legacy/libisofs_outdated/branches/thomas/libisofs/ecma119.c

1580 lines
42 KiB
C

/*
* Copyright (c) 2007 Vreixo Formoso
* Copyright (c) 2007 Mario Danic
*
* This file is part of the libisofs project; you can redistribute it and/or
* modify it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation. See COPYING file for details.
*/
#include "libisofs.h"
#include "ecma119.h"
#include "joliet.h"
#include "iso1999.h"
#include "eltorito.h"
#include "ecma119_tree.h"
#include "filesrc.h"
#include "image.h"
#include "writer.h"
#include "messages.h"
#include "rockridge.h"
#include "util.h"
#include "libburn/libburn.h"
#include <stdlib.h>
#include <time.h>
#include <string.h>
#include <locale.h>
#include <langinfo.h>
/*
* TODO #00011 : guard against bad path table usage with more than 65535 dirs
* image with more than 65535 directories have path_table related problems
* due to 16 bits parent id. Note that this problem only affects to folders
* that are parent of another folder.
*/
static
void ecma119_image_free(Ecma119Image *t)
{
size_t i;
ecma119_node_free(t->root);
iso_image_unref(t->image);
iso_rbtree_destroy(t->files, iso_file_src_free);
iso_ring_buffer_free(t->buffer);
for (i = 0; i < t->nwriters; ++i) {
IsoImageWriter *writer = t->writers[i];
writer->free_data(writer);
free(writer);
}
free(t->input_charset);
free(t->output_charset);
free(t->writers);
free(t);
}
/**
* Check if we should add version number ";" to the given node name.
*/
static
int need_version_number(Ecma119Image *t, Ecma119Node *n)
{
if (t->omit_version_numbers) {
return 0;
}
if (n->type == ECMA119_DIR || n->type == ECMA119_PLACEHOLDER) {
return 0;
} else {
return 1;
}
}
/**
* Compute the size of a directory entry for a single node
*/
static
size_t calc_dirent_len(Ecma119Image *t, Ecma119Node *n)
{
int ret = n->iso_name ? strlen(n->iso_name) + 33 : 34;
if (need_version_number(t, n)) {
ret += 2; /* take into account version numbers */
}
if (ret % 2)
ret++;
return ret;
}
/**
* Computes the total size of all directory entries of a single dir,
* acording to ECMA-119 6.8.1.1
*
* This also take into account the size needed for RR entries and
* SUSP continuation areas (SUSP, 5.1).
*
* @param ce
* Will be filled with the size needed for Continuation Areas
* @return
* The size needed for all dir entries of the given dir, without
* taking into account the continuation areas.
*/
static
size_t calc_dir_size(Ecma119Image *t, Ecma119Node *dir, size_t *ce)
{
size_t i, len;
size_t ce_len = 0;
/* size of "." and ".." entries */
len = 34 + 34;
if (t->rockridge) {
len += rrip_calc_len(t, dir, 1, 255 - 34, &ce_len);
*ce += ce_len;
len += rrip_calc_len(t, dir, 2, 255 - 34, &ce_len);
*ce += ce_len;
}
for (i = 0; i < dir->info.dir->nchildren; ++i) {
size_t remaining;
Ecma119Node *child = dir->info.dir->children[i];
size_t dirent_len = calc_dirent_len(t, child);
if (t->rockridge) {
dirent_len += rrip_calc_len(t, child, 0, 255 - dirent_len, &ce_len);
*ce += ce_len;
}
remaining = BLOCK_SIZE - (len % BLOCK_SIZE);
if (dirent_len > remaining) {
/* child directory entry doesn't fit on block */
len += remaining + dirent_len;
} else {
len += dirent_len;
}
}
/*
* The size of a dir is always a multiple of block size, as we must add
* the size of the unused space after the last directory record
* (ECMA-119, 6.8.1.3)
*/
len = ROUND_UP(len, BLOCK_SIZE);
/* cache the len */
dir->info.dir->len = len;
return len;
}
static
void calc_dir_pos(Ecma119Image *t, Ecma119Node *dir)
{
size_t i, len;
size_t ce_len = 0;
t->ndirs++;
dir->info.dir->block = t->curblock;
len = calc_dir_size(t, dir, &ce_len);
t->curblock += DIV_UP(len, BLOCK_SIZE);
if (t->rockridge) {
t->curblock += DIV_UP(ce_len, BLOCK_SIZE);
}
for (i = 0; i < dir->info.dir->nchildren; i++) {
Ecma119Node *child = dir->info.dir->children[i];
if (child->type == ECMA119_DIR) {
calc_dir_pos(t, child);
}
}
}
/**
* Compute the length of the path table, in bytes.
*/
static
uint32_t calc_path_table_size(Ecma119Node *dir)
{
uint32_t size;
size_t i;
/* size of path table for this entry */
size = 8;
size += dir->iso_name ? strlen(dir->iso_name) : 1;
size += (size % 2);
/* and recurse */
for (i = 0; i < dir->info.dir->nchildren; i++) {
Ecma119Node *child = dir->info.dir->children[i];
if (child->type == ECMA119_DIR) {
size += calc_path_table_size(child);
}
}
return size;
}
static
int ecma119_writer_compute_data_blocks(IsoImageWriter *writer)
{
Ecma119Image *target;
uint32_t path_table_size;
if (writer == NULL) {
return ISO_ASSERT_FAILURE;
}
target = writer->target;
/* compute position of directories */
iso_msg_debug(target->image->id, "Computing position of dir structure");
target->ndirs = 0;
calc_dir_pos(target, target->root);
/* compute length of pathlist */
iso_msg_debug(target->image->id, "Computing length of pathlist");
path_table_size = calc_path_table_size(target->root);
/* compute location for path tables */
target->l_path_table_pos = target->curblock;
target->curblock += DIV_UP(path_table_size, BLOCK_SIZE);
target->m_path_table_pos = target->curblock;
target->curblock += DIV_UP(path_table_size, BLOCK_SIZE);
target->path_table_size = path_table_size;
return ISO_SUCCESS;
}
/**
* Write a single directory record (ECMA-119, 9.1)
*
* @param file_id
* if >= 0, we use it instead of the filename (for "." and ".." entries).
* @param len_fi
* Computed length of the file identifier. Total size of the directory
* entry will be len + 33 + padding if needed (ECMA-119, 9.1.12)
* @param info
* SUSP entries for the given directory record. It will be NULL for the
* root directory record in the PVD (ECMA-119, 8.4.18) (in order to
* distinguish it from the "." entry in the root directory)
*/
static
void write_one_dir_record(Ecma119Image *t, Ecma119Node *node, int file_id,
uint8_t *buf, size_t len_fi, struct susp_info *info)
{
uint32_t len;
uint32_t block;
uint8_t len_dr; /*< size of dir entry without SUSP fields */
uint8_t *name = (file_id >= 0) ? (uint8_t*)&file_id
: (uint8_t*)node->iso_name;
struct ecma119_dir_record *rec = (struct ecma119_dir_record*)buf;
len_dr = 33 + len_fi + (len_fi % 2 ? 0 : 1);
memcpy(rec->file_id, name, len_fi);
if (need_version_number(t, node)) {
len_dr += 2;
rec->file_id[len_fi++] = ';';
rec->file_id[len_fi++] = '1';
}
if (node->type == ECMA119_DIR) {
/* use the cached length */
len = node->info.dir->len;
block = node->info.dir->block;
} else if (node->type == ECMA119_FILE) {
len = iso_file_src_get_size(node->info.file);
block = node->info.file->block;
} else {
/*
* for nodes other than files and dirs, we set both
* len and block to 0
*/
len = 0;
block = 0;
}
/*
* For ".." entry we need to write the parent info!
*/
if (file_id == 1 && node->parent)
node = node->parent;
rec->len_dr[0] = len_dr + (info != NULL ? info->suf_len : 0);
iso_bb(rec->block, block, 4);
iso_bb(rec->length, len, 4);
iso_datetime_7(rec->recording_time, t->now, t->always_gmt);
rec->flags[0] = (node->type == ECMA119_DIR) ? 2 : 0;
iso_bb(rec->vol_seq_number, 1, 2);
rec->len_fi[0] = len_fi;
/* and finally write the SUSP fields */
if (info != NULL) {
rrip_write_susp_fields(t, info, buf + len_dr);
}
}
static
char *get_relaxed_vol_id(Ecma119Image *t, const char *name)
{
int ret;
if (name == NULL) {
return NULL;
}
if (strcmp(t->input_charset, t->output_charset)) {
/* charset conversion needed */
char *str;
ret = strconv(name, t->input_charset, t->output_charset, &str);
if (ret == ISO_SUCCESS) {
return str;
}
iso_msg_submit(t->image->id, ISO_FILENAME_WRONG_CHARSET, ret,
"Charset conversion error. Can't convert %s from %s to %s",
name, t->input_charset, t->output_charset);
}
return strdup(name);
}
/**
* Write the Primary Volume Descriptor (ECMA-119, 8.4)
*/
static
int ecma119_writer_write_vol_desc(IsoImageWriter *writer)
{
IsoImage *image;
Ecma119Image *t;
struct ecma119_pri_vol_desc vol;
char *vol_id, *pub_id, *data_id, *volset_id;
char *system_id, *application_id, *copyright_file_id;
char *abstract_file_id, *biblio_file_id;
if (writer == NULL) {
return ISO_ASSERT_FAILURE;
}
t = writer->target;
image = t->image;
iso_msg_debug(image->id, "Write Primary Volume Descriptor");
memset(&vol, 0, sizeof(struct ecma119_pri_vol_desc));
if (t->relaxed_vol_atts) {
vol_id = get_relaxed_vol_id(t, image->volume_id);
volset_id = get_relaxed_vol_id(t, image->volset_id);
} else {
str2d_char(t->input_charset, image->volume_id, &vol_id);
str2d_char(t->input_charset, image->volset_id, &volset_id);
}
str2a_char(t->input_charset, image->publisher_id, &pub_id);
str2a_char(t->input_charset, image->data_preparer_id, &data_id);
str2a_char(t->input_charset, image->system_id, &system_id);
str2a_char(t->input_charset, image->application_id, &application_id);
str2d_char(t->input_charset, image->copyright_file_id, &copyright_file_id);
str2d_char(t->input_charset, image->abstract_file_id, &abstract_file_id);
str2d_char(t->input_charset, image->biblio_file_id, &biblio_file_id);
vol.vol_desc_type[0] = 1;
memcpy(vol.std_identifier, "CD001", 5);
vol.vol_desc_version[0] = 1;
strncpy_pad((char*)vol.system_id, system_id, 32);
strncpy_pad((char*)vol.volume_id, vol_id, 32);
iso_bb(vol.vol_space_size, t->vol_space_size, 4);
iso_bb(vol.vol_set_size, 1, 2);
iso_bb(vol.vol_seq_number, 1, 2);
iso_bb(vol.block_size, BLOCK_SIZE, 2);
iso_bb(vol.path_table_size, t->path_table_size, 4);
iso_lsb(vol.l_path_table_pos, t->l_path_table_pos, 4);
iso_msb(vol.m_path_table_pos, t->m_path_table_pos, 4);
write_one_dir_record(t, t->root, 0, vol.root_dir_record, 1, NULL);
strncpy_pad((char*)vol.vol_set_id, volset_id, 128);
strncpy_pad((char*)vol.publisher_id, pub_id, 128);
strncpy_pad((char*)vol.data_prep_id, data_id, 128);
strncpy_pad((char*)vol.application_id, application_id, 128);
strncpy_pad((char*)vol.copyright_file_id, copyright_file_id, 37);
strncpy_pad((char*)vol.abstract_file_id, abstract_file_id, 37);
strncpy_pad((char*)vol.bibliographic_file_id, biblio_file_id, 37);
iso_datetime_17(vol.vol_creation_time, t->now, t->always_gmt);
iso_datetime_17(vol.vol_modification_time, t->now, t->always_gmt);
iso_datetime_17(vol.vol_effective_time, t->now, t->always_gmt);
vol.file_structure_version[0] = 1;
free(vol_id);
free(volset_id);
free(pub_id);
free(data_id);
free(system_id);
free(application_id);
free(copyright_file_id);
free(abstract_file_id);
free(biblio_file_id);
/* Finally write the Volume Descriptor */
return iso_write(t, &vol, sizeof(struct ecma119_pri_vol_desc));
}
static
int write_one_dir(Ecma119Image *t, Ecma119Node *dir)
{
int ret;
uint8_t buffer[BLOCK_SIZE];
size_t i;
size_t fi_len, len;
struct susp_info info;
/* buf will point to current write position on buffer */
uint8_t *buf = buffer;
/* initialize buffer with 0s */
memset(buffer, 0, BLOCK_SIZE);
/*
* set susp_info to 0's, this way code for both plain ECMA-119 and
* RR is very similar
*/
memset(&info, 0, sizeof(struct susp_info));
if (t->rockridge) {
/* initialize the ce_block, it might be needed */
info.ce_block = dir->info.dir->block + DIV_UP(dir->info.dir->len,
BLOCK_SIZE);
}
/* write the "." and ".." entries first */
if (t->rockridge) {
ret = rrip_get_susp_fields(t, dir, 1, 255 - 32, &info);
if (ret < 0) {
return ret;
}
}
len = 34 + info.suf_len;
write_one_dir_record(t, dir, 0, buf, 1, &info);
buf += len;
if (t->rockridge) {
ret = rrip_get_susp_fields(t, dir, 2, 255 - 32, &info);
if (ret < 0) {
return ret;
}
}
len = 34 + info.suf_len;
write_one_dir_record(t, dir, 1, buf, 1, &info);
buf += len;
for (i = 0; i < dir->info.dir->nchildren; i++) {
Ecma119Node *child = dir->info.dir->children[i];
/* compute len of directory entry */
fi_len = strlen(child->iso_name);
len = fi_len + 33 + (fi_len % 2 ? 0 : 1);
if (need_version_number(t, child)) {
len += 2;
}
/* get the SUSP fields if rockridge is enabled */
if (t->rockridge) {
ret = rrip_get_susp_fields(t, child, 0, 255 - len, &info);
if (ret < 0) {
return ret;
}
len += info.suf_len;
}
if ( (buf + len - buffer) > BLOCK_SIZE) {
/* dir doesn't fit in current block */
ret = iso_write(t, buffer, BLOCK_SIZE);
if (ret < 0) {
return ret;
}
memset(buffer, 0, BLOCK_SIZE);
buf = buffer;
}
/* write the directory entry in any case */
write_one_dir_record(t, child, -1, buf, fi_len, &info);
buf += len;
}
/* write the last block */
ret = iso_write(t, buffer, BLOCK_SIZE);
if (ret < 0) {
return ret;
}
/* write the Continuation Area if needed */
if (info.ce_len > 0) {
ret = rrip_write_ce_fields(t, &info);
}
return ret;
}
static
int write_dirs(Ecma119Image *t, Ecma119Node *root)
{
int ret;
size_t i;
/* write all directory entries for this dir */
ret = write_one_dir(t, root);
if (ret < 0) {
return ret;
}
/* recurse */
for (i = 0; i < root->info.dir->nchildren; i++) {
Ecma119Node *child = root->info.dir->children[i];
if (child->type == ECMA119_DIR) {
ret = write_dirs(t, child);
if (ret < 0) {
return ret;
}
}
}
return ISO_SUCCESS;
}
static
int write_path_table(Ecma119Image *t, Ecma119Node **pathlist, int l_type)
{
size_t i, len;
uint8_t buf[64]; /* 64 is just a convenient size larger enought */
struct ecma119_path_table_record *rec;
void (*write_int)(uint8_t*, uint32_t, int);
Ecma119Node *dir;
uint32_t path_table_size;
int parent = 0;
int ret= ISO_SUCCESS;
path_table_size = 0;
write_int = l_type ? iso_lsb : iso_msb;
for (i = 0; i < t->ndirs; i++) {
dir = pathlist[i];
/* find the index of the parent in the table */
while ((i) && pathlist[parent] != dir->parent) {
parent++;
}
/* write the Path Table Record (ECMA-119, 9.4) */
memset(buf, 0, 64);
rec = (struct ecma119_path_table_record*) buf;
rec->len_di[0] = dir->parent ? (uint8_t) strlen(dir->iso_name) : 1;
rec->len_xa[0] = 0;
write_int(rec->block, dir->info.dir->block, 4);
write_int(rec->parent, parent + 1, 2);
if (dir->parent) {
memcpy(rec->dir_id, dir->iso_name, rec->len_di[0]);
}
len = 8 + rec->len_di[0] + (rec->len_di[0] % 2);
ret = iso_write(t, buf, len);
if (ret < 0) {
/* error */
return ret;
}
path_table_size += len;
}
/* we need to fill the last block with zeros */
path_table_size %= BLOCK_SIZE;
if (path_table_size) {
uint8_t zeros[BLOCK_SIZE];
len = BLOCK_SIZE - path_table_size;
memset(zeros, 0, len);
ret = iso_write(t, zeros, len);
}
return ret;
}
static
int write_path_tables(Ecma119Image *t)
{
int ret;
size_t i, j, cur;
Ecma119Node **pathlist;
iso_msg_debug(t->image->id, "Writing ISO Path tables");
/* allocate temporal pathlist */
pathlist = malloc(sizeof(void*) * t->ndirs);
if (pathlist == NULL) {
return ISO_OUT_OF_MEM;
}
pathlist[0] = t->root;
cur = 1;
for (i = 0; i < t->ndirs; i++) {
Ecma119Node *dir = pathlist[i];
for (j = 0; j < dir->info.dir->nchildren; j++) {
Ecma119Node *child = dir->info.dir->children[j];
if (child->type == ECMA119_DIR) {
pathlist[cur++] = child;
}
}
}
/* Write L Path Table */
ret = write_path_table(t, pathlist, 1);
if (ret < 0) {
goto write_path_tables_exit;
}
/* Write L Path Table */
ret = write_path_table(t, pathlist, 0);
write_path_tables_exit: ;
free(pathlist);
return ret;
}
/**
* Write both the directory structure (ECMA-119, 6.8) and the L and M
* Path Tables (ECMA-119, 6.9).
*/
static
int ecma119_writer_write_data(IsoImageWriter *writer)
{
int ret;
Ecma119Image *t;
if (writer == NULL) {
return ISO_ASSERT_FAILURE;
}
t = writer->target;
/* first of all, we write the directory structure */
ret = write_dirs(t, t->root);
if (ret < 0) {
return ret;
}
/* and write the path tables */
ret = write_path_tables(t);
return ret;
}
static
int ecma119_writer_free_data(IsoImageWriter *writer)
{
/* nothing to do */
return ISO_SUCCESS;
}
int ecma119_writer_create(Ecma119Image *target)
{
int ret;
IsoImageWriter *writer;
writer = malloc(sizeof(IsoImageWriter));
if (writer == NULL) {
return ISO_OUT_OF_MEM;
}
writer->compute_data_blocks = ecma119_writer_compute_data_blocks;
writer->write_vol_desc = ecma119_writer_write_vol_desc;
writer->write_data = ecma119_writer_write_data;
writer->free_data = ecma119_writer_free_data;
writer->data = NULL;
writer->target = target;
/* add this writer to image */
target->writers[target->nwriters++] = writer;
iso_msg_debug(target->image->id, "Creating low level ECMA-119 tree...");
ret = ecma119_tree_create(target);
if (ret < 0) {
return ret;
}
/* we need the volume descriptor */
target->curblock++;
return ISO_SUCCESS;
}
/** compute how many padding bytes are needed */
static
int pad_writer_compute_data_blocks(IsoImageWriter *writer)
{
Ecma119Image *target;
if (writer == NULL) {
return ISO_ASSERT_FAILURE;
}
target = writer->target;
if (target->curblock < 32) {
target->pad_blocks = 32 - target->curblock;
target->curblock = 32;
}
return ISO_SUCCESS;
}
static
int pad_writer_write_vol_desc(IsoImageWriter *writer)
{
/* nothing to do */
return ISO_SUCCESS;
}
static
int pad_writer_write_data(IsoImageWriter *writer)
{
int ret;
Ecma119Image *t;
uint32_t pad[BLOCK_SIZE];
size_t i;
if (writer == NULL) {
return ISO_ASSERT_FAILURE;
}
t = writer->target;
if (t->pad_blocks == 0) {
return ISO_SUCCESS;
}
memset(pad, 0, BLOCK_SIZE);
for (i = 0; i < t->pad_blocks; ++i) {
ret = iso_write(t, pad, BLOCK_SIZE);
if (ret < 0) {
return ret;
}
}
return ISO_SUCCESS;
}
static
int pad_writer_free_data(IsoImageWriter *writer)
{
/* nothing to do */
return ISO_SUCCESS;
}
static
int pad_writer_create(Ecma119Image *target)
{
IsoImageWriter *writer;
writer = malloc(sizeof(IsoImageWriter));
if (writer == NULL) {
return ISO_OUT_OF_MEM;
}
writer->compute_data_blocks = pad_writer_compute_data_blocks;
writer->write_vol_desc = pad_writer_write_vol_desc;
writer->write_data = pad_writer_write_data;
writer->free_data = pad_writer_free_data;
writer->data = NULL;
writer->target = target;
/* add this writer to image */
target->writers[target->nwriters++] = writer;
return ISO_SUCCESS;
}
static
void *write_function(void *arg)
{
int res;
size_t i;
uint8_t buf[BLOCK_SIZE];
IsoImageWriter *writer;
Ecma119Image *target = (Ecma119Image*)arg;
iso_msg_debug(target->image->id, "Starting image writing...");
target->bytes_written = (off_t) 0;
target->percent_written = 0;
/* Write System Area, 16 blocks of zeros (ECMA-119, 6.2.1) */
memset(buf, 0, BLOCK_SIZE);
for (i = 0; i < 16; ++i) {
res = iso_write(target, buf, BLOCK_SIZE);
if (res < 0) {
goto write_error;
}
}
/* write volume descriptors, one per writer */
iso_msg_debug(target->image->id, "Write volume descriptors");
for (i = 0; i < target->nwriters; ++i) {
writer = target->writers[i];
res = writer->write_vol_desc(writer);
if (res < 0) {
goto write_error;
}
}
/* write Volume Descriptor Set Terminator (ECMA-119, 8.3) */
{
struct ecma119_vol_desc_terminator *vol;
vol = (struct ecma119_vol_desc_terminator *) buf;
vol->vol_desc_type[0] = 255;
memcpy(vol->std_identifier, "CD001", 5);
vol->vol_desc_version[0] = 1;
res = iso_write(target, buf, BLOCK_SIZE);
if (res < 0) {
goto write_error;
}
}
/* write data for each writer */
for (i = 0; i < target->nwriters; ++i) {
writer = target->writers[i];
res = writer->write_data(writer);
if (res < 0) {
goto write_error;
}
}
iso_ring_buffer_writer_close(target->buffer, 0);
pthread_exit(NULL);
write_error: ;
if (res == ISO_CANCELED) {
/* canceled */
iso_msg_submit(target->image->id, ISO_IMAGE_WRITE_CANCELED, 0, NULL);
} else {
/* image write error */
iso_msg_submit(target->image->id, ISO_WRITE_ERROR, res,
"Image write error");
}
iso_ring_buffer_writer_close(target->buffer, 1);
pthread_exit(NULL);
}
static
int ecma119_image_new(IsoImage *src, IsoWriteOpts *opts, Ecma119Image **img)
{
int ret, i, voldesc_size, nwriters;
Ecma119Image *target;
/* 1. Allocate target and copy opts there */
target = calloc(1, sizeof(Ecma119Image));
if (target == NULL) {
return ISO_OUT_OF_MEM;
}
/* create the tree for file caching */
ret = iso_rbtree_new(iso_file_src_cmp, &(target->files));
if (ret < 0) {
free(target);
return ret;
}
target->image = src;
iso_image_ref(src);
target->iso_level = opts->level;
target->rockridge = opts->rockridge;
target->joliet = opts->joliet;
target->iso1999 = opts->iso1999;
target->always_gmt = opts->always_gmt;
target->ino = 0;
target->omit_version_numbers = opts->omit_version_numbers
| opts->max_37_char_filenames;
target->allow_deep_paths = opts->allow_deep_paths;
target->allow_longer_paths = opts->allow_longer_paths;
target->max_37_char_filenames = opts->max_37_char_filenames;
target->no_force_dots = opts->no_force_dots;
target->allow_lowercase = opts->allow_lowercase;
target->allow_full_ascii = opts->allow_full_ascii;
target->relaxed_vol_atts = opts->relaxed_vol_atts;
target->joliet_longer_paths = opts->joliet_longer_paths;
target->sort_files = opts->sort_files;
target->replace_uid = opts->replace_uid ? 1 : 0;
target->replace_gid = opts->replace_gid ? 1 : 0;
target->replace_dir_mode = opts->replace_dir_mode ? 1 : 0;
target->replace_file_mode = opts->replace_file_mode ? 1 : 0;
target->uid = opts->replace_uid == 2 ? opts->uid : 0;
target->gid = opts->replace_gid == 2 ? opts->gid : 0;
target->dir_mode = opts->replace_dir_mode == 2 ? opts->dir_mode : 0555;
target->file_mode = opts->replace_file_mode == 2 ? opts->file_mode : 0444;
target->now = time(NULL);
target->ms_block = opts->ms_block;
target->appendable = opts->appendable;
target->replace_timestamps = opts->replace_timestamps ? 1 : 0;
target->timestamp = opts->replace_timestamps == 2 ?
opts->timestamp : target->now;
/* el-torito? */
target->eltorito = (src->bootcat == NULL ? 0 : 1);
target->catalog = src->bootcat;
/* default to locale charset */
setlocale(LC_CTYPE, "");
target->input_charset = strdup(nl_langinfo(CODESET));
if (target->input_charset == NULL) {
iso_image_unref(src);
free(target);
return ISO_OUT_OF_MEM;
}
if (opts->output_charset != NULL) {
target->output_charset = strdup(opts->output_charset);
} else {
target->output_charset = strdup(target->input_charset);
}
if (target->output_charset == NULL) {
iso_image_unref(src);
free(target);
return ISO_OUT_OF_MEM;
}
/*
* 2. Based on those options, create needed writers: iso, joliet...
* Each writer inits its structures and stores needed info into
* target.
* If the writer needs an volume descriptor, it increments image
* current block.
* Finally, create Writer for files.
*/
target->curblock = target->ms_block + 16;
/* the number of writers is dependent of the extensions */
nwriters = 1 + 1 + 1; /* ECMA-119 + padding + files */
if (target->eltorito) {
nwriters++;
}
if (target->joliet) {
nwriters++;
}
if (target->iso1999) {
nwriters++;
}
target->writers = malloc(nwriters * sizeof(void*));
if (target->writers == NULL) {
iso_image_unref(src);
free(target);
return ISO_OUT_OF_MEM;
}
/* create writer for ECMA-119 structure */
ret = ecma119_writer_create(target);
if (ret < 0) {
goto target_cleanup;
}
/* create writer for El-Torito */
if (target->eltorito) {
ret = eltorito_writer_create(target);
if (ret < 0) {
goto target_cleanup;
}
}
/* create writer for Joliet structure */
if (target->joliet) {
ret = joliet_writer_create(target);
if (ret < 0) {
goto target_cleanup;
}
}
/* create writer for ISO 9660:1999 structure */
if (target->iso1999) {
ret = iso1999_writer_create(target);
if (ret < 0) {
goto target_cleanup;
}
}
voldesc_size = target->curblock - target->ms_block - 16;
/* Volume Descriptor Set Terminator */
target->curblock++;
/*
* Create the writer for possible padding to ensure that in case of image
* growing we can safety overwrite the first 64 KiB of image.
*/
ret = pad_writer_create(target);
if (ret < 0) {
goto target_cleanup;
}
/* create writer for file contents */
ret = iso_file_src_writer_create(target);
if (ret < 0) {
goto target_cleanup;
}
/*
* 3.
* Call compute_data_blocks() in each Writer.
* That function computes the size needed by its structures and
* increments image current block propertly.
*/
for (i = 0; i < target->nwriters; ++i) {
IsoImageWriter *writer = target->writers[i];
ret = writer->compute_data_blocks(writer);
if (ret < 0) {
goto target_cleanup;
}
}
/* create the ring buffer */
ret = iso_ring_buffer_new(opts->fifo_size, &target->buffer);
if (ret < 0) {
goto target_cleanup;
}
/* check if we need to provide a copy of volume descriptors */
if (opts->overwrite) {
/*
* Get a copy of the volume descriptors to be written in a DVD+RW
* disc
*/
uint8_t *buf;
struct ecma119_vol_desc_terminator *vol;
IsoImageWriter *writer;
/*
* In the PVM to be written in the 16th sector of the disc, we
* need to specify the full size.
*/
target->vol_space_size = target->curblock;
/* write volume descriptor */
for (i = 0; i < target->nwriters; ++i) {
writer = target->writers[i];
ret = writer->write_vol_desc(writer);
if (ret < 0) {
iso_msg_debug(target->image->id,
"Error writing overwrite volume descriptors");
goto target_cleanup;
}
}
/* skip the first 16 blocks (system area) */
buf = opts->overwrite + 16 * BLOCK_SIZE;
voldesc_size *= BLOCK_SIZE;
/* copy the volume descriptors to the overwrite buffer... */
ret = iso_ring_buffer_read(target->buffer, buf, voldesc_size);
if (ret < 0) {
iso_msg_debug(target->image->id,
"Error reading overwrite volume descriptors");
goto target_cleanup;
}
/* ...including the vol desc terminator */
memset(buf + voldesc_size, 0, BLOCK_SIZE);
vol = (struct ecma119_vol_desc_terminator*) (buf + voldesc_size);
vol->vol_desc_type[0] = 255;
memcpy(vol->std_identifier, "CD001", 5);
vol->vol_desc_version[0] = 1;
}
/*
* The volume space size is just the size of the last session, in
* case of ms images.
*/
target->vol_space_size = target->curblock - target->ms_block;
target->total_size = (off_t) target->vol_space_size * BLOCK_SIZE;
/* 4. Create and start writting thread */
/* ensure the thread is created joinable */
pthread_attr_init(&(target->th_attr));
pthread_attr_setdetachstate(&(target->th_attr), PTHREAD_CREATE_JOINABLE);
ret = pthread_create(&(target->wthread), &(target->th_attr),
write_function, (void *) target);
if (ret != 0) {
iso_msg_submit(target->image->id, ISO_THREAD_ERROR, 0,
"Cannot create writer thread");
ret = ISO_THREAD_ERROR;
goto target_cleanup;
}
/*
* Notice that once we reach this point, target belongs to the writer
* thread and should not be modified until the writer thread finished.
* There're however, specific fields in target that can be accessed, or
* even modified by the read thread (look inside bs_* functions)
*/
*img = target;
return ISO_SUCCESS;
target_cleanup: ;
ecma119_image_free(target);
return ret;
}
static int bs_read(struct burn_source *bs, unsigned char *buf, int size)
{
int ret;
Ecma119Image *t = (Ecma119Image*)bs->data;
ret = iso_ring_buffer_read(t->buffer, buf, size);
if (ret == ISO_SUCCESS) {
return size;
} else if (ret < 0) {
/* error */
iso_msg_submit(t->image->id, ISO_BUF_READ_ERROR, ret, NULL);
return -1;
} else {
/* EOF */
return 0;
}
}
static off_t bs_get_size(struct burn_source *bs)
{
Ecma119Image *target = (Ecma119Image*)bs->data;
return target->total_size;
}
static void bs_free_data(struct burn_source *bs)
{
int st;
Ecma119Image *target = (Ecma119Image*)bs->data;
st = iso_ring_buffer_get_status(bs, NULL, NULL);
/* was read already finished (i.e, canceled)? */
if (st < 4) {
/* forces writer to stop if it is still running */
iso_ring_buffer_reader_close(target->buffer, 0);
/* wait until writer thread finishes */
pthread_join(target->wthread, NULL);
iso_msg_debug(target->image->id, "Writer thread joined");
}
iso_msg_debug(target->image->id,
"Ring buffer was %d times full and %d times empty",
iso_ring_buffer_get_times_full(target->buffer),
iso_ring_buffer_get_times_empty(target->buffer));
/* now we can safety free target */
ecma119_image_free(target);
}
static
int bs_cancel(struct burn_source *bs)
{
int st;
size_t cap, free;
Ecma119Image *target = (Ecma119Image*)bs->data;
st = iso_ring_buffer_get_status(bs, &cap, &free);
if (free == cap && (st == 2 || st == 3)) {
/* image was already consumed */
iso_ring_buffer_reader_close(target->buffer, 0);
} else {
iso_msg_debug(target->image->id, "Reader thread being cancelled");
/* forces writer to stop if it is still running */
iso_ring_buffer_reader_close(target->buffer, ISO_CANCELED);
}
/* wait until writer thread finishes */
pthread_join(target->wthread, NULL);
iso_msg_debug(target->image->id, "Writer thread joined");
return ISO_SUCCESS;
}
static
int bs_set_size(struct burn_source *bs, off_t size)
{
Ecma119Image *target = (Ecma119Image*)bs->data;
/*
* just set the value to be returned by get_size. This is not used at
* all by libisofs, it is here just for helping libburn to correctly pad
* the image if needed.
*/
target->total_size = size;
return 1;
}
int iso_image_create_burn_source(IsoImage *image, IsoWriteOpts *opts,
struct burn_source **burn_src)
{
int ret;
struct burn_source *source;
Ecma119Image *target= NULL;
if (image == NULL || opts == NULL || burn_src == NULL) {
return ISO_NULL_POINTER;
}
source = calloc(1, sizeof(struct burn_source));
if (source == NULL) {
return ISO_OUT_OF_MEM;
}
ret = ecma119_image_new(image, opts, &target);
if (ret < 0) {
free(source);
return ret;
}
source->refcount = 1;
source->version = 1;
source->read = NULL;
source->get_size = bs_get_size;
source->set_size = bs_set_size;
source->free_data = bs_free_data;
source->read_xt = bs_read;
source->cancel = bs_cancel;
source->data = target;
*burn_src = source;
return ISO_SUCCESS;
}
int iso_write(Ecma119Image *target, void *buf, size_t count)
{
int ret;
ret = iso_ring_buffer_write(target->buffer, buf, count);
if (ret == 0) {
/* reader cancelled */
return ISO_CANCELED;
}
/* total size is 0 when writing the overwrite buffer */
if (ret > 0 && (target->total_size != (off_t) 0)){
unsigned int kbw, kbt;
int percent;
target->bytes_written += (off_t) count;
kbw = (unsigned int) (target->bytes_written >> 10);
kbt = (unsigned int) (target->total_size >> 10);
percent = (kbw * 100) / kbt;
/* only report in 5% chunks */
if (percent >= target->percent_written + 5) {
iso_msg_debug(target->image->id, "Processed %u of %u KB (%d %%)",
kbw, kbt, percent);
target->percent_written = percent;
}
}
return ret;
}
int iso_write_opts_new(IsoWriteOpts **opts, int profile)
{
IsoWriteOpts *wopts;
if (opts == NULL) {
return ISO_NULL_POINTER;
}
if (profile < 0 || profile > 2) {
return ISO_WRONG_ARG_VALUE;
}
wopts = calloc(1, sizeof(IsoWriteOpts));
if (wopts == NULL) {
return ISO_OUT_OF_MEM;
}
switch (profile) {
case 0:
wopts->level = 1;
break;
case 1:
wopts->level = 2;
wopts->rockridge = 1;
break;
case 2:
wopts->level = 2;
wopts->rockridge = 1;
wopts->joliet = 1;
wopts->replace_dir_mode = 1;
wopts->replace_file_mode = 1;
wopts->replace_uid = 1;
wopts->replace_gid = 1;
wopts->replace_timestamps = 1;
wopts->always_gmt = 1;
break;
default:
/* should never happen */
free(wopts);
return ISO_ASSERT_FAILURE;
break;
}
wopts->fifo_size = 1024; /* 2 MB buffer */
wopts->sort_files = 1; /* file sorting is always good */
*opts = wopts;
return ISO_SUCCESS;
}
void iso_write_opts_free(IsoWriteOpts *opts)
{
if (opts == NULL) {
return;
}
free(opts->output_charset);
free(opts);
}
int iso_write_opts_set_iso_level(IsoWriteOpts *opts, int level)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
if (level != 1 && level != 2) {
return ISO_WRONG_ARG_VALUE;
}
opts->level = level;
return ISO_SUCCESS;
}
int iso_write_opts_set_rockridge(IsoWriteOpts *opts, int enable)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->rockridge = enable ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_joliet(IsoWriteOpts *opts, int enable)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->joliet = enable ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_iso1999(IsoWriteOpts *opts, int enable)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->iso1999 = enable ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_omit_version_numbers(IsoWriteOpts *opts, int omit)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->omit_version_numbers = omit ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_allow_deep_paths(IsoWriteOpts *opts, int allow)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->allow_deep_paths = allow ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_allow_longer_paths(IsoWriteOpts *opts, int allow)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->allow_longer_paths = allow ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_max_37_char_filenames(IsoWriteOpts *opts, int allow)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->max_37_char_filenames = allow ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_no_force_dots(IsoWriteOpts *opts, int no)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->no_force_dots = no ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_allow_lowercase(IsoWriteOpts *opts, int allow)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->allow_lowercase = allow ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_allow_full_ascii(IsoWriteOpts *opts, int allow)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->allow_full_ascii = allow ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_relaxed_vol_atts(IsoWriteOpts *opts, int allow)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->relaxed_vol_atts = allow ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_joliet_longer_paths(IsoWriteOpts *opts, int allow)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->joliet_longer_paths = allow ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_sort_files(IsoWriteOpts *opts, int sort)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->sort_files = sort ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_replace_mode(IsoWriteOpts *opts, int dir_mode,
int file_mode, int uid, int gid)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
if (dir_mode < 0 || dir_mode > 2) {
return ISO_WRONG_ARG_VALUE;
}
if (file_mode < 0 || file_mode > 2) {
return ISO_WRONG_ARG_VALUE;
}
if (uid < 0 || uid > 2) {
return ISO_WRONG_ARG_VALUE;
}
if (gid < 0 || gid > 2) {
return ISO_WRONG_ARG_VALUE;
}
opts->replace_dir_mode = dir_mode;
opts->replace_file_mode = file_mode;
opts->replace_uid = uid;
opts->replace_gid = gid;
return ISO_SUCCESS;
}
int iso_write_opts_set_default_dir_mode(IsoWriteOpts *opts, mode_t dir_mode)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->dir_mode = dir_mode;
return ISO_SUCCESS;
}
int iso_write_opts_set_default_file_mode(IsoWriteOpts *opts, mode_t file_mode)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->file_mode = file_mode;
return ISO_SUCCESS;
}
int iso_write_opts_set_default_uid(IsoWriteOpts *opts, uid_t uid)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->uid = uid;
return ISO_SUCCESS;
}
int iso_write_opts_set_default_gid(IsoWriteOpts *opts, gid_t gid)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->gid = gid;
return ISO_SUCCESS;
}
int iso_write_opts_set_replace_timestamps(IsoWriteOpts *opts, int replace)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
if (replace < 0 || replace > 2) {
return ISO_WRONG_ARG_VALUE;
}
opts->replace_timestamps = replace;
return ISO_SUCCESS;
}
int iso_write_opts_set_default_timestamp(IsoWriteOpts *opts, time_t timestamp)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->timestamp = timestamp;
return ISO_SUCCESS;
}
int iso_write_opts_set_always_gmt(IsoWriteOpts *opts, int gmt)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->always_gmt = gmt ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_output_charset(IsoWriteOpts *opts, const char *charset)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->output_charset = charset ? strdup(charset) : NULL;
return ISO_SUCCESS;
}
int iso_write_opts_set_appendable(IsoWriteOpts *opts, int appendable)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->appendable = appendable ? 1 : 0;
return ISO_SUCCESS;
}
int iso_write_opts_set_ms_block(IsoWriteOpts *opts, uint32_t ms_block)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->ms_block = ms_block;
return ISO_SUCCESS;
}
int iso_write_opts_set_overwrite_buf(IsoWriteOpts *opts, uint8_t *overwrite)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
opts->overwrite = overwrite;
return ISO_SUCCESS;
}
int iso_write_opts_set_fifo_size(IsoWriteOpts *opts, size_t fifo_size)
{
if (opts == NULL) {
return ISO_NULL_POINTER;
}
if (fifo_size < 32) {
return ISO_WRONG_ARG_VALUE;
}
opts->fifo_size = fifo_size;
return ISO_SUCCESS;
}