pb_common.c - third_party/github/nanopb/nanopb - Git at Google

 /* pb_common.c: Common support functions for pb_encode.c and pb_decode.c.
  *
  * 2014 Petteri Aimonen <jpa@kapsi.fi>
  */

 #include "pb_common.h"

 static bool load_descriptor_values(pb_field_iter_t *iter)
 {
     uint32_t word0;
     uint32_t data_offset;
     int_least8_t size_offset;

     if (iter->index >= iter->descriptor->field_count)
         return false;

     word0 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);
     iter->type = (pb_type_t)((word0 >> 8) & 0xFF);

     switch(word0 & 3)
     {
         case 0: {
             /* 1-word format */
             iter->array_size = 1;
             iter->tag = (pb_size_t)((word0 >> 2) & 0x3F);
             size_offset = (int_least8_t)((word0 >> 24) & 0x0F);
             data_offset = (word0 >> 16) & 0xFF;
             iter->data_size = (pb_size_t)((word0 >> 28) & 0x0F);
             break;
         }

         case 1: {
             /* 2-word format */
             uint32_t word1 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 1]);

             iter->array_size = (pb_size_t)((word0 >> 16) & 0x0FFF);
             iter->tag = (pb_size_t)(((word0 >> 2) & 0x3F) | ((word1 >> 28) << 6));
             size_offset = (int_least8_t)((word0 >> 28) & 0x0F);
             data_offset = word1 & 0xFFFF;
             iter->data_size = (pb_size_t)((word1 >> 16) & 0x0FFF);
             break;
         }

         case 2: {
             /* 4-word format */
             uint32_t word1 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 1]);
             uint32_t word2 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 2]);
             uint32_t word3 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 3]);

             iter->array_size = (pb_size_t)(word0 >> 16);
             iter->tag = (pb_size_t)(((word0 >> 2) & 0x3F) | ((word1 >> 8) << 6));
             size_offset = (int_least8_t)(word1 & 0xFF);
             data_offset = word2;
             iter->data_size = (pb_size_t)word3;
             break;
         }

         default: {
             /* 8-word format */
             uint32_t word1 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 1]);
             uint32_t word2 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 2]);
             uint32_t word3 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 3]);
             uint32_t word4 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 4]);

             iter->array_size = (pb_size_t)word4;
             iter->tag = (pb_size_t)(((word0 >> 2) & 0x3F) | ((word1 >> 8) << 6));
             size_offset = (int_least8_t)(word1 & 0xFF);
             data_offset = word2;
             iter->data_size = (pb_size_t)word3;
             break;
         }
     }

     if (!iter->message)
     {
         /* Avoid doing arithmetic on null pointers, it is undefined */
         iter->pField = NULL;
         iter->pSize = NULL;
     }
     else
     {
         iter->pField = (char*)iter->message + data_offset;

         if (size_offset)
         {
             iter->pSize = (char*)iter->pField - size_offset;
         }
         else if (PB_HTYPE(iter->type) == PB_HTYPE_REPEATED &&
                  (PB_ATYPE(iter->type) == PB_ATYPE_STATIC ||
                   PB_ATYPE(iter->type) == PB_ATYPE_POINTER))
         {
             /* Fixed count array */
             iter->pSize = &iter->array_size;
         }
         else
         {
             iter->pSize = NULL;
         }

         if (PB_ATYPE(iter->type) == PB_ATYPE_POINTER && iter->pField != NULL)
         {
             iter->pData = *(void**)iter->pField;
         }
         else
         {
             iter->pData = iter->pField;
         }
     }

     if (PB_LTYPE_IS_SUBMSG(iter->type))
     {
         iter->submsg_desc = iter->descriptor->submsg_info[iter->submessage_index];
     }
     else
     {
         iter->submsg_desc = NULL;
     }

     return true;
 }

 static void advance_iterator(pb_field_iter_t *iter)
 {
     iter->index++;

     if (iter->index >= iter->descriptor->field_count)
     {
         /* Restart */
         iter->index = 0;
         iter->field_info_index = 0;
         iter->submessage_index = 0;
         iter->required_field_index = 0;
     }
     else
     {
         /* Increment indexes based on previous field type.
          * All field info formats have the following fields:
          * - lowest 2 bits tell the amount of words in the descriptor (2^n words)
          * - bits 2..7 give the lowest bits of tag number.
          * - bits 8..15 give the field type.
          */
         uint32_t prev_descriptor = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);
         pb_type_t prev_type = (prev_descriptor >> 8) & 0xFF;
         pb_size_t descriptor_len = (pb_size_t)(1 << (prev_descriptor & 3));

         /* Add to fields.
          * The cast to pb_size_t is needed to avoid -Wconversion warning.
          * Because the data is is constants from generator, there is no danger of overflow.
          */
         iter->field_info_index = (pb_size_t)(iter->field_info_index + descriptor_len);
         iter->required_field_index = (pb_size_t)(iter->required_field_index + (PB_HTYPE(prev_type) == PB_HTYPE_REQUIRED));
         iter->submessage_index = (pb_size_t)(iter->submessage_index + PB_LTYPE_IS_SUBMSG(prev_type));
     }
 }

 bool pb_field_iter_begin(pb_field_iter_t *iter, const pb_msgdesc_t *desc, void *message)
 {
     memset(iter, 0, sizeof(*iter));

     iter->descriptor = desc;
     iter->message = message;

     return load_descriptor_values(iter);
 }

 bool pb_field_iter_begin_extension(pb_field_iter_t *iter, pb_extension_t *extension)
 {
     const pb_msgdesc_t *msg = (const pb_msgdesc_t*)extension->type->arg;
     bool status;

     uint32_t word0 = PB_PROGMEM_READU32(msg->field_info[0]);
     if (PB_ATYPE(word0 >> 8) == PB_ATYPE_POINTER)
     {
         /* For pointer extensions, the pointer is stored directly
          * in the extension structure. This avoids having an extra
          * indirection. */
         status = pb_field_iter_begin(iter, msg, &extension->dest);
     }
     else
     {
         status = pb_field_iter_begin(iter, msg, extension->dest);
     }

     iter->pSize = &extension->found;
     return status;
 }

 bool pb_field_iter_next(pb_field_iter_t *iter)
 {
     advance_iterator(iter);
     (void)load_descriptor_values(iter);
     return iter->index != 0;
 }

 bool pb_field_iter_find(pb_field_iter_t *iter, uint32_t tag)
 {
     if (iter->tag == tag)
     {
         return true; /* Nothing to do, correct field already. */
     }
     else if (tag > iter->descriptor->largest_tag)
     {
         return false;
     }
     else
     {
         pb_size_t start = iter->index;
         uint32_t fieldinfo;

         if (tag < iter->tag)
         {
             /* Fields are in tag number order, so we know that tag is between
              * 0 and our start position. Setting index to end forces
              * advance_iterator() call below to restart from beginning. */
             iter->index = iter->descriptor->field_count;
         }

         do
         {
             /* Advance iterator but don't load values yet */
             advance_iterator(iter);

             /* Do fast check for tag number match */
             fieldinfo = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);

             if (((fieldinfo >> 2) & 0x3F) == (tag & 0x3F))
             {
                 /* Good candidate, check further */
                 (void)load_descriptor_values(iter);

                 if (iter->tag == tag &&
                     PB_LTYPE(iter->type) != PB_LTYPE_EXTENSION)
                 {
                     /* Found it */
                     return true;
                 }
             }
         } while (iter->index != start);

         /* Searched all the way back to start, and found nothing. */
         (void)load_descriptor_values(iter);
         return false;
     }
 }

 bool pb_field_iter_find_extension(pb_field_iter_t *iter)
 {
     if (PB_LTYPE(iter->type) == PB_LTYPE_EXTENSION)
     {
         return true;
     }
     else
     {
         pb_size_t start = iter->index;
         uint32_t fieldinfo;

         do
         {
             /* Advance iterator but don't load values yet */
             advance_iterator(iter);

             /* Do fast check for field type */
             fieldinfo = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);

             if (PB_LTYPE((fieldinfo >> 8) & 0xFF) == PB_LTYPE_EXTENSION)
             {
                 return load_descriptor_values(iter);
             }
         } while (iter->index != start);

         /* Searched all the way back to start, and found nothing. */
         (void)load_descriptor_values(iter);
         return false;
     }
 }

 static void *pb_const_cast(const void *p)
 {
     /* Note: this casts away const, in order to use the common field iterator
      * logic for both encoding and decoding. The cast is done using union
      * to avoid spurious compiler warnings. */
     union {
         void *p1;
         const void *p2;
     } t;
     t.p2 = p;
     return t.p1;
 }

 bool pb_field_iter_begin_const(pb_field_iter_t *iter, const pb_msgdesc_t *desc, const void *message)
 {
     return pb_field_iter_begin(iter, desc, pb_const_cast(message));
 }

 bool pb_field_iter_begin_extension_const(pb_field_iter_t *iter, const pb_extension_t *extension)
 {
     return pb_field_iter_begin_extension(iter, (pb_extension_t*)pb_const_cast(extension));
 }

 bool pb_default_field_callback(pb_istream_t *istream, pb_ostream_t *ostream, const pb_field_t *field)
 {
     if (field->data_size == sizeof(pb_callback_t))
     {
         pb_callback_t *pCallback = (pb_callback_t*)field->pData;

         if (pCallback != NULL)
         {
             if (istream != NULL && pCallback->funcs.decode != NULL)
             {
                 return pCallback->funcs.decode(istream, field, &pCallback->arg);
             }

             if (ostream != NULL && pCallback->funcs.encode != NULL)
             {
                 return pCallback->funcs.encode(ostream, field, &pCallback->arg);
             }
         }
     }

     return true; /* Success, but didn't do anything */

 }

 #ifdef PB_VALIDATE_UTF8

 /* This function checks whether a string is valid UTF-8 text.
  *
  * Algorithm is adapted from https://www.cl.cam.ac.uk/~mgk25/ucs/utf8_check.c
  * Original copyright: Markus Kuhn <http://www.cl.cam.ac.uk/~mgk25/> 2005-03-30
  * Licensed under "Short code license", which allows use under MIT license or
  * any compatible with it.
  */

 bool pb_validate_utf8(const char *str)
 {
     const pb_byte_t *s = (const pb_byte_t*)str;
     while (*s)
     {
         if (*s < 0x80)
         {
             /* 0xxxxxxx */
             s++;
         }
         else if ((s[0] & 0xe0) == 0xc0)
         {
             /* 110XXXXx 10xxxxxx */
             if ((s[1] & 0xc0) != 0x80 ||
                 (s[0] & 0xfe) == 0xc0)                        /* overlong? */
                 return false;
             else
                 s += 2;
         }
         else if ((s[0] & 0xf0) == 0xe0)
         {
             /* 1110XXXX 10Xxxxxx 10xxxxxx */
             if ((s[1] & 0xc0) != 0x80 ||
                 (s[2] & 0xc0) != 0x80 ||
                 (s[0] == 0xe0 && (s[1] & 0xe0) == 0x80) ||    /* overlong? */
                 (s[0] == 0xed && (s[1] & 0xe0) == 0xa0) ||    /* surrogate? */
                 (s[0] == 0xef && s[1] == 0xbf &&
                 (s[2] & 0xfe) == 0xbe))                 /* U+FFFE or U+FFFF? */
                 return false;
             else
                 s += 3;
         }
         else if ((s[0] & 0xf8) == 0xf0)
         {
             /* 11110XXX 10XXxxxx 10xxxxxx 10xxxxxx */
             if ((s[1] & 0xc0) != 0x80 ||
                 (s[2] & 0xc0) != 0x80 ||
                 (s[3] & 0xc0) != 0x80 ||
                 (s[0] == 0xf0 && (s[1] & 0xf0) == 0x80) ||    /* overlong? */
                 (s[0] == 0xf4 && s[1] > 0x8f) || s[0] > 0xf4) /* > U+10FFFF? */
                 return false;
             else
                 s += 4;
         }
         else
         {
             return false;
         }
     }

     return true;
 }

 #endif
	/* pb_common.c: Common support functions for pb_encode.c and pb_decode.c.
	*
	* 2014 Petteri Aimonen <jpa@kapsi.fi>
	*/

	#include "pb_common.h"

	static bool load_descriptor_values(pb_field_iter_t *iter)
	{
	uint32_t word0;
	uint32_t data_offset;
	int_least8_t size_offset;

	if (iter->index >= iter->descriptor->field_count)
	return false;

	word0 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);
	iter->type = (pb_type_t)((word0 >> 8) & 0xFF);

	switch(word0 & 3)
	{
	case 0: {
	/* 1-word format */
	iter->array_size = 1;
	iter->tag = (pb_size_t)((word0 >> 2) & 0x3F);
	size_offset = (int_least8_t)((word0 >> 24) & 0x0F);
	data_offset = (word0 >> 16) & 0xFF;
	iter->data_size = (pb_size_t)((word0 >> 28) & 0x0F);
	break;
	}

	case 1: {
	/* 2-word format */
	uint32_t word1 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 1]);

	iter->array_size = (pb_size_t)((word0 >> 16) & 0x0FFF);
	iter->tag = (pb_size_t)(((word0 >> 2) & 0x3F) \| ((word1 >> 28) << 6));
	size_offset = (int_least8_t)((word0 >> 28) & 0x0F);
	data_offset = word1 & 0xFFFF;
	iter->data_size = (pb_size_t)((word1 >> 16) & 0x0FFF);
	break;
	}

	case 2: {
	/* 4-word format */
	uint32_t word1 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 1]);
	uint32_t word2 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 2]);
	uint32_t word3 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 3]);

	iter->array_size = (pb_size_t)(word0 >> 16);
	iter->tag = (pb_size_t)(((word0 >> 2) & 0x3F) \| ((word1 >> 8) << 6));
	size_offset = (int_least8_t)(word1 & 0xFF);
	data_offset = word2;
	iter->data_size = (pb_size_t)word3;
	break;
	}

	default: {
	/* 8-word format */
	uint32_t word1 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 1]);
	uint32_t word2 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 2]);
	uint32_t word3 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 3]);
	uint32_t word4 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 4]);

	iter->array_size = (pb_size_t)word4;
	iter->tag = (pb_size_t)(((word0 >> 2) & 0x3F) \| ((word1 >> 8) << 6));
	size_offset = (int_least8_t)(word1 & 0xFF);
	data_offset = word2;
	iter->data_size = (pb_size_t)word3;
	break;
	}
	}

	if (!iter->message)
	{
	/* Avoid doing arithmetic on null pointers, it is undefined */
	iter->pField = NULL;
	iter->pSize = NULL;
	}
	else
	{
	iter->pField = (char*)iter->message + data_offset;

	if (size_offset)
	{
	iter->pSize = (char*)iter->pField - size_offset;
	}
	else if (PB_HTYPE(iter->type) == PB_HTYPE_REPEATED &&
	(PB_ATYPE(iter->type) == PB_ATYPE_STATIC \|\|
	PB_ATYPE(iter->type) == PB_ATYPE_POINTER))
	{
	/* Fixed count array */
	iter->pSize = &iter->array_size;
	}
	else
	{
	iter->pSize = NULL;
	}

	if (PB_ATYPE(iter->type) == PB_ATYPE_POINTER && iter->pField != NULL)
	{
	iter->pData = (void*)iter->pField;
	}
	else
	{
	iter->pData = iter->pField;
	}
	}

	if (PB_LTYPE_IS_SUBMSG(iter->type))
	{
	iter->submsg_desc = iter->descriptor->submsg_info[iter->submessage_index];
	}
	else
	{
	iter->submsg_desc = NULL;
	}

	return true;
	}

	static void advance_iterator(pb_field_iter_t *iter)
	{
	iter->index++;

	if (iter->index >= iter->descriptor->field_count)
	{
	/* Restart */
	iter->index = 0;
	iter->field_info_index = 0;
	iter->submessage_index = 0;
	iter->required_field_index = 0;
	}
	else
	{
	/* Increment indexes based on previous field type.
	* All field info formats have the following fields:
	* - lowest 2 bits tell the amount of words in the descriptor (2^n words)
	* - bits 2..7 give the lowest bits of tag number.
	* - bits 8..15 give the field type.
	*/
	uint32_t prev_descriptor = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);
	pb_type_t prev_type = (prev_descriptor >> 8) & 0xFF;
	pb_size_t descriptor_len = (pb_size_t)(1 << (prev_descriptor & 3));

	/* Add to fields.
	* The cast to pb_size_t is needed to avoid -Wconversion warning.
	* Because the data is is constants from generator, there is no danger of overflow.
	*/
	iter->field_info_index = (pb_size_t)(iter->field_info_index + descriptor_len);
	iter->required_field_index = (pb_size_t)(iter->required_field_index + (PB_HTYPE(prev_type) == PB_HTYPE_REQUIRED));
	iter->submessage_index = (pb_size_t)(iter->submessage_index + PB_LTYPE_IS_SUBMSG(prev_type));
	}
	}

	bool pb_field_iter_begin(pb_field_iter_t iter, const pb_msgdesc_t desc, void *message)
	{
	memset(iter, 0, sizeof(*iter));

	iter->descriptor = desc;
	iter->message = message;

	return load_descriptor_values(iter);
	}

	bool pb_field_iter_begin_extension(pb_field_iter_t iter, pb_extension_t extension)
	{
	const pb_msgdesc_t msg = (const pb_msgdesc_t)extension->type->arg;
	bool status;

	uint32_t word0 = PB_PROGMEM_READU32(msg->field_info[0]);
	if (PB_ATYPE(word0 >> 8) == PB_ATYPE_POINTER)
	{
	/* For pointer extensions, the pointer is stored directly
	* in the extension structure. This avoids having an extra
	* indirection. */
	status = pb_field_iter_begin(iter, msg, &extension->dest);
	}
	else
	{
	status = pb_field_iter_begin(iter, msg, extension->dest);
	}

	iter->pSize = &extension->found;
	return status;
	}

	bool pb_field_iter_next(pb_field_iter_t *iter)
	{
	advance_iterator(iter);
	(void)load_descriptor_values(iter);
	return iter->index != 0;
	}

	bool pb_field_iter_find(pb_field_iter_t *iter, uint32_t tag)
	{
	if (iter->tag == tag)
	{
	return true; /* Nothing to do, correct field already. */
	}
	else if (tag > iter->descriptor->largest_tag)
	{
	return false;
	}
	else
	{
	pb_size_t start = iter->index;
	uint32_t fieldinfo;

	if (tag < iter->tag)
	{
	/* Fields are in tag number order, so we know that tag is between
	* 0 and our start position. Setting index to end forces
	* advance_iterator() call below to restart from beginning. */
	iter->index = iter->descriptor->field_count;
	}

	do
	{
	/* Advance iterator but don't load values yet */
	advance_iterator(iter);

	/* Do fast check for tag number match */
	fieldinfo = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);

	if (((fieldinfo >> 2) & 0x3F) == (tag & 0x3F))
	{
	/* Good candidate, check further */
	(void)load_descriptor_values(iter);

	if (iter->tag == tag &&
	PB_LTYPE(iter->type) != PB_LTYPE_EXTENSION)
	{
	/* Found it */
	return true;
	}
	}
	} while (iter->index != start);

	/* Searched all the way back to start, and found nothing. */
	(void)load_descriptor_values(iter);
	return false;
	}
	}

	bool pb_field_iter_find_extension(pb_field_iter_t *iter)
	{
	if (PB_LTYPE(iter->type) == PB_LTYPE_EXTENSION)
	{
	return true;
	}
	else
	{
	pb_size_t start = iter->index;
	uint32_t fieldinfo;

	do
	{
	/* Advance iterator but don't load values yet */
	advance_iterator(iter);

	/* Do fast check for field type */
	fieldinfo = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);

	if (PB_LTYPE((fieldinfo >> 8) & 0xFF) == PB_LTYPE_EXTENSION)
	{
	return load_descriptor_values(iter);
	}
	} while (iter->index != start);

	/* Searched all the way back to start, and found nothing. */
	(void)load_descriptor_values(iter);
	return false;
	}
	}

	static void pb_const_cast(const void p)
	{
	/* Note: this casts away const, in order to use the common field iterator
	* logic for both encoding and decoding. The cast is done using union
	* to avoid spurious compiler warnings. */
	union {
	void *p1;
	const void *p2;
	} t;
	t.p2 = p;
	return t.p1;
	}

	bool pb_field_iter_begin_const(pb_field_iter_t iter, const pb_msgdesc_t desc, const void *message)
	{
	return pb_field_iter_begin(iter, desc, pb_const_cast(message));
	}

	bool pb_field_iter_begin_extension_const(pb_field_iter_t iter, const pb_extension_t extension)
	{
	return pb_field_iter_begin_extension(iter, (pb_extension_t*)pb_const_cast(extension));
	}

	bool pb_default_field_callback(pb_istream_t istream, pb_ostream_t ostream, const pb_field_t *field)
	{
	if (field->data_size == sizeof(pb_callback_t))
	{
	pb_callback_t pCallback = (pb_callback_t)field->pData;

	if (pCallback != NULL)
	{
	if (istream != NULL && pCallback->funcs.decode != NULL)
	{
	return pCallback->funcs.decode(istream, field, &pCallback->arg);
	}

	if (ostream != NULL && pCallback->funcs.encode != NULL)
	{
	return pCallback->funcs.encode(ostream, field, &pCallback->arg);
	}
	}
	}

	return true; /* Success, but didn't do anything */

	}

	#ifdef PB_VALIDATE_UTF8

	/* This function checks whether a string is valid UTF-8 text.
	*
	* Algorithm is adapted from https://www.cl.cam.ac.uk/~mgk25/ucs/utf8_check.c
	* Original copyright: Markus Kuhn <http://www.cl.cam.ac.uk/~mgk25/> 2005-03-30
	* Licensed under "Short code license", which allows use under MIT license or
	* any compatible with it.
	*/

	bool pb_validate_utf8(const char *str)
	{
	const pb_byte_t s = (const pb_byte_t)str;
	while (*s)
	{
	if (*s < 0x80)
	{
	/* 0xxxxxxx */
	s++;
	}
	else if ((s[0] & 0xe0) == 0xc0)
	{
	/* 110XXXXx 10xxxxxx */
	if ((s[1] & 0xc0) != 0x80 \|\|
	(s[0] & 0xfe) == 0xc0) /* overlong? */
	return false;
	else
	s += 2;
	}
	else if ((s[0] & 0xf0) == 0xe0)
	{
	/* 1110XXXX 10Xxxxxx 10xxxxxx */
	if ((s[1] & 0xc0) != 0x80 \|\|
	(s[2] & 0xc0) != 0x80 \|\|
	(s[0] == 0xe0 && (s[1] & 0xe0) == 0x80) \|\| /* overlong? */
	(s[0] == 0xed && (s[1] & 0xe0) == 0xa0) \|\| /* surrogate? */
	(s[0] == 0xef && s[1] == 0xbf &&
	(s[2] & 0xfe) == 0xbe)) /* U+FFFE or U+FFFF? */
	return false;
	else
	s += 3;
	}
	else if ((s[0] & 0xf8) == 0xf0)
	{
	/* 11110XXX 10XXxxxx 10xxxxxx 10xxxxxx */
	if ((s[1] & 0xc0) != 0x80 \|\|
	(s[2] & 0xc0) != 0x80 \|\|
	(s[3] & 0xc0) != 0x80 \|\|
	(s[0] == 0xf0 && (s[1] & 0xf0) == 0x80) \|\| /* overlong? */
	(s[0] == 0xf4 && s[1] > 0x8f) \|\| s[0] > 0xf4) /* > U+10FFFF? */
	return false;
	else
	s += 4;
	}
	else
	{
	return false;
	}
	}

	return true;
	}

	#endif