buf.c - third_party/github.com/GNOME/libxml2 - Git at Google

 /*
  * buf.c: memory buffers for libxml2
  *
  * new buffer structures and entry points to simplify the maintenance
  * of libxml2 and ensure we keep good control over memory allocations
  * and stay 64 bits clean.
  * The new entry point use the xmlBufPtr opaque structure and
  * xmlBuf...() counterparts to the old xmlBuf...() functions
  *
  * See Copyright for the status of this software.
  *
  * daniel@veillard.com
  */

 #define IN_LIBXML
 #include "libxml.h"

 #include <string.h> /* for memset() only ! */
 #include <limits.h>
 #include <ctype.h>
 #include <stdlib.h>

 #include <libxml/tree.h>
 #include <libxml/parserInternals.h> /* for XML_MAX_TEXT_LENGTH */

 #include "private/buf.h"
 #include "private/error.h"

 #ifndef SIZE_MAX
 #define SIZE_MAX ((size_t) -1)
 #endif

 #define WITH_BUFFER_COMPAT

 /**
  * xmlBuf:
  *
  * A buffer structure. The base of the structure is somehow compatible
  * with struct _xmlBuffer to limit risks on application which accessed
  * directly the input->buf->buffer structures.
  */

 struct _xmlBuf {
     xmlChar *content;		/* The buffer content UTF8 */
     unsigned int compat_use;    /* for binary compatibility */
     unsigned int compat_size;   /* for binary compatibility */
     xmlBufferAllocationScheme alloc; /* The realloc method */
     xmlChar *contentIO;		/* in IO mode we may have a different base */
     size_t use;		        /* The buffer size used */
     size_t size;		/* The buffer size */
     xmlBufferPtr buffer;        /* wrapper for an old buffer */
     int error;                  /* an error code if a failure occurred */
 };

 #ifdef WITH_BUFFER_COMPAT
 /*
  * Macro for compatibility with xmlBuffer to be used after an xmlBuf
  * is updated. This makes sure the compat fields are updated too.
  */
 #define UPDATE_COMPAT(buf)				    \
      if (buf->size < INT_MAX) buf->compat_size = buf->size; \
      else buf->compat_size = INT_MAX;			    \
      if (buf->use < INT_MAX) buf->compat_use = buf->use; \
      else buf->compat_use = INT_MAX;

 /*
  * Macro for compatibility with xmlBuffer to be used in all the xmlBuf
  * entry points, it checks that the compat fields have not been modified
  * by direct call to xmlBuffer function from code compiled before 2.9.0 .
  */
 #define CHECK_COMPAT(buf)				    \
      if (buf->size != (size_t) buf->compat_size)	    \
          if (buf->compat_size < INT_MAX)		    \
 	     buf->size = buf->compat_size;		    \
      if (buf->use != (size_t) buf->compat_use)		    \
          if (buf->compat_use < INT_MAX)			    \
 	     buf->use = buf->compat_use;

 #else /* ! WITH_BUFFER_COMPAT */
 #define UPDATE_COMPAT(buf)
 #define CHECK_COMPAT(buf)
 #endif /* WITH_BUFFER_COMPAT */

 /**
  * xmlBufMemoryError:
  * @extra:  extra information
  *
  * Handle an out of memory condition
  * To be improved...
  */
 static void
 xmlBufMemoryError(xmlBufPtr buf)
 {
     if (buf->error == 0)
         buf->error = XML_ERR_NO_MEMORY;
 }

 /**
  * xmlBufOverflowError:
  * @extra:  extra information
  *
  * Handle a buffer overflow error
  * To be improved...
  */
 static void
 xmlBufOverflowError(xmlBufPtr buf)
 {
     if (buf->error == 0)
         buf->error = XML_BUF_OVERFLOW;
 }


 /**
  * xmlBufCreate:
  *
  * routine to create an XML buffer.
  * returns the new structure.
  */
 xmlBufPtr
 xmlBufCreate(void) {
     xmlBufPtr ret;

     ret = (xmlBufPtr) xmlMalloc(sizeof(xmlBuf));
     if (ret == NULL)
         return(NULL);
     ret->use = 0;
     ret->error = 0;
     ret->buffer = NULL;
     ret->size = xmlDefaultBufferSize;
     UPDATE_COMPAT(ret);
     ret->alloc = xmlBufferAllocScheme;
     ret->content = (xmlChar *) xmlMallocAtomic(ret->size);
     if (ret->content == NULL) {
 	xmlFree(ret);
         return(NULL);
     }
     ret->content[0] = 0;
     ret->contentIO = NULL;
     return(ret);
 }

 /**
  * xmlBufCreateSize:
  * @size: initial size of buffer
  *
  * routine to create an XML buffer.
  * returns the new structure.
  */
 xmlBufPtr
 xmlBufCreateSize(size_t size) {
     xmlBufPtr ret;

     if (size == SIZE_MAX)
         return(NULL);
     ret = (xmlBufPtr) xmlMalloc(sizeof(xmlBuf));
     if (ret == NULL)
         return(NULL);
     ret->use = 0;
     ret->error = 0;
     ret->buffer = NULL;
     ret->alloc = xmlBufferAllocScheme;
     ret->size = (size ? size + 1 : 0);         /* +1 for ending null */
     UPDATE_COMPAT(ret);
     if (ret->size){
         ret->content = (xmlChar *) xmlMallocAtomic(ret->size);
         if (ret->content == NULL) {
             xmlFree(ret);
             return(NULL);
         }
         ret->content[0] = 0;
     } else
 	ret->content = NULL;
     ret->contentIO = NULL;
     return(ret);
 }

 /**
  * xmlBufDetach:
  * @buf:  the buffer
  *
  * Remove the string contained in a buffer and give it back to the
  * caller. The buffer is reset to an empty content.
  * This doesn't work with immutable buffers as they can't be reset.
  *
  * Returns the previous string contained by the buffer.
  */
 xmlChar *
 xmlBufDetach(xmlBufPtr buf) {
     xmlChar *ret;

     if (buf == NULL)
         return(NULL);
     if (buf->buffer != NULL)
         return(NULL);
     if (buf->error)
         return(NULL);

     if ((buf->alloc == XML_BUFFER_ALLOC_IO) &&
         (buf->content != buf->contentIO)) {
         ret = xmlStrndup(buf->content, buf->use);
         xmlFree(buf->contentIO);
     } else {
         ret = buf->content;
     }

     buf->content = NULL;
     buf->contentIO = NULL;
     buf->size = 0;
     buf->use = 0;
     UPDATE_COMPAT(buf);

     return ret;
 }

 /**
  * xmlBufGetAllocationScheme:
  * @buf:  the buffer
  *
  * Get the buffer allocation scheme
  *
  * Returns the scheme or -1 in case of error
  */
 int
 xmlBufGetAllocationScheme(xmlBufPtr buf) {
     if (buf == NULL) {
         return(-1);
     }
     return(buf->alloc);
 }

 /**
  * xmlBufSetAllocationScheme:
  * @buf:  the buffer to tune
  * @scheme:  allocation scheme to use
  *
  * Sets the allocation scheme for this buffer
  *
  * returns 0 in case of success and -1 in case of failure
  */
 int
 xmlBufSetAllocationScheme(xmlBufPtr buf,
                           xmlBufferAllocationScheme scheme) {
     if ((buf == NULL) || (buf->error != 0)) {
         return(-1);
     }
     if (buf->alloc == XML_BUFFER_ALLOC_IO)
         return(-1);
     if ((scheme == XML_BUFFER_ALLOC_DOUBLEIT) ||
         (scheme == XML_BUFFER_ALLOC_EXACT) ||
         (scheme == XML_BUFFER_ALLOC_HYBRID) ||
 	(scheme == XML_BUFFER_ALLOC_BOUNDED)) {
 	buf->alloc = scheme;
         if (buf->buffer)
             buf->buffer->alloc = scheme;
         return(0);
     }
     /*
      * Switching a buffer ALLOC_IO has the side effect of initializing
      * the contentIO field with the current content
      */
     if (scheme == XML_BUFFER_ALLOC_IO) {
         buf->alloc = XML_BUFFER_ALLOC_IO;
         buf->contentIO = buf->content;
     }
     return(-1);
 }

 /**
  * xmlBufFree:
  * @buf:  the buffer to free
  *
  * Frees an XML buffer. It frees both the content and the structure which
  * encapsulate it.
  */
 void
 xmlBufFree(xmlBufPtr buf) {
     if (buf == NULL) {
 	return;
     }

     if ((buf->alloc == XML_BUFFER_ALLOC_IO) &&
         (buf->contentIO != NULL)) {
         xmlFree(buf->contentIO);
     } else if (buf->content != NULL) {
         xmlFree(buf->content);
     }
     xmlFree(buf);
 }

 /**
  * xmlBufEmpty:
  * @buf:  the buffer
  *
  * empty a buffer.
  */
 void
 xmlBufEmpty(xmlBufPtr buf) {
     if ((buf == NULL) || (buf->error != 0)) return;
     if (buf->content == NULL) return;
     CHECK_COMPAT(buf)
     buf->use = 0;
     if ((buf->alloc == XML_BUFFER_ALLOC_IO) &&
                (buf->contentIO != NULL)) {
         size_t start_buf = buf->content - buf->contentIO;

 	buf->size += start_buf;
         buf->content = buf->contentIO;
         buf->content[0] = 0;
     } else {
         buf->content[0] = 0;
     }
     UPDATE_COMPAT(buf)
 }

 /**
  * xmlBufShrink:
  * @buf:  the buffer to dump
  * @len:  the number of xmlChar to remove
  *
  * Remove the beginning of an XML buffer.
  * NOTE that this routine behaviour differs from xmlBufferShrink()
  * as it will return 0 on error instead of -1 due to size_t being
  * used as the return type.
  *
  * Returns the number of byte removed or 0 in case of failure
  */
 size_t
 xmlBufShrink(xmlBufPtr buf, size_t len) {
     if ((buf == NULL) || (buf->error != 0)) return(0);
     CHECK_COMPAT(buf)
     if (len == 0) return(0);
     if (len > buf->use) return(0);

     buf->use -= len;
     if ((buf->alloc == XML_BUFFER_ALLOC_IO) && (buf->contentIO != NULL)) {
 	/*
 	 * we just move the content pointer, but also make sure
 	 * the perceived buffer size has shrunk accordingly
 	 */
         buf->content += len;
 	buf->size -= len;

         /*
 	 * sometimes though it maybe be better to really shrink
 	 * on IO buffers
 	 */
 	if ((buf->alloc == XML_BUFFER_ALLOC_IO) && (buf->contentIO != NULL)) {
 	    size_t start_buf = buf->content - buf->contentIO;
 	    if (start_buf >= buf->size) {
 		memmove(buf->contentIO, &buf->content[0], buf->use);
 		buf->content = buf->contentIO;
 		buf->content[buf->use] = 0;
 		buf->size += start_buf;
 	    }
 	}
     } else {
 	memmove(buf->content, &buf->content[len], buf->use);
 	buf->content[buf->use] = 0;
     }
     UPDATE_COMPAT(buf)
     return(len);
 }

 /**
  * xmlBufGrowInternal:
  * @buf:  the buffer
  * @len:  the minimum free size to allocate
  *
  * Grow the available space of an XML buffer, @len is the target value
  * Error checking should be done on buf->error since using the return
  * value doesn't work that well
  *
  * Returns 0 in case of error or the length made available otherwise
  */
 static size_t
 xmlBufGrowInternal(xmlBufPtr buf, size_t len) {
     size_t size;
     xmlChar *newbuf;

     if ((buf == NULL) || (buf->error != 0)) return(0);
     CHECK_COMPAT(buf)

     if (len < buf->size - buf->use)
         return(buf->size - buf->use - 1);
     if (len >= SIZE_MAX - buf->use) {
         xmlBufMemoryError(buf);
         return(0);
     }

     if (buf->size > (size_t) len) {
         size = buf->size > SIZE_MAX / 2 ? SIZE_MAX : buf->size * 2;
     } else {
         size = buf->use + len;
         size = size > SIZE_MAX - 100 ? SIZE_MAX : size + 100;
     }

     if (buf->alloc == XML_BUFFER_ALLOC_BOUNDED) {
         /*
 	 * Used to provide parsing limits
 	 */
         if ((buf->use + len + 1 >= XML_MAX_TEXT_LENGTH) ||
 	    (buf->size >= XML_MAX_TEXT_LENGTH)) {
 	    xmlBufMemoryError(buf);
 	    return(0);
 	}
 	if (size >= XML_MAX_TEXT_LENGTH)
 	    size = XML_MAX_TEXT_LENGTH;
     }
     if ((buf->alloc == XML_BUFFER_ALLOC_IO) && (buf->contentIO != NULL)) {
         size_t start_buf = buf->content - buf->contentIO;

 	newbuf = (xmlChar *) xmlRealloc(buf->contentIO, start_buf + size);
 	if (newbuf == NULL) {
 	    xmlBufMemoryError(buf);
 	    return(0);
 	}
 	buf->contentIO = newbuf;
 	buf->content = newbuf + start_buf;
     } else {
 	newbuf = (xmlChar *) xmlRealloc(buf->content, size);
 	if (newbuf == NULL) {
 	    xmlBufMemoryError(buf);
 	    return(0);
 	}
 	buf->content = newbuf;
     }
     buf->size = size;
     UPDATE_COMPAT(buf)
     return(buf->size - buf->use - 1);
 }

 /**
  * xmlBufGrow:
  * @buf:  the buffer
  * @len:  the minimum free size to allocate
  *
  * Grow the available space of an XML buffer, @len is the target value
  * This is been kept compatible with xmlBufferGrow() as much as possible
  *
  * Returns -1 in case of error or the length made available otherwise
  */
 int
 xmlBufGrow(xmlBufPtr buf, int len) {
     size_t ret;

     if ((buf == NULL) || (len < 0)) return(-1);
     if (len == 0)
         return(0);
     ret = xmlBufGrowInternal(buf, len);
     if (buf->error != 0)
         return(-1);
     return(ret > INT_MAX ? INT_MAX : ret);
 }

 /**
  * xmlBufDump:
  * @file:  the file output
  * @buf:  the buffer to dump
  *
  * Dumps an XML buffer to  a FILE *.
  * Returns the number of #xmlChar written
  */
 size_t
 xmlBufDump(FILE *file, xmlBufPtr buf) {
     size_t ret;

     if ((buf == NULL) || (buf->error != 0)) {
 	return(0);
     }
     if (buf->content == NULL) {
 	return(0);
     }
     CHECK_COMPAT(buf)
     if (file == NULL)
 	file = stdout;
     ret = fwrite(buf->content, 1, buf->use, file);
     return(ret);
 }

 /**
  * xmlBufContent:
  * @buf:  the buffer
  *
  * Function to extract the content of a buffer
  *
  * Returns the internal content
  */

 xmlChar *
 xmlBufContent(const xmlBuf *buf)
 {
     if ((!buf) || (buf->error))
         return NULL;

     return(buf->content);
 }

 /**
  * xmlBufEnd:
  * @buf:  the buffer
  *
  * Function to extract the end of the content of a buffer
  *
  * Returns the end of the internal content or NULL in case of error
  */

 xmlChar *
 xmlBufEnd(xmlBufPtr buf)
 {
     if ((!buf) || (buf->error))
         return NULL;
     CHECK_COMPAT(buf)

     return(&buf->content[buf->use]);
 }

 /**
  * xmlBufAddLen:
  * @buf:  the buffer
  * @len:  the size which were added at the end
  *
  * Sometime data may be added at the end of the buffer without
  * using the xmlBuf APIs that is used to expand the used space
  * and set the zero terminating at the end of the buffer
  *
  * Returns -1 in case of error and 0 otherwise
  */
 int
 xmlBufAddLen(xmlBufPtr buf, size_t len) {
     if ((buf == NULL) || (buf->error))
         return(-1);
     CHECK_COMPAT(buf)
     if (len >= (buf->size - buf->use))
         return(-1);
     buf->use += len;
     buf->content[buf->use] = 0;
     UPDATE_COMPAT(buf)
     return(0);
 }

 /**
  * xmlBufLength:
  * @buf:  the buffer
  *
  * Function to get the length of a buffer
  *
  * Returns the length of data in the internal content
  */

 size_t
 xmlBufLength(const xmlBufPtr buf)
 {
     if ((!buf) || (buf->error))
         return 0;
     CHECK_COMPAT(buf)

     return(buf->use);
 }

 /**
  * xmlBufUse:
  * @buf:  the buffer
  *
  * Function to get the length of a buffer
  *
  * Returns the length of data in the internal content
  */

 size_t
 xmlBufUse(const xmlBufPtr buf)
 {
     if ((!buf) || (buf->error))
         return 0;
     CHECK_COMPAT(buf)

     return(buf->use);
 }

 /**
  * xmlBufAvail:
  * @buf:  the buffer
  *
  * Function to find how much free space is allocated but not
  * used in the buffer. It reserves one byte for the NUL
  * terminator character that is usually needed, so there is
  * no need to subtract 1 from the result anymore.
  *
  * Returns the amount, or 0 if none or if an error occurred.
  */

 size_t
 xmlBufAvail(const xmlBufPtr buf)
 {
     if ((!buf) || (buf->error))
         return 0;
     CHECK_COMPAT(buf)

     return((buf->size > buf->use) ? (buf->size - buf->use - 1) : 0);
 }

 /**
  * xmlBufIsEmpty:
  * @buf:  the buffer
  *
  * Tell if a buffer is empty
  *
  * Returns 0 if no, 1 if yes and -1 in case of error
  */
 int
 xmlBufIsEmpty(const xmlBufPtr buf)
 {
     if ((!buf) || (buf->error))
         return(-1);
     CHECK_COMPAT(buf)

     return(buf->use == 0);
 }

 /**
  * xmlBufResize:
  * @buf:  the buffer to resize
  * @size:  the desired size
  *
  * Resize a buffer to accommodate minimum size of @size.
  *
  * Returns  0 in case of problems, 1 otherwise
  */
 int
 xmlBufResize(xmlBufPtr buf, size_t size)
 {
     size_t newSize;
     xmlChar* rebuf = NULL;
     size_t start_buf;

     if ((buf == NULL) || (buf->error))
         return(0);
     CHECK_COMPAT(buf)

     if (buf->alloc == XML_BUFFER_ALLOC_BOUNDED) {
         /*
 	 * Used to provide parsing limits
 	 */
         if (size >= XML_MAX_TEXT_LENGTH) {
 	    xmlBufMemoryError(buf);
 	    return(0);
 	}
     }

     /* Don't resize if we don't have to */
     if (size < buf->size)
         return 1;

     /* figure out new size */
     switch (buf->alloc){
 	case XML_BUFFER_ALLOC_IO:
 	case XML_BUFFER_ALLOC_DOUBLEIT:
 	    /*take care of empty case*/
             if (buf->size == 0) {
                 newSize = (size > SIZE_MAX - 10 ? SIZE_MAX : size + 10);
             } else {
                 newSize = buf->size;
             }
 	    while (size > newSize) {
 	        if (newSize > SIZE_MAX / 2) {
 	            xmlBufMemoryError(buf);
 	            return 0;
 	        }
 	        newSize *= 2;
 	    }
 	    break;
 	case XML_BUFFER_ALLOC_EXACT:
             newSize = (size > SIZE_MAX - 10 ? SIZE_MAX : size + 10);
 	    break;
         case XML_BUFFER_ALLOC_HYBRID:
             if (buf->use < BASE_BUFFER_SIZE)
                 newSize = size;
             else {
                 newSize = buf->size;
                 while (size > newSize) {
                     if (newSize > SIZE_MAX / 2) {
                         xmlBufMemoryError(buf);
                         return 0;
                     }
                     newSize *= 2;
                 }
             }
             break;

 	default:
             newSize = (size > SIZE_MAX - 10 ? SIZE_MAX : size + 10);
 	    break;
     }

     if ((buf->alloc == XML_BUFFER_ALLOC_IO) && (buf->contentIO != NULL)) {
         start_buf = buf->content - buf->contentIO;

         if (start_buf > newSize) {
 	    /* move data back to start */
 	    memmove(buf->contentIO, buf->content, buf->use);
 	    buf->content = buf->contentIO;
 	    buf->content[buf->use] = 0;
 	    buf->size += start_buf;
 	} else {
 	    rebuf = (xmlChar *) xmlRealloc(buf->contentIO, start_buf + newSize);
 	    if (rebuf == NULL) {
 		xmlBufMemoryError(buf);
 		return 0;
 	    }
 	    buf->contentIO = rebuf;
 	    buf->content = rebuf + start_buf;
 	}
     } else {
 	if (buf->content == NULL) {
 	    rebuf = (xmlChar *) xmlMallocAtomic(newSize);
 	    buf->use = 0;
             if (rebuf != NULL)
 	        rebuf[buf->use] = 0;
 	} else if (buf->size - buf->use < 100) {
 	    rebuf = (xmlChar *) xmlRealloc(buf->content, newSize);
         } else {
 	    /*
 	     * if we are reallocating a buffer far from being full, it's
 	     * better to make a new allocation and copy only the used range
 	     * and free the old one.
 	     */
 	    rebuf = (xmlChar *) xmlMallocAtomic(newSize);
 	    if (rebuf != NULL) {
 		memcpy(rebuf, buf->content, buf->use);
 		xmlFree(buf->content);
 		rebuf[buf->use] = 0;
 	    }
 	}
 	if (rebuf == NULL) {
 	    xmlBufMemoryError(buf);
 	    return 0;
 	}
 	buf->content = rebuf;
     }
     buf->size = newSize;
     UPDATE_COMPAT(buf)

     return 1;
 }

 /**
  * xmlBufAdd:
  * @buf:  the buffer to dump
  * @str:  the #xmlChar string
  * @len:  the number of #xmlChar to add
  *
  * Add a string range to an XML buffer. if len == -1, the length of
  * str is recomputed.
  *
  * Returns 0 if successful, -1 in case of error.
  */
 int
 xmlBufAdd(xmlBufPtr buf, const xmlChar *str, int len) {
     size_t needSize;

     if ((str == NULL) || (buf == NULL) || (buf->error))
 	return -1;
     CHECK_COMPAT(buf)

     if (len < -1) {
 	return -1;
     }
     if (len == 0) return 0;

     if (len < 0)
         len = xmlStrlen(str);

     if (len < 0) return -1;
     if (len == 0) return 0;

     /* Note that both buf->size and buf->use can be zero here. */
     if ((size_t) len >= buf->size - buf->use) {
         if ((size_t) len >= SIZE_MAX - buf->use) {
             xmlBufMemoryError(buf);
             return(-1);
         }
         needSize = buf->use + len + 1;
 	if (buf->alloc == XML_BUFFER_ALLOC_BOUNDED) {
 	    /*
 	     * Used to provide parsing limits
 	     */
 	    if (needSize >= XML_MAX_TEXT_LENGTH) {
 		xmlBufMemoryError(buf);
 		return(-1);
 	    }
 	}
         if (!xmlBufResize(buf, needSize))
             return(-1);
     }

     memmove(&buf->content[buf->use], str, len);
     buf->use += len;
     buf->content[buf->use] = 0;
     UPDATE_COMPAT(buf)
     return 0;
 }

 /**
  * xmlBufCat:
  * @buf:  the buffer to add to
  * @str:  the #xmlChar string
  *
  * Append a zero terminated string to an XML buffer.
  *
  * Returns 0 successful, a positive error code number otherwise
  *         and -1 in case of internal or API error.
  */
 int
 xmlBufCat(xmlBufPtr buf, const xmlChar *str) {
     if ((buf == NULL) || (buf->error))
         return(-1);
     CHECK_COMPAT(buf)
     if (str == NULL) return -1;
     return xmlBufAdd(buf, str, -1);
 }

 /**
  * xmlBufFromBuffer:
  * @buffer: incoming old buffer to convert to a new one
  *
  * Helper routine to switch from the old buffer structures in use
  * in various APIs. It creates a wrapper xmlBufPtr which will be
  * used for internal processing until the xmlBufBackToBuffer() is
  * issued.
  *
  * Returns a new xmlBufPtr unless the call failed and NULL is returned
  */
 xmlBufPtr
 xmlBufFromBuffer(xmlBufferPtr buffer) {
     xmlBufPtr ret;

     if (buffer == NULL)
         return(NULL);

     ret = (xmlBufPtr) xmlMalloc(sizeof(xmlBuf));
     if (ret == NULL) {
         return(NULL);
     }
     ret->use = buffer->use;
     ret->size = buffer->size;
     UPDATE_COMPAT(ret);
     ret->error = 0;
     ret->buffer = buffer;
     ret->alloc = buffer->alloc;
     ret->content = buffer->content;
     ret->contentIO = buffer->contentIO;

     return(ret);
 }

 /**
  * xmlBufBackToBuffer:
  * @buf: new buffer wrapping the old one
  *
  * Function to be called once internal processing had been done to
  * update back the buffer provided by the user. This can lead to
  * a failure in case the size accumulated in the xmlBuf is larger
  * than what an xmlBuffer can support on 64 bits (INT_MAX)
  * The xmlBufPtr @buf wrapper is deallocated by this call in any case.
  *
  * Returns the old xmlBufferPtr unless the call failed and NULL is returned
  */
 xmlBufferPtr
 xmlBufBackToBuffer(xmlBufPtr buf) {
     xmlBufferPtr ret;

     if (buf == NULL)
         return(NULL);
     CHECK_COMPAT(buf)
     ret = buf->buffer;

     if ((buf->error) || (ret == NULL)) {
         xmlBufFree(buf);
         if (ret != NULL) {
             ret->content = NULL;
             ret->contentIO = NULL;
             ret->use = 0;
             ret->size = 0;
         }
         return(NULL);
     }

     /*
      * What to do in case of error in the buffer ???
      */
     if (buf->use > INT_MAX) {
         /*
          * Worse case, we really allocated and used more than the
          * maximum allowed memory for an xmlBuffer on this architecture.
          * Keep the buffer but provide a truncated size value.
          */
         xmlBufOverflowError(buf);
         ret->use = INT_MAX;
         ret->size = INT_MAX;
     } else if (buf->size > INT_MAX) {
         /*
          * milder case, we allocated more than the maximum allowed memory
          * for an xmlBuffer on this architecture, but used less than the
          * limit.
          * Keep the buffer but provide a truncated size value.
          */
         xmlBufOverflowError(buf);
         ret->use = buf->use;
         ret->size = INT_MAX;
     } else {
         ret->use = buf->use;
         ret->size = buf->size;
     }
     ret->alloc = buf->alloc;
     ret->content = buf->content;
     ret->contentIO = buf->contentIO;
     xmlFree(buf);
     return(ret);
 }

 /**
  * xmlBufResetInput:
  * @buf: an xmlBufPtr
  * @input: an xmlParserInputPtr
  *
  * Update the input to use the current set of pointers from the buffer.
  *
  * Returns -1 in case of error, 0 otherwise
  */
 int
 xmlBufResetInput(xmlBufPtr buf, xmlParserInputPtr input) {
     return(xmlBufUpdateInput(buf, input, 0));
 }

 /**
  * xmlBufUpdateInput:
  * @buf: an xmlBufPtr
  * @input: an xmlParserInputPtr
  * @pos: the cur value relative to the beginning of the buffer
  *
  * Update the input to use the base and cur relative to the buffer
  * after a possible reallocation of its content
  *
  * Returns -1 in case of error, 0 otherwise
  */
 int
 xmlBufUpdateInput(xmlBufPtr buf, xmlParserInputPtr input, size_t pos) {
     if ((buf == NULL) || (input == NULL))
         return(-1);
     CHECK_COMPAT(buf)
     input->base = buf->content;
     input->cur = input->base + pos;
     input->end = &buf->content[buf->use];
     return(0);
 }
	/*
	* buf.c: memory buffers for libxml2
	*
	* new buffer structures and entry points to simplify the maintenance
	* of libxml2 and ensure we keep good control over memory allocations
	* and stay 64 bits clean.
	* The new entry point use the xmlBufPtr opaque structure and
	* xmlBuf...() counterparts to the old xmlBuf...() functions
	*
	* See Copyright for the status of this software.
	*
	* daniel@veillard.com
	*/

	#define IN_LIBXML
	#include "libxml.h"

	#include <string.h> /* for memset() only ! */
	#include <limits.h>
	#include <ctype.h>
	#include <stdlib.h>

	#include <libxml/tree.h>
	#include <libxml/parserInternals.h> /* for XML_MAX_TEXT_LENGTH */

	#include "private/buf.h"
	#include "private/error.h"

	#ifndef SIZE_MAX
	#define SIZE_MAX ((size_t) -1)
	#endif

	#define WITH_BUFFER_COMPAT

	/**
	* xmlBuf:
	*
	* A buffer structure. The base of the structure is somehow compatible
	* with struct _xmlBuffer to limit risks on application which accessed
	* directly the input->buf->buffer structures.
	*/

	struct _xmlBuf {
	xmlChar content; / The buffer content UTF8 */
	unsigned int compat_use; /* for binary compatibility */
	unsigned int compat_size; /* for binary compatibility */
	xmlBufferAllocationScheme alloc; /* The realloc method */
	xmlChar contentIO; / in IO mode we may have a different base */
	size_t use; /* The buffer size used */
	size_t size; /* The buffer size */
	xmlBufferPtr buffer; /* wrapper for an old buffer */
	int error; /* an error code if a failure occurred */
	};

	#ifdef WITH_BUFFER_COMPAT
	/*
	* Macro for compatibility with xmlBuffer to be used after an xmlBuf
	* is updated. This makes sure the compat fields are updated too.
	*/
	#define UPDATE_COMPAT(buf) \
	if (buf->size < INT_MAX) buf->compat_size = buf->size; \
	else buf->compat_size = INT_MAX; \
	if (buf->use < INT_MAX) buf->compat_use = buf->use; \
	else buf->compat_use = INT_MAX;

	/*
	* Macro for compatibility with xmlBuffer to be used in all the xmlBuf
	* entry points, it checks that the compat fields have not been modified
	* by direct call to xmlBuffer function from code compiled before 2.9.0 .
	*/
	#define CHECK_COMPAT(buf) \
	if (buf->size != (size_t) buf->compat_size) \
	if (buf->compat_size < INT_MAX) \
	buf->size = buf->compat_size; \
	if (buf->use != (size_t) buf->compat_use) \
	if (buf->compat_use < INT_MAX) \
	buf->use = buf->compat_use;

	#else /* ! WITH_BUFFER_COMPAT */
	#define UPDATE_COMPAT(buf)
	#define CHECK_COMPAT(buf)
	#endif /* WITH_BUFFER_COMPAT */

	/**
	* xmlBufMemoryError:
	* @extra: extra information
	*
	* Handle an out of memory condition
	* To be improved...
	*/
	static void
	xmlBufMemoryError(xmlBufPtr buf)
	{
	if (buf->error == 0)
	buf->error = XML_ERR_NO_MEMORY;
	}

	/**
	* xmlBufOverflowError:
	* @extra: extra information
	*
	* Handle a buffer overflow error
	* To be improved...
	*/
	static void
	xmlBufOverflowError(xmlBufPtr buf)
	{
	if (buf->error == 0)
	buf->error = XML_BUF_OVERFLOW;
	}


	/**
	* xmlBufCreate:
	*
	* routine to create an XML buffer.
	* returns the new structure.
	*/
	xmlBufPtr
	xmlBufCreate(void) {
	xmlBufPtr ret;

	ret = (xmlBufPtr) xmlMalloc(sizeof(xmlBuf));
	if (ret == NULL)
	return(NULL);
	ret->use = 0;
	ret->error = 0;
	ret->buffer = NULL;
	ret->size = xmlDefaultBufferSize;
	UPDATE_COMPAT(ret);
	ret->alloc = xmlBufferAllocScheme;
	ret->content = (xmlChar *) xmlMallocAtomic(ret->size);
	if (ret->content == NULL) {
	xmlFree(ret);
	return(NULL);
	}
	ret->content[0] = 0;
	ret->contentIO = NULL;
	return(ret);
	}

	/**
	* xmlBufCreateSize:
	* @size: initial size of buffer
	*
	* routine to create an XML buffer.
	* returns the new structure.
	*/
	xmlBufPtr
	xmlBufCreateSize(size_t size) {
	xmlBufPtr ret;

	if (size == SIZE_MAX)
	return(NULL);
	ret = (xmlBufPtr) xmlMalloc(sizeof(xmlBuf));
	if (ret == NULL)
	return(NULL);
	ret->use = 0;
	ret->error = 0;
	ret->buffer = NULL;
	ret->alloc = xmlBufferAllocScheme;
	ret->size = (size ? size + 1 : 0); /* +1 for ending null */
	UPDATE_COMPAT(ret);
	if (ret->size){
	ret->content = (xmlChar *) xmlMallocAtomic(ret->size);
	if (ret->content == NULL) {
	xmlFree(ret);
	return(NULL);
	}
	ret->content[0] = 0;
	} else
	ret->content = NULL;
	ret->contentIO = NULL;
	return(ret);
	}

	/**
	* xmlBufDetach:
	* @buf: the buffer
	*
	* Remove the string contained in a buffer and give it back to the
	* caller. The buffer is reset to an empty content.
	* This doesn't work with immutable buffers as they can't be reset.
	*
	* Returns the previous string contained by the buffer.
	*/
	xmlChar *
	xmlBufDetach(xmlBufPtr buf) {
	xmlChar *ret;

	if (buf == NULL)
	return(NULL);
	if (buf->buffer != NULL)
	return(NULL);
	if (buf->error)
	return(NULL);

	if ((buf->alloc == XML_BUFFER_ALLOC_IO) &&
	(buf->content != buf->contentIO)) {
	ret = xmlStrndup(buf->content, buf->use);
	xmlFree(buf->contentIO);
	} else {
	ret = buf->content;
	}

	buf->content = NULL;
	buf->contentIO = NULL;
	buf->size = 0;
	buf->use = 0;
	UPDATE_COMPAT(buf);

	return ret;
	}

	/**
	* xmlBufGetAllocationScheme:
	* @buf: the buffer
	*
	* Get the buffer allocation scheme
	*
	* Returns the scheme or -1 in case of error
	*/
	int
	xmlBufGetAllocationScheme(xmlBufPtr buf) {
	if (buf == NULL) {
	return(-1);
	}
	return(buf->alloc);
	}

	/**
	* xmlBufSetAllocationScheme:
	* @buf: the buffer to tune
	* @scheme: allocation scheme to use
	*
	* Sets the allocation scheme for this buffer
	*
	* returns 0 in case of success and -1 in case of failure
	*/
	int
	xmlBufSetAllocationScheme(xmlBufPtr buf,
	xmlBufferAllocationScheme scheme) {
	if ((buf == NULL) \|\| (buf->error != 0)) {
	return(-1);
	}
	if (buf->alloc == XML_BUFFER_ALLOC_IO)
	return(-1);
	if ((scheme == XML_BUFFER_ALLOC_DOUBLEIT) \|\|
	(scheme == XML_BUFFER_ALLOC_EXACT) \|\|
	(scheme == XML_BUFFER_ALLOC_HYBRID) \|\|
	(scheme == XML_BUFFER_ALLOC_BOUNDED)) {
	buf->alloc = scheme;
	if (buf->buffer)
	buf->buffer->alloc = scheme;
	return(0);
	}
	/*
	* Switching a buffer ALLOC_IO has the side effect of initializing
	* the contentIO field with the current content
	*/
	if (scheme == XML_BUFFER_ALLOC_IO) {
	buf->alloc = XML_BUFFER_ALLOC_IO;
	buf->contentIO = buf->content;
	}
	return(-1);
	}

	/**
	* xmlBufFree:
	* @buf: the buffer to free
	*
	* Frees an XML buffer. It frees both the content and the structure which
	* encapsulate it.
	*/
	void
	xmlBufFree(xmlBufPtr buf) {
	if (buf == NULL) {
	return;
	}

	if ((buf->alloc == XML_BUFFER_ALLOC_IO) &&
	(buf->contentIO != NULL)) {
	xmlFree(buf->contentIO);
	} else if (buf->content != NULL) {
	xmlFree(buf->content);
	}
	xmlFree(buf);
	}

	/**
	* xmlBufEmpty:
	* @buf: the buffer
	*
	* empty a buffer.
	*/
	void
	xmlBufEmpty(xmlBufPtr buf) {
	if ((buf == NULL) \|\| (buf->error != 0)) return;
	if (buf->content == NULL) return;
	CHECK_COMPAT(buf)
	buf->use = 0;
	if ((buf->alloc == XML_BUFFER_ALLOC_IO) &&
	(buf->contentIO != NULL)) {
	size_t start_buf = buf->content - buf->contentIO;

	buf->size += start_buf;
	buf->content = buf->contentIO;
	buf->content[0] = 0;
	} else {
	buf->content[0] = 0;
	}
	UPDATE_COMPAT(buf)
	}

	/**
	* xmlBufShrink:
	* @buf: the buffer to dump
	* @len: the number of xmlChar to remove
	*
	* Remove the beginning of an XML buffer.
	* NOTE that this routine behaviour differs from xmlBufferShrink()
	* as it will return 0 on error instead of -1 due to size_t being
	* used as the return type.
	*
	* Returns the number of byte removed or 0 in case of failure
	*/
	size_t
	xmlBufShrink(xmlBufPtr buf, size_t len) {
	if ((buf == NULL) \|\| (buf->error != 0)) return(0);
	CHECK_COMPAT(buf)
	if (len == 0) return(0);
	if (len > buf->use) return(0);

	buf->use -= len;
	if ((buf->alloc == XML_BUFFER_ALLOC_IO) && (buf->contentIO != NULL)) {
	/*
	* we just move the content pointer, but also make sure
	* the perceived buffer size has shrunk accordingly
	*/
	buf->content += len;
	buf->size -= len;

	/*
	* sometimes though it maybe be better to really shrink
	* on IO buffers
	*/
	if ((buf->alloc == XML_BUFFER_ALLOC_IO) && (buf->contentIO != NULL)) {
	size_t start_buf = buf->content - buf->contentIO;
	if (start_buf >= buf->size) {
	memmove(buf->contentIO, &buf->content[0], buf->use);
	buf->content = buf->contentIO;
	buf->content[buf->use] = 0;
	buf->size += start_buf;
	}
	}
	} else {
	memmove(buf->content, &buf->content[len], buf->use);
	buf->content[buf->use] = 0;
	}
	UPDATE_COMPAT(buf)
	return(len);
	}

	/**
	* xmlBufGrowInternal:
	* @buf: the buffer
	* @len: the minimum free size to allocate
	*
	* Grow the available space of an XML buffer, @len is the target value
	* Error checking should be done on buf->error since using the return
	* value doesn't work that well
	*
	* Returns 0 in case of error or the length made available otherwise
	*/
	static size_t
	xmlBufGrowInternal(xmlBufPtr buf, size_t len) {
	size_t size;
	xmlChar *newbuf;

	if ((buf == NULL) \|\| (buf->error != 0)) return(0);
	CHECK_COMPAT(buf)

	if (len < buf->size - buf->use)
	return(buf->size - buf->use - 1);
	if (len >= SIZE_MAX - buf->use) {
	xmlBufMemoryError(buf);
	return(0);
	}

	if (buf->size > (size_t) len) {
	size = buf->size > SIZE_MAX / 2 ? SIZE_MAX : buf->size * 2;
	} else {
	size = buf->use + len;
	size = size > SIZE_MAX - 100 ? SIZE_MAX : size + 100;
	}

	if (buf->alloc == XML_BUFFER_ALLOC_BOUNDED) {
	/*
	* Used to provide parsing limits
	*/
	if ((buf->use + len + 1 >= XML_MAX_TEXT_LENGTH) \|\|
	(buf->size >= XML_MAX_TEXT_LENGTH)) {
	xmlBufMemoryError(buf);
	return(0);
	}
	if (size >= XML_MAX_TEXT_LENGTH)
	size = XML_MAX_TEXT_LENGTH;
	}
	if ((buf->alloc == XML_BUFFER_ALLOC_IO) && (buf->contentIO != NULL)) {
	size_t start_buf = buf->content - buf->contentIO;

	newbuf = (xmlChar *) xmlRealloc(buf->contentIO, start_buf + size);
	if (newbuf == NULL) {
	xmlBufMemoryError(buf);
	return(0);
	}
	buf->contentIO = newbuf;
	buf->content = newbuf + start_buf;
	} else {
	newbuf = (xmlChar *) xmlRealloc(buf->content, size);
	if (newbuf == NULL) {
	xmlBufMemoryError(buf);
	return(0);
	}
	buf->content = newbuf;
	}
	buf->size = size;
	UPDATE_COMPAT(buf)
	return(buf->size - buf->use - 1);
	}

	/**
	* xmlBufGrow:
	* @buf: the buffer
	* @len: the minimum free size to allocate
	*
	* Grow the available space of an XML buffer, @len is the target value
	* This is been kept compatible with xmlBufferGrow() as much as possible
	*
	* Returns -1 in case of error or the length made available otherwise
	*/
	int
	xmlBufGrow(xmlBufPtr buf, int len) {
	size_t ret;

	if ((buf == NULL) \|\| (len < 0)) return(-1);
	if (len == 0)
	return(0);
	ret = xmlBufGrowInternal(buf, len);
	if (buf->error != 0)
	return(-1);
	return(ret > INT_MAX ? INT_MAX : ret);
	}

	/**
	* xmlBufDump:
	* @file: the file output
	* @buf: the buffer to dump
	*
	* Dumps an XML buffer to a FILE *.
	* Returns the number of #xmlChar written
	*/
	size_t
	xmlBufDump(FILE *file, xmlBufPtr buf) {
	size_t ret;

	if ((buf == NULL) \|\| (buf->error != 0)) {
	return(0);
	}
	if (buf->content == NULL) {
	return(0);
	}
	CHECK_COMPAT(buf)
	if (file == NULL)
	file = stdout;
	ret = fwrite(buf->content, 1, buf->use, file);
	return(ret);
	}

	/**
	* xmlBufContent:
	* @buf: the buffer
	*
	* Function to extract the content of a buffer
	*
	* Returns the internal content
	*/

	xmlChar *
	xmlBufContent(const xmlBuf *buf)
	{
	if ((!buf) \|\| (buf->error))
	return NULL;

	return(buf->content);
	}

	/**
	* xmlBufEnd:
	* @buf: the buffer
	*
	* Function to extract the end of the content of a buffer
	*
	* Returns the end of the internal content or NULL in case of error
	*/

	xmlChar *
	xmlBufEnd(xmlBufPtr buf)
	{
	if ((!buf) \|\| (buf->error))
	return NULL;
	CHECK_COMPAT(buf)

	return(&buf->content[buf->use]);
	}

	/**
	* xmlBufAddLen:
	* @buf: the buffer
	* @len: the size which were added at the end
	*
	* Sometime data may be added at the end of the buffer without
	* using the xmlBuf APIs that is used to expand the used space
	* and set the zero terminating at the end of the buffer
	*
	* Returns -1 in case of error and 0 otherwise
	*/
	int
	xmlBufAddLen(xmlBufPtr buf, size_t len) {
	if ((buf == NULL) \|\| (buf->error))
	return(-1);
	CHECK_COMPAT(buf)
	if (len >= (buf->size - buf->use))
	return(-1);
	buf->use += len;
	buf->content[buf->use] = 0;
	UPDATE_COMPAT(buf)
	return(0);
	}

	/**
	* xmlBufLength:
	* @buf: the buffer
	*
	* Function to get the length of a buffer
	*
	* Returns the length of data in the internal content
	*/

	size_t
	xmlBufLength(const xmlBufPtr buf)
	{
	if ((!buf) \|\| (buf->error))
	return 0;
	CHECK_COMPAT(buf)

	return(buf->use);
	}

	/**
	* xmlBufUse:
	* @buf: the buffer
	*
	* Function to get the length of a buffer
	*
	* Returns the length of data in the internal content
	*/

	size_t
	xmlBufUse(const xmlBufPtr buf)
	{
	if ((!buf) \|\| (buf->error))
	return 0;
	CHECK_COMPAT(buf)

	return(buf->use);
	}

	/**
	* xmlBufAvail:
	* @buf: the buffer
	*
	* Function to find how much free space is allocated but not
	* used in the buffer. It reserves one byte for the NUL
	* terminator character that is usually needed, so there is
	* no need to subtract 1 from the result anymore.
	*
	* Returns the amount, or 0 if none or if an error occurred.
	*/

	size_t
	xmlBufAvail(const xmlBufPtr buf)
	{
	if ((!buf) \|\| (buf->error))
	return 0;
	CHECK_COMPAT(buf)

	return((buf->size > buf->use) ? (buf->size - buf->use - 1) : 0);
	}

	/**
	* xmlBufIsEmpty:
	* @buf: the buffer
	*
	* Tell if a buffer is empty
	*
	* Returns 0 if no, 1 if yes and -1 in case of error
	*/
	int
	xmlBufIsEmpty(const xmlBufPtr buf)
	{
	if ((!buf) \|\| (buf->error))
	return(-1);
	CHECK_COMPAT(buf)

	return(buf->use == 0);
	}

	/**
	* xmlBufResize:
	* @buf: the buffer to resize
	* @size: the desired size
	*
	* Resize a buffer to accommodate minimum size of @size.
	*
	* Returns 0 in case of problems, 1 otherwise
	*/
	int
	xmlBufResize(xmlBufPtr buf, size_t size)
	{
	size_t newSize;
	xmlChar* rebuf = NULL;
	size_t start_buf;

	if ((buf == NULL) \|\| (buf->error))
	return(0);
	CHECK_COMPAT(buf)

	if (buf->alloc == XML_BUFFER_ALLOC_BOUNDED) {
	/*
	* Used to provide parsing limits
	*/
	if (size >= XML_MAX_TEXT_LENGTH) {
	xmlBufMemoryError(buf);
	return(0);
	}
	}

	/* Don't resize if we don't have to */
	if (size < buf->size)
	return 1;

	/* figure out new size */
	switch (buf->alloc){
	case XML_BUFFER_ALLOC_IO:
	case XML_BUFFER_ALLOC_DOUBLEIT:
	/take care of empty case/
	if (buf->size == 0) {
	newSize = (size > SIZE_MAX - 10 ? SIZE_MAX : size + 10);
	} else {
	newSize = buf->size;
	}
	while (size > newSize) {
	if (newSize > SIZE_MAX / 2) {
	xmlBufMemoryError(buf);
	return 0;
	}
	newSize *= 2;
	}
	break;
	case XML_BUFFER_ALLOC_EXACT:
	newSize = (size > SIZE_MAX - 10 ? SIZE_MAX : size + 10);
	break;
	case XML_BUFFER_ALLOC_HYBRID:
	if (buf->use < BASE_BUFFER_SIZE)
	newSize = size;
	else {
	newSize = buf->size;
	while (size > newSize) {
	if (newSize > SIZE_MAX / 2) {
	xmlBufMemoryError(buf);
	return 0;
	}
	newSize *= 2;
	}
	}
	break;

	default:
	newSize = (size > SIZE_MAX - 10 ? SIZE_MAX : size + 10);
	break;
	}

	if ((buf->alloc == XML_BUFFER_ALLOC_IO) && (buf->contentIO != NULL)) {
	start_buf = buf->content - buf->contentIO;

	if (start_buf > newSize) {
	/* move data back to start */
	memmove(buf->contentIO, buf->content, buf->use);
	buf->content = buf->contentIO;
	buf->content[buf->use] = 0;
	buf->size += start_buf;
	} else {
	rebuf = (xmlChar *) xmlRealloc(buf->contentIO, start_buf + newSize);
	if (rebuf == NULL) {
	xmlBufMemoryError(buf);
	return 0;
	}
	buf->contentIO = rebuf;
	buf->content = rebuf + start_buf;
	}
	} else {
	if (buf->content == NULL) {
	rebuf = (xmlChar *) xmlMallocAtomic(newSize);
	buf->use = 0;
	if (rebuf != NULL)
	rebuf[buf->use] = 0;
	} else if (buf->size - buf->use < 100) {
	rebuf = (xmlChar *) xmlRealloc(buf->content, newSize);
	} else {
	/*
	* if we are reallocating a buffer far from being full, it's
	* better to make a new allocation and copy only the used range
	* and free the old one.
	*/
	rebuf = (xmlChar *) xmlMallocAtomic(newSize);
	if (rebuf != NULL) {
	memcpy(rebuf, buf->content, buf->use);
	xmlFree(buf->content);
	rebuf[buf->use] = 0;
	}
	}
	if (rebuf == NULL) {
	xmlBufMemoryError(buf);
	return 0;
	}
	buf->content = rebuf;
	}
	buf->size = newSize;
	UPDATE_COMPAT(buf)

	return 1;
	}

	/**
	* xmlBufAdd:
	* @buf: the buffer to dump
	* @str: the #xmlChar string
	* @len: the number of #xmlChar to add
	*
	* Add a string range to an XML buffer. if len == -1, the length of
	* str is recomputed.
	*
	* Returns 0 if successful, -1 in case of error.
	*/
	int
	xmlBufAdd(xmlBufPtr buf, const xmlChar *str, int len) {
	size_t needSize;

	if ((str == NULL) \|\| (buf == NULL) \|\| (buf->error))
	return -1;
	CHECK_COMPAT(buf)

	if (len < -1) {
	return -1;
	}
	if (len == 0) return 0;

	if (len < 0)
	len = xmlStrlen(str);

	if (len < 0) return -1;
	if (len == 0) return 0;

	/* Note that both buf->size and buf->use can be zero here. */
	if ((size_t) len >= buf->size - buf->use) {
	if ((size_t) len >= SIZE_MAX - buf->use) {
	xmlBufMemoryError(buf);
	return(-1);
	}
	needSize = buf->use + len + 1;
	if (buf->alloc == XML_BUFFER_ALLOC_BOUNDED) {
	/*
	* Used to provide parsing limits
	*/
	if (needSize >= XML_MAX_TEXT_LENGTH) {
	xmlBufMemoryError(buf);
	return(-1);
	}
	}
	if (!xmlBufResize(buf, needSize))
	return(-1);
	}

	memmove(&buf->content[buf->use], str, len);
	buf->use += len;
	buf->content[buf->use] = 0;
	UPDATE_COMPAT(buf)
	return 0;
	}

	/**
	* xmlBufCat:
	* @buf: the buffer to add to
	* @str: the #xmlChar string
	*
	* Append a zero terminated string to an XML buffer.
	*
	* Returns 0 successful, a positive error code number otherwise
	* and -1 in case of internal or API error.
	*/
	int
	xmlBufCat(xmlBufPtr buf, const xmlChar *str) {
	if ((buf == NULL) \|\| (buf->error))
	return(-1);
	CHECK_COMPAT(buf)
	if (str == NULL) return -1;
	return xmlBufAdd(buf, str, -1);
	}

	/**
	* xmlBufFromBuffer:
	* @buffer: incoming old buffer to convert to a new one
	*
	* Helper routine to switch from the old buffer structures in use
	* in various APIs. It creates a wrapper xmlBufPtr which will be
	* used for internal processing until the xmlBufBackToBuffer() is
	* issued.
	*
	* Returns a new xmlBufPtr unless the call failed and NULL is returned
	*/
	xmlBufPtr
	xmlBufFromBuffer(xmlBufferPtr buffer) {
	xmlBufPtr ret;

	if (buffer == NULL)
	return(NULL);

	ret = (xmlBufPtr) xmlMalloc(sizeof(xmlBuf));
	if (ret == NULL) {
	return(NULL);
	}
	ret->use = buffer->use;
	ret->size = buffer->size;
	UPDATE_COMPAT(ret);
	ret->error = 0;
	ret->buffer = buffer;
	ret->alloc = buffer->alloc;
	ret->content = buffer->content;
	ret->contentIO = buffer->contentIO;

	return(ret);
	}

	/**
	* xmlBufBackToBuffer:
	* @buf: new buffer wrapping the old one
	*
	* Function to be called once internal processing had been done to
	* update back the buffer provided by the user. This can lead to
	* a failure in case the size accumulated in the xmlBuf is larger
	* than what an xmlBuffer can support on 64 bits (INT_MAX)
	* The xmlBufPtr @buf wrapper is deallocated by this call in any case.
	*
	* Returns the old xmlBufferPtr unless the call failed and NULL is returned
	*/
	xmlBufferPtr
	xmlBufBackToBuffer(xmlBufPtr buf) {
	xmlBufferPtr ret;

	if (buf == NULL)
	return(NULL);
	CHECK_COMPAT(buf)
	ret = buf->buffer;

	if ((buf->error) \|\| (ret == NULL)) {
	xmlBufFree(buf);
	if (ret != NULL) {
	ret->content = NULL;
	ret->contentIO = NULL;
	ret->use = 0;
	ret->size = 0;
	}
	return(NULL);
	}

	/*
	* What to do in case of error in the buffer ???
	*/
	if (buf->use > INT_MAX) {
	/*
	* Worse case, we really allocated and used more than the
	* maximum allowed memory for an xmlBuffer on this architecture.
	* Keep the buffer but provide a truncated size value.
	*/
	xmlBufOverflowError(buf);
	ret->use = INT_MAX;
	ret->size = INT_MAX;
	} else if (buf->size > INT_MAX) {
	/*
	* milder case, we allocated more than the maximum allowed memory
	* for an xmlBuffer on this architecture, but used less than the
	* limit.
	* Keep the buffer but provide a truncated size value.
	*/
	xmlBufOverflowError(buf);
	ret->use = buf->use;
	ret->size = INT_MAX;
	} else {
	ret->use = buf->use;
	ret->size = buf->size;
	}
	ret->alloc = buf->alloc;
	ret->content = buf->content;
	ret->contentIO = buf->contentIO;
	xmlFree(buf);
	return(ret);
	}

	/**
	* xmlBufResetInput:
	* @buf: an xmlBufPtr
	* @input: an xmlParserInputPtr
	*
	* Update the input to use the current set of pointers from the buffer.
	*
	* Returns -1 in case of error, 0 otherwise
	*/
	int
	xmlBufResetInput(xmlBufPtr buf, xmlParserInputPtr input) {
	return(xmlBufUpdateInput(buf, input, 0));
	}

	/**
	* xmlBufUpdateInput:
	* @buf: an xmlBufPtr
	* @input: an xmlParserInputPtr
	* @pos: the cur value relative to the beginning of the buffer
	*
	* Update the input to use the base and cur relative to the buffer
	* after a possible reallocation of its content
	*
	* Returns -1 in case of error, 0 otherwise
	*/
	int
	xmlBufUpdateInput(xmlBufPtr buf, xmlParserInputPtr input, size_t pos) {
	if ((buf == NULL) \|\| (input == NULL))
	return(-1);
	CHECK_COMPAT(buf)
	input->base = buf->content;
	input->cur = input->base + pos;
	input->end = &buf->content[buf->use];
	return(0);
	}