADD_LABEL(cond_seq, elselabel);
ADD_INSN(cond_seq, line, pop);
COMPILE_(cond_seq, "else", node, poped);
ADD_INSNL(cond_seq, line, jump, endlabel);
}
else {
debugs("== else (implicit)\n");
ADD_LABEL(cond_seq, elselabel);
ADD_INSN(cond_seq, nd_line(tempnode), pop);
if (!poped) {
ADD_INSN(cond_seq, nd_line(tempnode), putnil);
}
ADD_INSNL(cond_seq, nd_line(tempnode), jump, endlabel);
}
if (only_special_literals) {
iseq_add_mark_object(iseq, literals);
ADD_INSN(ret, nd_line(tempnode), dup);
ADD_INSN2(ret, nd_line(tempnode), opt_case_dispatch, literals, elselabel);
LABEL_REF(elselabel);
}
ADD_SEQ(ret, cond_seq);
ADD_SEQ(ret, body_seq);
ADD_LABEL(ret, endlabel);
break;
}
case NODE_WHEN:{
NODE *vals;
NODE *val;
NODE *orig_node = node;
LABEL *endlabel;
DECL_ANCHOR(body_seq);
INIT_ANCHOR(body_seq);
endlabel = NEW_LABEL(line);
while (node && nd_type(node) == NODE_WHEN) {
LABEL *l1 = NEW_LABEL(line = nd_line(node));
ADD_LABEL(body_seq, l1);
COMPILE_(body_seq, "when", node->nd_body, poped);
ADD_INSNL(body_seq, line, jump, endlabel);
vals = node->nd_head;
if (!vals) {
rb_compile_bug_str(ERROR_ARGS "NODE_WHEN: must be NODE_ARRAY, but 0");
}
switch (nd_type(vals)) {
case NODE_ARRAY:
while (vals) {
val = vals->nd_head;
COMPILE(ret, "when2", val);
ADD_INSNL(ret, nd_line(val), branchif, l1);
vals = vals->nd_next;
}
break;
case NODE_SPLAT:
case NODE_ARGSCAT:
case NODE_ARGSPUSH:
ADD_INSN(ret, nd_line(vals), putnil);
COMPILE(ret, "when2/cond splat", vals);
ADD_INSN1(ret, nd_line(vals), checkmatch, INT2FIX(VM_CHECKMATCH_TYPE_WHEN | VM_CHECKMATCH_ARRAY));
ADD_INSNL(ret, nd_line(vals), branchif, l1);
break;
default:
UNKNOWN_NODE("NODE_WHEN", vals);
}
node = node->nd_next;
}
/* else */
COMPILE_(ret, "else", node, poped);
ADD_INSNL(ret, nd_line(orig_node), jump, endlabel);
ADD_SEQ(ret, body_seq);
ADD_LABEL(ret, endlabel);
break;
}
case NODE_OPT_N:
case NODE_WHILE:
case NODE_UNTIL:{
LABEL *prev_start_label = ISEQ_COMPILE_DATA(iseq)->start_label;
LABEL *prev_end_label = ISEQ_COMPILE_DATA(iseq)->end_label;
LABEL *prev_redo_label = ISEQ_COMPILE_DATA(iseq)->redo_label;
int prev_loopval_popped = ISEQ_COMPILE_DATA(iseq)->loopval_popped;
struct iseq_compile_data_ensure_node_stack enl;
LABEL *next_label = ISEQ_COMPILE_DATA(iseq)->start_label = NEW_LABEL(line); /* next */
LABEL *redo_label = ISEQ_COMPILE_DATA(iseq)->redo_label = NEW_LABEL(line); /* redo */
LABEL *break_label = ISEQ_COMPILE_DATA(iseq)->end_label = NEW_LABEL(line); /* break */
LABEL *end_label = NEW_LABEL(line);
LABEL *adjust_label = NEW_LABEL(line);
LABEL *next_catch_label = NEW_LABEL(line);
LABEL *tmp_label = NULL;
ISEQ_COMPILE_DATA(iseq)->loopval_popped = 0;
push_ensure_entry(iseq, &enl, 0, 0);
if (type == NODE_OPT_N || node->nd_state == 1) {
ADD_INSNL(ret, line, jump, next_label);
}
else {
tmp_label = NEW_LABEL(line);
ADD_INSNL(ret, line, jump, tmp_label);
}
ADD_LABEL(ret, adjust_label);
ADD_INSN(ret, line, putnil);
ADD_LABEL(ret, next_catch_label);
ADD_INSN(ret, line, pop);
ADD_INSNL(ret, line, jump, next_label);
if (tmp_label) ADD_LABEL(ret, tmp_label);
ADD_LABEL(ret, redo_label);
COMPILE_POPED(ret, "while body", node->nd_body);
ADD_LABEL(ret, next_label); /* next */
if (type == NODE_WHILE) {
compile_branch_condition(iseq, ret, node->nd_cond,
redo_label, end_label);
}
else if (type == NODE_UNTIL) {
/* until */
compile_branch_condition(iseq, ret, node->nd_cond,
end_label, redo_label);
}
else {
ADD_CALL_RECEIVER(ret, line);
ADD_CALL(ret, line, idGets, INT2FIX(0));
ADD_INSNL(ret, line, branchif, redo_label);
/* opt_n */
}
ADD_LABEL(ret, end_label);
ADD_ADJUST_RESTORE(ret, adjust_label);
if (node->nd_state == Qundef) {
/* ADD_INSN(ret, line, putundef); */
rb_compile_bug_str(ERROR_ARGS "unsupported: putundef");
}
else {
ADD_INSN(ret, line, putnil);
}
ADD_LABEL(ret, break_label); /* break */
if (poped) {
ADD_INSN(ret, line, pop);
}
ADD_CATCH_ENTRY(CATCH_TYPE_BREAK, redo_label, break_label,
0, break_label);
ADD_CATCH_ENTRY(CATCH_TYPE_NEXT, redo_label, break_label, 0,
next_catch_label);
ADD_CATCH_ENTRY(CATCH_TYPE_REDO, redo_label, break_label, 0,
ISEQ_COMPILE_DATA(iseq)->redo_label);
ISEQ_COMPILE_DATA(iseq)->start_label = prev_start_label;
ISEQ_COMPILE_DATA(iseq)->end_label = prev_end_label;
ISEQ_COMPILE_DATA(iseq)->redo_label = prev_redo_label;
ISEQ_COMPILE_DATA(iseq)->loopval_popped = prev_loopval_popped;
ISEQ_COMPILE_DATA(iseq)->ensure_node_stack = ISEQ_COMPILE_DATA(iseq)->ensure_node_stack->prev;
break;
}
case NODE_FOR:
if (node->nd_var) {
/* massign to var in "for"
* args.length == 1 && Array === (tmp = args[0]) ? tmp : args
*/
NODE *var = node->nd_var;
LABEL *not_single = NEW_LABEL(nd_line(var));
LABEL *not_ary = NEW_LABEL(nd_line(var));
COMPILE(ret, "for var", var);
ADD_INSN(ret, line, dup);
ADD_CALL(ret, line, idLength, INT2FIX(0));
ADD_INSN1(ret, line, putobject, INT2FIX(1));
ADD_CALL(ret, line, idEq, INT2FIX(1));
ADD_INSNL(ret, line, branchunless, not_single);
ADD_INSN(ret, line, dup);
ADD_INSN1(ret, line, putobject, INT2FIX(0));
ADD_CALL(ret, line, idAREF, INT2FIX(1));
ADD_INSN1(ret, line, putobject, rb_cArray);
ADD_INSN1(ret, line, topn, INT2FIX(1));
ADD_CALL(ret, line, idEqq, INT2FIX(1));
ADD_INSNL(ret, line, branchunless, not_ary);
ADD_INSN(ret, line, swap);
ADD_LABEL(ret, not_ary);
ADD_INSN(ret, line, pop);
ADD_LABEL(ret, not_single);
break;
}
case NODE_ITER:{
const rb_iseq_t *prevblock = ISEQ_COMPILE_DATA(iseq)->current_block;
LABEL *retry_label = NEW_LABEL(line);
LABEL *retry_end_l = NEW_LABEL(line);
ADD_LABEL(ret, retry_label);
if (nd_type(node) == NODE_FOR) {
COMPILE(ret, "iter caller (for)", node->nd_iter);
ISEQ_COMPILE_DATA(iseq)->current_block = NEW_CHILD_ISEQ(node->nd_body, make_name_for_block(iseq),
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ISEQ_TYPE_BLOCK, line);
ADD_SEND_WITH_BLOCK(ret, line, idEach, INT2FIX(0), ISEQ_COMPILE_DATA(iseq)->current_block);
}
else {
ISEQ_COMPILE_DATA(iseq)->current_block = NEW_CHILD_ISEQ(node->nd_body, make_name_for_block(iseq),
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ISEQ_TYPE_BLOCK, line);
COMPILE(ret, "iter caller", node->nd_iter);
}
ADD_LABEL(ret, retry_end_l);
if (poped) {
ADD_INSN(ret, line, pop);
}
ISEQ_COMPILE_DATA(iseq)->current_block = prevblock;
ADD_CATCH_ENTRY(CATCH_TYPE_BREAK, retry_label, retry_end_l, 0, retry_end_l);
break;
}
case NODE_BREAK:{
unsigned long level = 0;
if (ISEQ_COMPILE_DATA(iseq)->redo_label != 0) {
/* while/until */
LABEL *splabel = NEW_LABEL(0);
ADD_LABEL(ret, splabel);
ADD_ADJUST(ret, line, ISEQ_COMPILE_DATA(iseq)->redo_label);
COMPILE_(ret, "break val (while/until)", node->nd_stts, ISEQ_COMPILE_DATA(iseq)->loopval_popped);
add_ensure_iseq(ret, iseq, 0);
ADD_INSNL(ret, line, jump, ISEQ_COMPILE_DATA(iseq)->end_label);
ADD_ADJUST_RESTORE(ret, splabel);
if (!poped) {
ADD_INSN(ret, line, putnil);
}
}
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else if (iseq->body->type == ISEQ_TYPE_BLOCK) {
break_by_insn:
/* escape from block */
COMPILE(ret, "break val (block)", node->nd_stts);
ADD_INSN1(ret, line, throw, INT2FIX(level | TAG_BREAK));
if (poped) {
ADD_INSN(ret, line, pop);
}
}
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else if (iseq->body->type == ISEQ_TYPE_EVAL) {
break_in_eval:
COMPILE_ERROR(ERROR_ARGS "Can't escape from eval with break");
debug_node_end();
return COMPILE_NG;
}
else {
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const rb_iseq_t *ip = iseq->body->parent_iseq;
while (ip) {
if (!ISEQ_COMPILE_DATA(ip)) {
ip = 0;
break;
}
level++;
if (ISEQ_COMPILE_DATA(ip)->redo_label != 0) {
level = VM_THROW_NO_ESCAPE_FLAG;
goto break_by_insn;
}
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else if (ip->body->type == ISEQ_TYPE_BLOCK) {
level <<= VM_THROW_LEVEL_SHIFT;
goto break_by_insn;
}
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else if (ip->body->type == ISEQ_TYPE_EVAL) {
goto break_in_eval;
}
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ip = ip->body->parent_iseq;
}
COMPILE_ERROR(ERROR_ARGS "Invalid break");
debug_node_end();
return COMPILE_NG;
}
break;
}
case NODE_NEXT:{
unsigned long level = 0;
if (ISEQ_COMPILE_DATA(iseq)->redo_label != 0) {
LABEL *splabel = NEW_LABEL(0);
debugs("next in while loop\n");
ADD_LABEL(ret, splabel);
COMPILE(ret, "next val/valid syntax?", node->nd_stts);
add_ensure_iseq(ret, iseq, 0);
ADD_ADJUST(ret, line, ISEQ_COMPILE_DATA(iseq)->redo_label);
ADD_INSNL(ret, line, jump, ISEQ_COMPILE_DATA(iseq)->start_label);
ADD_ADJUST_RESTORE(ret, splabel);
if (!poped) {
ADD_INSN(ret, line, putnil);
}
}
else if (ISEQ_COMPILE_DATA(iseq)->end_label) {
LABEL *splabel = NEW_LABEL(0);
debugs("next in block\n");
ADD_LABEL(ret, splabel);
ADD_ADJUST(ret, line, ISEQ_COMPILE_DATA(iseq)->start_label);
COMPILE(ret, "next val", node->nd_stts);
add_ensure_iseq(ret, iseq, 0);
ADD_INSNL(ret, line, jump, ISEQ_COMPILE_DATA(iseq)->end_label);
ADD_ADJUST_RESTORE(ret, splabel);
if (!poped) {
ADD_INSN(ret, line, putnil);
}
}
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else if (iseq->body->type == ISEQ_TYPE_EVAL) {
next_in_eval:
COMPILE_ERROR(ERROR_ARGS "Can't escape from eval with next");
}
else {
const rb_iseq_t *ip = iseq;
while (ip) {
if (!ISEQ_COMPILE_DATA(ip)) {
ip = 0;
break;
}
level = VM_THROW_NO_ESCAPE_FLAG;
if (ISEQ_COMPILE_DATA(ip)->redo_label != 0) {
/* while loop */
break;
}
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else if (ip->body->type == ISEQ_TYPE_BLOCK) {
break;
}
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else if (ip->body->type == ISEQ_TYPE_EVAL) {
goto next_in_eval;
}
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ip = ip->body->parent_iseq;
}
if (ip != 0) {
COMPILE(ret, "next val", node->nd_stts);
ADD_INSN1(ret, line, throw, INT2FIX(level | TAG_NEXT));
if (poped) {
ADD_INSN(ret, line, pop);
}
}
else {
COMPILE_ERROR(ERROR_ARGS "Invalid next");
}
}
break;
}
case NODE_REDO:{
if (ISEQ_COMPILE_DATA(iseq)->redo_label) {
LABEL *splabel = NEW_LABEL(0);
debugs("redo in while");
ADD_LABEL(ret, splabel);
ADD_ADJUST(ret, line, ISEQ_COMPILE_DATA(iseq)->redo_label);
add_ensure_iseq(ret, iseq, 0);
ADD_INSNL(ret, line, jump, ISEQ_COMPILE_DATA(iseq)->redo_label);
ADD_ADJUST_RESTORE(ret, splabel);
if (!poped) {
ADD_INSN(ret, line, putnil);
}
}
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else if (iseq->body->type == ISEQ_TYPE_EVAL) {
redo_in_eval:
COMPILE_ERROR(ERROR_ARGS "Can't escape from eval with redo");
}
else if (ISEQ_COMPILE_DATA(iseq)->start_label) {
LABEL *splabel = NEW_LABEL(0);
debugs("redo in block");
ADD_LABEL(ret, splabel);
add_ensure_iseq(ret, iseq, 0);
ADD_ADJUST(ret, line, ISEQ_COMPILE_DATA(iseq)->start_label);
ADD_INSNL(ret, line, jump, ISEQ_COMPILE_DATA(iseq)->start_label);
ADD_ADJUST_RESTORE(ret, splabel);
if (!poped) {
ADD_INSN(ret, line, putnil);
}
}
else {
const rb_iseq_t *ip = iseq;
const unsigned long level = VM_THROW_NO_ESCAPE_FLAG;
while (ip) {
if (!ISEQ_COMPILE_DATA(ip)) {
ip = 0;
break;
}
if (ISEQ_COMPILE_DATA(ip)->redo_label != 0) {
break;
}
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else if (ip->body->type == ISEQ_TYPE_BLOCK) {
break;
}
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else if (ip->body->type == ISEQ_TYPE_EVAL) {
goto redo_in_eval;
}
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ip = ip->body->parent_iseq;
}
if (ip != 0) {
ADD_INSN(ret, line, putnil);
ADD_INSN1(ret, line, throw, INT2FIX(level | TAG_REDO));
if (poped) {
ADD_INSN(ret, line, pop);
}
}
else {
COMPILE_ERROR(ERROR_ARGS "Invalid redo");
}
}
break;
}
case NODE_RETRY:{
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if (iseq->body->type == ISEQ_TYPE_RESCUE) {
ADD_INSN(ret, line, putnil);
ADD_INSN1(ret, line, throw, INT2FIX(TAG_RETRY));
if (poped) {
ADD_INSN(ret, line, pop);
}
}
else {
COMPILE_ERROR(ERROR_ARGS "Invalid retry");
}
break;
}
case NODE_BEGIN:{
COMPILE_(ret, "NODE_BEGIN", node->nd_body, poped);
break;
}
case NODE_RESCUE:{
LABEL *lstart = NEW_LABEL(line);
LABEL *lend = NEW_LABEL(line);
LABEL *lcont = NEW_LABEL(line);
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const rb_iseq_t *rescue = NEW_CHILD_ISEQ(node->nd_resq,
rb_str_concat(rb_str_new2("rescue in "), iseq->body->location.label),
ISEQ_TYPE_RESCUE, line);
ADD_LABEL(ret, lstart);
COMPILE(ret, "rescue head", node->nd_head);
ADD_LABEL(ret, lend);
if (node->nd_else) {
ADD_INSN(ret, line, pop);
COMPILE(ret, "rescue else", node->nd_else);
}
ADD_INSN(ret, line, nop);
ADD_LABEL(ret, lcont);
if (poped) {
ADD_INSN(ret, line, pop);
}
/* register catch entry */
ADD_CATCH_ENTRY(CATCH_TYPE_RESCUE, lstart, lend, rescue, lcont);
ADD_CATCH_ENTRY(CATCH_TYPE_RETRY, lend, lcont, 0, lstart);
break;
}
case NODE_RESBODY:{
NODE *resq = node;
NODE *narg;
LABEL *label_miss, *label_hit;
while (resq) {
label_miss = NEW_LABEL(line);
label_hit = NEW_LABEL(line);
narg = resq->nd_args;
if (narg) {
switch (nd_type(narg)) {
case NODE_ARRAY:
while (narg) {
ADD_INSN2(ret, line, getlocal, INT2FIX(2), INT2FIX(0));
COMPILE(ret, "rescue arg", narg->nd_head);
ADD_INSN1(ret, line, checkmatch, INT2FIX(VM_CHECKMATCH_TYPE_RESCUE));
ADD_INSNL(ret, line, branchif, label_hit);
narg = narg->nd_next;
}
break;
case NODE_SPLAT:
case NODE_ARGSCAT:
case NODE_ARGSPUSH:
ADD_INSN2(ret, line, getlocal, INT2FIX(2), INT2FIX(0));
COMPILE(ret, "rescue/cond splat", narg);
ADD_INSN1(ret, line, checkmatch, INT2FIX(VM_CHECKMATCH_TYPE_RESCUE | VM_CHECKMATCH_ARRAY));
ADD_INSNL(ret, line, branchif, label_hit);
break;
default:
UNKNOWN_NODE("NODE_RESBODY", narg);
}
}
else {
ADD_INSN2(ret, line, getlocal, INT2FIX(2), INT2FIX(0));
ADD_INSN1(ret, line, putobject, rb_eStandardError);
ADD_INSN1(ret, line, checkmatch, INT2FIX(VM_CHECKMATCH_TYPE_RESCUE));
ADD_INSNL(ret, line, branchif, label_hit);
}
ADD_INSNL(ret, line, jump, label_miss);
ADD_LABEL(ret, label_hit);
COMPILE(ret, "resbody body", resq->nd_body);
if (ISEQ_COMPILE_DATA(iseq)->option->tailcall_optimization) {
ADD_INSN(ret, line, nop);
}
ADD_INSN(ret, line, leave);
ADD_LABEL(ret, label_miss);
resq = resq->nd_head;
}
break;
}
case NODE_ENSURE:{
DECL_ANCHOR(ensr);
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const rb_iseq_t *ensure = NEW_CHILD_ISEQ(node->nd_ensr,
rb_str_concat(rb_str_new2 ("ensure in "), iseq->body->location.label),
ISEQ_TYPE_ENSURE, line);
LABEL *lstart = NEW_LABEL(line);
LABEL *lend = NEW_LABEL(line);
LABEL *lcont = NEW_LABEL(line);
struct ensure_range er;
struct iseq_compile_data_ensure_node_stack enl;
struct ensure_range *erange;
INIT_ANCHOR(ensr);
COMPILE_POPED(ensr, "ensure ensr", node->nd_ensr);
er.begin = lstart;
er.end = lend;
er.next = 0;
push_ensure_entry(iseq, &enl, &er, node->nd_ensr);
ADD_LABEL(ret, lstart);
COMPILE_(ret, "ensure head", node->nd_head, poped);
ADD_LABEL(ret, lend);
if (ensr->anchor.next == 0) {
ADD_INSN(ret, line, nop);
}
else {
ADD_SEQ(ret, ensr);
}
ADD_LABEL(ret, lcont);
erange = ISEQ_COMPILE_DATA(iseq)->ensure_node_stack->erange;
while (erange) {
ADD_CATCH_ENTRY(CATCH_TYPE_ENSURE, erange->begin, erange->end,
ensure, lcont);
erange = erange->next;
}
ISEQ_COMPILE_DATA(iseq)->ensure_node_stack = enl.prev;
break;
}
case NODE_AND:
case NODE_OR:{
LABEL *end_label = NEW_LABEL(line);
COMPILE(ret, "nd_1st", node->nd_1st);
if (!poped) {
ADD_INSN(ret, line, dup);
}
if (type == NODE_AND) {
ADD_INSNL(ret, line, branchunless, end_label);
}
else {
ADD_INSNL(ret, line, branchif, end_label);
}
if (!poped) {
ADD_INSN(ret, line, pop);
}
COMPILE_(ret, "nd_2nd", node->nd_2nd, poped);
ADD_LABEL(ret, end_label);
break;
}
case NODE_MASGN:{
compile_massign(iseq, ret, node, poped);
break;
}
case NODE_LASGN:{
ID id = node->nd_vid;
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int idx = iseq->body->local_iseq->body->local_size - get_local_var_idx(iseq, id);
debugs("lvar: %"PRIsVALUE" idx: %d\n", rb_id2str(id), idx);
COMPILE(ret, "rvalue", node->nd_value);
if (!poped) {
ADD_INSN(ret, line, dup);
}
ADD_INSN2(ret, line, setlocal, INT2FIX(idx), INT2FIX(get_lvar_level(iseq)));
break;
}
case NODE_DASGN:
case NODE_DASGN_CURR:{
int idx, lv, ls;
COMPILE(ret, "dvalue", node->nd_value);
debugi("dassn id", rb_id2str(node->nd_vid) ? node->nd_vid : '*');
if (!poped) {
ADD_INSN(ret, line, dup);
}
idx = get_dyna_var_idx(iseq, node->nd_vid, &lv, &ls);
if (idx < 0) {
rb_compile_bug_str(ERROR_ARGS "NODE_DASGN(_CURR): unknown id (%"PRIsVALUE")", rb_id2str(node->nd_vid));
}
ADD_INSN2(ret, line, setlocal, INT2FIX(ls - idx), INT2FIX(lv));
break;
}
case NODE_GASGN:{
COMPILE(ret, "lvalue", node->nd_value);
if (!poped) {
ADD_INSN(ret, line, dup);
}
ADD_INSN1(ret, line, setglobal,
((VALUE)node->nd_entry | 1));
break;
}
case NODE_IASGN:
case NODE_IASGN2:{
COMPILE(ret, "lvalue", node->nd_value);
if (!poped) {
ADD_INSN(ret, line, dup);
}
ADD_INSN2(ret, line, setinstancevariable,
2015-07-22 01:52:59 +03:00
ID2SYM(node->nd_vid), INT2FIX(iseq->body->is_size++));
break;
}
case NODE_CDECL:{
COMPILE(ret, "lvalue", node->nd_value);
if (!poped) {
ADD_INSN(ret, line, dup);
}
if (node->nd_vid) {
ADD_INSN1(ret, line, putspecialobject,
INT2FIX(VM_SPECIAL_OBJECT_CONST_BASE));
ADD_INSN1(ret, line, setconstant, ID2SYM(node->nd_vid));
}
else {
compile_cpath(ret, iseq, node->nd_else);
ADD_INSN1(ret, line, setconstant, ID2SYM(node->nd_else->nd_mid));
}
break;
}
case NODE_CVASGN:{
COMPILE(ret, "cvasgn val", node->nd_value);
if (!poped) {
ADD_INSN(ret, line, dup);
}
ADD_INSN1(ret, line, setclassvariable,
ID2SYM(node->nd_vid));
break;
}
case NODE_OP_ASGN1: {
DECL_ANCHOR(args);
VALUE argc;
unsigned int flag = 0;
unsigned int asgnflag = 0;
ID id = node->nd_mid;
int boff = 0;
/*
* a[x] (op)= y
*
* nil # nil
* eval a # nil a
* eval x # nil a x
* dupn 2 # nil a x a x
* send :[] # nil a x a[x]
* eval y # nil a x a[x] y
* send op # nil a x ret
* setn 3 # ret a x ret
* send []= # ret ?
* pop # ret
*/
/*
* nd_recv[nd_args->nd_body] (nd_mid)= nd_args->nd_head;
* NODE_OP_ASGN nd_recv
* nd_args->nd_head
* nd_args->nd_body
* nd_mid
*/
if (!poped) {
ADD_INSN(ret, line, putnil);
}
asgnflag = COMPILE_RECV(ret, "NODE_OP_ASGN1 recv", node);
switch (nd_type(node->nd_args->nd_head)) {
case NODE_ZARRAY:
argc = INT2FIX(0);
break;
case NODE_BLOCK_PASS:
boff = 1;
default:
INIT_ANCHOR(args);
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
argc = setup_args(iseq, args, node->nd_args->nd_head, &flag, NULL);
ADD_SEQ(ret, args);
}
ADD_INSN1(ret, line, dupn, FIXNUM_INC(argc, 1 + boff));
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_SEND_WITH_FLAG(ret, line, idAREF, argc, INT2FIX(flag));
flag |= asgnflag;
if (id == 0 || id == 1) {
/* 0: or, 1: and
a[x] ||= y
unless/if a[x]
a[x]= y
else
nil
end
*/
LABEL *label = NEW_LABEL(line);
LABEL *lfin = NEW_LABEL(line);
ADD_INSN(ret, line, dup);
if (id == 0) {
/* or */
ADD_INSNL(ret, line, branchif, label);
}
else {
/* and */
ADD_INSNL(ret, line, branchunless, label);
}
ADD_INSN(ret, line, pop);
COMPILE(ret, "NODE_OP_ASGN1 args->body: ", node->nd_args->nd_body);
if (!poped) {
ADD_INSN1(ret, line, setn, FIXNUM_INC(argc, 2+boff));
}
if (flag & VM_CALL_ARGS_SPLAT) {
ADD_INSN1(ret, line, newarray, INT2FIX(1));
if (boff > 0) {
ADD_INSN1(ret, line, dupn, INT2FIX(3));
ADD_INSN(ret, line, swap);
ADD_INSN(ret, line, pop);
}
ADD_INSN(ret, line, concatarray);
if (boff > 0) {
ADD_INSN1(ret, line, setn, INT2FIX(3));
ADD_INSN(ret, line, pop);
ADD_INSN(ret, line, pop);
}
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_SEND_WITH_FLAG(ret, line, idASET, argc, INT2FIX(flag));
}
else {
if (boff > 0)
ADD_INSN(ret, line, swap);
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_SEND_WITH_FLAG(ret, line, idASET, FIXNUM_INC(argc, 1), INT2FIX(flag));
}
ADD_INSN(ret, line, pop);
ADD_INSNL(ret, line, jump, lfin);
ADD_LABEL(ret, label);
if (!poped) {
ADD_INSN1(ret, line, setn, FIXNUM_INC(argc, 2+boff));
}
ADD_INSN1(ret, line, adjuststack, FIXNUM_INC(argc, 2+boff));
ADD_LABEL(ret, lfin);
}
else {
COMPILE(ret, "NODE_OP_ASGN1 args->body: ", node->nd_args->nd_body);
ADD_SEND(ret, line, id, INT2FIX(1));
if (!poped) {
ADD_INSN1(ret, line, setn, FIXNUM_INC(argc, 2+boff));
}
if (flag & VM_CALL_ARGS_SPLAT) {
ADD_INSN1(ret, line, newarray, INT2FIX(1));
if (boff > 0) {
ADD_INSN1(ret, line, dupn, INT2FIX(3));
ADD_INSN(ret, line, swap);
ADD_INSN(ret, line, pop);
}
ADD_INSN(ret, line, concatarray);
if (boff > 0) {
ADD_INSN1(ret, line, setn, INT2FIX(3));
ADD_INSN(ret, line, pop);
ADD_INSN(ret, line, pop);
}
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_SEND_WITH_FLAG(ret, line, idASET, argc, INT2FIX(flag));
}
else {
if (boff > 0)
ADD_INSN(ret, line, swap);
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_SEND_WITH_FLAG(ret, line, idASET, FIXNUM_INC(argc, 1), INT2FIX(flag));
}
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_OP_ASGN2:{
ID atype = node->nd_next->nd_mid;
ID vid = node->nd_next->nd_vid, aid = rb_id_attrset(vid);
VALUE asgnflag;
LABEL *lfin = NEW_LABEL(line);
LABEL *lcfin = NEW_LABEL(line);
LABEL *lskip = 0;
/*
class C; attr_accessor :c; end
r = C.new
r.a &&= v # asgn2
eval r # r
dup # r r
eval r.a # r o
# or
dup # r o o
if lcfin # r o
pop # r
eval v # r v
swap # v r
topn 1 # v r v
send a= # v ?
jump lfin # v ?
lcfin: # r o
swap # o r
lfin: # o ?
pop # o
# and
dup # r o o
unless lcfin
pop # r
eval v # r v
swap # v r
topn 1 # v r v
send a= # v ?
jump lfin # v ?
# others
eval v # r o v
send ?? # r w
send a= # w
*/
asgnflag = COMPILE_RECV(ret, "NODE_OP_ASGN2#recv", node);
if (node->nd_next->nd_aid) {
lskip = NEW_LABEL(line);
ADD_INSN(ret, line, dup);
ADD_INSNL(ret, line, branchnil, lskip);
}
ADD_INSN(ret, line, dup);
ADD_SEND(ret, line, vid, INT2FIX(0));
if (atype == 0 || atype == 1) { /* 0: OR or 1: AND */
ADD_INSN(ret, line, dup);
if (atype == 0) {
ADD_INSNL(ret, line, branchif, lcfin);
}
else {
ADD_INSNL(ret, line, branchunless, lcfin);
}
ADD_INSN(ret, line, pop);
COMPILE(ret, "NODE_OP_ASGN2 val", node->nd_value);
ADD_INSN(ret, line, swap);
ADD_INSN1(ret, line, topn, INT2FIX(1));
ADD_SEND_WITH_FLAG(ret, line, aid, INT2FIX(1), INT2FIX(asgnflag));
ADD_INSNL(ret, line, jump, lfin);
ADD_LABEL(ret, lcfin);
ADD_INSN(ret, line, swap);
ADD_LABEL(ret, lfin);
ADD_INSN(ret, line, pop);
if (lskip) {
ADD_LABEL(ret, lskip);
}
if (poped) {
/* we can apply more optimize */
ADD_INSN(ret, line, pop);
}
}
else {
COMPILE(ret, "NODE_OP_ASGN2 val", node->nd_value);
ADD_SEND(ret, line, atype, INT2FIX(1));
if (!poped) {
ADD_INSN(ret, line, swap);
ADD_INSN1(ret, line, topn, INT2FIX(1));
}
ADD_SEND_WITH_FLAG(ret, line, aid, INT2FIX(1), INT2FIX(asgnflag));
ADD_INSN(ret, line, pop);
if (lskip) {
ADD_LABEL(ret, lskip);
}
}
break;
}
case NODE_OP_CDECL: {
LABEL *lfin = 0;
LABEL *lassign = 0;
ID mid;
switch (nd_type(node->nd_head)) {
case NODE_COLON3:
ADD_INSN1(ret, line, putobject, rb_cObject);
break;
case NODE_COLON2:
COMPILE(ret, "NODE_OP_CDECL/colon2#nd_head", node->nd_head->nd_head);
break;
default:
COMPILE_ERROR(ERROR_ARGS "%s: invalid node in NODE_OP_CDECL",
ruby_node_name(nd_type(node->nd_head)));
debug_node_end();
return COMPILE_NG;
}
mid = node->nd_head->nd_mid;
/* cref */
if (node->nd_aid == 0) {
lassign = NEW_LABEL(line);
ADD_INSN(ret, line, dup); /* cref cref */
ADD_INSN3(ret, line, defined, INT2FIX(DEFINED_CONST),
ID2SYM(mid), Qfalse); /* cref bool */
ADD_INSNL(ret, line, branchunless, lassign); /* cref */
}
ADD_INSN(ret, line, dup); /* cref cref */
ADD_INSN1(ret, line, getconstant, ID2SYM(mid)); /* cref obj */
if (node->nd_aid == 0 || node->nd_aid == 1) {
lfin = NEW_LABEL(line);
if (!poped) ADD_INSN(ret, line, dup); /* cref [obj] obj */
if (node->nd_aid == 0)
ADD_INSNL(ret, line, branchif, lfin);
else
ADD_INSNL(ret, line, branchunless, lfin);
/* cref [obj] */
if (!poped) ADD_INSN(ret, line, pop); /* cref */
if (lassign) ADD_LABEL(ret, lassign);
COMPILE(ret, "NODE_OP_CDECL#nd_value", node->nd_value);
/* cref value */
if (poped)
ADD_INSN1(ret, line, topn, INT2FIX(1)); /* cref value cref */
else {
ADD_INSN1(ret, line, dupn, INT2FIX(2)); /* cref value cref value */
ADD_INSN(ret, line, swap); /* cref value value cref */
}
ADD_INSN1(ret, line, setconstant, ID2SYM(mid)); /* cref [value] */
ADD_LABEL(ret, lfin); /* cref [value] */
if (!poped) ADD_INSN(ret, line, swap); /* [value] cref */
ADD_INSN(ret, line, pop); /* [value] */
}
else {
COMPILE(ret, "NODE_OP_CDECL#nd_value", node->nd_value);
/* cref obj value */
ADD_CALL(ret, line, node->nd_aid, INT2FIX(1));
/* cref value */
ADD_INSN(ret, line, swap); /* value cref */
if (!poped) {
ADD_INSN1(ret, line, topn, INT2FIX(1)); /* value cref value */
ADD_INSN(ret, line, swap); /* value value cref */
}
ADD_INSN1(ret, line, setconstant, ID2SYM(mid));
}
break;
}
case NODE_OP_ASGN_AND:
case NODE_OP_ASGN_OR:{
LABEL *lfin = NEW_LABEL(line);
LABEL *lassign;
if (nd_type(node) == NODE_OP_ASGN_OR) {
LABEL *lfinish[2];
lfinish[0] = lfin;
lfinish[1] = 0;
defined_expr(iseq, ret, node->nd_head, lfinish, Qfalse);
lassign = lfinish[1];
if (!lassign) {
lassign = NEW_LABEL(line);
}
ADD_INSNL(ret, line, branchunless, lassign);
}
else {
lassign = NEW_LABEL(line);
}
COMPILE(ret, "NODE_OP_ASGN_AND/OR#nd_head", node->nd_head);
ADD_INSN(ret, line, dup);
if (nd_type(node) == NODE_OP_ASGN_AND) {
ADD_INSNL(ret, line, branchunless, lfin);
}
else {
ADD_INSNL(ret, line, branchif, lfin);
}
ADD_INSN(ret, line, pop);
ADD_LABEL(ret, lassign);
COMPILE(ret, "NODE_OP_ASGN_AND/OR#nd_value", node->nd_value);
ADD_LABEL(ret, lfin);
if (poped) {
/* we can apply more optimize */
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_CALL:
/* optimization shortcut
* "literal".freeze -> opt_str_freeze("literal")
*/
if (node->nd_recv && nd_type(node->nd_recv) == NODE_STR &&
node->nd_mid == idFreeze && node->nd_args == NULL &&
ISEQ_COMPILE_DATA(iseq)->current_block == NULL &&
ISEQ_COMPILE_DATA(iseq)->option->specialized_instruction) {
VALUE str = rb_fstring(node->nd_recv->nd_lit);
iseq_add_mark_object(iseq, str);
ADD_INSN1(ret, line, opt_str_freeze, str);
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
/* optimization shortcut
* obj["literal"] -> opt_aref_with(obj, "literal")
*/
if (node->nd_mid == idAREF && !private_recv_p(node) && node->nd_args &&
nd_type(node->nd_args) == NODE_ARRAY && node->nd_args->nd_alen == 1 &&
nd_type(node->nd_args->nd_head) == NODE_STR &&
ISEQ_COMPILE_DATA(iseq)->current_block == NULL &&
ISEQ_COMPILE_DATA(iseq)->option->specialized_instruction) {
VALUE str = rb_fstring(node->nd_args->nd_head->nd_lit);
node->nd_args->nd_head->nd_lit = str;
COMPILE(ret, "recv", node->nd_recv);
ADD_INSN3(ret, line, opt_aref_with,
new_callinfo(iseq, idAREF, 1, 0, NULL, FALSE),
NULL/* CALL_CACHE */, str);
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_QCALL:
case NODE_FCALL:
case NODE_VCALL:{ /* VCALL: variable or call */
/*
call: obj.method(...)
fcall: func(...)
vcall: func
*/
DECL_ANCHOR(recv);
DECL_ANCHOR(args);
LABEL *lskip = 0;
ID mid = node->nd_mid;
VALUE argc;
unsigned int flag = 0;
struct rb_call_info_kw_arg *keywords = NULL;
const rb_iseq_t *parent_block = ISEQ_COMPILE_DATA(iseq)->current_block;
ISEQ_COMPILE_DATA(iseq)->current_block = NULL;
INIT_ANCHOR(recv);
INIT_ANCHOR(args);
#if SUPPORT_JOKE
if (nd_type(node) == NODE_VCALL) {
ID id_bitblt;
ID id_answer;
CONST_ID(id_bitblt, "bitblt");
CONST_ID(id_answer, "the_answer_to_life_the_universe_and_everything");
if (mid == id_bitblt) {
ADD_INSN(ret, line, bitblt);
break;
}
else if (mid == id_answer) {
ADD_INSN(ret, line, answer);
break;
}
}
/* only joke */
{
ID goto_id;
ID label_id;
CONST_ID(goto_id, "__goto__");
CONST_ID(label_id, "__label__");
if (nd_type(node) == NODE_FCALL &&
(mid == goto_id || mid == label_id)) {
LABEL *label;
st_data_t data;
st_table *labels_table = ISEQ_COMPILE_DATA(iseq)->labels_table;
ID label_name;
if (!labels_table) {
labels_table = st_init_numtable();
ISEQ_COMPILE_DATA(iseq)->labels_table = labels_table;
}
if (nd_type(node->nd_args->nd_head) == NODE_LIT &&
SYMBOL_P(node->nd_args->nd_head->nd_lit)) {
label_name = SYM2ID(node->nd_args->nd_head->nd_lit);
if (!st_lookup(labels_table, (st_data_t)label_name, &data)) {
label = NEW_LABEL(line);
label->position = line;
st_insert(labels_table, (st_data_t)label_name, (st_data_t)label);
}
else {
label = (LABEL *)data;
}
}
else {
COMPILE_ERROR(ERROR_ARGS "invalid goto/label format");
}
if (mid == goto_id) {
ADD_INSNL(ret, line, jump, label);
}
else {
ADD_LABEL(ret, label);
}
break;
}
}
#endif
/* receiver */
if (type == NODE_CALL || type == NODE_QCALL) {
COMPILE(recv, "recv", node->nd_recv);
if (type == NODE_QCALL) {
lskip = NEW_LABEL(line);
ADD_INSN(recv, line, dup);
ADD_INSNL(recv, line, branchnil, lskip);
}
}
else if (type == NODE_FCALL || type == NODE_VCALL) {
ADD_CALL_RECEIVER(recv, line);
}
/* args */
if (nd_type(node) != NODE_VCALL) {
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
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argc = setup_args(iseq, args, node->nd_args, &flag, &keywords);
}
else {
argc = INT2FIX(0);
}
ADD_SEQ(ret, recv);
ADD_SEQ(ret, args);
debugp_param("call args argc", argc);
debugp_param("call method", ID2SYM(mid));
switch (nd_type(node)) {
case NODE_VCALL:
flag |= VM_CALL_VCALL;
/* VCALL is funcall, so fall through */
case NODE_FCALL:
flag |= VM_CALL_FCALL;
}
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_SEND_R(ret, line, mid, argc, parent_block, INT2FIX(flag), keywords);
if (lskip) {
ADD_LABEL(ret, lskip);
}
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_SUPER:
case NODE_ZSUPER:{
DECL_ANCHOR(args);
int argc;
unsigned int flag = 0;
struct rb_call_info_kw_arg *keywords = NULL;
const rb_iseq_t *parent_block = ISEQ_COMPILE_DATA(iseq)->current_block;
INIT_ANCHOR(args);
ISEQ_COMPILE_DATA(iseq)->current_block = NULL;
if (nd_type(node) == NODE_SUPER) {
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
VALUE vargc = setup_args(iseq, args, node->nd_args, &flag, &keywords);
argc = FIX2INT(vargc);
}
else {
/* NODE_ZSUPER */
int i;
2015-07-22 01:52:59 +03:00
const rb_iseq_t *liseq = iseq->body->local_iseq;
int lvar_level = get_lvar_level(iseq);
2015-07-22 01:52:59 +03:00
argc = liseq->body->param.lead_num;
/* normal arguments */
2015-07-22 01:52:59 +03:00
for (i = 0; i < liseq->body->param.lead_num; i++) {
int idx = liseq->body->local_size - i;
ADD_INSN2(args, line, getlocal, INT2FIX(idx), INT2FIX(lvar_level));
}
2015-07-22 01:52:59 +03:00
if (liseq->body->param.flags.has_opt) {
/* optional arguments */
int j;
2015-07-22 01:52:59 +03:00
for (j = 0; j < liseq->body->param.opt_num; j++) {
int idx = liseq->body->local_size - (i + j);
ADD_INSN2(args, line, getlocal, INT2FIX(idx), INT2FIX(lvar_level));
}
i += j;
argc = i;
}
2015-07-22 01:52:59 +03:00
if (liseq->body->param.flags.has_rest) {
/* rest argument */
2015-07-22 01:52:59 +03:00
int idx = liseq->body->local_size - liseq->body->param.rest_start;
ADD_INSN2(args, line, getlocal, INT2FIX(idx), INT2FIX(lvar_level));
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argc = liseq->body->param.rest_start + 1;
flag |= VM_CALL_ARGS_SPLAT;
}
2015-07-22 01:52:59 +03:00
if (liseq->body->param.flags.has_post) {
/* post arguments */
2015-07-22 01:52:59 +03:00
int post_len = liseq->body->param.post_num;
int post_start = liseq->body->param.post_start;
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if (liseq->body->param.flags.has_rest) {
int j;
for (j=0; j<post_len; j++) {
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int idx = liseq->body->local_size - (post_start + j);
ADD_INSN2(args, line, getlocal, INT2FIX(idx), INT2FIX(lvar_level));
}
ADD_INSN1(args, line, newarray, INT2FIX(j));
ADD_INSN (args, line, concatarray);
/* argc is settled at above */
}
else {
int j;
for (j=0; j<post_len; j++) {
2015-07-22 01:52:59 +03:00
int idx = liseq->body->local_size - (post_start + j);
ADD_INSN2(args, line, getlocal, INT2FIX(idx), INT2FIX(lvar_level));
}
argc = post_len + post_start;
}
}
2015-07-22 01:52:59 +03:00
if (liseq->body->param.flags.has_kw) { /* TODO: support keywords */
int local_size = liseq->body->local_size;
argc++;
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_INSN1(args, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
2015-07-22 01:52:59 +03:00
if (liseq->body->param.flags.has_kwrest) {
ADD_INSN2(args, line, getlocal, INT2FIX(liseq->body->local_size - liseq->body->param.keyword->rest_start), INT2FIX(lvar_level));
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_SEND (args, line, rb_intern("dup"), INT2FIX(0));
}
else {
ADD_INSN1(args, line, newhash, INT2FIX(0));
}
2015-07-22 01:52:59 +03:00
for (i = 0; i < liseq->body->param.keyword->num; ++i) {
ID id = liseq->body->param.keyword->table[i];
int idx = local_size - get_local_var_idx(liseq, id);
ADD_INSN1(args, line, putobject, ID2SYM(id));
ADD_INSN2(args, line, getlocal, INT2FIX(idx), INT2FIX(lvar_level));
}
ADD_SEND(args, line, id_core_hash_merge_ptr, INT2FIX(i * 2 + 1));
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if (liseq->body->param.flags.has_rest) {
ADD_INSN1(args, line, newarray, INT2FIX(1));
ADD_INSN (args, line, concatarray);
--argc;
}
}
2015-07-22 01:52:59 +03:00
else if (liseq->body->param.flags.has_kwrest) {
ADD_INSN2(args, line, getlocal, INT2FIX(liseq->body->local_size - liseq->body->param.keyword->rest_start), INT2FIX(lvar_level));
ADD_SEND (args, line, rb_intern("dup"), INT2FIX(0));
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if (liseq->body->param.flags.has_rest) {
ADD_INSN1(args, line, newarray, INT2FIX(1));
ADD_INSN (args, line, concatarray);
}
else {
argc++;
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
}
}
}
/* dummy receiver */
ADD_INSN1(ret, line, putobject, nd_type(node) == NODE_ZSUPER ? Qfalse : Qtrue);
ADD_SEQ(ret, args);
ADD_INSN3(ret, line, invokesuper,
new_callinfo(iseq, 0, argc, flag | VM_CALL_SUPER | VM_CALL_FCALL, keywords, parent_block != NULL),
Qnil, /* CALL_CACHE */
parent_block);
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_ARRAY:{
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
compile_array_(iseq, ret, node, COMPILE_ARRAY_TYPE_ARRAY, NULL, poped);
break;
}
case NODE_ZARRAY:{
if (!poped) {
ADD_INSN1(ret, line, newarray, INT2FIX(0));
}
break;
}
case NODE_VALUES:{
NODE *n = node;
while (n) {
COMPILE(ret, "values item", n->nd_head);
n = n->nd_next;
}
ADD_INSN1(ret, line, newarray, INT2FIX(node->nd_alen));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_HASH:{
DECL_ANCHOR(list);
int type = node->nd_head ? nd_type(node->nd_head) : NODE_ZARRAY;
INIT_ANCHOR(list);
switch (type) {
case NODE_ARRAY:
compile_array(iseq, list, node->nd_head, COMPILE_ARRAY_TYPE_HASH);
ADD_SEQ(ret, list);
break;
case NODE_ZARRAY:
ADD_INSN1(ret, line, newhash, INT2FIX(0));
break;
default:
rb_compile_bug_str(ERROR_ARGS_AT(node->nd_head) "can't make hash with this node: %s",
ruby_node_name(type));
}
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_RETURN:{
rb_iseq_t *is = iseq;
if (is) {
2015-07-22 01:52:59 +03:00
if (is->body->type == ISEQ_TYPE_TOP) {
COMPILE_ERROR(ERROR_ARGS "Invalid return");
}
else {
LABEL *splabel = 0;
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if (is->body->type == ISEQ_TYPE_METHOD) {
splabel = NEW_LABEL(0);
ADD_LABEL(ret, splabel);
ADD_ADJUST(ret, line, 0);
}
COMPILE(ret, "return nd_stts (return val)", node->nd_stts);
2015-07-22 01:52:59 +03:00
if (is->body->type == ISEQ_TYPE_METHOD) {
add_ensure_iseq(ret, iseq, 1);
ADD_TRACE(ret, line, RUBY_EVENT_RETURN);
ADD_INSN(ret, line, leave);
ADD_ADJUST_RESTORE(ret, splabel);
if (!poped) {
ADD_INSN(ret, line, putnil);
}
}
else {
ADD_INSN1(ret, line, throw, INT2FIX(TAG_RETURN));
if (poped) {
ADD_INSN(ret, line, pop);
}
}
}
}
break;
}
case NODE_YIELD:{
DECL_ANCHOR(args);
VALUE argc;
unsigned int flag = 0;
struct rb_call_info_kw_arg *keywords = NULL;
INIT_ANCHOR(args);
2015-07-22 01:52:59 +03:00
if (iseq->body->type == ISEQ_TYPE_TOP) {
COMPILE_ERROR(ERROR_ARGS "Invalid yield");
debug_node_end();
return COMPILE_NG;
}
if (node->nd_head) {
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
argc = setup_args(iseq, args, node->nd_head, &flag, &keywords);
}
else {
argc = INT2FIX(0);
}
ADD_SEQ(ret, args);
ADD_INSN1(ret, line, invokeblock, new_callinfo(iseq, 0, FIX2INT(argc), flag, keywords, FALSE));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_LVAR:{
if (!poped) {
ID id = node->nd_vid;
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int idx = iseq->body->local_iseq->body->local_size - get_local_var_idx(iseq, id);
debugs("id: %"PRIsVALUE" idx: %d\n", rb_id2str(id), idx);
ADD_INSN2(ret, line, getlocal, INT2FIX(idx), INT2FIX(get_lvar_level(iseq)));
}
break;
}
case NODE_DVAR:{
int lv, idx, ls;
debugi("nd_vid", node->nd_vid);
if (!poped) {
idx = get_dyna_var_idx(iseq, node->nd_vid, &lv, &ls);
if (idx < 0) {
rb_compile_bug_str(ERROR_ARGS "unknown dvar (%"PRIsVALUE")", rb_id2str(node->nd_vid));
}
ADD_INSN2(ret, line, getlocal, INT2FIX(ls - idx), INT2FIX(lv));
}
break;
}
case NODE_GVAR:{
ADD_INSN1(ret, line, getglobal,
((VALUE)node->nd_entry | 1));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_IVAR:{
debugi("nd_vid", node->nd_vid);
if (!poped) {
ADD_INSN2(ret, line, getinstancevariable,
2015-07-22 01:52:59 +03:00
ID2SYM(node->nd_vid), INT2FIX(iseq->body->is_size++));
}
break;
}
case NODE_CONST:{
debugi("nd_vid", node->nd_vid);
if (ISEQ_COMPILE_DATA(iseq)->option->inline_const_cache) {
LABEL *lend = NEW_LABEL(line);
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int ic_index = iseq->body->is_size++;
ADD_INSN2(ret, line, getinlinecache, lend, INT2FIX(ic_index));
ADD_INSN1(ret, line, getconstant, ID2SYM(node->nd_vid));
ADD_INSN1(ret, line, setinlinecache, INT2FIX(ic_index));
ADD_LABEL(ret, lend);
}
else {
ADD_INSN(ret, line, putnil);
ADD_INSN1(ret, line, getconstant, ID2SYM(node->nd_vid));
}
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_CVAR:{
if (!poped) {
ADD_INSN1(ret, line, getclassvariable,
ID2SYM(node->nd_vid));
}
break;
}
case NODE_NTH_REF:{
if (!poped) {
if (!node->nd_nth) {
ADD_INSN(ret, line, putnil);
break;
}
ADD_INSN2(ret, line, getspecial, INT2FIX(1) /* '~' */,
INT2FIX(node->nd_nth << 1));
}
break;
}
case NODE_BACK_REF:{
if (!poped) {
ADD_INSN2(ret, line, getspecial, INT2FIX(1) /* '~' */,
INT2FIX(0x01 | (node->nd_nth << 1)));
}
break;
}
case NODE_MATCH:
case NODE_MATCH2:
case NODE_MATCH3:{
DECL_ANCHOR(recv);
DECL_ANCHOR(val);
INIT_ANCHOR(recv);
INIT_ANCHOR(val);
switch (nd_type(node)) {
case NODE_MATCH:
ADD_INSN1(recv, line, putobject, node->nd_lit);
ADD_INSN2(val, line, getspecial, INT2FIX(0),
INT2FIX(0));
break;
case NODE_MATCH2:
COMPILE(recv, "receiver", node->nd_recv);
COMPILE(val, "value", node->nd_value);
break;
case NODE_MATCH3:
COMPILE(recv, "receiver", node->nd_value);
COMPILE(val, "value", node->nd_recv);
break;
}
if (ISEQ_COMPILE_DATA(iseq)->option->specialized_instruction) {
/* TODO: detect by node */
if (recv->last == recv->anchor.next &&
INSN_OF(recv->last) == BIN(putobject) &&
nd_type(node) == NODE_MATCH2) {
ADD_SEQ(ret, val);
ADD_INSN1(ret, line, opt_regexpmatch1,
OPERAND_AT(recv->last, 0));
}
else {
ADD_SEQ(ret, recv);
ADD_SEQ(ret, val);
ADD_INSN2(ret, line, opt_regexpmatch2, new_callinfo(iseq, idEqTilde, 1, 0, NULL, FALSE), Qnil);
}
}
else {
ADD_SEQ(ret, recv);
ADD_SEQ(ret, val);
ADD_SEND(ret, line, idEqTilde, INT2FIX(1));
}
if (node->nd_args) {
compile_named_capture_assign(iseq, ret, node->nd_args);
}
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_LIT:{
debugp_param("lit", node->nd_lit);
if (!poped) {
ADD_INSN1(ret, line, putobject, node->nd_lit);
}
break;
}
case NODE_STR:{
debugp_param("nd_lit", node->nd_lit);
if (!poped) {
node->nd_lit = rb_fstring(node->nd_lit);
if (!ISEQ_COMPILE_DATA(iseq)->option->frozen_string_literal) {
ADD_INSN1(ret, line, putstring, node->nd_lit);
}
else {
if (ISEQ_COMPILE_DATA(iseq)->option->debug_frozen_string_literal || RTEST(ruby_debug)) {
VALUE debug_info = rb_ary_new_from_args(2, iseq->body->location.path, INT2FIX(line));
VALUE str = rb_str_dup(node->nd_lit);
rb_ivar_set(str, id_debug_created_info, rb_obj_freeze(debug_info));
ADD_INSN1(ret, line, putobject, rb_obj_freeze(str));
iseq_add_mark_object_compile_time(iseq, str);
}
else {
ADD_INSN1(ret, line, putobject, node->nd_lit);
}
}
}
break;
}
case NODE_DSTR:{
compile_dstr(iseq, ret, node);
if (poped) {
ADD_INSN(ret, line, pop);
}
else {
if (ISEQ_COMPILE_DATA(iseq)->option->frozen_string_literal) {
VALUE debug_info = Qnil;
if (ISEQ_COMPILE_DATA(iseq)->option->debug_frozen_string_literal || RTEST(ruby_debug)) {
debug_info = rb_ary_new_from_args(2, iseq->body->location.path, INT2FIX(line));
iseq_add_mark_object_compile_time(iseq, rb_obj_freeze(debug_info));
}
ADD_INSN1(ret, line, freezestring, debug_info);
}
}
break;
}
case NODE_XSTR:{
node->nd_lit = rb_fstring(node->nd_lit);
ADD_CALL_RECEIVER(ret, line);
ADD_INSN1(ret, line, putobject, node->nd_lit);
ADD_CALL(ret, line, idBackquote, INT2FIX(1));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_DXSTR:{
ADD_CALL_RECEIVER(ret, line);
compile_dstr(iseq, ret, node);
ADD_CALL(ret, line, idBackquote, INT2FIX(1));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_EVSTR:{
COMPILE(ret, "nd_body", node->nd_body);
if (poped) {
ADD_INSN(ret, line, pop);
}
else {
ADD_INSN(ret, line, tostring);
}
break;
}
case NODE_DREGX:{
compile_dregx(iseq, ret, node);
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_DREGX_ONCE:{
2015-07-22 01:52:59 +03:00
int ic_index = iseq->body->is_size++;
NODE *dregx_node = NEW_NODE(NODE_DREGX, node->u1.value, node->u2.value, node->u3.value);
NODE *block_node = NEW_NODE(NODE_SCOPE, 0, dregx_node, 0);
2015-07-22 01:52:59 +03:00
const rb_iseq_t * block_iseq = NEW_CHILD_ISEQ(block_node, make_name_for_block(iseq), ISEQ_TYPE_BLOCK, line);
ADD_INSN2(ret, line, once, block_iseq, INT2FIX(ic_index));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_ARGSCAT:{
if (poped) {
COMPILE(ret, "argscat head", node->nd_head);
ADD_INSN1(ret, line, splatarray, Qfalse);
ADD_INSN(ret, line, pop);
COMPILE(ret, "argscat body", node->nd_body);
ADD_INSN1(ret, line, splatarray, Qfalse);
ADD_INSN(ret, line, pop);
}
else {
COMPILE(ret, "argscat head", node->nd_head);
COMPILE(ret, "argscat body", node->nd_body);
ADD_INSN(ret, line, concatarray);
}
break;
}
case NODE_ARGSPUSH:{
if (poped) {
COMPILE(ret, "arsgpush head", node->nd_head);
ADD_INSN1(ret, line, splatarray, Qfalse);
ADD_INSN(ret, line, pop);
COMPILE_(ret, "argspush body", node->nd_body, poped);
}
else {
COMPILE(ret, "arsgpush head", node->nd_head);
COMPILE_(ret, "argspush body", node->nd_body, poped);
ADD_INSN1(ret, line, newarray, INT2FIX(1));
ADD_INSN(ret, line, concatarray);
}
break;
}
case NODE_SPLAT:{
COMPILE(ret, "splat", node->nd_head);
ADD_INSN1(ret, line, splatarray, Qtrue);
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_DEFN:{
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const rb_iseq_t *method_iseq = NEW_ISEQ(node->nd_defn,
rb_id2str(node->nd_mid),
ISEQ_TYPE_METHOD, line);
debugp_param("defn/iseq", rb_iseqw_new(method_iseq));
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
ADD_INSN1(ret, line, putobject, ID2SYM(node->nd_mid));
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ADD_INSN1(ret, line, putiseq, method_iseq);
ADD_SEND (ret, line, id_core_define_method, INT2FIX(2));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_DEFS:{
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const rb_iseq_t * singleton_method = NEW_ISEQ(node->nd_defn,
rb_id2str(node->nd_mid),
ISEQ_TYPE_METHOD, line);
debugp_param("defs/iseq", rb_iseqw_new(singleton_method));
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
COMPILE(ret, "defs: recv", node->nd_recv);
ADD_INSN1(ret, line, putobject, ID2SYM(node->nd_mid));
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ADD_INSN1(ret, line, putiseq, singleton_method);
ADD_SEND (ret, line, id_core_define_singleton_method, INT2FIX(3));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_ALIAS:{
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_CBASE));
COMPILE(ret, "alias arg1", node->u1.node);
COMPILE(ret, "alias arg2", node->u2.node);
ADD_SEND(ret, line, id_core_set_method_alias, INT2FIX(3));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_VALIAS:{
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
ADD_INSN1(ret, line, putobject, ID2SYM(node->u1.id));
ADD_INSN1(ret, line, putobject, ID2SYM(node->u2.id));
ADD_SEND(ret, line, id_core_set_variable_alias, INT2FIX(2));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_UNDEF:{
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_CBASE));
COMPILE(ret, "undef arg", node->u2.node);
ADD_SEND(ret, line, id_core_undef_method, INT2FIX(2));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_CLASS:{
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const rb_iseq_t *class_iseq = NEW_CHILD_ISEQ(node->nd_body,
rb_sprintf("<class:%"PRIsVALUE">", rb_id2str(node->nd_cpath->nd_mid)),
ISEQ_TYPE_CLASS, line);
VALUE noscope = compile_cpath(ret, iseq, node->nd_cpath);
int flags = VM_DEFINECLASS_TYPE_CLASS;
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if (!noscope) flags |= VM_DEFINECLASS_FLAG_SCOPED;
if (node->nd_super) flags |= VM_DEFINECLASS_FLAG_HAS_SUPERCLASS;
COMPILE(ret, "super", node->nd_super);
2015-07-22 01:52:59 +03:00
ADD_INSN3(ret, line, defineclass, ID2SYM(node->nd_cpath->nd_mid), class_iseq, INT2FIX(flags));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_MODULE:{
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const rb_iseq_t *module_iseq = NEW_CHILD_ISEQ(node->nd_body,
rb_sprintf("<module:%"PRIsVALUE">", rb_id2str(node->nd_cpath->nd_mid)),
ISEQ_TYPE_CLASS, line);
VALUE noscope = compile_cpath(ret, iseq, node->nd_cpath);
int flags = VM_DEFINECLASS_TYPE_MODULE;
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if (!noscope) flags |= VM_DEFINECLASS_FLAG_SCOPED;
ADD_INSN (ret, line, putnil); /* dummy */
2015-07-22 01:52:59 +03:00
ADD_INSN3(ret, line, defineclass, ID2SYM(node->nd_cpath->nd_mid), module_iseq, INT2FIX(flags));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_SCLASS:{
ID singletonclass;
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const rb_iseq_t *singleton_class = NEW_ISEQ(node->nd_body, rb_str_new2("singleton class"),
ISEQ_TYPE_CLASS, line);
COMPILE(ret, "sclass#recv", node->nd_recv);
ADD_INSN (ret, line, putnil);
CONST_ID(singletonclass, "singletonclass");
ADD_INSN3(ret, line, defineclass,
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ID2SYM(singletonclass), singleton_class,
INT2FIX(VM_DEFINECLASS_TYPE_SINGLETON_CLASS));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_COLON2:{
if (rb_is_const_id(node->nd_mid)) {
/* constant */
LABEL *lend = NEW_LABEL(line);
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int ic_index = iseq->body->is_size++;
DECL_ANCHOR(pref);
DECL_ANCHOR(body);
INIT_ANCHOR(pref);
INIT_ANCHOR(body);
compile_colon2(iseq, node, pref, body);
if (LIST_SIZE_ZERO(pref)) {
if (ISEQ_COMPILE_DATA(iseq)->option->inline_const_cache) {
ADD_INSN2(ret, line, getinlinecache, lend, INT2FIX(ic_index));
}
else {
ADD_INSN(ret, line, putnil);
}
ADD_SEQ(ret, body);
if (ISEQ_COMPILE_DATA(iseq)->option->inline_const_cache) {
ADD_INSN1(ret, line, setinlinecache, INT2FIX(ic_index));
ADD_LABEL(ret, lend);
}
}
else {
ADD_SEQ(ret, pref);
ADD_SEQ(ret, body);
}
}
else {
/* function call */
ADD_CALL_RECEIVER(ret, line);
COMPILE(ret, "colon2#nd_head", node->nd_head);
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_CALL(ret, line, node->nd_mid, INT2FIX(1));
}
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_COLON3:{
LABEL *lend = NEW_LABEL(line);
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int ic_index = iseq->body->is_size++;
debugi("colon3#nd_mid", node->nd_mid);
/* add cache insn */
if (ISEQ_COMPILE_DATA(iseq)->option->inline_const_cache) {
ADD_INSN2(ret, line, getinlinecache, lend, INT2FIX(ic_index));
ADD_INSN(ret, line, pop);
}
ADD_INSN1(ret, line, putobject, rb_cObject);
ADD_INSN1(ret, line, getconstant, ID2SYM(node->nd_mid));
if (ISEQ_COMPILE_DATA(iseq)->option->inline_const_cache) {
ADD_INSN1(ret, line, setinlinecache, INT2FIX(ic_index));
ADD_LABEL(ret, lend);
}
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_DOT2:
case NODE_DOT3:{
VALUE flag = type == NODE_DOT2 ? INT2FIX(0) : INT2FIX(1);
COMPILE(ret, "min", (NODE *) node->nd_beg);
COMPILE(ret, "max", (NODE *) node->nd_end);
if (poped) {
ADD_INSN(ret, line, pop);
ADD_INSN(ret, line, pop);
}
else {
ADD_INSN1(ret, line, newrange, flag);
}
break;
}
case NODE_FLIP2:
case NODE_FLIP3:{
LABEL *lend = NEW_LABEL(line);
LABEL *lfin = NEW_LABEL(line);
LABEL *ltrue = NEW_LABEL(line);
2015-07-22 01:52:59 +03:00
rb_iseq_t *local_iseq = iseq->body->local_iseq;
rb_num_t cnt;
VALUE key;
cnt = ISEQ_FLIP_CNT_INCREMENT(local_iseq) + VM_SVAR_FLIPFLOP_START;
key = INT2FIX(cnt);
ADD_INSN2(ret, line, getspecial, key, INT2FIX(0));
ADD_INSNL(ret, line, branchif, lend);
/* *flip == 0 */
COMPILE(ret, "flip2 beg", node->nd_beg);
ADD_INSN(ret, line, dup);
ADD_INSNL(ret, line, branchunless, lfin);
if (nd_type(node) == NODE_FLIP3) {
ADD_INSN(ret, line, dup);
ADD_INSN1(ret, line, setspecial, key);
ADD_INSNL(ret, line, jump, lfin);
}
else {
ADD_INSN1(ret, line, setspecial, key);
}
/* *flip == 1 */
ADD_LABEL(ret, lend);
COMPILE(ret, "flip2 end", node->nd_end);
ADD_INSNL(ret, line, branchunless, ltrue);
ADD_INSN1(ret, line, putobject, Qfalse);
ADD_INSN1(ret, line, setspecial, key);
ADD_LABEL(ret, ltrue);
ADD_INSN1(ret, line, putobject, Qtrue);
ADD_LABEL(ret, lfin);
break;
}
case NODE_SELF:{
if (!poped) {
ADD_INSN(ret, line, putself);
}
break;
}
case NODE_NIL:{
if (!poped) {
ADD_INSN(ret, line, putnil);
}
break;
}
case NODE_TRUE:{
if (!poped) {
ADD_INSN1(ret, line, putobject, Qtrue);
}
break;
}
case NODE_FALSE:{
if (!poped) {
ADD_INSN1(ret, line, putobject, Qfalse);
}
break;
}
case NODE_ERRINFO:{
if (!poped) {
2015-07-22 01:52:59 +03:00
if (iseq->body->type == ISEQ_TYPE_RESCUE) {
ADD_INSN2(ret, line, getlocal, INT2FIX(2), INT2FIX(0));
}
else {
const rb_iseq_t *ip = iseq;
int level = 0;
while (ip) {
2015-07-22 01:52:59 +03:00
if (ip->body->type == ISEQ_TYPE_RESCUE) {
break;
}
2015-07-22 01:52:59 +03:00
ip = ip->body->parent_iseq;
level++;
}
if (ip) {
ADD_INSN2(ret, line, getlocal, INT2FIX(2), INT2FIX(level));
}
else {
ADD_INSN(ret, line, putnil);
}
}
}
break;
}
case NODE_DEFINED:{
if (poped) break;
if (!node->nd_head) {
VALUE str = rb_iseq_defined_string(DEFINED_NIL);
ADD_INSN1(ret, nd_line(node), putobject, str);
}
else {
LABEL *lfinish[2];
lfinish[0] = NEW_LABEL(line);
lfinish[1] = 0;
ADD_INSN(ret, line, putnil);
defined_expr(iseq, ret, node->nd_head, lfinish, Qtrue);
ADD_INSN(ret, line, swap);
ADD_INSN(ret, line, pop);
if (lfinish[1]) {
ADD_LABEL(ret, lfinish[1]);
}
ADD_LABEL(ret, lfinish[0]);
}
break;
}
case NODE_POSTEXE:{
/* compiled to:
* ONCE{ rb_mRubyVMFrozenCore::core#set_postexe{ ... } }
*/
2015-07-22 01:52:59 +03:00
int is_index = iseq->body->is_size++;
const rb_iseq_t *once_iseq = NEW_CHILD_ISEQ((NODE *)IFUNC_NEW(build_postexe_iseq, node->nd_body, 0),
make_name_for_block(iseq), ISEQ_TYPE_BLOCK, line);
ADD_INSN2(ret, line, once, once_iseq, INT2FIX(is_index));
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
case NODE_KW_ARG:
{
LABEL *end_label = NEW_LABEL(nd_line(node));
NODE *default_value = node->nd_body->nd_value;
if (default_value == (NODE *)-1) {
/* required argument. do nothing */
rb_compile_bug_str(ERROR_ARGS "unreachable");
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
}
else if (nd_type(default_value) == NODE_LIT ||
nd_type(default_value) == NODE_NIL ||
nd_type(default_value) == NODE_TRUE ||
nd_type(default_value) == NODE_FALSE) {
rb_compile_bug_str(ERROR_ARGS "unreachable");
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
}
else {
/* if keywordcheck(_kw_bits, nth_keyword)
* kw = default_value
* end
*/
2015-07-22 01:52:59 +03:00
int kw_bits_idx = iseq->body->local_size - iseq->body->param.keyword->bits_start;
int keyword_idx = iseq->body->param.keyword->num;
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
ADD_INSN2(ret, line, checkkeyword, INT2FIX(kw_bits_idx), INT2FIX(keyword_idx));
ADD_INSNL(ret, line, branchif, end_label);
COMPILE_POPED(ret, "keyword default argument", node->nd_body);
ADD_LABEL(ret, end_label);
}
break;
}
case NODE_DSYM:{
compile_dstr(iseq, ret, node);
if (!poped) {
ADD_SEND(ret, line, idIntern, INT2FIX(0));
}
else {
ADD_INSN(ret, line, pop);
}
break;
}
case NODE_ATTRASGN:{
DECL_ANCHOR(recv);
DECL_ANCHOR(args);
unsigned int flag = 0;
ID mid = node->nd_mid;
LABEL *lskip = 0;
VALUE argc;
/* optimization shortcut
* obj["literal"] = value -> opt_aset_with(obj, "literal", value)
*/
if (mid == idASET && !private_recv_p(node) && node->nd_args &&
nd_type(node->nd_args) == NODE_ARRAY && node->nd_args->nd_alen == 2 &&
nd_type(node->nd_args->nd_head) == NODE_STR &&
ISEQ_COMPILE_DATA(iseq)->current_block == NULL &&
ISEQ_COMPILE_DATA(iseq)->option->specialized_instruction)
{
VALUE str = rb_fstring(node->nd_args->nd_head->nd_lit);
node->nd_args->nd_head->nd_lit = str;
iseq_add_mark_object(iseq, str);
COMPILE(ret, "recv", node->nd_recv);
COMPILE(ret, "value", node->nd_args->nd_next->nd_head);
if (!poped) {
ADD_INSN(ret, line, swap);
ADD_INSN1(ret, line, topn, INT2FIX(1));
}
ADD_INSN3(ret, line, opt_aset_with,
new_callinfo(iseq, idASET, 2, 0, NULL, FALSE),
NULL/* CALL_CACHE */, str);
ADD_INSN(ret, line, pop);
break;
}
INIT_ANCHOR(recv);
INIT_ANCHOR(args);
* rewrite method/block parameter fitting logic to optimize keyword arguments/parameters and a splat argument. [Feature #10440] (Details are described in this ticket) Most of complex part is moved to vm_args.c. Now, ISeq#to_a does not catch up new instruction format. * vm_core.h: change iseq data structures. * introduce rb_call_info_kw_arg_t to represent keyword arguments. * add rb_call_info_t::kw_arg. * rename rb_iseq_t::arg_post_len to rb_iseq_t::arg_post_num. * rename rb_iseq_t::arg_keywords to arg_keyword_num. * rename rb_iseq_t::arg_keyword to rb_iseq_t::arg_keyword_bits. to represent keyword bitmap parameter index. This bitmap parameter shows that which keyword parameters are given or not given (0 for given). It is refered by `checkkeyword' instruction described bellow. * rename rb_iseq_t::arg_keyword_check to rb_iseq_t::arg_keyword_rest to represent keyword rest parameter index. * add rb_iseq_t::arg_keyword_default_values to represent default keyword values. * rename VM_CALL_ARGS_SKIP_SETUP to VM_CALL_ARGS_SIMPLE to represent (ci->flag & (SPLAT|BLOCKARG)) && ci->blockiseq == NULL && ci->kw_arg == NULL. * vm_insnhelper.c, vm_args.c: rewrite with refactoring. * rewrite splat argument code. * rewrite keyword arguments/parameters code. * merge method and block parameter fitting code into one code base. * vm.c, vm_eval.c: catch up these changes. * compile.c (new_callinfo): callinfo requires kw_arg parameter. * compile.c (compile_array_): check the last argument Hash object or not. If Hash object and all keys are Symbol literals, they are compiled to keyword arguments. * insns.def (checkkeyword): add new instruction. This instruction check the availability of corresponding keyword. For example, a method "def foo k1: 'v1'; end" is cimpiled to the following instructions. 0000 checkkeyword 2, 0 # check k1 is given. 0003 branchif 9 # if given, jump to address #9 0005 putstring "v1" 0007 setlocal_OP__WC__0 3 # k1 = 'v1' 0009 trace 8 0011 putnil 0012 trace 16 0014 leave * insns.def (opt_send_simple): removed and add new instruction "opt_send_without_block". * parse.y (new_args_tail_gen): reorder variables. Before this patch, a method "def foo(k1: 1, kr1:, k2: 2, **krest, &b)" has parameter variables "k1, kr1, k2, &b, internal_id, krest", but this patch reorders to "kr1, k1, k2, internal_id, krest, &b". (locate a block variable at last) * parse.y (vtable_pop): added. This function remove latest `n' variables from vtable. * iseq.c: catch up iseq data changes. * proc.c: ditto. * class.c (keyword_error): export as rb_keyword_error(). * common.mk: depend vm_args.c for vm.o. * hash.c (rb_hash_has_key): export. * internal.h: ditto. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@48239 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2014-11-02 21:02:55 +03:00
argc = setup_args(iseq, args, node->nd_args, &flag, NULL);
flag |= COMPILE_RECV(recv, "recv", node);
debugp_param("argc", argc);
debugp_param("nd_mid", ID2SYM(mid));
if (!rb_is_attrset_id(mid)) {
/* safe nav attr */
mid = rb_id_attrset(mid);
ADD_INSN(recv, line, dup);
lskip = NEW_LABEL(line);
ADD_INSNL(recv, line, branchnil, lskip);
}
if (!poped) {
ADD_INSN(ret, line, putnil);
ADD_SEQ(ret, recv);
ADD_SEQ(ret, args);
if (flag & VM_CALL_ARGS_BLOCKARG) {
ADD_INSN1(ret, line, topn, INT2FIX(1));
if (flag & VM_CALL_ARGS_SPLAT) {
ADD_INSN1(ret, line, putobject, INT2FIX(-1));
ADD_SEND(ret, line, idAREF, INT2FIX(1));
}
ADD_INSN1(ret, line, setn, FIXNUM_INC(argc, 3));
ADD_INSN (ret, line, pop);
}
else if (flag & VM_CALL_ARGS_SPLAT) {
ADD_INSN(ret, line, dup);
ADD_INSN1(ret, line, putobject, INT2FIX(-1));
ADD_SEND(ret, line, idAREF, INT2FIX(1));
ADD_INSN1(ret, line, setn, FIXNUM_INC(argc, 2));
ADD_INSN (ret, line, pop);
}
else {
ADD_INSN1(ret, line, setn, FIXNUM_INC(argc, 1));
}
}
else {
ADD_SEQ(ret, recv);
ADD_SEQ(ret, args);
}
ADD_SEND_WITH_FLAG(ret, line, mid, argc, INT2FIX(flag));
if (lskip) ADD_LABEL(ret, lskip);
ADD_INSN(ret, line, pop);
break;
}
case NODE_PRELUDE:{
const rb_compile_option_t *orig_opt = ISEQ_COMPILE_DATA(iseq)->option;
if (node->nd_orig) {
rb_compile_option_t new_opt = *orig_opt;
rb_iseq_make_compile_option(&new_opt, node->nd_orig);
ISEQ_COMPILE_DATA(iseq)->option = &new_opt;
}
COMPILE_POPED(ret, "prelude", node->nd_head);
COMPILE_(ret, "body", node->nd_body, poped);
ISEQ_COMPILE_DATA(iseq)->option = orig_opt;
break;
}
case NODE_LAMBDA:{
/* compile same as lambda{...} */
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const rb_iseq_t *block = NEW_CHILD_ISEQ(node->nd_body, make_name_for_block(iseq), ISEQ_TYPE_BLOCK, line);
VALUE argc = INT2FIX(0);
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ADD_INSN1(ret, line, putspecialobject, INT2FIX(VM_SPECIAL_OBJECT_VMCORE));
ADD_CALL_WITH_BLOCK(ret, line, idLambda, argc, block);
if (poped) {
ADD_INSN(ret, line, pop);
}
break;
}
default:
UNKNOWN_NODE("iseq_compile_each", node);
return COMPILE_NG;
}
/* check & remove redundant trace(line) */
if (saved_last_element && ret /* ret can be 0 when error */ &&
ret->last == saved_last_element &&
((INSN *)saved_last_element)->insn_id == BIN(trace)) {
POP_ELEMENT(ret);
}
debug_node_end();
return COMPILE_OK;
}
/***************************/
/* instruction information */
/***************************/
static int
insn_data_length(INSN *iobj)
{
return insn_len(iobj->insn_id);
}
static int
calc_sp_depth(int depth, INSN *insn)
{
return insn_stack_increase(depth, insn->insn_id, insn->operands);
}
static VALUE
opobj_inspect(VALUE obj)
{
struct RBasic *r = (struct RBasic *) obj;
if (!SPECIAL_CONST_P(r) && r->klass == 0) {
switch (BUILTIN_TYPE(r)) {
case T_STRING:
obj = rb_str_new_cstr(RSTRING_PTR(obj));
break;
case T_ARRAY:
obj = rb_ary_dup(obj);
break;
}
}
return rb_inspect(obj);
}
static VALUE
insn_data_to_s_detail(INSN *iobj)
{
VALUE str = rb_sprintf("%-20s ", insn_name(iobj->insn_id));
if (iobj->operands) {
const char *types = insn_op_types(iobj->insn_id);
int j;
for (j = 0; types[j]; j++) {
char type = types[j];
switch (type) {
case TS_OFFSET: /* label(destination position) */
{
LABEL *lobj = (LABEL *)OPERAND_AT(iobj, j);
rb_str_catf(str, "<L%03d>", lobj->label_no);
break;
}
break;
case TS_ISEQ: /* iseq */
{
rb_iseq_t *iseq = (rb_iseq_t *)OPERAND_AT(iobj, j);
VALUE val = Qnil;
if (0 && iseq) { /* TODO: invalidate now */
2015-07-22 01:52:59 +03:00
val = (VALUE)iseq;
}
rb_str_concat(str, opobj_inspect(val));
}
break;
case TS_LINDEX:
case TS_NUM: /* ulong */
case TS_VALUE: /* VALUE */
{
VALUE v = OPERAND_AT(iobj, j);
rb_str_concat(str, opobj_inspect(v));
break;
}
case TS_ID: /* ID */
rb_str_concat(str, opobj_inspect(OPERAND_AT(iobj, j)));
break;
case TS_GENTRY:
{
struct rb_global_entry *entry = (struct rb_global_entry *)
(OPERAND_AT(iobj, j) & (~1));
rb_str_append(str, rb_id2str(entry->id));
break;
}
case TS_IC: /* inline cache */
rb_str_catf(str, "<ic:%d>", FIX2INT(OPERAND_AT(iobj, j)));
break;
case TS_CALLINFO: /* call info */
{
struct rb_call_info *ci = (struct rb_call_info *)OPERAND_AT(iobj, j);
rb_str_cat2(str, "<callinfo:");
if (ci->mid) rb_str_catf(str, "%"PRIsVALUE, rb_id2str(ci->mid));
rb_str_catf(str, ", %d>", ci->orig_argc);
break;
}
case TS_CALLCACHE: /* call cache */
{
rb_str_catf(str, "<call cache>");
break;
}
case TS_CDHASH: /* case/when condition cache */
rb_str_cat2(str, "<ch>");
break;
case TS_FUNCPTR:
{
rb_insn_func_t func = (rb_insn_func_t)OPERAND_AT(iobj, j);
#ifdef HAVE_DLADDR
Dl_info info;
if (dladdr(func, &info) && info.dli_sname) {
rb_str_cat2(str, info.dli_sname);
break;
}
#endif
rb_str_catf(str, "<%p>", func);
}
break;
default:{
rb_raise(rb_eSyntaxError, "unknown operand type: %c", type);
}
}
if (types[j + 1]) {
rb_str_cat2(str, ", ");
}
}
}
return str;
}
static void
dump_disasm_list(struct iseq_link_element *link)
{
int pos = 0;
INSN *iobj;
LABEL *lobj;
VALUE str;
printf("-- raw disasm--------\n");
while (link) {
switch (link->type) {
case ISEQ_ELEMENT_INSN:
{
iobj = (INSN *)link;
str = insn_data_to_s_detail(iobj);
printf("%04d %-65s(%4u)\n", pos, StringValueCStr(str), iobj->line_no);
pos += insn_data_length(iobj);
break;
}
case ISEQ_ELEMENT_LABEL:
{
lobj = (LABEL *)link;
printf("<L%03d>\n", lobj->label_no);
break;
}
case ISEQ_ELEMENT_NONE:
{
printf("[none]\n");
break;
}
case ISEQ_ELEMENT_ADJUST:
{
ADJUST *adjust = (ADJUST *)link;
printf("adjust: [label: %d]\n", adjust->label ? adjust->label->label_no : -1);
break;
}
default:
/* ignore */
rb_raise(rb_eSyntaxError, "dump_disasm_list error: %ld\n", FIX2LONG(link->type));
}
link = link->next;
}
printf("---------------------\n");
fflush(stdout);
}
* probes.d: add DTrace probe declarations. [ruby-core:27448] * array.c (empty_ary_alloc, ary_new): added array create DTrace probe. * compile.c (rb_insns_name): allowing DTrace probes to access instruction sequence name. * Makefile.in: translate probes.d file to appropriate header file. * common.mk: declare dependencies on the DTrace header. * configure.in: add a test for existence of DTrace. * eval.c (setup_exception): add a probe for when an exception is raised. * gc.c: Add DTrace probes for mark begin and end, and sweep begin and end. * hash.c (empty_hash_alloc): Add a probe for hash allocation. * insns.def: Add probes for function entry and return. * internal.h: function declaration for compile.c change. * load.c (rb_f_load): add probes for `load` entry and exit, require entry and exit, and wrapping search_required for load path search. * object.c (rb_obj_alloc): added a probe for general object creation. * parse.y (yycompile0): added a probe around parse and compile phase. * string.c (empty_str_alloc, str_new): DTrace probes for string allocation. * test/dtrace/*: tests for DTrace probes. * vm.c (vm_invoke_proc): add probes for function return on exception raise, hash create, and instruction sequence execution. * vm_core.h: add probe declarations for function entry and exit. * vm_dump.c: add probes header file. * vm_eval.c (vm_call0_cfunc, vm_call0_cfunc_with_frame): add probe on function entry and return. * vm_exec.c: expose instruction number to instruction name function. * vm_insnshelper.c: add function entry and exit probes for cfunc methods. * vm_insnhelper.h: vm usage information is always collected, so uncomment the functions. 12 19:14:50 2012 Akinori MUSHA <knu@iDaemons.org> * configure.in (isinf, isnan): isinf() and isnan() are macros on DragonFly which cannot be found by AC_REPLACE_FUNCS(). This workaround enforces the fact that they exist on DragonFly. 12 15:59:38 2012 Shugo Maeda <shugo@ruby-lang.org> * vm_core.h (rb_call_info_t::refinements), compile.c (new_callinfo), vm_insnhelper.c (vm_search_method): revert r37616 because it's too slow. [ruby-dev:46477] * test/ruby/test_refinement.rb (test_inline_method_cache): skip the test until the bug is fixed efficiently. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@37631 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2012-11-13 01:52:12 +04:00
const char *
rb_insns_name(int i)
{
return insn_name_info[i];
}
VALUE
rb_insns_name_array(void)
{
VALUE ary = rb_ary_new();
int i;
for (i = 0; i < numberof(insn_name_info); i++) {
rb_ary_push(ary, rb_fstring(rb_str_new2(insn_name_info[i])));
}
return rb_obj_freeze(ary);
}
static LABEL *
register_label(rb_iseq_t *iseq, struct st_table *labels_table, VALUE obj)
{
LABEL *label = 0;
st_data_t tmp;
obj = rb_convert_type(obj, T_SYMBOL, "Symbol", "to_sym");
if (st_lookup(labels_table, obj, &tmp) == 0) {
label = NEW_LABEL(0);
st_insert(labels_table, obj, (st_data_t)label);
}
else {
label = (LABEL *)tmp;
}
LABEL_REF(label);
return label;
}
static VALUE
get_exception_sym2type(VALUE sym)
{
#undef rb_intern
#define rb_intern(str) rb_intern_const(str)
static VALUE symRescue, symEnsure, symRetry;
static VALUE symBreak, symRedo, symNext;
if (symRescue == 0) {
symRescue = ID2SYM(rb_intern("rescue"));
symEnsure = ID2SYM(rb_intern("ensure"));
symRetry = ID2SYM(rb_intern("retry"));
symBreak = ID2SYM(rb_intern("break"));
symRedo = ID2SYM(rb_intern("redo"));
symNext = ID2SYM(rb_intern("next"));
}
if (sym == symRescue) return CATCH_TYPE_RESCUE;
if (sym == symEnsure) return CATCH_TYPE_ENSURE;
if (sym == symRetry) return CATCH_TYPE_RETRY;
if (sym == symBreak) return CATCH_TYPE_BREAK;
if (sym == symRedo) return CATCH_TYPE_REDO;
if (sym == symNext) return CATCH_TYPE_NEXT;
rb_raise(rb_eSyntaxError, "invalid exception symbol: %+"PRIsVALUE, sym);
return 0;
}
static int
iseq_build_from_ary_exception(rb_iseq_t *iseq, struct st_table *labels_table,
VALUE exception)
{
int i;
for (i=0; i<RARRAY_LEN(exception); i++) {
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const rb_iseq_t *eiseq;
VALUE v, type;
const VALUE *ptr;
LABEL *lstart, *lend, *lcont;
unsigned int sp;
v = rb_convert_type(RARRAY_AREF(exception, i), T_ARRAY,
"Array", "to_ary");
if (RARRAY_LEN(v) != 6) {
rb_raise(rb_eSyntaxError, "wrong exception entry");
}
ptr = RARRAY_CONST_PTR(v);
type = get_exception_sym2type(ptr[0]);
if (ptr[1] == Qnil) {
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eiseq = NULL;
}
else {
2015-07-22 01:52:59 +03:00
eiseq = rb_iseqw_to_iseq(rb_iseq_load(ptr[1], (VALUE)iseq, Qnil));
}
lstart = register_label(iseq, labels_table, ptr[2]);
lend = register_label(iseq, labels_table, ptr[3]);
lcont = register_label(iseq, labels_table, ptr[4]);
sp = NUM2UINT(ptr[5]);
(void)sp;
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ADD_CATCH_ENTRY(type, lstart, lend, eiseq, lcont);
RB_GC_GUARD(v);
}
return COMPILE_OK;
}
static struct st_table *
insn_make_insn_table(void)
{
struct st_table *table;
int i;
table = st_init_numtable();
for (i=0; i<VM_INSTRUCTION_SIZE; i++) {
st_insert(table, ID2SYM(rb_intern(insn_name(i))), i);
}
return table;
}
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static const rb_iseq_t *
iseq_build_load_iseq(const rb_iseq_t *iseq, VALUE op)
{
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VALUE iseqw;
const rb_iseq_t *loaded_iseq;
if (RB_TYPE_P(op, T_ARRAY)) {
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iseqw = rb_iseq_load(op, (VALUE)iseq, Qnil);
}
else if (CLASS_OF(op) == rb_cISeq) {
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iseqw = op;
}
else {
rb_raise(rb_eSyntaxError, "ISEQ is required");
}
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loaded_iseq = rb_iseqw_to_iseq(iseqw);
iseq_add_mark_object(iseq, (VALUE)loaded_iseq);
return loaded_iseq;
}
static VALUE
iseq_build_callinfo_from_hash(rb_iseq_t *iseq, VALUE op)
{
ID mid = 0;
int orig_argc = 0;
unsigned int flag = 0;
struct rb_call_info_kw_arg *kw_arg = 0;
if (!NIL_P(op)) {
VALUE vmid = rb_hash_aref(op, ID2SYM(rb_intern("mid")));
VALUE vflag = rb_hash_aref(op, ID2SYM(rb_intern("flag")));
VALUE vorig_argc = rb_hash_aref(op, ID2SYM(rb_intern("orig_argc")));
VALUE vkw_arg = rb_hash_aref(op, ID2SYM(rb_intern("kw_arg")));
if (!NIL_P(vmid)) mid = SYM2ID(vmid);
if (!NIL_P(vflag)) flag = NUM2UINT(vflag);
if (!NIL_P(vorig_argc)) orig_argc = FIX2INT(vorig_argc);
if (!NIL_P(vkw_arg)) {
int i;
int len = RARRAY_LENINT(vkw_arg);
size_t n = rb_call_info_kw_arg_bytes(len);
kw_arg = xmalloc(n);
kw_arg->keyword_len = len;
for (i = 0; i < len; i++) {
VALUE kw = RARRAY_AREF(vkw_arg, i);
SYM2ID(kw); /* make immortal */
kw_arg->keywords[i] = kw;
}
}
}
return (VALUE)new_callinfo(iseq, mid, orig_argc, flag, kw_arg, (flag & VM_CALL_ARGS_SIMPLE) == 0);
}
static int
iseq_build_from_ary_body(rb_iseq_t *iseq, LINK_ANCHOR *anchor,
VALUE body, VALUE labels_wrapper)
{
/* TODO: body should be frozen */
const VALUE *ptr = RARRAY_CONST_PTR(body);
long i, len = RARRAY_LEN(body);
struct st_table *labels_table = DATA_PTR(labels_wrapper);
int j;
int line_no = 0;
int ret = COMPILE_OK;
/*
* index -> LABEL *label
*/
static struct st_table *insn_table;
if (insn_table == 0) {
insn_table = insn_make_insn_table();
}
for (i=0; i<len; i++) {
VALUE obj = ptr[i];
if (SYMBOL_P(obj)) {
LABEL *label = register_label(iseq, labels_table, obj);
ADD_LABEL(anchor, label);
}
else if (FIXNUM_P(obj)) {
line_no = NUM2INT(obj);
}
else if (RB_TYPE_P(obj, T_ARRAY)) {
VALUE *argv = 0;
int argc = RARRAY_LENINT(obj) - 1;
st_data_t insn_id;
VALUE insn;
insn = (argc < 0) ? Qnil : RARRAY_AREF(obj, 0);
if (st_lookup(insn_table, (st_data_t)insn, &insn_id) == 0) {
/* TODO: exception */
COMPILE_ERROR(ruby_sourcefile_string, line_no,
"unknown instruction: %+"PRIsVALUE, insn);
ret = COMPILE_NG;
break;
}
if (argc != insn_len((VALUE)insn_id)-1) {
COMPILE_ERROR(ruby_sourcefile_string, line_no,
"operand size mismatch");
ret = COMPILE_NG;
break;
}
if (argc > 0) {
argv = compile_data_alloc(iseq, sizeof(VALUE) * argc);
for (j=0; j<argc; j++) {
VALUE op = rb_ary_entry(obj, j+1);
switch (insn_op_type((VALUE)insn_id, j)) {
case TS_OFFSET: {
LABEL *label = register_label(iseq, labels_table, op);
argv[j] = (VALUE)label;
break;
}
case TS_LINDEX:
case TS_NUM:
(void)NUM2INT(op);
argv[j] = op;
break;
case TS_VALUE:
argv[j] = op;
iseq_add_mark_object(iseq, op);
break;
case TS_ISEQ:
{
if (op != Qnil) {
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argv[j] = (VALUE)iseq_build_load_iseq(iseq, op);
}
else {
argv[j] = 0;
}
}
break;
case TS_GENTRY:
op = rb_convert_type(op, T_SYMBOL, "Symbol", "to_sym");
argv[j] = (VALUE)rb_global_entry(SYM2ID(op));
break;
case TS_IC:
argv[j] = op;
if (NUM2UINT(op) >= iseq->body->is_size) {
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iseq->body->is_size = NUM2INT(op) + 1;
}
break;
case TS_CALLINFO:
argv[j] = iseq_build_callinfo_from_hash(iseq, op);
break;
case TS_CALLCACHE:
argv[j] = Qfalse;
break;
case TS_ID:
argv[j] = rb_convert_type(op, T_SYMBOL,
"Symbol", "to_sym");
break;
case TS_CDHASH:
{
int i;
VALUE map = rb_hash_new();
rb_hash_tbl_raw(map)->type = &cdhash_type;
op = rb_convert_type(op, T_ARRAY, "Array", "to_ary");
for (i=0; i<RARRAY_LEN(op); i+=2) {
VALUE key = RARRAY_AREF(op, i);
VALUE sym = RARRAY_AREF(op, i+1);
LABEL *label =
register_label(iseq, labels_table, sym);
rb_hash_aset(map, key, (VALUE)label | 1);
}
RB_GC_GUARD(op);
argv[j] = map;
rb_iseq_add_mark_object(iseq, map);
}
break;
case TS_FUNCPTR:
{
#if SIZEOF_VALUE <= SIZEOF_LONG
long funcptr = NUM2LONG(op);
#else
LONG_LONG funcptr = NUM2LL(op);
#endif
argv[j] = (VALUE)funcptr;
}
break;
default:
rb_raise(rb_eSyntaxError, "unknown operand: %c", insn_op_type((VALUE)insn_id, j));
}
}
}
ADD_ELEM(anchor,
(LINK_ELEMENT*)new_insn_core(iseq, line_no,
(enum ruby_vminsn_type)insn_id, argc, argv));
}
else {
rb_raise(rb_eTypeError, "unexpected object for instruction");
}
}
DATA_PTR(labels_wrapper) = 0;
validate_labels(iseq, labels_table);
if (!ret) return ret;
return iseq_setup(iseq, anchor);
}
#define CHECK_ARRAY(v) rb_convert_type((v), T_ARRAY, "Array", "to_ary")
#define CHECK_SYMBOL(v) rb_convert_type((v), T_SYMBOL, "Symbol", "to_sym")
static int
int_param(int *dst, VALUE param, VALUE sym)
{
VALUE val = rb_hash_aref(param, sym);
switch (TYPE(val)) {
case T_NIL:
return FALSE;
case T_FIXNUM:
*dst = FIX2INT(val);
return TRUE;
default:
rb_raise(rb_eTypeError, "invalid %+"PRIsVALUE" Fixnum: %+"PRIsVALUE,
sym, val);
}
return FALSE;
}
static const struct rb_iseq_param_keyword *
iseq_build_kw(rb_iseq_t *iseq, VALUE params, VALUE keywords)
{
int i, j;
int len = RARRAY_LENINT(keywords);
int default_len;
VALUE key, sym, default_val;
VALUE *dvs;
ID *ids;
struct rb_iseq_param_keyword *keyword = ZALLOC(struct rb_iseq_param_keyword);
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iseq->body->param.flags.has_kw = TRUE;
keyword->num = len;
#define SYM(s) ID2SYM(rb_intern(#s))
(void)int_param(&keyword->bits_start, params, SYM(kwbits));
i = keyword->bits_start - keyword->num;
ids = (VALUE *)&iseq->body->local_table[i];
#undef SYM
/* required args */
for (i = 0; i < len; i++) {
VALUE val = RARRAY_AREF(keywords, i);
if (!SYMBOL_P(val)) {
goto default_values;
}
ids[i] = SYM2ID(val);
keyword->required_num++;
}
default_values: /* note: we intentionally preserve `i' from previous loop */
default_len = len - i;
if (default_len == 0) {
return keyword;
}
dvs = ALLOC_N(VALUE, default_len);
for (j = 0; i < len; i++, j++) {
key = RARRAY_AREF(keywords, i);
CHECK_ARRAY(key);
switch (RARRAY_LEN(key)) {
case 1:
sym = RARRAY_AREF(key, 0);
default_val = Qundef;
break;
case 2:
sym = RARRAY_AREF(key, 0);
default_val = RARRAY_AREF(key, 1);
break;
default:
rb_raise(rb_eTypeError, "keyword default has unsupported len %+"PRIsVALUE, key);
}
ids[i] = SYM2ID(sym);
dvs[j] = default_val;
}
keyword->table = ids;
keyword->default_values = dvs;
return keyword;
}
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void
rb_iseq_build_from_ary(rb_iseq_t *iseq, VALUE misc, VALUE locals, VALUE params,
VALUE exception, VALUE body)
{
#define SYM(s) ID2SYM(rb_intern(#s))
int i, len;
ID *tbl;
struct st_table *labels_table = st_init_numtable();
VALUE labels_wrapper = Data_Wrap_Struct(0, 0, st_free_table, labels_table);
VALUE arg_opt_labels = rb_hash_aref(params, SYM(opt));
VALUE keywords = rb_hash_aref(params, SYM(keyword));
VALUE sym_arg_rest = ID2SYM(rb_intern("#arg_rest"));
DECL_ANCHOR(anchor);
INIT_ANCHOR(anchor);
len = RARRAY_LENINT(locals);
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iseq->body->local_table_size = len;
iseq->body->local_table = tbl = len > 0 ? (ID *)ALLOC_N(ID, iseq->body->local_table_size) : NULL;
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iseq->body->local_size = iseq->body->local_table_size + 1;
for (i = 0; i < len; i++) {
VALUE lv = RARRAY_AREF(locals, i);
if (sym_arg_rest == lv) {
tbl[i] = 0;
}
else {
tbl[i] = FIXNUM_P(lv) ? (ID)FIX2LONG(lv) : SYM2ID(CHECK_SYMBOL(lv));
}
}
/*
* we currently ignore misc params,
* local_size, stack_size and param.size are all calculated
*/
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#define INT_PARAM(F) int_param(&iseq->body->param.F, params, SYM(F))
if (INT_PARAM(lead_num)) {
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iseq->body->param.flags.has_lead = TRUE;
}
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if (INT_PARAM(post_num)) iseq->body->param.flags.has_post = TRUE;
if (INT_PARAM(post_start)) iseq->body->param.flags.has_post = TRUE;
if (INT_PARAM(rest_start)) iseq->body->param.flags.has_rest = TRUE;
if (INT_PARAM(block_start)) iseq->body->param.flags.has_block = TRUE;
#undef INT_PARAM
switch (TYPE(arg_opt_labels)) {
case T_ARRAY:
len = RARRAY_LENINT(arg_opt_labels);
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iseq->body->param.flags.has_opt = !!(len - 1 >= 0);
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if (iseq->body->param.flags.has_opt) {
VALUE *opt_table = ALLOC_N(VALUE, len);
for (i = 0; i < len; i++) {
VALUE ent = RARRAY_AREF(arg_opt_labels, i);
LABEL *label = register_label(iseq, labels_table, ent);
opt_table[i] = (VALUE)label;
}
iseq->body->param.opt_num = len - 1;
iseq->body->param.opt_table = opt_table;
}
case T_NIL:
break;
default:
rb_raise(rb_eTypeError, ":opt param is not an array: %+"PRIsVALUE,
arg_opt_labels);
}
switch (TYPE(keywords)) {
case T_ARRAY:
iseq->body->param.keyword = iseq_build_kw(iseq, params, keywords);
case T_NIL:
break;
default:
rb_raise(rb_eTypeError, ":keywords param is not an array: %+"PRIsVALUE,
keywords);
}
if (Qtrue == rb_hash_aref(params, SYM(ambiguous_param0))) {
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iseq->body->param.flags.ambiguous_param0 = TRUE;
}
if (int_param(&i, params, SYM(kwrest))) {
struct rb_iseq_param_keyword *keyword = (struct rb_iseq_param_keyword *)iseq->body->param.keyword;
if (keyword == NULL) {
iseq->body->param.keyword = keyword = ZALLOC(struct rb_iseq_param_keyword);
}
keyword->rest_start = i;
iseq->body->param.flags.has_kwrest = TRUE;
}
#undef SYM
iseq_calc_param_size(iseq);
/* exception */
iseq_build_from_ary_exception(iseq, labels_table, exception);
/* body */
iseq_build_from_ary_body(iseq, anchor, body, labels_wrapper);
}
/* for parser */
int
rb_dvar_defined(ID id)
{
rb_thread_t *th = GET_THREAD();
const rb_iseq_t *iseq;
if (th->base_block && (iseq = th->base_block->iseq)) {
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while (iseq->body->type == ISEQ_TYPE_BLOCK ||
iseq->body->type == ISEQ_TYPE_RESCUE ||
iseq->body->type == ISEQ_TYPE_ENSURE ||
iseq->body->type == ISEQ_TYPE_EVAL ||
iseq->body->type == ISEQ_TYPE_MAIN
) {
unsigned int i;
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for (i = 0; i < iseq->body->local_table_size; i++) {
if (iseq->body->local_table[i] == id) {
return 1;
}
}
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iseq = iseq->body->parent_iseq;
}
}
return 0;
}
int
rb_local_defined(ID id)
{
rb_thread_t *th = GET_THREAD();
const rb_iseq_t *iseq;
if (th->base_block && th->base_block->iseq) {
unsigned int i;
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iseq = th->base_block->iseq->body->local_iseq;
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for (i=0; i<iseq->body->local_table_size; i++) {
if (iseq->body->local_table[i] == id) {
return 1;
}
}
}
return 0;
}
int
rb_parse_in_eval(void)
{
return GET_THREAD()->parse_in_eval > 0;
}
int
rb_parse_in_main(void)
{
return GET_THREAD()->parse_in_eval < 0;
}
static int
caller_location(VALUE *path, VALUE *absolute_path)
{
const rb_thread_t *const th = GET_THREAD();
const rb_control_frame_t *const cfp =
rb_vm_get_ruby_level_next_cfp(th, th->cfp);
if (cfp) {
int line = rb_vm_get_sourceline(cfp);
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*path = cfp->iseq->body->location.path;
*absolute_path = cfp->iseq->body->location.absolute_path;
return line;
}
else {
*path = rb_fstring_cstr("<compiled>");
*absolute_path = *path;
return 1;
}
}
typedef struct {
VALUE arg;
rb_insn_func_t func;
int line;
} accessor_args;
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static const rb_iseq_t *
method_for_self(VALUE name, VALUE arg, rb_insn_func_t func,
VALUE (*build)(rb_iseq_t *, LINK_ANCHOR *, VALUE))
{
VALUE path, absolute_path;
accessor_args acc;
acc.arg = arg;
acc.func = func;
acc.line = caller_location(&path, &absolute_path);
return rb_iseq_new_with_opt((NODE *)IFUNC_NEW(build, (VALUE)&acc, 0),
rb_sym2str(name), path, absolute_path,
INT2FIX(acc.line), 0, ISEQ_TYPE_METHOD, 0);
}
static VALUE
for_self_aref(rb_iseq_t *iseq, LINK_ANCHOR *ret, VALUE a)
{
const accessor_args *const args = (void *)a;
const int line = args->line;
iseq_set_local_table(iseq, 0);
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iseq->body->param.lead_num = 0;
iseq->body->param.size = 0;
ADD_INSN1(ret, line, putobject, args->arg);
ADD_INSN1(ret, line, opt_call_c_function, (VALUE)args->func);
return Qnil;
}
static VALUE
for_self_aset(rb_iseq_t *iseq, LINK_ANCHOR *ret, VALUE a)
{
const accessor_args *const args = (void *)a;
const int line = args->line;
static const ID vars[] = {1, idUScore};
iseq_set_local_table(iseq, vars);
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iseq->body->param.lead_num = 1;
iseq->body->param.size = 1;
ADD_INSN2(ret, line, getlocal, INT2FIX(numberof(vars)-0), INT2FIX(0));
ADD_INSN1(ret, line, putobject, args->arg);
ADD_INSN1(ret, line, opt_call_c_function, (VALUE)args->func);
ADD_INSN(ret, line, pop);
return Qnil;
}
/*
* func (index) -> (value)
*/
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const rb_iseq_t *
rb_method_for_self_aref(VALUE name, VALUE arg, rb_insn_func_t func)
{
return method_for_self(name, arg, func, for_self_aref);
}
/*
* func (index, value) -> (index, value)
*/
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const rb_iseq_t *
rb_method_for_self_aset(VALUE name, VALUE arg, rb_insn_func_t func)
{
return method_for_self(name, arg, func, for_self_aset);
}
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
/* ISeq binary format */
typedef unsigned int ibf_offset_t;
#define IBF_OFFSET(ptr) ((ibf_offset_t)(VALUE)(ptr))
struct ibf_header {
char magic[4]; /* YARB */
unsigned int major_version;
unsigned int minor_version;
unsigned int size;
unsigned int extra_size;
unsigned int iseq_list_size;
unsigned int id_list_size;
unsigned int object_list_size;
ibf_offset_t iseq_list_offset;
ibf_offset_t id_list_offset;
ibf_offset_t object_list_offset;
};
struct ibf_id_entry {
enum {
ibf_id_enc_ascii,
ibf_id_enc_utf8,
ibf_id_enc_other
} enc : 2;
char body[1];
};
struct ibf_dump {
VALUE str;
VALUE iseq_list; /* [iseq0 offset, ...] */
VALUE obj_list; /* [objs] */
st_table *iseq_table; /* iseq -> iseq number */
st_table *id_table; /* id -> id number */
};
rb_iseq_t * iseq_alloc(void);
struct ibf_load {
const char *buff;
const struct ibf_header *header;
ID *id_list; /* [id0, ...] */
VALUE iseq_list; /* [iseq0, ...] */
VALUE obj_list; /* [obj0, ...] */
VALUE loader_obj;
VALUE str;
rb_iseq_t *iseq;
};
static ibf_offset_t
ibf_dump_pos(struct ibf_dump *dump)
{
return (unsigned int)rb_str_strlen(dump->str);
}
static ibf_offset_t
ibf_dump_write(struct ibf_dump *dump, const void *buff, unsigned long size)
{
ibf_offset_t pos = ibf_dump_pos(dump);
rb_str_cat(dump->str, (const char *)buff, size);
/* TODO: overflow check */
return pos;
}
static void
ibf_dump_overwrite(struct ibf_dump *dump, void *buff, unsigned int size, long offset)
{
VALUE str = dump->str;
char *ptr = RSTRING_PTR(str);
if ((unsigned long)(size + offset) > (unsigned long)RSTRING_LEN(str))
rb_bug("ibf_dump_overwrite: overflow");
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
memcpy(ptr + offset, buff, size);
}
static void *
ibf_load_alloc(const struct ibf_load *load, ibf_offset_t offset, int size)
{
void *buff = ruby_xmalloc(size);
memcpy(buff, load->buff + offset, size);
return buff;
}
#define IBF_W(b, type, n) (type *)(VALUE)ibf_dump_write(dump, (b), sizeof(type) * (n))
#define IBF_WV(variable) ibf_dump_write(dump, &(variable), sizeof(variable))
#define IBF_WP(b, type, n) ibf_dump_write(dump, (b), sizeof(type) * (n))
#define IBF_R(val, type, n) (type *)ibf_load_alloc(load, IBF_OFFSET(val), sizeof(type) * (n))
static int
ibf_table_lookup(struct st_table *table, st_data_t key)
{
st_data_t val;
if (st_lookup(table, key, &val)) {
return (int)val;
}
else {
return -1;
}
}
static int
ibf_table_index(struct st_table *table, st_data_t key)
{
int index = ibf_table_lookup(table, key);
if (index < 0) { /* not found */
index = (int)table->num_entries;
st_insert(table, key, (st_data_t)index);
}
return index;
}
/* dump/load generic */
static VALUE ibf_load_object(const struct ibf_load *load, VALUE object_index);
static rb_iseq_t *ibf_load_iseq(const struct ibf_load *load, const rb_iseq_t *index_iseq);
static VALUE
ibf_dump_object(struct ibf_dump *dump, VALUE obj)
{
long index = RARRAY_LEN(dump->obj_list);
long i;
for (i=0; i<index; i++) {
if (RARRAY_AREF(dump->obj_list, i) == obj) return (VALUE)i; /* dedup */
}
rb_ary_push(dump->obj_list, obj);
return (VALUE)index;
}
static VALUE
ibf_dump_id(struct ibf_dump *dump, ID id)
{
return (VALUE)ibf_table_index(dump->id_table, (st_data_t)id);
}
static ID
ibf_load_id(const struct ibf_load *load, const ID id_index)
{
ID id;
if (id_index == 0) {
id = 0;
}
else {
id = load->id_list[(long)id_index];
if (id == 0) {
long *indices = (long *)(load->buff + load->header->id_list_offset);
VALUE str = ibf_load_object(load, indices[id_index]);
id = NIL_P(str) ? 0 : rb_intern_str(str); /* str == nil -> internal junk id */
load->id_list[(long)id_index] = id;
}
}
return id;
}
/* dump/load: code */
static VALUE
ibf_dump_callinfo(struct ibf_dump *dump, const struct rb_call_info *ci)
{
return (ci->flag & VM_CALL_KWARG) ? Qtrue : Qfalse;
}
static ibf_offset_t ibf_dump_iseq_each(struct ibf_dump *dump, const rb_iseq_t *iseq);
static rb_iseq_t *
ibf_dump_iseq(struct ibf_dump *dump, const rb_iseq_t *iseq)
{
if (iseq == NULL) {
return (rb_iseq_t *)-1;
}
else {
int iseq_index = ibf_table_lookup(dump->iseq_table, (st_data_t)iseq);
if (iseq_index < 0) {
iseq_index = ibf_table_index(dump->iseq_table, (st_data_t)iseq);
rb_ary_store(dump->iseq_list, iseq_index, LONG2NUM(ibf_dump_iseq_each(dump, rb_iseq_check(iseq))));
}
return (rb_iseq_t *)(VALUE)iseq_index;
}
}
static VALUE
ibf_dump_gentry(struct ibf_dump *dump, const struct rb_global_entry *entry)
{
return (VALUE)ibf_dump_id(dump, entry->id);
}
static VALUE
ibf_load_gentry(const struct ibf_load *load, const struct rb_global_entry *entry)
{
ID gid = ibf_load_id(load, (ID)(VALUE)entry);
return (VALUE)rb_global_entry(gid);
}
static VALUE *
ibf_dump_code(struct ibf_dump *dump, const rb_iseq_t *iseq)
{
const int iseq_size = iseq->body->iseq_size;
int code_index;
VALUE *code;
const VALUE *orig_code = rb_iseq_original_iseq(iseq);
code = ALLOCA_N(VALUE, iseq_size);
for (code_index=0; code_index<iseq_size;) {
const VALUE insn = orig_code[code_index];
const char *types = insn_op_types(insn);
int op_index;
code[code_index++] = (VALUE)insn;
for (op_index=0; types[op_index]; op_index++, code_index++) {
VALUE op = orig_code[code_index];
switch (types[op_index]) {
case TS_CDHASH:
case TS_VALUE:
code[code_index] = ibf_dump_object(dump, op);
break;
case TS_ISEQ:
code[code_index] = (VALUE)ibf_dump_iseq(dump, (const rb_iseq_t *)op);
break;
case TS_IC:
{
unsigned int i;
for (i=0; i<iseq->body->is_size; i++) {
if (op == (VALUE)&iseq->body->is_entries[i]) {
break;
}
}
code[code_index] = i;
}
break;
case TS_CALLINFO:
code[code_index] = ibf_dump_callinfo(dump, (const struct rb_call_info *)op);
break;
case TS_CALLCACHE:
code[code_index] = 0;
break;
case TS_ID:
code[code_index] = ibf_dump_id(dump, (ID)op);
break;
case TS_GENTRY:
code[code_index] = ibf_dump_gentry(dump, (const struct rb_global_entry *)op);
break;
case TS_FUNCPTR:
rb_raise(rb_eRuntimeError, "TS_FUNCPTR is not supported");
break;
default:
code[code_index] = op;
break;
}
}
assert(insn_len(insn) == op_index+1);
}
return IBF_W(code, VALUE, iseq_size);
}
static VALUE *
ibf_load_code(const struct ibf_load *load, const rb_iseq_t *iseq, const struct rb_iseq_constant_body *body)
{
const int iseq_size = body->iseq_size;
int code_index;
VALUE *code = IBF_R(body->iseq_encoded, VALUE, iseq_size);
struct rb_call_info *ci_entries = iseq->body->ci_entries;
struct rb_call_info_with_kwarg *ci_kw_entries = (struct rb_call_info_with_kwarg *)&iseq->body->ci_entries[iseq->body->ci_size];
struct rb_call_cache *cc_entries = iseq->body->cc_entries;
union iseq_inline_storage_entry *is_entries = iseq->body->is_entries;
for (code_index=0; code_index<iseq_size;) {
const VALUE insn = code[code_index++];
const char *types = insn_op_types(insn);
int op_index;
for (op_index=0; types[op_index]; op_index++, code_index++) {
VALUE op = code[code_index];
switch (types[op_index]) {
case TS_CDHASH:
case TS_VALUE:
code[code_index] = ibf_load_object(load, op);
break;
case TS_ISEQ:
code[code_index] = (VALUE)ibf_load_iseq(load, (const rb_iseq_t *)op);
break;
case TS_IC:
code[code_index] = (VALUE)&is_entries[(int)op];
break;
case TS_CALLINFO:
code[code_index] = op ? (VALUE)ci_kw_entries++ : (VALUE)ci_entries++; /* op is Qtrue (kw) or Qfalse (!kw) */
break;
case TS_CALLCACHE:
code[code_index] = (VALUE)cc_entries++;
break;
case TS_ID:
code[code_index] = ibf_load_id(load, (ID)op);
break;
case TS_GENTRY:
code[code_index] = ibf_load_gentry(load, (const struct rb_global_entry *)op);
break;
case TS_FUNCPTR:
rb_raise(rb_eRuntimeError, "TS_FUNCPTR is not supported");
break;
default:
/* code[code_index] = op; */
break;
}
}
assert(insn_len(insn) == op_index+1);
};
return code;
}
static VALUE *
ibf_dump_param_opt_table(struct ibf_dump *dump, const rb_iseq_t *iseq)
{
int opt_num = iseq->body->param.opt_num;
if (opt_num > 0) {
return IBF_W(iseq->body->param.opt_table, VALUE, opt_num + 1);
}
else {
return NULL;
}
}
static VALUE *
ibf_load_param_opt_table(const struct ibf_load *load, const struct rb_iseq_constant_body *body)
{
int opt_num = body->param.opt_num;
if (opt_num > 0) {
ibf_offset_t offset = IBF_OFFSET(body->param.opt_table);
VALUE *table = ALLOC_N(VALUE, opt_num+1);
MEMCPY(table, load->buff + offset, VALUE, opt_num+1);
return table;
}
else {
return NULL;
}
}
static struct rb_iseq_param_keyword *
ibf_dump_param_keyword(struct ibf_dump *dump, const rb_iseq_t *iseq)
{
const struct rb_iseq_param_keyword *kw = iseq->body->param.keyword;
if (kw) {
struct rb_iseq_param_keyword dump_kw = *kw;
int dv_num = kw->num - kw->required_num;
ID *ids = kw->num > 0 ? ALLOCA_N(ID, kw->num) : NULL;
VALUE *dvs = dv_num > 0 ? ALLOCA_N(VALUE, dv_num) : NULL;
int i;
for (i=0; i<kw->num; i++) ids[i] = (ID)ibf_dump_id(dump, kw->table[i]);
for (i=0; i<dv_num; i++) dvs[i] = (VALUE)ibf_dump_object(dump, kw->default_values[i]);
dump_kw.table = IBF_W(ids, ID, kw->num);
dump_kw.default_values = IBF_W(dvs, VALUE, dv_num);
return IBF_W(&dump_kw, struct rb_iseq_param_keyword, 1);
}
else {
return NULL;
}
}
static const struct rb_iseq_param_keyword *
ibf_load_param_keyword(const struct ibf_load *load, const struct rb_iseq_constant_body *body)
{
if (body->param.keyword) {
struct rb_iseq_param_keyword *kw = IBF_R(body->param.keyword, struct rb_iseq_param_keyword, 1);
ID *ids = IBF_R(kw->table, ID, kw->num);
int dv_num = kw->num - kw->required_num;
VALUE *dvs = IBF_R(kw->default_values, VALUE, dv_num);
int i;
for (i=0; i<kw->num; i++) {
ids[i] = ibf_load_id(load, ids[i]);
}
for (i=0; i<dv_num; i++) {
dvs[i] = ibf_load_object(load, dvs[i]);
}
kw->table = ids;
kw->default_values = dvs;
return kw;
}
else {
return NULL;
}
}
static struct iseq_line_info_entry *
ibf_dump_line_info_table(struct ibf_dump *dump, const rb_iseq_t *iseq)
{
return IBF_W(iseq->body->line_info_table, struct iseq_line_info_entry, iseq->body->line_info_size);
}
static struct iseq_line_info_entry *
ibf_load_line_info_table(const struct ibf_load *load, const struct rb_iseq_constant_body *body)
{
return IBF_R(body->line_info_table, struct iseq_line_info_entry, body->line_info_size);
}
static ID *
ibf_dump_local_table(struct ibf_dump *dump, const rb_iseq_t *iseq)
{
const int size = iseq->body->local_size - 1;
ID *table = ALLOCA_N(ID, size);
int i;
for (i=0; i<size; i++) {
table[i] = ibf_dump_id(dump, iseq->body->local_table[i]);
}
return IBF_W(table, ID, size);
}
static ID *
ibf_load_local_table(const struct ibf_load *load, const struct rb_iseq_constant_body *body)
{
const int size = body->local_size - 1;
if (size > 0) {
ID *table = IBF_R(body->local_table, ID, size);
int i;
for (i=0; i<size; i++) {
table[i] = ibf_load_id(load, table[i]);
}
return table;
}
else {
return NULL;
}
}
static struct iseq_catch_table *
ibf_dump_catch_table(struct ibf_dump *dump, const rb_iseq_t *iseq)
{
const struct iseq_catch_table *table = iseq->body->catch_table;
if (table) {
int byte_size = iseq_catch_table_bytes(iseq->body->catch_table->size);
struct iseq_catch_table *dump_table = (struct iseq_catch_table *)ALLOCA_N(char, byte_size);
unsigned int i;
dump_table->size = table->size;
for (i=0; i<table->size; i++) {
dump_table->entries[i] = table->entries[i];
dump_table->entries[i].iseq = ibf_dump_iseq(dump, table->entries[i].iseq);
}
return (struct iseq_catch_table *)(VALUE)ibf_dump_write(dump, dump_table, byte_size);
}
else {
return NULL;
}
}
static struct iseq_catch_table *
ibf_load_catch_table(const struct ibf_load *load, const struct rb_iseq_constant_body *body)
{
if (body->catch_table) {
struct iseq_catch_table *table;
unsigned int i;
unsigned int size;
size = *(unsigned int *)(load->buff + IBF_OFFSET(body->catch_table));
table = ibf_load_alloc(load, IBF_OFFSET(body->catch_table), iseq_catch_table_bytes(size));
for (i=0; i<size; i++) {
table->entries[i].iseq = ibf_load_iseq(load, table->entries[i].iseq);
}
return table;
}
else {
return NULL;
}
}
static struct rb_call_info *
ibf_dump_ci_entries(struct ibf_dump *dump, const rb_iseq_t *iseq)
{
const unsigned int ci_size = iseq->body->ci_size;
const unsigned int ci_kw_size = iseq->body->ci_kw_size;
const struct rb_call_info *ci_entries = iseq->body->ci_entries;
struct rb_call_info *dump_ci_entries;
struct rb_call_info_with_kwarg *dump_ci_kw_entries;
int byte_size = ci_size * sizeof(struct rb_call_info) +
ci_kw_size * sizeof(struct rb_call_info_with_kwarg);
unsigned int i;
dump_ci_entries = (struct rb_call_info *)ALLOCA_N(char, byte_size);
dump_ci_kw_entries = (struct rb_call_info_with_kwarg *)&dump_ci_entries[ci_size];
memcpy(dump_ci_entries, ci_entries, byte_size);
for (i=0; i<ci_size; i++) { /* conver ID for each ci */
dump_ci_entries[i].mid = ibf_dump_id(dump, dump_ci_entries[i].mid);
}
for (i=0; i<ci_kw_size; i++) {
const struct rb_call_info_kw_arg *kw_arg = dump_ci_kw_entries[i].kw_arg;
int j;
VALUE *keywords = ALLOCA_N(VALUE, kw_arg->keyword_len);
for (j=0; j<kw_arg->keyword_len; j++) {
keywords[j] = (VALUE)ibf_dump_object(dump, kw_arg->keywords[j]); /* kw_arg->keywords[n] is Symbol */
}
dump_ci_kw_entries[i].kw_arg = (struct rb_call_info_kw_arg *)(VALUE)ibf_dump_write(dump, &kw_arg->keyword_len, sizeof(int));
ibf_dump_write(dump, keywords, sizeof(VALUE) * kw_arg->keyword_len);
dump_ci_kw_entries[i].ci.mid = ibf_dump_id(dump, dump_ci_kw_entries[i].ci.mid);
}
return (struct rb_call_info *)(VALUE)ibf_dump_write(dump, dump_ci_entries, byte_size);
}
static struct rb_call_info *
ibf_load_ci_entries(const struct ibf_load *load, const struct rb_iseq_constant_body *body)
{
unsigned int i;
const unsigned int ci_size = body->ci_size;
const unsigned int ci_kw_size = body->ci_kw_size;
struct rb_call_info *ci_entries = ibf_load_alloc(load, IBF_OFFSET(body->ci_entries),
sizeof(struct rb_call_info) * body->ci_size +
sizeof(struct rb_call_info_with_kwarg) * body->ci_kw_size);
struct rb_call_info_with_kwarg *ci_kw_entries = (struct rb_call_info_with_kwarg *)&ci_entries[ci_size];
for (i=0; i<ci_size; i++) {
ci_entries[i].mid = ibf_load_id(load, ci_entries[i].mid);
}
for (i=0; i<ci_kw_size; i++) {
int j;
ibf_offset_t kw_arg_offset = IBF_OFFSET(ci_kw_entries[i].kw_arg);
const int keyword_len = *(int *)(load->buff + kw_arg_offset);
const VALUE *keywords = (VALUE *)(load->buff + kw_arg_offset + sizeof(int));
struct rb_call_info_kw_arg *kw_arg = ruby_xmalloc(sizeof(struct rb_call_info_kw_arg) + sizeof(VALUE) * (keyword_len - 1));
kw_arg->keyword_len = keyword_len;
for (j=0; j<kw_arg->keyword_len; j++) {
kw_arg->keywords[j] = (VALUE)ibf_load_object(load, keywords[j]);
}
ci_kw_entries[i].kw_arg = kw_arg;
ci_kw_entries[i].ci.mid = ibf_load_id(load, ci_kw_entries[i].ci.mid);
}
return ci_entries;
}
static ibf_offset_t
ibf_dump_iseq_each(struct ibf_dump *dump, const rb_iseq_t *iseq)
{
struct rb_iseq_constant_body dump_body;
dump_body = *iseq->body;
dump_body.location.path = ibf_dump_object(dump, dump_body.location.path);
dump_body.location.absolute_path = ibf_dump_object(dump, dump_body.location.absolute_path);
dump_body.location.base_label = ibf_dump_object(dump, dump_body.location.base_label);
dump_body.location.label = ibf_dump_object(dump, dump_body.location.label);
dump_body.iseq_encoded = ibf_dump_code(dump, iseq);
dump_body.param.opt_table = ibf_dump_param_opt_table(dump, iseq);
dump_body.param.keyword = ibf_dump_param_keyword(dump, iseq);
dump_body.line_info_table = ibf_dump_line_info_table(dump, iseq);
dump_body.local_table = ibf_dump_local_table(dump, iseq);
dump_body.catch_table = ibf_dump_catch_table(dump, iseq);
dump_body.parent_iseq = ibf_dump_iseq(dump, iseq->body->parent_iseq);
dump_body.local_iseq = ibf_dump_iseq(dump, iseq->body->local_iseq);
dump_body.is_entries = NULL;
dump_body.ci_entries = ibf_dump_ci_entries(dump, iseq);
dump_body.cc_entries = NULL;
dump_body.mark_ary = ISEQ_FLIP_CNT(iseq);
return ibf_dump_write(dump, &dump_body, sizeof(dump_body));
}
static VALUE
ibf_load_location_str(const struct ibf_load *load, VALUE str_index)
{
VALUE str = ibf_load_object(load, str_index);
if (str != Qnil) {
str = rb_fstring(str);
}
return str;
}
static void
ibf_load_iseq_each(const struct ibf_load *load, rb_iseq_t *iseq, ibf_offset_t offset)
{
struct rb_iseq_constant_body *load_body = iseq->body = ZALLOC(struct rb_iseq_constant_body);
const struct rb_iseq_constant_body *body = (struct rb_iseq_constant_body *)(load->buff + offset);
/* memcpy(load_body, load->buff + offset, sizeof(*load_body)); */
load_body->type = body->type;
load_body->stack_max = body->stack_max;
load_body->local_size = body->local_size;
load_body->iseq_size = body->iseq_size;
load_body->param = body->param;
load_body->local_table_size = body->local_table_size;
load_body->is_size = body->is_size;
load_body->ci_size = body->ci_size;
load_body->ci_kw_size = body->ci_kw_size;
load_body->line_info_size = body->line_info_size;
RB_OBJ_WRITE(iseq, &load_body->mark_ary, iseq_mark_ary_create((int)body->mark_ary));
RB_OBJ_WRITE(iseq, &load_body->location.path, ibf_load_location_str(load, body->location.path));
RB_OBJ_WRITE(iseq, &load_body->location.absolute_path, ibf_load_location_str(load, body->location.absolute_path));
RB_OBJ_WRITE(iseq, &load_body->location.base_label, ibf_load_location_str(load, body->location.base_label));
RB_OBJ_WRITE(iseq, &load_body->location.label, ibf_load_location_str(load, body->location.label));
load_body->location.first_lineno = body->location.first_lineno;
load_body->is_entries = ZALLOC_N(union iseq_inline_storage_entry, body->is_size);
load_body->ci_entries = ibf_load_ci_entries(load, body);
load_body->cc_entries = ZALLOC_N(struct rb_call_cache, body->ci_size + body->ci_kw_size);
load_body->param.opt_table = ibf_load_param_opt_table(load, body);
load_body->param.keyword = ibf_load_param_keyword(load, body);
load_body->line_info_table = ibf_load_line_info_table(load, body);
load_body->local_table = ibf_load_local_table(load, body);
load_body->catch_table = ibf_load_catch_table(load, body);
load_body->parent_iseq = ibf_load_iseq(load, body->parent_iseq);
load_body->local_iseq = ibf_load_iseq(load, body->local_iseq);
load_body->iseq_encoded = ibf_load_code(load, iseq, body);
rb_iseq_translate_threaded_code(iseq);
}
static void
ibf_dump_iseq_list(struct ibf_dump *dump, struct ibf_header *header)
{
const long size = RARRAY_LEN(dump->iseq_list);
ibf_offset_t *list = ALLOCA_N(ibf_offset_t, size);
long i;
for (i=0; i<size; i++) {
list[i] = (ibf_offset_t)NUM2LONG(rb_ary_entry(dump->iseq_list, i));
}
header->iseq_list_offset = ibf_dump_write(dump, list, sizeof(ibf_offset_t) * size);
header->iseq_list_size = (unsigned int)size;
}
struct ibf_dump_id_list_i_arg {
struct ibf_dump *dump;
long *list;
int current_i;
};
static int
ibf_dump_id_list_i(st_data_t key, st_data_t val, st_data_t ptr)
{
struct ibf_dump_id_list_i_arg *arg = (struct ibf_dump_id_list_i_arg *)ptr;
int i = (int)val;
ID id = (ID)key;
assert(arg->current_i == i);
arg->current_i++;
if (rb_id2name(id)) {
arg->list[i] = (long)ibf_dump_object(arg->dump, rb_id2str(id));
}
else {
arg->list[i] = 0;
}
return ST_CONTINUE;
}
static void
ibf_dump_id_list(struct ibf_dump *dump, struct ibf_header *header)
{
const long size = dump->id_table->num_entries;
struct ibf_dump_id_list_i_arg arg;
arg.list = ALLOCA_N(long, size);
arg.dump = dump;
arg.current_i = 0;
st_foreach(dump->id_table, ibf_dump_id_list_i, (st_data_t)&arg);
header->id_list_offset = ibf_dump_write(dump, arg.list, sizeof(long) * size);
header->id_list_size = (unsigned int)size;
}
#define IBF_OBJECT_INTERNAL FL_PROMOTED0
/*
* Binary format
* - ibf_object_header
* - ibf_object_xxx (xxx is type)
*/
struct ibf_object_header {
unsigned int type: 5;
unsigned int special_const: 1;
unsigned int frozen: 1;
unsigned int internal: 1;
};
enum ibf_object_class_index {
IBF_OBJECT_CLASS_OBJECT,
IBF_OBJECT_CLASS_ARRAY,
IBF_OBJECT_CLASS_STANDARD_ERROR
};
struct ibf_object_string {
long encindex;
long len;
char ptr[1];
};
struct ibf_object_regexp {
long srcstr;
char option;
};
struct ibf_object_array {
long len;
long ary[1];
};
struct ibf_object_hash {
long len;
long keyval[1];
};
struct ibf_object_struct_range {
long class_index;
long len;
long beg;
long end;
int excl;
};
struct ibf_object_bignum {
ssize_t slen;
BDIGIT digits[1];
};
enum ibf_object_data_type {
IBF_OBJECT_DATA_ENCODING
};
struct ibf_object_complex_rational {
long a, b;
};
struct ibf_object_symbol {
long str;
};
#define IBF_OBJHEADER(offset) (struct ibf_object_header *)(load->buff + (offset))
#define IBF_OBJBODY(type, offset) (type *)(load->buff + sizeof(struct ibf_object_header) + (offset))
static void
ibf_dump_object_unsupported(struct ibf_dump *dump, VALUE obj)
{
rb_obj_info_dump(obj);
rb_bug("ibf_dump_object_unsupported: unsupported");
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
}
static VALUE
ibf_load_object_unsupported(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
rb_bug("unsupported");
return Qnil;
}
static void
ibf_dump_object_class(struct ibf_dump *dump, VALUE obj)
{
enum ibf_object_class_index cindex;
if (obj == rb_cObject) {
cindex = IBF_OBJECT_CLASS_OBJECT;
}
else if (obj == rb_cArray) {
cindex = IBF_OBJECT_CLASS_ARRAY;
}
else if (obj == rb_eStandardError) {
cindex = IBF_OBJECT_CLASS_STANDARD_ERROR;
}
else {
rb_obj_info_dump(obj);
rb_p(obj);
rb_bug("unsupported class");
}
ibf_dump_write(dump, &cindex, sizeof(cindex));
}
static VALUE
ibf_load_object_class(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
enum ibf_object_class_index *cindexp = IBF_OBJBODY(enum ibf_object_class_index, offset);
enum ibf_object_class_index cindex = *cindexp;
switch (cindex) {
case IBF_OBJECT_CLASS_OBJECT:
return rb_cObject;
case IBF_OBJECT_CLASS_ARRAY:
return rb_cArray;
case IBF_OBJECT_CLASS_STANDARD_ERROR:
return rb_eStandardError;
}
rb_bug("ibf_load_object_class: unknown class (%d)", (int)cindex);
}
static void
ibf_dump_object_float(struct ibf_dump *dump, VALUE obj)
{
double dbl = RFLOAT_VALUE(obj);
ibf_dump_write(dump, &dbl, sizeof(dbl));
}
static VALUE
ibf_load_object_float(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
double *dblp = IBF_OBJBODY(double, offset);
return DBL2NUM(*dblp);
}
static void
ibf_dump_object_string(struct ibf_dump *dump, VALUE obj)
{
long encindex = (long)rb_enc_get_index(obj);
long len = RSTRING_LEN(obj);
const char *ptr = RSTRING_PTR(obj);
if (encindex > RUBY_ENCINDEX_BUILTIN_MAX) {
rb_encoding *enc = rb_enc_from_index((int)encindex);
const char *enc_name = rb_enc_name(enc);
encindex = RUBY_ENCINDEX_BUILTIN_MAX + ibf_dump_object(dump, rb_str_new2(enc_name));
}
IBF_WV(encindex);
IBF_WV(len);
IBF_WP(ptr, char, len);
}
static VALUE
ibf_load_object_string(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
const struct ibf_object_string *string = IBF_OBJBODY(struct ibf_object_string, offset);
VALUE str = rb_str_new(string->ptr, string->len);
int encindex = (int)string->encindex;
if (encindex > RUBY_ENCINDEX_BUILTIN_MAX) {
VALUE enc_name_str = ibf_load_object(load, encindex - RUBY_ENCINDEX_BUILTIN_MAX);
encindex = rb_enc_find_index(RSTRING_PTR(enc_name_str));
}
rb_enc_associate_index(str, encindex);
if (header->internal) rb_obj_hide(str);
if (header->frozen) str = rb_fstring(str);
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
return str;
}
static void
ibf_dump_object_regexp(struct ibf_dump *dump, VALUE obj)
{
struct ibf_object_regexp regexp;
regexp.srcstr = RREGEXP_SRC(obj);
regexp.option = (char)rb_reg_options(obj);
regexp.srcstr = (long)ibf_dump_object(dump, regexp.srcstr);
IBF_WV(regexp);
}
static VALUE
ibf_load_object_regexp(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
const struct ibf_object_regexp *regexp = IBF_OBJBODY(struct ibf_object_regexp, offset);
VALUE srcstr = ibf_load_object(load, regexp->srcstr);
VALUE reg = rb_reg_compile(srcstr, (int)regexp->option, NULL, 0);
if (header->internal) rb_obj_hide(reg);
if (header->frozen) rb_obj_freeze(reg);
return reg;
}
static void
ibf_dump_object_array(struct ibf_dump *dump, VALUE obj)
{
long i, len = (int)RARRAY_LEN(obj);
IBF_WV(len);
for (i=0; i<len; i++) {
long index = (long)ibf_dump_object(dump, RARRAY_AREF(obj, i));
IBF_WV(index);
}
}
static VALUE
ibf_load_object_array(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
const struct ibf_object_array *array = IBF_OBJBODY(struct ibf_object_array, offset);
VALUE ary = rb_ary_new_capa(array->len);
int i;
for (i=0; i<array->len; i++) {
rb_ary_push(ary, ibf_load_object(load, array->ary[i]));
}
if (header->internal) rb_obj_hide(ary);
if (header->frozen) rb_obj_freeze(ary);
return ary;
}
static int
ibf_dump_object_hash_i(st_data_t key, st_data_t val, st_data_t ptr)
{
struct ibf_dump *dump = (struct ibf_dump *)ptr;
long key_index = (long)ibf_dump_object(dump, (VALUE)key);
long val_index = (long)ibf_dump_object(dump, (VALUE)val);
IBF_WV(key_index);
IBF_WV(val_index);
return ST_CONTINUE;
}
static void
ibf_dump_object_hash(struct ibf_dump *dump, VALUE obj)
{
long len = RHASH_SIZE(obj);
IBF_WV(len);
if (len > 0) st_foreach(RHASH(obj)->ntbl, ibf_dump_object_hash_i, (st_data_t)dump);
}
static VALUE
ibf_load_object_hash(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
const struct ibf_object_hash *hash = IBF_OBJBODY(struct ibf_object_hash, offset);
VALUE obj = rb_hash_new();
int i;
for (i=0; i<hash->len; i++) {
VALUE key = ibf_load_object(load, hash->keyval[i*2 ]);
VALUE val = ibf_load_object(load, hash->keyval[i*2+1]);
rb_hash_aset(obj, key, val);
}
rb_hash_rehash(obj);
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
if (header->internal) rb_obj_hide(obj);
if (header->frozen) rb_obj_freeze(obj);
return obj;
}
static void
ibf_dump_object_struct(struct ibf_dump *dump, VALUE obj)
{
if (rb_obj_is_kind_of(obj, rb_cRange)) {
struct ibf_object_struct_range range;
VALUE beg, end;
range.len = 3;
range.class_index = 0;
rb_range_values(obj, &beg, &end, &range.excl);
range.beg = (long)ibf_dump_object(dump, beg);
range.end = (long)ibf_dump_object(dump, end);
IBF_WV(range);
}
else {
rb_bug("ibf_dump_object_struct: unsupported class");
}
}
static VALUE
ibf_load_object_struct(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
const struct ibf_object_struct_range *range = IBF_OBJBODY(struct ibf_object_struct_range, offset);
VALUE beg = ibf_load_object(load, range->beg);
VALUE end = ibf_load_object(load, range->end);
VALUE obj = rb_range_new(beg, end, range->excl);
if (header->internal) rb_obj_hide(obj);
if (header->frozen) rb_obj_freeze(obj);
return obj;
}
static void
ibf_dump_object_bignum(struct ibf_dump *dump, VALUE obj)
{
ssize_t len = BIGNUM_LEN(obj);
ssize_t slen = BIGNUM_SIGN(obj) > 0 ? len : len * -1;
BDIGIT *d = BIGNUM_DIGITS(obj);
IBF_WV(slen);
IBF_WP(d, BDIGIT, len);
}
static VALUE
ibf_load_object_bignum(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
const struct ibf_object_bignum *bignum = IBF_OBJBODY(struct ibf_object_bignum, offset);
int sign = bignum->slen > 0;
ssize_t len = sign > 0 ? bignum->slen : -1 * bignum->slen;
VALUE obj = rb_integer_unpack(bignum->digits, len * 2, 2, 0,
INTEGER_PACK_LITTLE_ENDIAN | (sign == 0 ? INTEGER_PACK_NEGATIVE : 0));
if (header->internal) rb_obj_hide(obj);
if (header->frozen) rb_obj_freeze(obj);
return obj;
}
static void
ibf_dump_object_data(struct ibf_dump *dump, VALUE obj)
{
if (rb_data_is_encoding(obj)) {
rb_encoding *enc = rb_to_encoding(obj);
const char *name = rb_enc_name(enc);
enum ibf_object_data_type type = IBF_OBJECT_DATA_ENCODING;
long len = strlen(name) + 1;
IBF_WV(type);
IBF_WV(len);
IBF_WP(name, char, strlen(name) + 1);
}
else {
ibf_dump_object_unsupported(dump, obj);
}
}
static VALUE
ibf_load_object_data(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
const enum ibf_object_data_type *typep = IBF_OBJBODY(enum ibf_object_data_type, offset);
/* const long *lenp = IBF_OBJBODY(long, offset + sizeof(enum ibf_object_data_type)); */
const char *data = IBF_OBJBODY(char, offset + sizeof(enum ibf_object_data_type) + sizeof(long));
switch (*typep) {
case IBF_OBJECT_DATA_ENCODING:
{
VALUE encobj = rb_enc_from_encoding(rb_enc_find(data));
return encobj;
}
}
return ibf_load_object_unsupported(load, header, offset);
}
static void
ibf_dump_object_complex_rational(struct ibf_dump *dump, VALUE obj)
{
long real = (long)ibf_dump_object(dump, RCOMPLEX(obj)->real);
long imag = (long)ibf_dump_object(dump, RCOMPLEX(obj)->imag);
IBF_WV(real);
IBF_WV(imag);
}
static VALUE
ibf_load_object_complex_rational(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
const struct ibf_object_complex_rational *nums = IBF_OBJBODY(struct ibf_object_complex_rational, offset);
VALUE a = ibf_load_object(load, nums->a);
VALUE b = ibf_load_object(load, nums->b);
VALUE obj = header->type == T_COMPLEX ?
rb_complex_new(a, b) : rb_rational_new(a, b);
if (header->internal) rb_obj_hide(obj);
if (header->frozen) rb_obj_freeze(obj);
return obj;
}
static void
ibf_dump_object_symbol(struct ibf_dump *dump, VALUE obj)
{
VALUE str = rb_sym2str(obj);
long str_index = (long)ibf_dump_object(dump, str);
IBF_WV(str_index);
}
static VALUE
ibf_load_object_symbol(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t offset)
{
/* const struct ibf_object_header *header = IBF_OBJHEADER(offset); */
const struct ibf_object_symbol *symbol = IBF_OBJBODY(struct ibf_object_symbol, offset);
VALUE str = ibf_load_object(load, symbol->str);
ID id = rb_intern_str(str);
return ID2SYM(id);
}
typedef void (*ibf_dump_object_function)(struct ibf_dump *dump, VALUE obj);
static ibf_dump_object_function dump_object_functions[RUBY_T_MASK+1] = {
ibf_dump_object_unsupported, /* T_NONE */
ibf_dump_object_unsupported, /* T_OBJECT */
ibf_dump_object_class, /* T_CLASS */
ibf_dump_object_unsupported, /* T_MODULE */
ibf_dump_object_float, /* T_FLOAT */
ibf_dump_object_string, /* T_STRING */
ibf_dump_object_regexp, /* T_REGEXP */
ibf_dump_object_array, /* T_ARRAY */
ibf_dump_object_hash, /* T_HASH */
ibf_dump_object_struct, /* T_STRUCT */
ibf_dump_object_bignum, /* T_BIGNUM */
ibf_dump_object_unsupported, /* T_FILE */
ibf_dump_object_data, /* T_DATA */
ibf_dump_object_unsupported, /* T_MATCH */
ibf_dump_object_complex_rational, /* T_COMPLEX */
ibf_dump_object_complex_rational, /* T_RATIONAL */
ibf_dump_object_unsupported, /* 0x10 */
ibf_dump_object_unsupported, /* 0x11 T_NIL */
ibf_dump_object_unsupported, /* 0x12 T_TRUE */
ibf_dump_object_unsupported, /* 0x13 T_FALSE */
ibf_dump_object_symbol, /* 0x14 T_SYMBOL */
ibf_dump_object_unsupported, /* T_FIXNUM */
ibf_dump_object_unsupported, /* T_UNDEF */
ibf_dump_object_unsupported, /* 0x17 */
ibf_dump_object_unsupported, /* 0x18 */
ibf_dump_object_unsupported, /* 0x19 */
ibf_dump_object_unsupported, /* T_IMEMO 0x1a */
ibf_dump_object_unsupported, /* T_NODE 0x1b */
ibf_dump_object_unsupported, /* T_ICLASS 0x1c */
ibf_dump_object_unsupported, /* T_ZOMBIE 0x1d */
ibf_dump_object_unsupported, /* 0x1e */
ibf_dump_object_unsupported /* 0x1f */
};
static ibf_offset_t
lbf_dump_object_object(struct ibf_dump *dump, VALUE obj)
{
struct ibf_object_header obj_header;
ibf_offset_t current_offset = ibf_dump_pos(dump);
obj_header.type = TYPE(obj);
if (SPECIAL_CONST_P(obj)) {
if (RB_TYPE_P(obj, T_SYMBOL) ||
RB_TYPE_P(obj, T_FLOAT)) {
obj_header.internal = FALSE;
goto dump_object;
}
obj_header.special_const = TRUE;
obj_header.frozen = TRUE;
obj_header.internal = TRUE;
IBF_WV(obj_header);
IBF_WV(obj);
}
else {
obj_header.internal = (RBASIC_CLASS(obj) == 0) ? TRUE : FALSE;
dump_object:
obj_header.special_const = FALSE;
obj_header.frozen = FL_TEST(obj, FL_FREEZE) ? TRUE : FALSE;
IBF_WV(obj_header);
(*dump_object_functions[obj_header.type])(dump, obj);
}
return current_offset;
}
typedef VALUE (*ibf_load_object_function)(const struct ibf_load *load, const struct ibf_object_header *header, ibf_offset_t);
static ibf_load_object_function load_object_functions[RUBY_T_MASK+1] = {
ibf_load_object_unsupported, /* T_NONE */
ibf_load_object_unsupported, /* T_OBJECT */
ibf_load_object_class, /* T_CLASS */
ibf_load_object_unsupported, /* T_MODULE */
ibf_load_object_float, /* T_FLOAT */
ibf_load_object_string, /* T_STRING */
ibf_load_object_regexp, /* T_REGEXP */
ibf_load_object_array, /* T_ARRAY */
ibf_load_object_hash, /* T_HASH */
ibf_load_object_struct, /* T_STRUCT */
ibf_load_object_bignum, /* T_BIGNUM */
ibf_load_object_unsupported, /* T_FILE */
ibf_load_object_data, /* T_DATA */
ibf_load_object_unsupported, /* T_MATCH */
ibf_load_object_complex_rational, /* T_COMPLEX */
ibf_load_object_complex_rational, /* T_RATIONAL */
ibf_load_object_unsupported, /* 0x10 */
ibf_load_object_unsupported, /* T_NIL */
ibf_load_object_unsupported, /* T_TRUE */
ibf_load_object_unsupported, /* T_FALSE */
ibf_load_object_symbol,
ibf_load_object_unsupported, /* T_FIXNUM */
ibf_load_object_unsupported, /* T_UNDEF */
ibf_load_object_unsupported, /* 0x17 */
ibf_load_object_unsupported, /* 0x18 */
ibf_load_object_unsupported, /* 0x19 */
ibf_load_object_unsupported, /* T_IMEMO 0x1a */
ibf_load_object_unsupported, /* T_NODE 0x1b */
ibf_load_object_unsupported, /* T_ICLASS 0x1c */
ibf_load_object_unsupported, /* T_ZOMBIE 0x1d */
ibf_load_object_unsupported, /* 0x1e */
ibf_load_object_unsupported /* 0x1f */
};
static VALUE
ibf_load_object(const struct ibf_load *load, VALUE object_index)
{
if (object_index == 0) {
return Qnil;
}
else if (object_index >= load->header->object_list_size) {
rb_raise(rb_eIndexError, "object index out of range: %"PRIdVALUE, object_index);
}
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
else {
VALUE obj = rb_ary_entry(load->obj_list, (long)object_index);
if (obj == Qnil) { /* TODO: avoid multiple Qnil load */
ibf_offset_t *offsets = (ibf_offset_t *)(load->header->object_list_offset + load->buff);
ibf_offset_t offset = offsets[object_index];
const struct ibf_object_header *header = IBF_OBJHEADER(offset);
if (header->special_const) {
VALUE *vp = IBF_OBJBODY(VALUE, offset);
obj = *vp;
}
else {
obj = (*load_object_functions[header->type])(load, header, offset);
}
rb_ary_store(load->obj_list, (long)object_index, obj);
}
iseq_add_mark_object(load->iseq, obj);
return obj;
}
}
static void
ibf_dump_object_list(struct ibf_dump *dump, struct ibf_header *header)
{
VALUE list = rb_ary_tmp_new(RARRAY_LEN(dump->obj_list));
int i, size;
for (i=0; i<RARRAY_LEN(dump->obj_list); i++) {
VALUE obj = RARRAY_AREF(dump->obj_list, i);
ibf_offset_t offset = lbf_dump_object_object(dump, obj);
rb_ary_push(list, UINT2NUM(offset));
}
size = i;
header->object_list_offset = ibf_dump_pos(dump);
for (i=0; i<size; i++) {
ibf_offset_t offset = NUM2UINT(RARRAY_AREF(list, i));
IBF_WV(offset);
}
header->object_list_size = size;
}
static void
ibf_dump_mark(void *ptr)
{
struct ibf_dump *dump = (struct ibf_dump *)ptr;
rb_gc_mark(dump->str);
rb_gc_mark(dump->iseq_list);
rb_gc_mark(dump->obj_list);
}
static void
ibf_dump_free(void *ptr)
{
struct ibf_dump *dump = (struct ibf_dump *)ptr;
if (dump->iseq_table) {
st_free_table(dump->iseq_table);
dump->iseq_table = 0;
}
if (dump->id_table) {
st_free_table(dump->id_table);
dump->id_table = 0;
}
ruby_xfree(dump);
}
static size_t
ibf_dump_memsize(const void *ptr)
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
{
struct ibf_dump *dump = (struct ibf_dump *)ptr;
size_t size = sizeof(*dump);
if (dump->iseq_table) size += st_memsize(dump->iseq_table);
if (dump->id_table) size += st_memsize(dump->id_table);
return size;
}
static const rb_data_type_t ibf_dump_type = {
"ibf_dump",
{ibf_dump_mark, ibf_dump_free, ibf_dump_memsize,},
0, 0, RUBY_TYPED_WB_PROTECTED | RUBY_TYPED_FREE_IMMEDIATELY
};
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
static void
ibf_dump_setup(struct ibf_dump *dump, VALUE dumper_obj)
{
RB_OBJ_WRITE(dumper_obj, &dump->str, rb_str_new(0, 0));
RB_OBJ_WRITE(dumper_obj, &dump->iseq_list, rb_ary_tmp_new(0));
RB_OBJ_WRITE(dumper_obj, &dump->obj_list, rb_ary_tmp_new(1));
rb_ary_push(dump->obj_list, Qnil); /* 0th is nil */
dump->iseq_table = st_init_numtable(); /* need free */
dump->id_table = st_init_numtable(); /* need free */
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
ibf_table_index(dump->id_table, 0); /* id_index:0 is 0 */
}
VALUE
iseq_ibf_dump(const rb_iseq_t *iseq, VALUE opt)
{
struct ibf_dump *dump;
struct ibf_header header = {{0}};
VALUE dump_obj;
VALUE str;
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
if (iseq->body->parent_iseq != NULL ||
iseq->body->local_iseq != iseq) {
rb_raise(rb_eRuntimeError, "should be top of iseq");
}
if (RTEST(ISEQ_COVERAGE(iseq))) {
rb_raise(rb_eRuntimeError, "should not compile with coverage");
}
dump_obj = TypedData_Make_Struct(0, struct ibf_dump, &ibf_dump_type, dump);
ibf_dump_setup(dump, dump_obj);
ibf_dump_write(dump, &header, sizeof(header));
ibf_dump_write(dump, RUBY_PLATFORM, strlen(RUBY_PLATFORM) + 1);
ibf_dump_iseq(dump, iseq);
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
header.magic[0] = 'Y'; /* YARB */
header.magic[1] = 'A';
header.magic[2] = 'R';
header.magic[3] = 'B';
header.major_version = ISEQ_MAJOR_VERSION;
header.minor_version = ISEQ_MINOR_VERSION;
ibf_dump_iseq_list(dump, &header);
ibf_dump_id_list(dump, &header);
ibf_dump_object_list(dump, &header);
header.size = ibf_dump_pos(dump);
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
if (RTEST(opt)) {
VALUE opt_str = opt;
const char *ptr = StringValuePtr(opt_str);
header.extra_size = RSTRING_LENINT(opt_str);
ibf_dump_write(dump, ptr, header.extra_size);
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
}
else {
header.extra_size = 0;
}
ibf_dump_overwrite(dump, &header, sizeof(header), 0);
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
str = dump->str;
ibf_dump_free(dump);
DATA_PTR(dump_obj) = NULL;
RB_GC_GUARD(dump_obj);
return str;
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
}
static const ibf_offset_t *
ibf_iseq_list(const struct ibf_load *load)
{
return (ibf_offset_t *)(load->buff + load->header->iseq_list_offset);
}
void
ibf_load_iseq_complete(rb_iseq_t *iseq)
{
struct ibf_load *load = RTYPEDDATA_DATA(iseq->aux.loader.obj);
rb_iseq_t *prev_src_iseq = load->iseq;
load->iseq = iseq;
ibf_load_iseq_each(load, iseq, ibf_iseq_list(load)[iseq->aux.loader.index]);
ISEQ_COMPILE_DATA(iseq) = NULL;
FL_UNSET(iseq, ISEQ_NOT_LOADED_YET);
load->iseq = prev_src_iseq;
}
#if USE_LAZY_LOAD
const rb_iseq_t *
rb_iseq_complete(const rb_iseq_t *iseq)
{
ibf_load_iseq_complete((rb_iseq_t *)iseq);
return iseq;
}
#endif
static rb_iseq_t *
ibf_load_iseq(const struct ibf_load *load, const rb_iseq_t *index_iseq)
{
int iseq_index = (int)(VALUE)index_iseq;
if (iseq_index == -1) {
return NULL;
}
else {
VALUE iseqv = rb_ary_entry(load->iseq_list, iseq_index);
if (iseqv != Qnil) {
return (rb_iseq_t *)iseqv;
}
else {
rb_iseq_t *iseq = iseq_imemo_alloc();
FL_SET(iseq, ISEQ_NOT_LOADED_YET);
iseq->aux.loader.obj = load->loader_obj;
iseq->aux.loader.index = iseq_index;
rb_ary_store(load->iseq_list, iseq_index, (VALUE)iseq);
#if !USE_LAZY_LOAD
ibf_load_iseq_complete(iseq);
#endif /* !USE_LAZY_LOAD */
if (load->iseq) {
iseq_add_mark_object(load->iseq, (VALUE)iseq);
}
return iseq;
}
}
}
static void
ibf_load_setup(struct ibf_load *load, VALUE loader_obj, VALUE str)
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
{
rb_check_safe_obj(str);
if (RSTRING_LENINT(str) < (int)sizeof(struct ibf_header)) {
rb_raise(rb_eRuntimeError, "broken binary format");
}
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
RB_OBJ_WRITE(loader_obj, &load->str, str);
load->loader_obj = loader_obj;
load->buff = StringValuePtr(str);
load->header = (struct ibf_header *)load->buff;
RB_OBJ_WRITE(loader_obj, &load->iseq_list, rb_ary_tmp_new(0));
RB_OBJ_WRITE(loader_obj, &load->obj_list, rb_ary_tmp_new(0));
load->id_list = ZALLOC_N(ID, load->header->id_list_size);
load->iseq = NULL;
if (RSTRING_LENINT(str) < (int)load->header->size) {
rb_raise(rb_eRuntimeError, "broken binary format");
}
if (strncmp(load->header->magic, "YARB", 4) != 0) {
rb_raise(rb_eRuntimeError, "unknown binary format");
}
if (load->header->major_version != ISEQ_MAJOR_VERSION ||
load->header->minor_version != ISEQ_MINOR_VERSION) {
rb_raise(rb_eRuntimeError, "unmatched version file (%u.%u for %u.%u)",
load->header->major_version, load->header->minor_version, ISEQ_MAJOR_VERSION, ISEQ_MINOR_VERSION);
}
if (strcmp(load->buff + sizeof(struct ibf_header), RUBY_PLATFORM) != 0) {
rb_raise(rb_eRuntimeError, "unmatched platform");
}
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
}
static void
ibf_loader_mark(void *ptr)
{
if (ptr) {
struct ibf_load *load = (struct ibf_load *)ptr;
rb_gc_mark(load->str);
rb_gc_mark(load->iseq_list);
rb_gc_mark(load->obj_list);
}
}
static void
ibf_loader_free(void *ptr)
{
if (ptr) {
struct ibf_load *load = (struct ibf_load *)ptr;
ruby_xfree(load->id_list);
ruby_xfree(load);
}
}
static size_t
ibf_loader_memsize(const void *ptr)
{
struct ibf_load *load = (struct ibf_load *)ptr;
return sizeof(struct ibf_load) + load->header->id_list_size * sizeof(ID);
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
}
static const rb_data_type_t ibf_load_type = {
"ibf_loader",
{ibf_loader_mark, ibf_loader_free, ibf_loader_memsize,},
0, 0, RUBY_TYPED_WB_PROTECTED | RUBY_TYPED_FREE_IMMEDIATELY
};
const rb_iseq_t *
iseq_ibf_load(VALUE str)
{
struct ibf_load *load;
const rb_iseq_t *iseq;
VALUE loader_obj = TypedData_Make_Struct(0, struct ibf_load, &ibf_load_type, load);
ibf_load_setup(load, loader_obj, str);
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
iseq = ibf_load_iseq(load, 0);
RB_GC_GUARD(loader_obj);
return iseq;
}
VALUE
iseq_ibf_load_extra_data(VALUE str)
{
struct ibf_load *load;
VALUE loader_obj = TypedData_Make_Struct(0, struct ibf_load, &ibf_load_type, load);
VALUE extra_str;
ibf_load_setup(load, loader_obj, str);
extra_str = rb_str_new(load->buff + load->header->size, load->header->extra_size);
* introduce new ISeq binary format serializer/de-serializer and a pre-compilation/runtime loader sample. [Feature #11788] * iseq.c: add new methods: * RubyVM::InstructionSequence#to_binary_format(extra_data = nil) * RubyVM::InstructionSequence.from_binary_format(binary) * RubyVM::InstructionSequence.from_binary_format_extra_data(binary) * compile.c: implement body of this new feature. * load.c (rb_load_internal0), iseq.c (rb_iseq_load_iseq): call RubyVM::InstructionSequence.load_iseq(fname) with loading script name if this method is defined. We can return any ISeq object as a result value. Otherwise loading will be continue as usual. This interface is not matured and is not extensible. So that we don't guarantee the future compatibility of this method. Basically, you should'nt use this method. * iseq.h: move ISEQ_MAJOR/MINOR_VERSION (and some definitions) from iseq.c. * encoding.c (rb_data_is_encoding), internal.h: added. * vm_core.h: add several supports for lazy load. * add USE_LAZY_LOAD macro to specify enable or disable of this feature. * add several fields to rb_iseq_t. * introduce new macro rb_iseq_check(). * insns.def: some check for lazy loading feature. * vm_insnhelper.c: ditto. * proc.c: ditto. * vm.c: ditto. * test/lib/iseq_loader_checker.rb: enabled iff suitable environment variables are provided. * test/runner.rb: enable lib/iseq_loader_checker.rb. * sample/iseq_loader.rb: add sample compiler and loader. $ ruby sample/iseq_loader.rb [dir] will compile all ruby scripts in [dir]. With default setting, this compile creates *.rb.yarb files in same directory of target .rb scripts. $ ruby -r sample/iseq_loader.rb [app] will run with enable to load compiled binary data. git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@52949 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2015-12-08 16:58:50 +03:00
RB_GC_GUARD(loader_obj);
return extra_str;
}