src/cn-encoder.c - third_party/github/jimsch/cn-cbor - Git at Google

 #ifndef CN_ENCODER_C
 #define CN_ENCODER_C

 #ifdef  __cplusplus
 extern "C" {
 #endif
 #ifdef EMACS_INDENTATION_HELPER
 } /* Duh. */
 #endif

 #include <arpa/inet.h>
 #include <string.h>
 #include <strings.h>
 #include <stdbool.h>
 #include <assert.h>

 #include "cn-cbor/cn-cbor.h"
 #include "cbor.h"

 #define hton8p(p) (*(uint8_t*)(p))
 #define hton16p(p) (htons(*(uint16_t*)(p)))
 #define hton32p(p) (htonl(*(uint32_t*)(p)))
 static uint64_t hton64p(const uint8_t *p) {
   /* TODO: does this work on both BE and LE systems? */
   uint64_t ret = hton32p(p);
   ret <<= 32;
   ret |= hton32p(p+4);
   return ret;
 }

 typedef struct _write_state
 {
   uint8_t *buf;
   ssize_t offset;
   ssize_t size;
 } cn_write_state;

 #define ensure_writable(sz) if ((ws->offset<0) || (ws->offset + (sz) >= ws->size)) { \
   ws->offset = -1; \
   return; \
 }

 #define write_byte_and_data(b, data, sz) \
 ws->buf[ws->offset++] = (b); \
 memcpy(ws->buf+ws->offset, (data), (sz)); \
 ws->offset += sz;

 #define write_byte(b) \
 ws->buf[ws->offset++] = (b); \

 #define write_byte_ensured(b) \
 ensure_writable(1); \
 write_byte(b); \

 static uint8_t _xlate[] = {
   IB_FALSE,    /* CN_CBOR_FALSE */
   IB_TRUE,     /* CN_CBOR_TRUE */
   IB_NIL,      /* CN_CBOR_NULL */
   IB_UNDEF,    /* CN_CBOR_UNDEF */
   IB_UNSIGNED, /* CN_CBOR_UINT */
   IB_NEGATIVE, /* CN_CBOR_INT */
   IB_BYTES,    /* CN_CBOR_BYTES */
   IB_TEXT,     /* CN_CBOR_TEXT */
   IB_BYTES,    /* CN_CBOR_BYTES_CHUNKED */
   IB_TEXT,     /* CN_CBOR_TEXT_CHUNKED */
   IB_ARRAY,    /* CN_CBOR_ARRAY */
   IB_MAP,      /* CN_CBOR_MAP */
   IB_TAG,      /* CN_CBOR_TAG */
   IB_PRIM,     /* CN_CBOR_SIMPLE */
   0xFF,        /* CN_CBOR_DOUBLE */
   0xFF         /* CN_CBOR_INVALID */
 };

 static inline bool is_indefinite(const cn_cbor *cb)
 {
   return (cb->flags & CN_CBOR_FL_INDEF) != 0;
 }

 static void _write_positive(cn_write_state *ws, cn_cbor_type typ, uint64_t val) {
   uint8_t ib;

   assert((size_t)typ < sizeof(_xlate));

   ib = _xlate[typ];
   if (ib == 0xFF) {
     ws->offset = -1;
     return;
   }

   if (val < 24) {
     ensure_writable(1);
     write_byte(ib | val);
   } else if (val < 256) {
     ensure_writable(2);
     write_byte(ib | 24);
     write_byte((uint8_t)val);
   } else if (val < 65536) {
     uint16_t be16 = (uint16_t)val;
     ensure_writable(3);
     be16 = hton16p(&be16);
     write_byte_and_data(ib | 25, (const void*)&be16, 2);
   } else if (val < 0x100000000L) {
     uint32_t be32 = (uint32_t)val;
     ensure_writable(5);
     be32 = hton32p(&be32);
     write_byte_and_data(ib | 26, (const void*)&be32, 4);
   } else {
     uint64_t be64;
     ensure_writable(9);
     be64 = hton64p((const uint8_t*)&val);
     write_byte_and_data(ib | 27, (const void*)&be64, 8);
   }
 }

 #ifndef CBOR_NO_FLOAT
 static void _write_double(cn_write_state *ws, double val)
 {
   float float_val = val;
   if (float_val == val) {                /* 32 bits is enough and we aren't NaN */
     uint32_t be32;
     uint16_t be16, u16;
     union {
       float f;
       uint32_t u;
     } u32;
     u32.f = float_val;
     if ((u32.u & 0x1FFF) == 0) { /* worth trying half */
       int s16 = (u32.u >> 16) & 0x8000;
       int exp = (u32.u >> 23) & 0xff;
       int mant = u32.u & 0x7fffff;
       if (exp == 0 && mant == 0)
         ;              /* 0.0, -0.0 */
       else if (exp >= 113 && exp <= 142) /* normalized */
         s16 += ((exp - 112) << 10) + (mant >> 13);
       else if (exp >= 103 && exp < 113) { /* denorm, exp16 = 0 */
         if (mant & ((1 << (126 - exp)) - 1))
           goto float32;         /* loss of precision */
         s16 += ((mant + 0x800000) >> (126 - exp));
       } else if (exp == 255 && mant == 0) { /* Inf */
         s16 += 0x7c00;
       } else
         goto float32;           /* loss of range */

       ensure_writable(3);
       u16 = s16;
       be16 = hton16p((const uint8_t*)&u16);

       write_byte_and_data(IB_PRIM | 25, (const void*)&be16, 2);
       return;
     }
   float32:
     ensure_writable(5);
     be32 = hton32p((const uint8_t*)&u32.u);

     write_byte_and_data(IB_PRIM | 26, (const void*)&be32, 4);

   } else if (val != val) {      /* NaN -- we always write a half NaN*/
     ensure_writable(3);
     write_byte_and_data(IB_PRIM | 25, (const void*)"\x7e\x00", 2);
   } else {
     uint64_t be64;
     /* Copy the same problematic implementation from the decoder. */
     union {
       double d;
       uint64_t u;
     } u64;

     u64.d = val;

     ensure_writable(9);
     be64 = hton64p((const uint8_t*)&u64.u);

     write_byte_and_data(IB_PRIM | 27, (const void*)&be64, 8);

   }
 }
 #endif /* CBOR_NO_FLOAT */

 // TODO: make public?
 typedef void (*cn_visit_func)(const cn_cbor *cb, int depth, void *context);
 static void _visit(const cn_cbor *cb,
                    cn_visit_func visitor,
                    cn_visit_func breaker,
                    void *context)
 {
     const cn_cbor *p = cb;
     int depth = 0;
     while (p)
     {
 visit:
       visitor(p, depth, context);
       if (p->first_child) {
         p = p->first_child;
         depth++;
       } else{
         // Empty indefinite
         if (is_indefinite(p)) {
           breaker(p->parent, depth, context);
         }
         if (p->next) {
           p = p->next;
         } else {
           while (p->parent) {
             depth--;
             if (is_indefinite(p->parent)) {
               breaker(p->parent, depth, context);
             }
             if (p->parent->next) {
               p = p->parent->next;
               goto visit;
             }
             p = p->parent;
           }
           return;
         }
       }
     }
 }

 #define CHECK(st) (st); \
 if (ws->offset < 0) { return; }

 void _encoder_visitor(const cn_cbor *cb, int depth, void *context)
 {
   cn_write_state *ws = context;
   UNUSED_PARAM(depth);

   switch (cb->type) {
   case CN_CBOR_ARRAY:
     if (is_indefinite(cb)) {
       write_byte_ensured(IB_ARRAY | AI_INDEF);
     } else {
       CHECK(_write_positive(ws, CN_CBOR_ARRAY, cb->length));
     }
     break;
   case CN_CBOR_MAP:
     if (is_indefinite(cb)) {
       write_byte_ensured(IB_MAP | AI_INDEF);
     } else {
       CHECK(_write_positive(ws, CN_CBOR_MAP, cb->length/2));
     }
     break;
   case CN_CBOR_BYTES_CHUNKED:
   case CN_CBOR_TEXT_CHUNKED:
     write_byte_ensured(_xlate[cb->type] | AI_INDEF);
     break;

   case CN_CBOR_TEXT:
   case CN_CBOR_BYTES:
     CHECK(_write_positive(ws, cb->type, cb->length));
     ensure_writable(cb->length);
     memcpy(ws->buf+ws->offset, cb->v.str, cb->length);
     ws->offset += cb->length;
     break;

   case CN_CBOR_FALSE:
   case CN_CBOR_TRUE:
   case CN_CBOR_NULL:
   case CN_CBOR_UNDEF:
     write_byte_ensured(_xlate[cb->type]);
     break;

   case CN_CBOR_TAG:
   case CN_CBOR_UINT:
   case CN_CBOR_SIMPLE:
     CHECK(_write_positive(ws, cb->type, cb->v.uint));
     break;

   case CN_CBOR_INT:
     assert(cb->v.sint < 0);
     CHECK(_write_positive(ws, CN_CBOR_INT, ~(cb->v.sint)));
     break;

   case CN_CBOR_DOUBLE:
 #ifndef CBOR_NO_FLOAT
     CHECK(_write_double(ws, cb->v.dbl));
 #endif /* CBOR_NO_FLOAT */
     break;

   case CN_CBOR_INVALID:
     ws->offset = -1;
     break;
   }
 }

 void _encoder_breaker(const cn_cbor *cb, int depth, void *context)
 {
   cn_write_state *ws = context;
   UNUSED_PARAM(cb);
   UNUSED_PARAM(depth);
   write_byte_ensured(IB_BREAK);
 }

 ssize_t cn_cbor_encoder_write(uint8_t *buf,
 			      size_t buf_offset,
 			      size_t buf_size,
 			      const cn_cbor *cb)
 {
   cn_write_state ws = { buf, buf_offset, buf_size };
   _visit(cb, _encoder_visitor, _encoder_breaker, &ws);
   if (ws.offset < 0) { return -1; }
   return ws.offset - buf_offset;
 }

 #ifdef  __cplusplus
 }
 #endif

 #endif  /* CN_CBOR_C */
	#ifndef CN_ENCODER_C
	#define CN_ENCODER_C

	#ifdef __cplusplus
	extern "C" {
	#endif
	#ifdef EMACS_INDENTATION_HELPER
	} /* Duh. */
	#endif

	#include <arpa/inet.h>
	#include <string.h>
	#include <strings.h>
	#include <stdbool.h>
	#include <assert.h>

	#include "cn-cbor/cn-cbor.h"
	#include "cbor.h"

	#define hton8p(p) ((uint8_t)(p))
	#define hton16p(p) (htons((uint16_t)(p)))
	#define hton32p(p) (htonl((uint32_t)(p)))
	static uint64_t hton64p(const uint8_t *p) {
	/* TODO: does this work on both BE and LE systems? */
	uint64_t ret = hton32p(p);
	ret <<= 32;
	ret \|= hton32p(p+4);
	return ret;
	}

	typedef struct _write_state
	{
	uint8_t *buf;
	ssize_t offset;
	ssize_t size;
	} cn_write_state;

	#define ensure_writable(sz) if ((ws->offset<0) \|\| (ws->offset + (sz) >= ws->size)) { \
	ws->offset = -1; \
	return; \
	}

	#define write_byte_and_data(b, data, sz) \
	ws->buf[ws->offset++] = (b); \
	memcpy(ws->buf+ws->offset, (data), (sz)); \
	ws->offset += sz;

	#define write_byte(b) \
	ws->buf[ws->offset++] = (b); \

	#define write_byte_ensured(b) \
	ensure_writable(1); \
	write_byte(b); \

	static uint8_t _xlate[] = {
	IB_FALSE, /* CN_CBOR_FALSE */
	IB_TRUE, /* CN_CBOR_TRUE */
	IB_NIL, /* CN_CBOR_NULL */
	IB_UNDEF, /* CN_CBOR_UNDEF */
	IB_UNSIGNED, /* CN_CBOR_UINT */
	IB_NEGATIVE, /* CN_CBOR_INT */
	IB_BYTES, /* CN_CBOR_BYTES */
	IB_TEXT, /* CN_CBOR_TEXT */
	IB_BYTES, /* CN_CBOR_BYTES_CHUNKED */
	IB_TEXT, /* CN_CBOR_TEXT_CHUNKED */
	IB_ARRAY, /* CN_CBOR_ARRAY */
	IB_MAP, /* CN_CBOR_MAP */
	IB_TAG, /* CN_CBOR_TAG */
	IB_PRIM, /* CN_CBOR_SIMPLE */
	0xFF, /* CN_CBOR_DOUBLE */
	0xFF /* CN_CBOR_INVALID */
	};

	static inline bool is_indefinite(const cn_cbor *cb)
	{
	return (cb->flags & CN_CBOR_FL_INDEF) != 0;
	}

	static void _write_positive(cn_write_state *ws, cn_cbor_type typ, uint64_t val) {
	uint8_t ib;

	assert((size_t)typ < sizeof(_xlate));

	ib = _xlate[typ];
	if (ib == 0xFF) {
	ws->offset = -1;
	return;
	}

	if (val < 24) {
	ensure_writable(1);
	write_byte(ib \| val);
	} else if (val < 256) {
	ensure_writable(2);
	write_byte(ib \| 24);
	write_byte((uint8_t)val);
	} else if (val < 65536) {
	uint16_t be16 = (uint16_t)val;
	ensure_writable(3);
	be16 = hton16p(&be16);
	write_byte_and_data(ib \| 25, (const void*)&be16, 2);
	} else if (val < 0x100000000L) {
	uint32_t be32 = (uint32_t)val;
	ensure_writable(5);
	be32 = hton32p(&be32);
	write_byte_and_data(ib \| 26, (const void*)&be32, 4);
	} else {
	uint64_t be64;
	ensure_writable(9);
	be64 = hton64p((const uint8_t*)&val);
	write_byte_and_data(ib \| 27, (const void*)&be64, 8);
	}
	}

	#ifndef CBOR_NO_FLOAT
	static void _write_double(cn_write_state *ws, double val)
	{
	float float_val = val;
	if (float_val == val) { /* 32 bits is enough and we aren't NaN */
	uint32_t be32;
	uint16_t be16, u16;
	union {
	float f;
	uint32_t u;
	} u32;
	u32.f = float_val;
	if ((u32.u & 0x1FFF) == 0) { /* worth trying half */
	int s16 = (u32.u >> 16) & 0x8000;
	int exp = (u32.u >> 23) & 0xff;
	int mant = u32.u & 0x7fffff;
	if (exp == 0 && mant == 0)
	; /* 0.0, -0.0 */
	else if (exp >= 113 && exp <= 142) /* normalized */
	s16 += ((exp - 112) << 10) + (mant >> 13);
	else if (exp >= 103 && exp < 113) { /* denorm, exp16 = 0 */
	if (mant & ((1 << (126 - exp)) - 1))
	goto float32; /* loss of precision */
	s16 += ((mant + 0x800000) >> (126 - exp));
	} else if (exp == 255 && mant == 0) { /* Inf */
	s16 += 0x7c00;
	} else
	goto float32; /* loss of range */

	ensure_writable(3);
	u16 = s16;
	be16 = hton16p((const uint8_t*)&u16);

	write_byte_and_data(IB_PRIM \| 25, (const void*)&be16, 2);
	return;
	}
	float32:
	ensure_writable(5);
	be32 = hton32p((const uint8_t*)&u32.u);

	write_byte_and_data(IB_PRIM \| 26, (const void*)&be32, 4);

	} else if (val != val) { /* NaN -- we always write a half NaN*/
	ensure_writable(3);
	write_byte_and_data(IB_PRIM \| 25, (const void*)"\x7e\x00", 2);
	} else {
	uint64_t be64;
	/* Copy the same problematic implementation from the decoder. */
	union {
	double d;
	uint64_t u;
	} u64;

	u64.d = val;

	ensure_writable(9);
	be64 = hton64p((const uint8_t*)&u64.u);

	write_byte_and_data(IB_PRIM \| 27, (const void*)&be64, 8);

	}
	}
	#endif /* CBOR_NO_FLOAT */

	// TODO: make public?
	typedef void (cn_visit_func)(const cn_cbor cb, int depth, void *context);
	static void _visit(const cn_cbor *cb,
	cn_visit_func visitor,
	cn_visit_func breaker,
	void *context)
	{
	const cn_cbor *p = cb;
	int depth = 0;
	while (p)
	{
	visit:
	visitor(p, depth, context);
	if (p->first_child) {
	p = p->first_child;
	depth++;
	} else{
	// Empty indefinite
	if (is_indefinite(p)) {
	breaker(p->parent, depth, context);
	}
	if (p->next) {
	p = p->next;
	} else {
	while (p->parent) {
	depth--;
	if (is_indefinite(p->parent)) {
	breaker(p->parent, depth, context);
	}
	if (p->parent->next) {
	p = p->parent->next;
	goto visit;
	}
	p = p->parent;
	}
	return;
	}
	}
	}
	}

	#define CHECK(st) (st); \
	if (ws->offset < 0) { return; }

	void _encoder_visitor(const cn_cbor cb, int depth, void context)
	{
	cn_write_state *ws = context;
	UNUSED_PARAM(depth);

	switch (cb->type) {
	case CN_CBOR_ARRAY:
	if (is_indefinite(cb)) {
	write_byte_ensured(IB_ARRAY \| AI_INDEF);
	} else {
	CHECK(_write_positive(ws, CN_CBOR_ARRAY, cb->length));
	}
	break;
	case CN_CBOR_MAP:
	if (is_indefinite(cb)) {
	write_byte_ensured(IB_MAP \| AI_INDEF);
	} else {
	CHECK(_write_positive(ws, CN_CBOR_MAP, cb->length/2));
	}
	break;
	case CN_CBOR_BYTES_CHUNKED:
	case CN_CBOR_TEXT_CHUNKED:
	write_byte_ensured(_xlate[cb->type] \| AI_INDEF);
	break;

	case CN_CBOR_TEXT:
	case CN_CBOR_BYTES:
	CHECK(_write_positive(ws, cb->type, cb->length));
	ensure_writable(cb->length);
	memcpy(ws->buf+ws->offset, cb->v.str, cb->length);
	ws->offset += cb->length;
	break;

	case CN_CBOR_FALSE:
	case CN_CBOR_TRUE:
	case CN_CBOR_NULL:
	case CN_CBOR_UNDEF:
	write_byte_ensured(_xlate[cb->type]);
	break;

	case CN_CBOR_TAG:
	case CN_CBOR_UINT:
	case CN_CBOR_SIMPLE:
	CHECK(_write_positive(ws, cb->type, cb->v.uint));
	break;

	case CN_CBOR_INT:
	assert(cb->v.sint < 0);
	CHECK(_write_positive(ws, CN_CBOR_INT, ~(cb->v.sint)));
	break;

	case CN_CBOR_DOUBLE:
	#ifndef CBOR_NO_FLOAT
	CHECK(_write_double(ws, cb->v.dbl));
	#endif /* CBOR_NO_FLOAT */
	break;

	case CN_CBOR_INVALID:
	ws->offset = -1;
	break;
	}
	}

	void _encoder_breaker(const cn_cbor cb, int depth, void context)
	{
	cn_write_state *ws = context;
	UNUSED_PARAM(cb);
	UNUSED_PARAM(depth);
	write_byte_ensured(IB_BREAK);
	}

	ssize_t cn_cbor_encoder_write(uint8_t *buf,
	size_t buf_offset,
	size_t buf_size,
	const cn_cbor *cb)
	{
	cn_write_state ws = { buf, buf_offset, buf_size };
	_visit(cb, _encoder_visitor, _encoder_breaker, &ws);
	if (ws.offset < 0) { return -1; }
	return ws.offset - buf_offset;
	}

	#ifdef __cplusplus
	}
	#endif

	#endif /* CN_CBOR_C */