putty/marshal.h

305 строки
13 KiB
C

#ifndef PUTTY_MARSHAL_H
#define PUTTY_MARSHAL_H
#include "defs.h"
/*
* A sort of 'abstract base class' or 'interface' or 'trait' which is
* the common feature of all types that want to accept data formatted
* using the SSH binary conventions of uint32, string, mpint etc.
*/
struct BinarySink {
void (*write)(BinarySink *sink, const void *data, size_t len);
BinarySink *binarysink_;
};
/*
* To define a structure type as a valid target for binary formatted
* data, put 'BinarySink_IMPLEMENTATION' in its declaration, and when
* an instance is set up, use 'BinarySink_INIT' to initialise the
* 'base class' state, providing a function pointer to be the
* implementation of the write() call above.
*/
#define BinarySink_IMPLEMENTATION BinarySink binarysink_[1]
#define BinarySink_INIT(obj, writefn) \
((obj)->binarysink_->write = (writefn), \
(obj)->binarysink_->binarysink_ = (obj)->binarysink_)
/*
* To define a larger structure type as a valid BinarySink in such a
* way that it will delegate the write method to some other object,
* put 'BinarySink_DELEGATE_IMPLEMENTATION' in its declaration, and
* when an instance is set up, use 'BinarySink_DELEGATE_INIT' to point
* at the object it wants to delegate to.
*
* In such a delegated structure, you might sometimes want to have the
* delegation stop being valid (e.g. it might be delegating to an
* object that only sometimes exists). You can null out the delegate
* pointer using BinarySink_DELEGATE_CLEAR.
*/
#define BinarySink_DELEGATE_IMPLEMENTATION BinarySink *binarysink_
#define BinarySink_DELEGATE_INIT(obj, othersink) \
((obj)->binarysink_ = BinarySink_UPCAST(othersink))
#define BinarySink_DELEGATE_CLEAR(obj) ((obj)->binarysink_ = NULL)
/*
* The implementing type's write function will want to downcast its
* 'BinarySink *' parameter back to the more specific type. Also,
* sometimes you'll want to upcast a pointer to a particular
* implementing type into an abstract 'BinarySink *' to pass to
* generic subroutines not defined in this file. These macros do that
* job.
*
* Importantly, BinarySink_UPCAST can also be applied to a BinarySink
* * itself (and leaves it unchanged). That's achieved by a small
* piece of C trickery: implementing structures and the BinarySink
* structure itself both contain a field called binarysink_, but in
* implementing objects it's a BinarySink[1] whereas in the abstract
* type it's a 'BinarySink *' pointing back to the same structure,
* meaning that you can say 'foo->binarysink_' in either case and get
* a pointer type by different methods.
*/
#define BinarySink_DOWNCAST(object, type) \
TYPECHECK((object) == ((type *)0)->binarysink_, \
((type *)(((char *)(object)) - offsetof(type, binarysink_))))
#define BinarySink_UPCAST(object) \
TYPECHECK((object)->binarysink_ == (BinarySink *)0, \
(object)->binarysink_)
/*
* If you structure-copy an object that's implementing BinarySink,
* then that tricky self-pointer in its trait subobject will point to
* the wrong place. You could call BinarySink_INIT again, but this
* macro is terser and does all that's needed to fix up the copied
* object.
*/
#define BinarySink_COPIED(obj) \
((obj)->binarysink_->binarysink_ = (obj)->binarysink_)
/*
* The put_* macros are the main client to this system. Any structure
* which implements the BinarySink 'trait' is valid for use as the
* first parameter of any of these put_* macros.
*/
/* Basic big-endian integer types. */
#define put_byte(bs, val) \
BinarySink_put_byte(BinarySink_UPCAST(bs), val)
#define put_uint16(bs, val) \
BinarySink_put_uint16(BinarySink_UPCAST(bs), val)
#define put_uint32(bs, val) \
BinarySink_put_uint32(BinarySink_UPCAST(bs), val)
#define put_uint64(bs, val) \
BinarySink_put_uint64(BinarySink_UPCAST(bs), val)
/* SSH booleans, encoded as a single byte storing either 0 or 1. */
#define put_bool(bs, val) \
BinarySink_put_bool(BinarySink_UPCAST(bs), val)
/* SSH strings, with a leading uint32 length field. 'stringz' is a
* convenience function that takes an ordinary C zero-terminated
* string as input. 'stringsb' takes a strbuf * as input, and
* finalises it as a side effect (handy for multi-level marshalling in
* which you use these same functions to format an inner blob of data
* that then gets wrapped into a string container in an outer one). */
#define put_string(bs, val, len) \
BinarySink_put_string(BinarySink_UPCAST(bs),val,len)
#define put_stringpl(bs, ptrlen) \
BinarySink_put_stringpl(BinarySink_UPCAST(bs),ptrlen)
#define put_stringz(bs, val) \
BinarySink_put_stringz(BinarySink_UPCAST(bs), val)
#define put_stringsb(bs, val) \
BinarySink_put_stringsb(BinarySink_UPCAST(bs), val)
/* Other string outputs: 'asciz' emits the string data directly into
* the output including the terminating \0, and 'pstring' emits the
* string in Pascal style with a leading _one_-byte length field.
* pstring can fail if the string is too long. */
#define put_asciz(bs, val) \
BinarySink_put_asciz(BinarySink_UPCAST(bs), val)
#define put_pstring(bs, val) \
BinarySink_put_pstring(BinarySink_UPCAST(bs), val)
/* Multiprecision integers, in both the SSH-1 and SSH-2 formats. */
#define put_mp_ssh1(bs, val) \
BinarySink_put_mp_ssh1(BinarySink_UPCAST(bs), val)
#define put_mp_ssh2(bs, val) \
BinarySink_put_mp_ssh2(BinarySink_UPCAST(bs), val)
/* Padding with a specified byte. */
#define put_padding(bs, len, padbyte) \
BinarySink_put_padding(BinarySink_UPCAST(bs), len, padbyte)
/* Fallback: just emit raw data bytes, using a syntax that matches the
* rest of these macros. */
#define put_data(bs, val, len) \
BinarySink_put_data(BinarySink_UPCAST(bs), val, len)
#define put_datapl(bs, pl) \
BinarySink_put_datapl(BinarySink_UPCAST(bs), pl)
/*
* The underlying real C functions that implement most of those
* macros. Generally you won't want to call these directly, because
* they have such cumbersome names; you call the wrapper macros above
* instead.
*
* A few functions whose wrapper macros are defined above are actually
* declared in other headers, so as to guarantee that the
* declaration(s) of their other parameter type(s) are in scope.
*/
void BinarySink_put_data(BinarySink *, const void *data, size_t len);
void BinarySink_put_datapl(BinarySink *, ptrlen);
void BinarySink_put_padding(BinarySink *, size_t len, unsigned char padbyte);
void BinarySink_put_byte(BinarySink *, unsigned char);
void BinarySink_put_bool(BinarySink *, bool);
void BinarySink_put_uint16(BinarySink *, unsigned long);
void BinarySink_put_uint32(BinarySink *, unsigned long);
void BinarySink_put_uint64(BinarySink *, uint64_t);
void BinarySink_put_string(BinarySink *, const void *data, size_t len);
void BinarySink_put_stringpl(BinarySink *, ptrlen);
void BinarySink_put_stringz(BinarySink *, const char *str);
struct strbuf;
void BinarySink_put_stringsb(BinarySink *, struct strbuf *);
void BinarySink_put_asciz(BinarySink *, const char *str);
bool BinarySink_put_pstring(BinarySink *, const char *str);
void BinarySink_put_mp_ssh1(BinarySink *bs, mp_int *x);
void BinarySink_put_mp_ssh2(BinarySink *bs, mp_int *x);
/* ---------------------------------------------------------------------- */
/*
* A complementary trait structure for _un_-marshalling.
*
* This structure contains client-visible data fields rather than
* methods, because that seemed more useful than leaving it totally
* opaque. But it's still got the self-pointer system that will allow
* the set of get_* macros to target one of these itself or any other
* type that 'derives' from it. So, for example, an SSH packet
* structure can act as a BinarySource while also having additional
* fields like the packet type.
*/
typedef enum BinarySourceError {
BSE_NO_ERROR,
BSE_OUT_OF_DATA,
BSE_INVALID
} BinarySourceError;
struct BinarySource {
/*
* (data, len) is the data block being decoded. pos is the current
* position within the block.
*/
const void *data;
size_t pos, len;
/*
* 'err' indicates whether a decoding error has happened at any
* point. Once this has been set to something other than
* BSE_NO_ERROR, it shouldn't be changed by any unmarshalling
* function. So you can safely do a long sequence of get_foo()
* operations and then test err just once at the end, rather than
* having to conditionalise every single get.
*
* The unmarshalling functions should always return some value,
* even if a decoding error occurs. Generally on error they'll
* return zero (if numeric) or the empty string (if string-based),
* or some other appropriate default value for more complicated
* types.
*
* If the usual return value is dynamically allocated (e.g. a
* bignum, or a normal C 'char *' string), then the error value is
* also dynamic in the same way. So you have to free exactly the
* same set of things whether or not there was a decoding error,
* which simplifies exit paths - for example, you could call a big
* pile of get_foo functions, then put the actual handling of the
* results under 'if (!get_err(src))', and then free everything
* outside that if.
*/
BinarySourceError err;
/*
* Self-pointer for the implicit derivation trick, same as
* BinarySink above.
*/
BinarySource *binarysource_;
};
/*
* Implementation macros, similar to BinarySink.
*/
#define BinarySource_IMPLEMENTATION BinarySource binarysource_[1]
static inline void BinarySource_INIT__(BinarySource *src, ptrlen data)
{
src->data = data.ptr;
src->len = data.len;
src->pos = 0;
src->err = BSE_NO_ERROR;
src->binarysource_ = src;
}
#define BinarySource_BARE_INIT_PL(obj, pl) \
TYPECHECK(&(obj)->binarysource_ == (BinarySource **)0, \
BinarySource_INIT__(obj, pl))
#define BinarySource_BARE_INIT(obj, data_, len_) \
BinarySource_BARE_INIT_PL(obj, make_ptrlen(data_, len_))
#define BinarySource_INIT_PL(obj, pl) \
TYPECHECK(&(obj)->binarysource_ == (BinarySource (*)[1])0, \
BinarySource_INIT__(BinarySource_UPCAST(obj), pl))
#define BinarySource_INIT(obj, data_, len_) \
BinarySource_INIT_PL(obj, make_ptrlen(data_, len_))
#define BinarySource_DOWNCAST(object, type) \
TYPECHECK((object) == ((type *)0)->binarysource_, \
((type *)(((char *)(object)) - offsetof(type, binarysource_))))
#define BinarySource_UPCAST(object) \
TYPECHECK((object)->binarysource_ == (BinarySource *)0, \
(object)->binarysource_)
#define BinarySource_COPIED(obj) \
((obj)->binarysource_->binarysource_ = (obj)->binarysource_)
#define get_data(src, len) \
BinarySource_get_data(BinarySource_UPCAST(src), len)
#define get_byte(src) \
BinarySource_get_byte(BinarySource_UPCAST(src))
#define get_bool(src) \
BinarySource_get_bool(BinarySource_UPCAST(src))
#define get_uint16(src) \
BinarySource_get_uint16(BinarySource_UPCAST(src))
#define get_uint32(src) \
BinarySource_get_uint32(BinarySource_UPCAST(src))
#define get_uint64(src) \
BinarySource_get_uint64(BinarySource_UPCAST(src))
#define get_string(src) \
BinarySource_get_string(BinarySource_UPCAST(src))
#define get_asciz(src) \
BinarySource_get_asciz(BinarySource_UPCAST(src))
#define get_pstring(src) \
BinarySource_get_pstring(BinarySource_UPCAST(src))
#define get_mp_ssh1(src) \
BinarySource_get_mp_ssh1(BinarySource_UPCAST(src))
#define get_mp_ssh2(src) \
BinarySource_get_mp_ssh2(BinarySource_UPCAST(src))
#define get_rsa_ssh1_pub(src, rsa, order) \
BinarySource_get_rsa_ssh1_pub(BinarySource_UPCAST(src), rsa, order)
#define get_rsa_ssh1_priv(src, rsa) \
BinarySource_get_rsa_ssh1_priv(BinarySource_UPCAST(src), rsa)
#define get_err(src) (BinarySource_UPCAST(src)->err)
#define get_avail(src) (BinarySource_UPCAST(src)->len - \
BinarySource_UPCAST(src)->pos)
#define get_ptr(src) \
((const void *)( \
(const unsigned char *)(BinarySource_UPCAST(src)->data) + \
BinarySource_UPCAST(src)->pos))
ptrlen BinarySource_get_data(BinarySource *, size_t);
unsigned char BinarySource_get_byte(BinarySource *);
bool BinarySource_get_bool(BinarySource *);
unsigned BinarySource_get_uint16(BinarySource *);
unsigned long BinarySource_get_uint32(BinarySource *);
uint64_t BinarySource_get_uint64(BinarySource *);
ptrlen BinarySource_get_string(BinarySource *);
const char *BinarySource_get_asciz(BinarySource *);
ptrlen BinarySource_get_pstring(BinarySource *);
mp_int *BinarySource_get_mp_ssh1(BinarySource *src);
mp_int *BinarySource_get_mp_ssh2(BinarySource *src);
#endif /* PUTTY_MARSHAL_H */