lib/zip_source_buffer.c - third_party/libzip - Git at Google

 /*
   zip_source_buffer.c -- create zip data source from buffer
   Copyright (C) 1999-2016 Dieter Baron and Thomas Klausner

   This file is part of libzip, a library to manipulate ZIP archives.
   The authors can be contacted at <libzip@nih.at>

   Redistribution and use in source and binary forms, with or without
   modification, are permitted provided that the following conditions
   are met:
   1. Redistributions of source code must retain the above copyright
      notice, this list of conditions and the following disclaimer.
   2. Redistributions in binary form must reproduce the above copyright
      notice, this list of conditions and the following disclaimer in
      the documentation and/or other materials provided with the
      distribution.
   3. The names of the authors may not be used to endorse or promote
      products derived from this software without specific prior
      written permission.

   THIS SOFTWARE IS PROVIDED BY THE AUTHORS ``AS IS'' AND ANY EXPRESS
   OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
   WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
   ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY
   DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
   DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE
   GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
   INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER
   IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
   OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
   IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */

 #include <stdlib.h>
 #include <string.h>

 #include "zipint.h"

 #ifndef WRITE_FRAGMENT_SIZE
 #define WRITE_FRAGMENT_SIZE 64*1024
 #endif

 struct buffer {
     zip_uint64_t fragment_size;		/* size of each fragment */

     zip_uint8_t **fragments;		/* pointers to fragments */
     zip_uint64_t nfragments;		/* number of allocated fragments */
     zip_uint64_t fragments_capacity;	/* size of fragments (number of pointers) */
     zip_uint64_t size;			/* size of data in bytes */
     zip_uint64_t offset;		/* current offset */
     int free_data;
 };

 typedef struct buffer buffer_t;

 struct read_data {
     zip_error_t error;
     time_t mtime;
     buffer_t *in;
     buffer_t *out;
 };

 static void buffer_free(buffer_t *buffer);
 static buffer_t *buffer_new(zip_uint64_t fragment_size);
 static buffer_t *buffer_new_read(const void *data, zip_uint64_t length, int free_data);
 static buffer_t *buffer_new_write(zip_uint64_t fragment_size);
 static zip_int64_t buffer_read(buffer_t *buffer, zip_uint8_t *data, zip_uint64_t length);
 static int buffer_seek(buffer_t *buffer, void *data, zip_uint64_t len, zip_error_t *error);
 static zip_int64_t buffer_write(buffer_t *buffer, const zip_uint8_t *data, zip_uint64_t length, zip_error_t *);

 static zip_int64_t read_data(void *, void *, zip_uint64_t, zip_source_cmd_t);


 ZIP_EXTERN zip_source_t *
 zip_source_buffer(zip_t *za, const void *data, zip_uint64_t len, int freep)
 {
     if (za == NULL)
 	return NULL;

     return zip_source_buffer_create(data, len, freep, &za->error);
 }


 ZIP_EXTERN zip_source_t *
 zip_source_buffer_create(const void *data, zip_uint64_t len, int freep, zip_error_t *error)
 {
     struct read_data *ctx;
     zip_source_t *zs;

     if (data == NULL && len > 0) {
 	zip_error_set(error, ZIP_ER_INVAL, 0);
 	return NULL;
     }

     if ((ctx=(struct read_data *)malloc(sizeof(*ctx))) == NULL) {
 	zip_error_set(error, ZIP_ER_MEMORY, 0);
 	return NULL;
     }

     if ((ctx->in = buffer_new_read(data, len, freep)) == NULL) {
 	zip_error_set(error, ZIP_ER_MEMORY, 0);
 	free(ctx);
 	return NULL;
     }

     ctx->out = NULL;
     ctx->mtime = time(NULL);
     zip_error_init(&ctx->error);

     if ((zs=zip_source_function_create(read_data, ctx, error)) == NULL) {
 	buffer_free(ctx->in);
 	free(ctx);
 	return NULL;
     }

     return zs;
 }


 static zip_int64_t
 read_data(void *state, void *data, zip_uint64_t len, zip_source_cmd_t cmd)
 {
     struct read_data *ctx = (struct read_data *)state;

     switch (cmd) {
         case ZIP_SOURCE_BEGIN_WRITE:
 	    if ((ctx->out = buffer_new_write(WRITE_FRAGMENT_SIZE)) == NULL) {
 		zip_error_set(&ctx->error, ZIP_ER_MEMORY, 0);
 		return -1;
 	    }
 	    return 0;

         case ZIP_SOURCE_CLOSE:
             return 0;

         case ZIP_SOURCE_COMMIT_WRITE:
 	    buffer_free(ctx->in);
 	    ctx->in = ctx->out;
 	    ctx->out = NULL;
 	    return 0;

         case ZIP_SOURCE_ERROR:
             return zip_error_to_data(&ctx->error, data, len);

         case ZIP_SOURCE_FREE:
 	    buffer_free(ctx->in);
 	    buffer_free(ctx->out);
             free(ctx);
             return 0;

         case ZIP_SOURCE_OPEN:
 	    ctx->in->offset = 0;
             return 0;

         case ZIP_SOURCE_READ:
 	    if (len > ZIP_INT64_MAX) {
 		zip_error_set(&ctx->error, ZIP_ER_INVAL, 0);
 		return -1;
 	    }
             return buffer_read(ctx->in, data, len);

         case ZIP_SOURCE_REMOVE:
 	{
 	    buffer_t *empty = buffer_new_read(NULL, 0, 0);
 	    if (empty == 0) {
 		zip_error_set(&ctx->error, ZIP_ER_MEMORY, 0);
 		return -1;
 	    }

 	    buffer_free(ctx->in);
 	    ctx->in = empty;
 	    return 0;
 	}

         case ZIP_SOURCE_ROLLBACK_WRITE:
 	    buffer_free(ctx->out);
 	    ctx->out = NULL;
 	    return 0;

         case ZIP_SOURCE_SEEK:
 	    return buffer_seek(ctx->in, data, len, &ctx->error);

         case ZIP_SOURCE_SEEK_WRITE:
 	    return buffer_seek(ctx->out, data, len, &ctx->error);

         case ZIP_SOURCE_STAT:
         {
             zip_stat_t *st;

 	    if (len < sizeof(*st)) {
                 zip_error_set(&ctx->error, ZIP_ER_INVAL, 0);
 		return -1;
 	    }

 	    st = (zip_stat_t *)data;

 	    zip_stat_init(st);
 	    st->mtime = ctx->mtime;
 	    st->size = ctx->in->size;
 	    st->comp_size = st->size;
 	    st->comp_method = ZIP_CM_STORE;
 	    st->encryption_method = ZIP_EM_NONE;
 	    st->valid = ZIP_STAT_MTIME|ZIP_STAT_SIZE|ZIP_STAT_COMP_SIZE|ZIP_STAT_COMP_METHOD|ZIP_STAT_ENCRYPTION_METHOD;

 	    return sizeof(*st);
 	}

         case ZIP_SOURCE_SUPPORTS:
 	    return zip_source_make_command_bitmap(ZIP_SOURCE_OPEN, ZIP_SOURCE_READ, ZIP_SOURCE_CLOSE, ZIP_SOURCE_STAT, ZIP_SOURCE_ERROR, ZIP_SOURCE_FREE, ZIP_SOURCE_SEEK, ZIP_SOURCE_TELL, ZIP_SOURCE_BEGIN_WRITE, ZIP_SOURCE_COMMIT_WRITE, ZIP_SOURCE_REMOVE, ZIP_SOURCE_ROLLBACK_WRITE, ZIP_SOURCE_SEEK_WRITE, ZIP_SOURCE_TELL_WRITE, ZIP_SOURCE_WRITE, -1);

         case ZIP_SOURCE_TELL:
             if (ctx->in->offset > ZIP_INT64_MAX) {
 		zip_error_set(&ctx->error, ZIP_ER_TELL, EOVERFLOW);
 		return -1;
 	    }
 	    return (zip_int64_t)ctx->in->offset;


         case ZIP_SOURCE_TELL_WRITE:
             if (ctx->out->offset > ZIP_INT64_MAX) {
 		zip_error_set(&ctx->error, ZIP_ER_TELL, EOVERFLOW);
 		return -1;
 	    }
 	    return (zip_int64_t)ctx->out->offset;

         case ZIP_SOURCE_WRITE:
 	    if (len > ZIP_INT64_MAX) {
 		zip_error_set(&ctx->error, ZIP_ER_INVAL, 0);
 		return -1;
 	    }
 	    return buffer_write(ctx->out, data, len, &ctx->error);

         default:
 	    zip_error_set(&ctx->error, ZIP_ER_OPNOTSUPP, 0);
             return -1;
     }
 }


 static void
 buffer_free(buffer_t *buffer)
 {
     if (buffer == NULL) {
 	return;
     }

     if (buffer->free_data) {
 	zip_uint64_t i;

 	for (i=0; i < buffer->nfragments; i++) {
 	    free(buffer->fragments[i]);
 	}
     }
     free(buffer->fragments);
     free(buffer);
 }


 static buffer_t *
 buffer_new(zip_uint64_t fragment_size)
 {
     buffer_t *buffer;

     if ((buffer = malloc(sizeof(*buffer))) == NULL) {
 	return NULL;
     }

     buffer->fragment_size = fragment_size;
     buffer->offset = 0;
     buffer->free_data = 0;
     buffer->nfragments = 0;
     buffer->fragments_capacity = 0;
     buffer->fragments = NULL;
     buffer->size = 0;

     return buffer;
 }


 static buffer_t *
 buffer_new_read(const void *data, zip_uint64_t length, int free_data)
 {
     buffer_t *buffer;

     if ((buffer = buffer_new(length)) == NULL) {
 	return NULL;
     }

     buffer->size = length;

     if (length > 0) {
 	if ((buffer->fragments = malloc(sizeof(*(buffer->fragments)))) == NULL) {
 	    buffer_free(buffer);
 	    return NULL;
 	}
 	buffer->fragments_capacity = 1;

 	buffer->nfragments = 1;
 	buffer->fragments[0] = (zip_uint8_t *)data;
 	buffer->free_data = free_data;
     }

     return buffer;
 }


 static buffer_t *
 buffer_new_write(zip_uint64_t fragment_size)
 {
     buffer_t *buffer;

     if ((buffer = buffer_new(fragment_size)) == NULL) {
 	return NULL;
     }

     if ((buffer->fragments = malloc(sizeof(*(buffer->fragments)))) == NULL) {
 	buffer_free(buffer);
 	return NULL;
     }
     buffer->fragments_capacity = 1;
     buffer->nfragments = 0;
     buffer->free_data = 1;

     return buffer;
 }


 static zip_int64_t
 buffer_read(buffer_t *buffer, zip_uint8_t *data, zip_uint64_t length)
 {
     zip_uint64_t n, i, fragment_offset;

     length = ZIP_MIN(length, buffer->size - buffer->offset);

     if (length == 0) {
 	return 0;
     }
     if (length > ZIP_INT64_MAX) {
 	return -1;
     }

     i = buffer->offset / buffer->fragment_size;
     fragment_offset = buffer->offset % buffer->fragment_size;
     n = 0;
     while (n < length) {
 	zip_uint64_t left = ZIP_MIN(length - n, buffer->fragment_size - fragment_offset);

 	memcpy(data + n, buffer->fragments[i] + fragment_offset, left);

 	n += left;
 	i++;
 	fragment_offset = 0;
     }

     buffer->offset += n;
     return (zip_int64_t)n;
 }


 static int
 buffer_seek(buffer_t *buffer, void *data, zip_uint64_t len, zip_error_t *error)
 {
     zip_int64_t new_offset = zip_source_seek_compute_offset(buffer->offset, buffer->size, data, len, error);

     if (new_offset < 0) {
         return -1;
     }

     buffer->offset = (zip_uint64_t)new_offset;
     return 0;
 }


 static zip_int64_t
 buffer_write(buffer_t *buffer, const zip_uint8_t *data, zip_uint64_t length, zip_error_t *error)
 {
     zip_uint64_t n, i, fragment_offset;
     zip_uint8_t **fragments;

     if (buffer->offset + length + buffer->fragment_size - 1 < length) {
 	zip_error_set(error, ZIP_ER_INVAL, 0);
 	return -1;
     }

     /* grow buffer if needed */
     if (buffer->offset + length > buffer->nfragments * buffer->fragment_size) {
 	zip_uint64_t needed_fragments = (buffer->offset + length + buffer->fragment_size - 1) / buffer->fragment_size;

 	if (needed_fragments > buffer->fragments_capacity) {
 	    zip_uint64_t new_capacity = buffer->fragments_capacity;

 	    while (new_capacity < needed_fragments) {
 		new_capacity *= 2;
 	    }

 	    fragments = realloc(buffer->fragments, new_capacity * sizeof(*fragments));

 	    if (fragments == NULL) {
 		zip_error_set(error, ZIP_ER_MEMORY, 0);
 		return -1;
 	    }

 	    buffer->fragments = fragments;
 	    buffer->fragments_capacity = new_capacity;
 	}

 	while (buffer->nfragments < needed_fragments) {
 	    if ((buffer->fragments[buffer->nfragments] = malloc(buffer->fragment_size)) == NULL) {
 		zip_error_set(error, ZIP_ER_MEMORY, 0);
 		return -1;
 	    }
 	    buffer->nfragments++;
 	}
     }

     i = buffer->offset / buffer->fragment_size;
     fragment_offset = buffer->offset % buffer->fragment_size;
     n = 0;
     while (n < length) {
 	zip_uint64_t left = ZIP_MIN(length - n, buffer->fragment_size - fragment_offset);

 	memcpy(buffer->fragments[i] + fragment_offset, data + n, left);

 	n += left;
 	i++;
 	fragment_offset = 0;
     }

     buffer->offset += n;
     if (buffer->offset > buffer->size) {
 	buffer->size = buffer->offset;
     }

     return (zip_int64_t)n;
 }
	/*
	zip_source_buffer.c -- create zip data source from buffer
	Copyright (C) 1999-2016 Dieter Baron and Thomas Klausner

	This file is part of libzip, a library to manipulate ZIP archives.
	The authors can be contacted at <libzip@nih.at>

	Redistribution and use in source and binary forms, with or without
	modification, are permitted provided that the following conditions
	are met:
	1. Redistributions of source code must retain the above copyright
	notice, this list of conditions and the following disclaimer.
	2. Redistributions in binary form must reproduce the above copyright
	notice, this list of conditions and the following disclaimer in
	the documentation and/or other materials provided with the
	distribution.
	3. The names of the authors may not be used to endorse or promote
	products derived from this software without specific prior
	written permission.

	THIS SOFTWARE IS PROVIDED BY THE AUTHORS ``AS IS'' AND ANY EXPRESS
	OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
	WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
	ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY
	DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
	DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE
	GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
	INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER
	IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
	OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
	IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include <stdlib.h>
	#include <string.h>

	#include "zipint.h"

	#ifndef WRITE_FRAGMENT_SIZE
	#define WRITE_FRAGMENT_SIZE 64*1024
	#endif

	struct buffer {
	zip_uint64_t fragment_size; /* size of each fragment */

	zip_uint8_t *fragments; / pointers to fragments */
	zip_uint64_t nfragments; /* number of allocated fragments */
	zip_uint64_t fragments_capacity; /* size of fragments (number of pointers) */
	zip_uint64_t size; /* size of data in bytes */
	zip_uint64_t offset; /* current offset */
	int free_data;
	};

	typedef struct buffer buffer_t;

	struct read_data {
	zip_error_t error;
	time_t mtime;
	buffer_t *in;
	buffer_t *out;
	};

	static void buffer_free(buffer_t *buffer);
	static buffer_t *buffer_new(zip_uint64_t fragment_size);
	static buffer_t buffer_new_read(const void data, zip_uint64_t length, int free_data);
	static buffer_t *buffer_new_write(zip_uint64_t fragment_size);
	static zip_int64_t buffer_read(buffer_t buffer, zip_uint8_t data, zip_uint64_t length);
	static int buffer_seek(buffer_t buffer, void data, zip_uint64_t len, zip_error_t *error);
	static zip_int64_t buffer_write(buffer_t buffer, const zip_uint8_t data, zip_uint64_t length, zip_error_t *);

	static zip_int64_t read_data(void , void , zip_uint64_t, zip_source_cmd_t);


	ZIP_EXTERN zip_source_t *
	zip_source_buffer(zip_t za, const void data, zip_uint64_t len, int freep)
	{
	if (za == NULL)
	return NULL;

	return zip_source_buffer_create(data, len, freep, &za->error);
	}


	ZIP_EXTERN zip_source_t *
	zip_source_buffer_create(const void data, zip_uint64_t len, int freep, zip_error_t error)
	{
	struct read_data *ctx;
	zip_source_t *zs;

	if (data == NULL && len > 0) {
	zip_error_set(error, ZIP_ER_INVAL, 0);
	return NULL;
	}

	if ((ctx=(struct read_data )malloc(sizeof(ctx))) == NULL) {
	zip_error_set(error, ZIP_ER_MEMORY, 0);
	return NULL;
	}

	if ((ctx->in = buffer_new_read(data, len, freep)) == NULL) {
	zip_error_set(error, ZIP_ER_MEMORY, 0);
	free(ctx);
	return NULL;
	}

	ctx->out = NULL;
	ctx->mtime = time(NULL);
	zip_error_init(&ctx->error);

	if ((zs=zip_source_function_create(read_data, ctx, error)) == NULL) {
	buffer_free(ctx->in);
	free(ctx);
	return NULL;
	}

	return zs;
	}


	static zip_int64_t
	read_data(void state, void data, zip_uint64_t len, zip_source_cmd_t cmd)
	{
	struct read_data ctx = (struct read_data )state;

	switch (cmd) {
	case ZIP_SOURCE_BEGIN_WRITE:
	if ((ctx->out = buffer_new_write(WRITE_FRAGMENT_SIZE)) == NULL) {
	zip_error_set(&ctx->error, ZIP_ER_MEMORY, 0);
	return -1;
	}
	return 0;

	case ZIP_SOURCE_CLOSE:
	return 0;

	case ZIP_SOURCE_COMMIT_WRITE:
	buffer_free(ctx->in);
	ctx->in = ctx->out;
	ctx->out = NULL;
	return 0;

	case ZIP_SOURCE_ERROR:
	return zip_error_to_data(&ctx->error, data, len);

	case ZIP_SOURCE_FREE:
	buffer_free(ctx->in);
	buffer_free(ctx->out);
	free(ctx);
	return 0;

	case ZIP_SOURCE_OPEN:
	ctx->in->offset = 0;
	return 0;

	case ZIP_SOURCE_READ:
	if (len > ZIP_INT64_MAX) {
	zip_error_set(&ctx->error, ZIP_ER_INVAL, 0);
	return -1;
	}
	return buffer_read(ctx->in, data, len);

	case ZIP_SOURCE_REMOVE:
	{
	buffer_t *empty = buffer_new_read(NULL, 0, 0);
	if (empty == 0) {
	zip_error_set(&ctx->error, ZIP_ER_MEMORY, 0);
	return -1;
	}

	buffer_free(ctx->in);
	ctx->in = empty;
	return 0;
	}

	case ZIP_SOURCE_ROLLBACK_WRITE:
	buffer_free(ctx->out);
	ctx->out = NULL;
	return 0;

	case ZIP_SOURCE_SEEK:
	return buffer_seek(ctx->in, data, len, &ctx->error);

	case ZIP_SOURCE_SEEK_WRITE:
	return buffer_seek(ctx->out, data, len, &ctx->error);

	case ZIP_SOURCE_STAT:
	{
	zip_stat_t *st;

	if (len < sizeof(*st)) {
	zip_error_set(&ctx->error, ZIP_ER_INVAL, 0);
	return -1;
	}

	st = (zip_stat_t *)data;

	zip_stat_init(st);
	st->mtime = ctx->mtime;
	st->size = ctx->in->size;
	st->comp_size = st->size;
	st->comp_method = ZIP_CM_STORE;
	st->encryption_method = ZIP_EM_NONE;
	st->valid = ZIP_STAT_MTIME\|ZIP_STAT_SIZE\|ZIP_STAT_COMP_SIZE\|ZIP_STAT_COMP_METHOD\|ZIP_STAT_ENCRYPTION_METHOD;

	return sizeof(*st);
	}

	case ZIP_SOURCE_SUPPORTS:
	return zip_source_make_command_bitmap(ZIP_SOURCE_OPEN, ZIP_SOURCE_READ, ZIP_SOURCE_CLOSE, ZIP_SOURCE_STAT, ZIP_SOURCE_ERROR, ZIP_SOURCE_FREE, ZIP_SOURCE_SEEK, ZIP_SOURCE_TELL, ZIP_SOURCE_BEGIN_WRITE, ZIP_SOURCE_COMMIT_WRITE, ZIP_SOURCE_REMOVE, ZIP_SOURCE_ROLLBACK_WRITE, ZIP_SOURCE_SEEK_WRITE, ZIP_SOURCE_TELL_WRITE, ZIP_SOURCE_WRITE, -1);

	case ZIP_SOURCE_TELL:
	if (ctx->in->offset > ZIP_INT64_MAX) {
	zip_error_set(&ctx->error, ZIP_ER_TELL, EOVERFLOW);
	return -1;
	}
	return (zip_int64_t)ctx->in->offset;


	case ZIP_SOURCE_TELL_WRITE:
	if (ctx->out->offset > ZIP_INT64_MAX) {
	zip_error_set(&ctx->error, ZIP_ER_TELL, EOVERFLOW);
	return -1;
	}
	return (zip_int64_t)ctx->out->offset;

	case ZIP_SOURCE_WRITE:
	if (len > ZIP_INT64_MAX) {
	zip_error_set(&ctx->error, ZIP_ER_INVAL, 0);
	return -1;
	}
	return buffer_write(ctx->out, data, len, &ctx->error);

	default:
	zip_error_set(&ctx->error, ZIP_ER_OPNOTSUPP, 0);
	return -1;
	}
	}


	static void
	buffer_free(buffer_t *buffer)
	{
	if (buffer == NULL) {
	return;
	}

	if (buffer->free_data) {
	zip_uint64_t i;

	for (i=0; i < buffer->nfragments; i++) {
	free(buffer->fragments[i]);
	}
	}
	free(buffer->fragments);
	free(buffer);
	}


	static buffer_t *
	buffer_new(zip_uint64_t fragment_size)
	{
	buffer_t *buffer;

	if ((buffer = malloc(sizeof(*buffer))) == NULL) {
	return NULL;
	}

	buffer->fragment_size = fragment_size;
	buffer->offset = 0;
	buffer->free_data = 0;
	buffer->nfragments = 0;
	buffer->fragments_capacity = 0;
	buffer->fragments = NULL;
	buffer->size = 0;

	return buffer;
	}


	static buffer_t *
	buffer_new_read(const void *data, zip_uint64_t length, int free_data)
	{
	buffer_t *buffer;

	if ((buffer = buffer_new(length)) == NULL) {
	return NULL;
	}

	buffer->size = length;

	if (length > 0) {
	if ((buffer->fragments = malloc(sizeof(*(buffer->fragments)))) == NULL) {
	buffer_free(buffer);
	return NULL;
	}
	buffer->fragments_capacity = 1;

	buffer->nfragments = 1;
	buffer->fragments[0] = (zip_uint8_t *)data;
	buffer->free_data = free_data;
	}

	return buffer;
	}


	static buffer_t *
	buffer_new_write(zip_uint64_t fragment_size)
	{
	buffer_t *buffer;

	if ((buffer = buffer_new(fragment_size)) == NULL) {
	return NULL;
	}

	if ((buffer->fragments = malloc(sizeof(*(buffer->fragments)))) == NULL) {
	buffer_free(buffer);
	return NULL;
	}
	buffer->fragments_capacity = 1;
	buffer->nfragments = 0;
	buffer->free_data = 1;

	return buffer;
	}


	static zip_int64_t
	buffer_read(buffer_t buffer, zip_uint8_t data, zip_uint64_t length)
	{
	zip_uint64_t n, i, fragment_offset;

	length = ZIP_MIN(length, buffer->size - buffer->offset);

	if (length == 0) {
	return 0;
	}
	if (length > ZIP_INT64_MAX) {
	return -1;
	}

	i = buffer->offset / buffer->fragment_size;
	fragment_offset = buffer->offset % buffer->fragment_size;
	n = 0;
	while (n < length) {
	zip_uint64_t left = ZIP_MIN(length - n, buffer->fragment_size - fragment_offset);

	memcpy(data + n, buffer->fragments[i] + fragment_offset, left);

	n += left;
	i++;
	fragment_offset = 0;
	}

	buffer->offset += n;
	return (zip_int64_t)n;
	}


	static int
	buffer_seek(buffer_t buffer, void data, zip_uint64_t len, zip_error_t *error)
	{
	zip_int64_t new_offset = zip_source_seek_compute_offset(buffer->offset, buffer->size, data, len, error);

	if (new_offset < 0) {
	return -1;
	}

	buffer->offset = (zip_uint64_t)new_offset;
	return 0;
	}


	static zip_int64_t
	buffer_write(buffer_t buffer, const zip_uint8_t data, zip_uint64_t length, zip_error_t *error)
	{
	zip_uint64_t n, i, fragment_offset;
	zip_uint8_t **fragments;

	if (buffer->offset + length + buffer->fragment_size - 1 < length) {
	zip_error_set(error, ZIP_ER_INVAL, 0);
	return -1;
	}

	/* grow buffer if needed */
	if (buffer->offset + length > buffer->nfragments * buffer->fragment_size) {
	zip_uint64_t needed_fragments = (buffer->offset + length + buffer->fragment_size - 1) / buffer->fragment_size;

	if (needed_fragments > buffer->fragments_capacity) {
	zip_uint64_t new_capacity = buffer->fragments_capacity;

	while (new_capacity < needed_fragments) {
	new_capacity *= 2;
	}

	fragments = realloc(buffer->fragments, new_capacity * sizeof(*fragments));

	if (fragments == NULL) {
	zip_error_set(error, ZIP_ER_MEMORY, 0);
	return -1;
	}

	buffer->fragments = fragments;
	buffer->fragments_capacity = new_capacity;
	}

	while (buffer->nfragments < needed_fragments) {
	if ((buffer->fragments[buffer->nfragments] = malloc(buffer->fragment_size)) == NULL) {
	zip_error_set(error, ZIP_ER_MEMORY, 0);
	return -1;
	}
	buffer->nfragments++;
	}
	}

	i = buffer->offset / buffer->fragment_size;
	fragment_offset = buffer->offset % buffer->fragment_size;
	n = 0;
	while (n < length) {
	zip_uint64_t left = ZIP_MIN(length - n, buffer->fragment_size - fragment_offset);

	memcpy(buffer->fragments[i] + fragment_offset, data + n, left);

	n += left;
	i++;
	fragment_offset = 0;
	}

	buffer->offset += n;
	if (buffer->offset > buffer->size) {
	buffer->size = buffer->offset;
	}

	return (zip_int64_t)n;
	}