Remove obsolete files

This commit is contained in:
Mario Danic 2006-08-24 19:28:58 +00:00
parent e943c8c648
commit ca771aae2e
8 changed files with 0 additions and 2797 deletions

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/* -*- indent-tabs-mode: t; tab-width: 8; c-basic-offset: 8; -*- */
#include "errors.h"
#include <stdio.h>
void iso_warn(enum iso_warnings w)
{
printf("WARNING: %u\n", w);
}
void iso_error(enum iso_errors e)
{
printf("ERROR: %u\n", e);
}

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/* -*- indent-tabs-mode: t; tab-width: 8; c-basic-offset: 8; -*- */
#ifndef __ERRORS
#define __ERRORS
enum iso_warnings
{
ISO_WARNING_FOO
};
enum iso_errors
{
ISO_ERROR_FOO
};
void iso_warn(enum iso_warnings w);
void iso_error(enum iso_errors e);
#endif /* __ERRORS */

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/* -*- indent-tabs-mode: t; tab-width: 8; c-basic-offset: 8; -*- */
#ifndef LIBBURN_H
#define LIBBURN_H
/* Needed for off_t which is the (POSIX-ly) appropriate type for
expressing a file or stream size.
XXX we should enforce 64-bitness for off_t
*/
#include <sys/types.h>
#ifndef DOXYGEN
#if defined(__cplusplus)
#define BURN_BEGIN_DECLS \
namespace burn { \
extern "C" {
#define BURN_END_DECLS \
} \
}
#else
#define BURN_BEGIN_DECLS
#define BURN_END_DECLS
#endif
BURN_BEGIN_DECLS
#endif
/** References a physical drive in the system */
struct burn_drive;
/** References a whole disc */
struct burn_disc;
/** References a single session on a disc */
struct burn_session;
/** References a single track on a disc */
struct burn_track;
/** Session format for normal audio or data discs */
#define BURN_CDROM 0
/** Session format for obsolete CD-I discs */
#define BURN_CDI 0x10
/** Session format for CDROM-XA discs */
#define BURN_CDXA 0x20
#define BURN_POS_END 100
/** Mask for mode bits */
#define BURN_MODE_BITS 127
/** Track mode - mode 0 data
0 bytes of user data. it's all 0s. mode 0. get it? HAH
*/
#define BURN_MODE0 (1 << 0)
/** Track mode - mode "raw" - all 2352 bytes supplied by app
FOR DATA TRACKS ONLY!
*/
#define BURN_MODE_RAW (1 << 1)
/** Track mode - mode 1 data
2048 bytes user data, and all the LEC money can buy
*/
#define BURN_MODE1 (1 << 2)
/** Track mode - mode 2 data
defaults to formless, 2336 bytes of user data, unprotected
| with a data form if required.
*/
#define BURN_MODE2 (1 << 3)
/** Track mode modifier - Form 1, | with MODE2 for reasonable results
2048 bytes of user data, 4 bytes of subheader
*/
#define BURN_FORM1 (1 << 4)
/** Track mode modifier - Form 2, | with MODE2 for reasonable results
lots of user data. not much LEC.
*/
#define BURN_FORM2 (1 << 5)
/** Track mode - audio
2352 bytes per sector. may be | with 4ch or preemphasis.
NOT TO BE CONFUSED WITH BURN_MODE_RAW
*/
#define BURN_AUDIO (1 << 6)
/** Track mode modifier - 4 channel audio. */
#define BURN_4CH (1 << 7)
/** Track mode modifier - Digital copy permitted, can be set on any track.*/
#define BURN_COPY (1 << 8)
/** Track mode modifier - 50/15uS pre-emphasis */
#define BURN_PREEMPHASIS (1 << 9)
/** Input mode modifier - subcodes present packed 16 */
#define BURN_SUBCODE_P16 (1 << 10)
/** Input mode modifier - subcodes present packed 96 */
#define BURN_SUBCODE_P96 (1 << 11)
/** Input mode modifier - subcodes present raw 96 */
#define BURN_SUBCODE_R96 (1 << 12)
/** Possible disc writing style/modes */
enum burn_write_types
{
/** Packet writing.
currently unsupported
*/
BURN_WRITE_PACKET,
/** Track At Once recording.
2s gaps between tracks, no fonky lead-ins
*/
BURN_WRITE_TAO,
/** Session At Once.
block type MUST be BURN_BLOCK_SAO
*/
BURN_WRITE_SAO,
/** Raw disc at once recording.
all subcodes must be provided by lib or user
only raw block types are supported
*/
BURN_WRITE_RAW
};
/** Data format to send to the drive */
enum burn_block_types
{
/** sync, headers, edc/ecc provided by lib/user */
BURN_BLOCK_RAW0 = 1,
/** sync, headers, edc/ecc and p/q subs provided by lib/user */
BURN_BLOCK_RAW16 = 2,
/** sync, headers, edc/ecc and packed p-w subs provided by lib/user */
BURN_BLOCK_RAW96P = 4,
/** sync, headers, edc/ecc and raw p-w subs provided by lib/user */
BURN_BLOCK_RAW96R = 8,
/** only 2048 bytes of user data provided by lib/user */
BURN_BLOCK_MODE1 = 256,
/** 2336 bytes of user data provided by lib/user */
BURN_BLOCK_MODE2R = 512,
/** 2048 bytes of user data provided by lib/user
subheader provided in write parameters
are we ever going to support this shit? I vote no.
(supposed to be supported on all drives...)
*/
BURN_BLOCK_MODE2_PATHETIC = 1024,
/** 2048 bytes of data + 8 byte subheader provided by lib/user
hey, this is also dumb
*/
BURN_BLOCK_MODE2_LAME = 2048,
/** 2324 bytes of data provided by lib/user
subheader provided in write parameters
no sir, I don't like it.
*/
BURN_BLOCK_MODE2_OBSCURE = 4096,
/** 2332 bytes of data supplied by lib/user
8 bytes sub header provided in write parameters
this is the second least suck mode2, and is mandatory for
all drives to support.
*/
BURN_BLOCK_MODE2_OK = 8192,
/** SAO block sizes are based on cue sheet, so use this. */
BURN_BLOCK_SAO = 16384
};
/** Possible status' of the drive in regard to the disc in it. */
enum burn_disc_status
{
/** The current status is not yet known */
BURN_DISC_UNREADY,
/** The drive holds a blank disc */
BURN_DISC_BLANK,
/** There is no disc at all in the drive */
BURN_DISC_EMPTY,
/** There is an incomplete disc in the drive */
BURN_DISC_APPENDABLE,
/** There is a disc with data on it in the drive */
BURN_DISC_FULL
};
/** Possible types of messages form the library. */
enum burn_message_type
{
/** Diagnostic/Process information. For the curious user. */
BURN_MESSAGE_INFO,
/** A warning regarding a possible problem. The user should probably
be notified, but its not fatal. */
BURN_MESSAGE_WARNING,
/** An error message. This usually means the current process will be
aborted, and the user should definately see these. */
BURN_MESSAGE_ERROR
};
/** Possible information messages */
enum burn_message_info
{
BURN_INFO_FOO
};
/** Possible warning messages */
enum burn_message_warning
{
BURN_WARNING_FOO
};
/** Possible error messages */
enum burn_message_error
{
BURN_ERROR_CANCELLED
};
/** Possible data source return values */
enum burn_source_status
{
/** The source is ok */
BURN_SOURCE_OK,
/** The source is at end of file */
BURN_SOURCE_EOF,
/** The source is unusable */
BURN_SOURCE_FAILED
};
/** Possible busy states for a drive */
enum burn_drive_status
{
/** The drive is not in an operation */
BURN_DRIVE_IDLE,
/** The library is spawning the processes to handle a pending
operation (A read/write/etc is about to start but hasn't quite
yet) */
BURN_DRIVE_SPAWNING,
/** The drive is reading data from a disc */
BURN_DRIVE_READING,
/** The drive is writing data to a disc */
BURN_DRIVE_WRITING,
/** The drive is writing Lead-In */
BURN_DRIVE_WRITING_LEADIN,
/** The drive is writing Lead-Out */
BURN_DRIVE_WRITING_LEADOUT,
/** The drive is erasing a disc */
BURN_DRIVE_ERASING,
/** The drive is being grabbed */
BURN_DRIVE_GRABBING
};
/** Information about a track on a disc - this is from the q sub channel of the
lead-in area of a disc. The documentation here is very terse.
See a document such as mmc3 for proper information.
*/
struct burn_toc_entry
{
/** Session the track is in */
unsigned char session;
/** Type of data. for this struct to be valid, it must be 1 */
unsigned char adr;
/** Type of data in the track */
unsigned char control;
/** Zero. Always. Really. */
unsigned char tno;
/** Track number or special information */
unsigned char point;
unsigned char min;
unsigned char sec;
unsigned char frame;
unsigned char zero;
/** Track start time minutes for normal tracks */
unsigned char pmin;
/** Track start time seconds for normal tracks */
unsigned char psec;
/** Track start time frames for normal tracks */
unsigned char pframe;
};
/** Data source for tracks */
struct burn_source {
/** Reference count for the data source. Should be 1 when a new source
is created. Increment it to take a reference for yourself. Use
burn_source_free to destroy your reference to it. */
int refcount;
/** Read data from the source */
int (*read)(struct burn_source *,
unsigned char *buffer,
int size);
/** Read subchannel data from the source (NULL if lib generated) */
int (*read_sub)(struct burn_source *,
unsigned char *buffer,
int size);
/** Get the size of the source's data */
off_t (*get_size)(struct burn_source *);
/** Clean up the source specific data */
void (*free_data)(struct burn_source *);
/** Next source, for when a source runs dry and padding is disabled
THIS IS AUTOMATICALLY HANDLED, DO NOT TOUCH
*/
struct burn_source *next;
/** Source specific data */
void *data;
};
/** Information on a drive in the system */
struct burn_drive_info
{
/** Name of the vendor of the drive */
char vendor[9];
/** Name of the drive */
char product[17];
/** Revision of the drive */
char revision[5];
/** Location of the drive in the filesystem. */
char location[17];
/** Can the drive read DVD-RAM discs */
unsigned int read_dvdram:1;
/** Can the drive read DVD-R discs */
unsigned int read_dvdr:1;
/** Can the drive read DVD-ROM discs */
unsigned int read_dvdrom:1;
/** Can the drive read CD-R discs */
unsigned int read_cdr:1;
/** Can the drive read CD-RW discs */
unsigned int read_cdrw:1;
/** Can the drive write DVD-RAM discs */
unsigned int write_dvdram:1;
/** Can the drive write DVD-R discs */
unsigned int write_dvdr:1;
/** Can the drive write CD-R discs */
unsigned int write_cdr:1;
/** Can the drive write CD-RW discs */
unsigned int write_cdrw:1;
/** Can the drive simulate a write */
unsigned int write_simulate:1;
/** Can the drive report C2 errors */
unsigned int c2_errors:1;
/** The size of the drive's buffer (in kilobytes) */
int buffer_size;
/**
* The supported block types in tao mode.
* They should be tested with the desired block type.
* See also burn_block_types.
*/
int tao_block_types;
/**
* The supported block types in sao mode.
* They should be tested with the desired block type.
* See also burn_block_types.
*/
int sao_block_types;
/**
* The supported block types in raw mode.
* They should be tested with the desired block type.
* See also burn_block_types.
*/
int raw_block_types;
/**
* The supported block types in packet mode.
* They should be tested with the desired block type.
* See also burn_block_types.
*/
int packet_block_types;
/** The value by which this drive can be indexed when using functions
in the library. This is the value to pass to all libbburn functions
that operate on a drive. */
struct burn_drive *drive;
};
/** Messages from the library */
struct burn_message
{
/** The drive associated with the message. NULL if the error is not
related to a specific drive. */
struct burn_drive *drive;
/** The type of message this is. See message_type for details. */
enum burn_message_type type;
/** The actual message */
union detail {
struct {
enum burn_message_info message;
} info;
struct {
enum burn_message_warning message;
} warning;
struct {
enum burn_message_error message;
} error;
} detail;
};
/** Operation progress report. All values are 0 based indices.
* */
struct burn_progress {
/** The total number of sessions */
int sessions;
/** Current session.*/
int session;
/** The total number of tracks */
int tracks;
/** Current track. */
int track;
/** The total number of indices */
int indices;
/** Curent index. */
int index;
/** The starting logical block address */
int start_sector;
/** The number of sector */
int sectors;
/** The current sector being processed */
int sector;
};
/** Initialize the library.
This must be called before using any other functions in the library. It
may be called more than once with no effect.
If is possible to 'restart' the library by shutting it down and
re-initializing it, though there is no good reason to do that.
@return Nonzero if the library was able to initialize; zero if
initialization failed.
*/
int burn_initialize(void);
/** Shutdown the library.
This should be called before exiting your application. Make sure that all
drives you have grabbed are released <i>before</i> calling this.
*/
void burn_finish(void);
/** Set the verbosity level of the library. The default value is 0, which means
that nothing is output on stderr. The more you increase this, the more
debug output should be displayed on stderr for you.
@param level The verbosity level desired. 0 for nothing, higher positive
values for more information output.
*/
void burn_set_verbosity(int level);
/** Returns a newly allocated burn_message structure. This message should be
freed with burn_message_free() when you are finished with it.
@return A message or NULL when there are no more messages to retrieve.
*/
struct burn_message* burn_get_message(void);
/** Frees a burn_message structure */
void burn_message_free(struct burn_message *msg);
/** Scans for drives. This function MUST be called until it returns nonzero.
No drives can be in use when this is called or it will assert.
All drive pointers are invalidated by using this function. Do NOT store
drive pointers across calls to this function or death AND pain will ensue.
When the app is done with the burn_drive_info array, it must be freed with
burn_drive_info_free()
@param drives Returns an array of drives (cdroms/burners). The returned
array should be freed when it is no longer needed, and
before calling this function again to rescan.
@param n_drives Returns the number of hardware drives in @c drives.
@return Zero while scanning is not complete; non-zero when it is finished.
*/
int burn_drive_scan(struct burn_drive_info *drives[],
unsigned int *n_drives);
/** Frees a burn_drive_info array returned by burn_drive_scan
@param info The array to free
*/
void burn_drive_info_free(struct burn_drive_info *info);
/** Grab a drive. This must be done before the drive can be used (for reading,
writing, etc). It may be neccesary to call this function more than once
to grab a drive. See burn_grab for details.
@param drive The drive to grab. This is found in a returned
burn_drive_info struct.
@param load Nonzero to make the drive attempt to load a disc (close its
tray door, etc).
@return 1 if the drive has been grabbed, else 0
*/
int burn_drive_grab(struct burn_drive *drive, int load);
/** Release a drive. This should not be done until the drive is no longer
busy (see burn_drive_get_status).
@param drive The drive to release.
@param eject Nonzero to make the drive eject the disc in it.
*/
void burn_drive_release(struct burn_drive *drive, int eject);
/** Returns what kind of disc a drive is holding. This function may need to be
called more than once to get a proper status from it. See burn_status
for details.
@param drive The drive to query for a disc.
@return The status of the drive, or what kind of disc is in it.
*/
enum burn_disc_status burn_disc_get_status(struct burn_drive *drive);
/** Tells whether a disc can be erased or not
@return Non-zero means erasable
*/
int burn_disc_erasable(struct burn_drive *d);
/** Returns the progress and status of a drive.
@param drive The drive to query busy state for.
@param p Returns the progress of the operation, NULL if you don't care
@return the current status of the drive. See also burn_drive_status.
*/
enum burn_drive_status burn_drive_get_status(struct burn_drive *drive,
struct burn_progress *p);
/** Creates a write_opts struct for burning to the specified drive
must be freed with burn_write_opts_free
@param drive The drive to write with
@return The write_opts
*/
struct burn_write_opts *burn_write_opts_new(struct burn_drive *drive);
/** Frees a write_opts struct created with burn_write_opts_new
@param opts write_opts to free
*/
void burn_write_opts_free(struct burn_write_opts *opts);
/** Creates a write_opts struct for reading from the specified drive
must be freed with burn_write_opts_free
@param drive The drive to read from
@return The read_opts
*/
struct burn_read_opts *burn_read_opts_new(struct burn_drive *drive);
/** Frees a read_opts struct created with burn_read_opts_new
@param opts write_opts to free
*/
void burn_read_opts_free(struct burn_read_opts *opts);
/** Erase a disc in the drive. The drive must be grabbed successfully BEFORE
calling this functions. Always ensure that the drive reports a status of
BURN_DISC_FULL before calling this function. An erase operation is not
cancellable, as control of the operation is passed wholly to the drive and
there is no way to interrupt it safely.
@param drive The drive with which to erase a disc.
@param fast Nonzero to do a fast erase, where only the disc's headers are
erased; zero to erase the entire disc.
*/
void burn_disc_erase(struct burn_drive *drive, int fast);
/** Read a disc from the drive and write it to an fd pair. The drive must be
grabbed successfully BEFORE calling this function. Always ensure that the
drive reports a status of BURN_DISC_FULL before calling this function.
@param drive The drive from which to read a disc.
@param o The options for the read operation.
*/
void burn_disc_read(struct burn_drive *drive, const struct burn_read_opts *o);
/** Write a disc in the drive. The drive must be grabbed successfully BEFORE
calling this function. Always ensure that the drive reports a status of
BURN_DISC_BLANK or BURN_STATUS_FULL (to append a new session to the
disc) before calling this function.
@param o The options for the writing operation.
@param disc The struct burn_disc * that described the disc to be created
*/
void burn_disc_write(struct burn_write_opts *o, struct burn_disc *disc);
/** Cancel an operation on a drive.
This will only work when the drive's busy state is BURN_DRIVE_READING or
BURN_DRIVE_WRITING.
@param drive The drive on which to cancel the current operation.
*/
void burn_drive_cancel(struct burn_drive *drive);
/** Convert a minute-second-frame (MSF) value to sector count
@param m Minute component
@param s Second component
@param f Frame component
@return The sector count
*/
int burn_msf_to_sectors(int m, int s, int f);
/** Convert a sector count to minute-second-frame (MSF)
@param sectors The sector count
@param m Returns the minute component
@param s Returns the second component
@param f Returns the frame component
*/
void burn_sectors_to_msf(int sectors, int *m, int *s, int *f);
/** Convert a minute-second-frame (MSF) value to an lba
@param m Minute component
@param s Second component
@param f Frame component
@return The lba
*/
int burn_msf_to_lba(int m, int s, int f);
/** Convert an lba to minute-second-frame (MSF)
@param lba The lba
@param m Returns the minute component
@param s Returns the second component
@param f Returns the frame component
*/
void burn_lba_to_msf(int lba, int *m, int *s, int *f);
/** Create a new disc (for DAO recording)*/
struct burn_disc *burn_disc_create(void);
/** Delete disc and decrease the reference count on all its sessions
@param d The disc to be freed
*/
void burn_disc_free(struct burn_disc *d);
/** Create a new session (For SAO at once recording, or to be added to a
disc for DAO)
*/
struct burn_session *burn_session_create(void);
/** Free a session (and decrease reference count on all tracks inside)
@param s Session to be freed
*/
void burn_session_free(struct burn_session *s);
/** Add a session to a disc at a specific position, increasing the
sessions's reference count.
@param d Disc to add the session to
@param s Session to add to the disc
@param pos position to add at (BURN_POS_END is "at the end")
@return 0 for failure, 1 for success
*/
int burn_disc_add_session(struct burn_disc *d, struct burn_session *s,
unsigned int pos);
/** Remove a session from a disc
@param d Disc to remove session from
@param s Session pointer to find and remove
*/
int burn_disc_remove_session(struct burn_disc *d, struct burn_session *s);
/** Create a track (for TAO recording, or to put in a session) */
struct burn_track *burn_track_create(void);
/** Free a track
@param t Track to free
*/
void burn_track_free(struct burn_track *t);
/** Add a track to a session at specified position
@param s Session to add to
@param t Track to insert in session
@param pos position to add at (BURN_POS_END is "at the end")
@return 0 for failure, 1 for success
*/
int burn_session_add_track(struct burn_session *s, struct burn_track *t,
unsigned int pos);
/** Remove a track from a session
@param s Session to remove track from
@param t Track pointer to find and remove
@return 0 for failure, 1 for success
*/
int burn_session_remove_track(struct burn_session *s, struct burn_track *t);
/** Define the data in a track
@param t the track to define
@param offset The lib will write this many 0s before start of data
@param tail The number of extra 0s to write after data
@param pad 1 means the lib should pad the last sector with 0s if the
track isn't exactly sector sized. (otherwise the lib will
begin reading from the next track)
@param mode data format (bitfield)
*/
void burn_track_define_data(struct burn_track *t, int offset, int tail,
int pad, int mode);
/** Set the ISRC details for a track
@param t The track to change
@param country the 2 char country code. Each character must be
only numbers or letters.
@param owner 3 char owner code. Each character must be only numbers
or letters.
@param year 2 digit year. A number in 0-99 (Yep, not Y2K friendly).
@param serial 5 digit serial number. A number in 0-99999.
*/
void burn_track_set_isrc(struct burn_track *t, char *country, char *owner,
unsigned char year, unsigned int serial);
/** Disable ISRC parameters for a track
@param t The track to change
*/
void burn_track_clear_isrc(struct burn_track *t);
/** Hide the first track in the "pre gap" of the disc
@param s session to change
@param onoff 1 to enable hiding, 0 to disable
*/
void burn_session_hide_first_track(struct burn_session *s, int onoff);
/** Get the drive's disc struct - free when done
@param d drive to query
@return the disc struct
*/
struct burn_disc *burn_drive_get_disc(struct burn_drive *d);
/** Set the track's data source
@param t The track to set the data source for
@param s The data source to use for the contents of the track
@return An error code stating if the source is ready for use for
writing the track, or if an error occured
*/
enum burn_source_status burn_track_set_source(struct burn_track *t,
struct burn_source *s);
/** Free a burn_source (decrease its refcount and maybe free it)
@param s Source to free
*/
void burn_source_free(struct burn_source *s);
/** Creates a data source for an image file (and maybe subcode file) */
struct burn_source *burn_file_source_new(const char *path,
const char *subpath);
/** Creates a data source for an image file (resp. a track) from an open
readable filedescriptor, an eventually open readable subcodes file
descriptor and eventually a fixed size in bytes.
@param datafd The source of data.
@param subfd The eventual source for subcodes. Not used if -1.
@param size The eventual fixed size of eventually both fds.
If this value is 0, the size will be determined from datafd.
*/
struct burn_source *burn_fd_source_new(int datafd, int subfd, off_t size);
/** Tells how long a track will be on disc */
int burn_track_get_sectors(struct burn_track *);
/** Sets drive read and write speed
@param d The drive to set speed for
@param read Read speed in k/s (0 is max)
@param write Write speed in k/s (0 is max)
*/
void burn_drive_set_speed(struct burn_drive *d, int read, int write);
/* these are for my debugging, they will disappear */
void burn_structure_print_disc(struct burn_disc *d);
void burn_structure_print_session(struct burn_session *s);
void burn_structure_print_track(struct burn_track *t);
/** Sets the write type for the write_opts struct
@param opts The write opts to change
@param write_type The write type to use
@param block_type The block type to use
@return Returns 1 on success and 0 on failure.
*/
int burn_write_opts_set_write_type(struct burn_write_opts *opts,
enum burn_write_types write_type,
int block_type);
/** Supplies toc entries for writing - not normally required for cd mastering
@param opts The write opts to change
@param count The number of entries
@param toc_entries
*/
void burn_write_opts_set_toc_entries(struct burn_write_opts *opts,
int count,
struct burn_toc_entry *toc_entries);
/** Sets the session format for a disc
@param opts The write opts to change
@param format The session format to set
*/
void burn_write_opts_set_format(struct burn_write_opts *opts, int format);
/** Sets the simulate value for the write_opts struct
@param opts The write opts to change
@param sim If non-zero, the drive will perform a simulation instead of a burn
@return Returns 1 on success and 0 on failure.
*/
int burn_write_opts_set_simulate(struct burn_write_opts *opts, int sim);
/** Controls buffer underrun prevention
@param opts The write opts to change
@param underrun_proof if non-zero, buffer underrun protection is enabled
@return Returns 1 on success and 0 on failure.
*/
int burn_write_opts_set_underrun_proof(struct burn_write_opts *opts,
int underrun_proof);
/** Sets whether to use opc or not with the write_opts struct
@param opts The write opts to change
@param opc If non-zero, optical power calibration will be performed at
start of burn
*/
void burn_write_opts_set_perform_opc(struct burn_write_opts *opts, int opc);
void burn_write_opts_set_has_mediacatalog(struct burn_write_opts *opts, int has_mediacatalog);
void burn_write_opts_set_mediacatalog(struct burn_write_opts *opts, unsigned char mediacatalog[13]);
/** Sets whether to read in raw mode or not
@param opts The read opts to change
@param raw_mode If non-zero, reading will be done in raw mode, so that everything in the data tracks on the
disc is read, including headers.
*/
void burn_read_opts_set_raw(struct burn_read_opts *opts, int raw_mode);
/** Sets whether to report c2 errors or not
@param opts The read opts to change
@param c2errors If non-zero, report c2 errors.
*/
void burn_read_opts_set_c2errors(struct burn_read_opts *opts, int c2errors);
/** Sets whether to read subcodes from audio tracks or not
@param opts The read opts to change
@param subcodes_audio If non-zero, read subcodes from audio tracks on the disc.
*/
void burn_read_opts_read_subcodes_audio(struct burn_read_opts *opts,
int subcodes_audio);
/** Sets whether to read subcodes from data tracks or not
@param opts The read opts to change
@param subcodes_data If non-zero, read subcodes from data tracks on the disc.
*/
void burn_read_opts_read_subcodes_data(struct burn_read_opts *opts,
int subcodes_data);
/** Sets whether to recover errors if possible
@param opts The read opts to change
@param hardware_error_recovery If non-zero, attempt to recover errors if possible.
*/
void burn_read_opts_set_hardware_error_recovery(struct burn_read_opts *opts,
int hardware_error_recovery);
/** Sets whether to report recovered errors or not
@param opts The read opts to change
@param report_recovered_errors If non-zero, recovered errors will be reported.
*/
void burn_read_opts_report_recovered_errors(struct burn_read_opts *opts,
int report_recovered_errors);
/** Sets whether blocks with unrecoverable errors should be read or not
@param opts The read opts to change
@param transfer_damaged_blocks If non-zero, blocks with unrecoverable errors will still be read.
*/
void burn_read_opts_transfer_damaged_blocks(struct burn_read_opts *opts,
int transfer_damaged_blocks);
/** Sets the number of retries to attempt when trying to correct an error
@param opts The read opts to change
@param hardware_error_retries The number of retries to attempt when correcting an error.
*/
void burn_read_opts_set_hardware_error_retries(struct burn_read_opts *opts,
unsigned char hardware_error_retries);
/** Gets the maximum write speed for a drive
@param d Drive to query
@return Maximum write speed in K/s
*/
int burn_drive_get_write_speed(struct burn_drive *d);
/** Gets the maximum read speed for a drive
@param d Drive to query
@return Maximum read speed in K/s
*/
int burn_drive_get_read_speed(struct burn_drive *d);
/** Gets a copy of the toc_entry structure associated with a track
@param t Track to get the entry from
@param entry Struct for the library to fill out
*/
void burn_track_get_entry(struct burn_track *t, struct burn_toc_entry *entry);
/** Gets a copy of the toc_entry structure associated with a session's lead out
@param s Session to get the entry from
@param entry Struct for the library to fill out
*/
void burn_session_get_leadout_entry(struct burn_session *s,
struct burn_toc_entry *entry);
/** Gets an array of all the sessions for the disc
THIS IS NO LONGER VALID AFTER YOU ADD OR REMOVE A SESSION
@param d Disc to get session array for
@param num Returns the number of sessions in the array
@return array of sessions
*/
struct burn_session **burn_disc_get_sessions(struct burn_disc *d,
int *num);
int burn_disc_get_sectors(struct burn_disc *d);
/** Gets an array of all the tracks for a session
THIS IS NO LONGER VALID AFTER YOU ADD OR REMOVE A TRACK
@param s session to get track array for
@param num Returns the number of tracks in the array
@return array of tracks
*/
struct burn_track **burn_session_get_tracks(struct burn_session *s,
int *num);
int burn_session_get_sectors(struct burn_session *s);
/** Gets the mode of a track
@param track the track to query
@return the track's mode
*/
int burn_track_get_mode(struct burn_track *track);
/** Returns whether the first track of a session is hidden in the pregap
@param session the session to query
@return non-zero means the first track is hidden
*/
int burn_session_get_hidefirst(struct burn_session *session);
/** Returns the library's version in its parts
@param major The major version number
@param minor The minor version number
@param micro The micro version number
*/
void burn_version(int *major, int *minor, int *micro);
#ifndef DOXYGEN
BURN_END_DECLS
#endif
#endif /*LIBBURN_H*/

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@ -1,340 +0,0 @@
/* vim: set noet ts=8 sts=8 sw=8 : */
#include "struct.h"
#include "util.h"
#include <stdio.h>
#include <stdarg.h>
#include <ctype.h>
#include <stdlib.h>
#include <string.h>
struct struct_element {
uint8_t ch;
int bytes; /* The number of bytes in the value to convert
* from/to. */
uint8_t end; /* The endianness specifier. */
int mul; /* The number of values to convert. */
union { /* Pointer to the value. */
uint8_t *val8;
uint16_t *val16;
uint32_t *val32;
time_t *time;
} val;
};
/* check if a character is a valid endian-ness specifier */
#define isend(a) ((a) == '=' || (a) == '<' || (a) == '>')
static int iso_struct_element_make(struct struct_element *elem,
int mul,
char end,
char ch)
{
if (!end) {
#ifdef WORDS_BIGENDIAN
elem->end = '>'; /* default endianness is native */
#else
elem->end = '<';
#endif
} else {
elem->end = end;
}
elem->ch = ch;
elem->mul = mul;
elem->val.val8 = NULL;
switch(toupper(ch)) {
case 'X':
case 'B':
elem->bytes = 1;
break;
case 'H':
elem->bytes = 2;
break;
case 'L':
elem->bytes = 4;
break;
case 'S':
elem->bytes = 7;
elem->end = '<';
break;
case 'T':
elem->bytes = 17;
elem->end = '<';
break;
default:
elem->bytes = -1;
break;
}
return elem->bytes * elem->mul * ((elem->end == '=') ? 2 : 1);
}
static int iso_struct_element_make_v(struct struct_element *elem,
va_list *ap)
{
int mul = va_arg(*ap, int);
int end = va_arg(*ap, int);
int ch = va_arg(*ap, int);
return iso_struct_element_make(elem, mul, end, ch);
}
static int iso_struct_element_parse(const char **ffmt,
struct struct_element *elem)
{
off_t pos;
const char *fmt = *ffmt;
int mul;
char end = 0;
mul = 1;
for (pos=0; isdigit(fmt[pos]) || isend(fmt[pos]); pos++) {
if (isdigit(fmt[pos])) {
mul = atoi( fmt + pos );
while (isdigit(fmt[pos+1])) pos++;
} else {
end = fmt[pos];
}
}
(*ffmt) += pos + 1;
return iso_struct_element_make(elem, mul, end, fmt[pos]);
}
/* read a single integer from data[i] to elem[i], interpreting the endian-ness
* and offset appropriately. */
static uint32_t iso_struct_element_read_int(struct struct_element *elem,
const uint8_t *data,
int i)
{
uint32_t el;
switch(elem->end) {
case '>':
el = iso_read_msb(data + i*elem->bytes, elem->bytes);
break;
case '<':
el = iso_read_lsb(data + i*elem->bytes, elem->bytes);
break;
case '=':
el = iso_read_bb(data + i*elem->bytes*2, elem->bytes);
}
switch(elem->bytes) {
case 1:
elem->val.val8[i] = el;
break;
case 2:
elem->val.val16[i] = el;
break;
case 4:
elem->val.val32[i] = el;
break;
}
return el;
}
/* write a single integer from elem[i] to data[i]. */
static uint32_t iso_struct_element_write1(struct struct_element *elem,
uint8_t *data,
int i)
{
uint32_t el;
switch(elem->bytes) {
case 1:
el = elem->val.val8[i];
break;
case 2:
el = elem->val.val16[i];
break;
case 4:
el = elem->val.val32[i];
break;
}
switch(elem->end) {
case '>':
iso_msb(data + i*elem->bytes, el, elem->bytes);
break;
case '<':
iso_lsb(data + i*elem->bytes, el, elem->bytes);
break;
case '=':
iso_bb(data + i*elem->bytes*2, el, elem->bytes);
}
return el;
}
static int iso_struct_element_read(struct struct_element *elem,
const uint8_t *data)
{
int size = elem->bytes * ((elem->end == '=') ? 2 : 1);
int i;
if (elem->ch == 'x') {
return size * elem->mul;
}
for (i=0; i<elem->mul; i++) {
switch(toupper(elem->ch)) {
case 'S':
/*
elem->val.time[i] = iso_datetime_read_7(&data[i*7]);
*/
break;
case 'T':
/*
elem->val.time[i] = iso_datetime_read_17(&data[i*17]);
*/
break;
default:
iso_struct_element_read_int(elem, data, i);
}
}
return size * elem->mul;
}
static int iso_struct_element_write(struct struct_element *elem,
uint8_t *data)
{
int size = elem->bytes * ((elem->end == '=') ? 2 : 1);
int i;
uint32_t ret;
if (elem->ch == 'x') {
return size*elem->mul;
}
for (i=0; i<elem->mul; i++) {
switch(toupper(elem->ch)) {
case 'S':
iso_datetime_7(&data[i*7], elem->val.time[i]);
ret = elem->val.time[i];
break;
case 'T':
iso_datetime_17(&data[i*17], elem->val.time[i]);
ret = elem->val.time[i];
break;
default:
ret = iso_struct_element_write1(elem, data, i);
break;
}
if (islower(elem->ch) && ret == 0) {
memset(data + size*i, 0, size*(elem->mul-i));
break;
}
}
return size * elem->mul;
}
int iso_struct_unpack(const char *fmt, const uint8_t *data, ...)
{
int num_conv;
int ret;
va_list ap;
struct struct_element elem;
off_t off;
va_start(ap, data);
num_conv = 0;
off = 0;
while(*fmt) {
ret = iso_struct_element_parse(&fmt, &elem);
if (ret < 0) {
va_end(ap);
return -1;
}
if (elem.ch != 'x') {
elem.val.val8 = va_arg(ap, void*);
}
off += iso_struct_element_read(&elem, data + off);
num_conv++;
}
va_end(ap);
return num_conv;
}
int iso_struct_pack(const char *fmt, uint8_t *data, ...)
{
int num_conv;
int ret;
va_list ap;
struct struct_element elem;
off_t off;
va_start(ap, data);
num_conv = 0;
off = 0;
while(*fmt) {
ret = iso_struct_element_parse(&fmt, &elem);
if (ret < 0) {
va_end(ap);
return -1;
}
if (elem.ch != 'x') {
elem.val.val8 = va_arg(ap, void*);
}
off += iso_struct_element_write(&elem, data + off);
num_conv++;
}
va_end(ap);
return num_conv;
}
int iso_struct_pack_long(uint8_t *data, ...)
{
int num_conv;
int ret;
int i, j;
va_list ap;
struct struct_element *elem = NULL;
off_t off;
va_start(ap, data);
num_conv = 0;
off = 0;
elem = calloc(1, sizeof(struct struct_element));
i=0;
while ((ret = iso_struct_element_make_v(&elem[i], &ap) > 0)) {
elem = realloc(elem, (++i + 1) * sizeof(struct struct_element));
}
for (j=0; j<i; j++) {
if (elem[j].ch != 'x') {
elem[j].val.val8 = va_arg(ap, void*);
}
off += iso_struct_element_write(&elem[j], data + off);
}
va_end(ap);
if (ret < 0) {
return -1;
}
return num_conv;
}
int iso_struct_calcsize(const char *fmt)
{
int ret, total;
struct struct_element elem;
total = 0;
while (*fmt) {
ret = iso_struct_element_parse(&fmt, &elem);
if (ret < 0) {
return -1;
}
total += ret;
}
return total;
}

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@ -1,77 +0,0 @@
/* vim: set noet ts=8 sts=8 sw=8 : */
/**
* \file struct.h
* Add functionality similar to the python "struct" module to make it easier
* to read and write .iso structures.
*
* The following conversions are supported:
* B uint8_t, the arg should be (uint8_t*)
* H uint16_t, the arg should be (uint16_t*)
* L uint32_t, the arg should be (uint32_t*)
* S a 7-byte timestamp, the arg should be (time_t*)
* T a 17-byte timestamp, the arg should be (time_t*)
* x ignored field, no arg should be specified
*
* Any of the first 3 conversions may be preceded by a endian specifier:
* < little-endian
* > big-endian
* = both-endian (ie. according to ecma119 7.2.3 or 7.3.3)
*
* Each conversion specifier may also be preceded by a length specifier. For
* example, "<5L" specifies an array of 5 little-endian 32-bit integers. Note
* that "=L" takes 8 bytes while "<L" and ">L" each take 4.
*
* You can use a lower-case conversion specifier instead of an upper-case one
* to signify that the (multi-element) conversion should stop when a zero is
* reached. This is useful for writing out NULL-terminated strings. Note that
* this has no effect when unpacking data from a struct.
*/
#ifndef __ISO_STRUCT
#define __ISO_STRUCT
#include <stdint.h>
/**
* Unpack a struct into its components. The list of components is a list of
* pointers to the variables to write.
*
* For example:
* uint8_t byte1, byte2;
* uint16_t uint;
* iso_struct_unpack("BB=H", data, &byte1, &byte2, &uint);
*
* \return The number of conversions performed, or -1 on error.
*/
int iso_struct_unpack(const char *fmt, const uint8_t *data, ...);
/**
* Write out a struct from its components. The list of components is a list of
* pointers to the variables to write and the buffer to which to write
* is assumed to be large
* enough to take the data.
*
* \return The number of conversions performed, or -1 on error.
*/
int iso_struct_pack(const char *fmt, uint8_t *data, ...);
/**
* Achieves the same effect as iso_struct_pack(), but the format is passed as
* a sequence of (int, char, char) triples. This list is terminated by
* (0, 0, 0) and the list of parameters follows.
*
* Example: iso_struct_pack_long(data, 4, '=', 'H', 0, 0, 0, &val) is the same
* as iso_struct_pack("4=H", 0, 0, 0, &val)
*/
int iso_struct_pack_long(uint8_t *data, ...);
/**
* Calculate the size of a given format string.
*
* \return The sum of the length of all formats in the string, in bytes. Return
* -1 on error.
*/
int iso_struct_calcsize(const char *fmt);
#endif

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/* -*- indent-tabs-mode: t; tab-width: 8; c-basic-offset: 8; -*- */
/* vim: set ts=8 sts=8 sw=8 noet : */
#define _GNU_SOURCE
#include "libisofs/libisofs.h"
#include "libburn/libburn.h"
#include <getopt.h>
#include <stdlib.h>
#include <stdio.h>
#include <unistd.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <assert.h>
#include <sys/types.h>
#include <dirent.h>
#include <string.h>
#include <errno.h>
#define SECSIZE 2048
const char * const optstring = "JRL:h";
extern char *optarg;
extern int optind;
void usage()
{
printf("test [OPTIONS] DIRECTORY OUTPUT\n");
}
void help()
{
printf(
"Options:\n"
" -J Add Joliet support\n"
" -R Add Rock Ridge support\n"
" -L <num> Set the ISO level (1 or 2)\n"
" -h Print this message\n"
);
}
int main(int argc, char **argv)
{
struct iso_volset *volset;
struct iso_volume *volume;
struct burn_source *src;
unsigned char buf[2048];
FILE *fd;
int c;
int level=1, flags=0;
DIR *dir;
struct dirent *ent;
while ((c = getopt(argc, argv, optstring)) != -1) {
switch(c) {
case 'h':
usage();
help();
exit(0);
break;
case 'J':
flags |= ECMA119_JOLIET;
break;
case 'R':
flags |= ECMA119_ROCKRIDGE;
break;
case 'L':
level = atoi(optarg);
break;
case '?':
usage();
exit(1);
break;
}
}
if (argc < 2) {
printf ("must pass directory to build iso from\n");
usage();
return 1;
}
if (argc < 3) {
printf ("must supply output file\n");
usage();
return 1;
}
fd = fopen(argv[optind+1], "w");
if (!fd) {
perror("error opening output file");
exit(1);
}
volume = iso_volume_new( "VOLID", "PUBID", "PREPID" );
volset = iso_volset_new( volume, "VOLSETID" );
dir = opendir(argv[optind]);
if (!dir) {
perror("error opening input directory");
exit(1);
}
while ( (ent = readdir(dir)) ) {
struct stat st;
char *name;
if (!strcmp(ent->d_name, ".") || !strcmp(ent->d_name, "..")) {
continue;
}
name = malloc(strlen(argv[optind]) + strlen(ent->d_name) + 2);
strcpy(name, argv[optind]);
strcat(name, "/");
strcat(name, ent->d_name);
if (lstat(name, &st) == -1) {
fprintf(stderr, "error opening file %s: %s\n",
name, strerror(errno));
exit(1);
}
if (S_ISDIR(st.st_mode)) {
iso_tree_radd_dir(iso_volume_get_root(volume), name);
} else {
iso_tree_add_file(iso_volume_get_root(volume), name);
}
free(name);
}
iso_tree_print(iso_volume_get_root(volume), 0);
src = iso_source_new_ecma119(volset, 0, level, flags);
while (src->read(src, buf, 2048) == 2048) {
fwrite(buf, 1, 2048, fd);
}
fclose(fd);
return 0;
}

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/* -*- indent-tabs-mode: t; tab-width: 8; c-basic-offset: 8; -*- */
#ifndef __WRITER
#define __WRITER
#include "libisofs.h"
#include <stdio.h>
#include <string.h>
#include <time.h>
enum iso_write_state
{
ISO_WRITE_BEFORE,
ISO_WRITE_SYSTEM_AREA,
ISO_WRITE_PRI_VOL_DESC,
ISO_WRITE_VOL_DESC_TERMINATOR,
ISO_WRITE_L_PATH_TABLE,
ISO_WRITE_M_PATH_TABLE,
ISO_WRITE_DIR_RECORDS,
ISO_WRITE_ER_AREA,
ISO_WRITE_FILES,
ISO_WRITE_DONE
};
/** File Flags (9.1.6) */
enum
{
ISO_FILE_FLAG_NORMAL = 0,
ISO_FILE_FLAG_HIDDEN = 1 << 0,
ISO_FILE_FLAG_DIRECTORY = 1 << 1,
ISO_FILE_FLAG_ASSOCIATED = 1 << 2,
ISO_FILE_FLAG_RECORD = 1 << 3,
ISO_FILE_FLAG_PROTECTION = 1 << 4,
ISO_FILE_FLAG_MULTIEXTENT = 1 << 7
};
struct iso_write_target
{
struct iso_volumeset *volset;
int volume;
/* the time at which the writing began */
time_t now;
/* size of a physical sector on the target disc */
int phys_sector_size;
/* size of the total output */
int total_size;
/* when compiling the iso, this is the next available logical block.
when writing the iso, this is the next block to write. */
int logical_block;
/* The number of Logical Blocks for the Volume Space */
int volume_space_size;
/* The Logical Block size */
int logical_block_size;
/* The Path Table size */
int path_table_size;
/* Locations of Type L Path Table (Logical Block Number) */
int l_path_table_pos;
/* Locations of Type M Path Table (Logical Block Number) */
int m_path_table_pos;
/* Location of the SUSP ER area (Logical Block Number) */
int susp_er_pos;
/* Current file being written in iso_write_files() */
struct iso_tree_file **current_file;
FILE *current_fd;
/* what we're doing when the generate function gets called next */
enum iso_write_state state;
union
{
struct iso_state_system_area
{
/* how many sectors in the system area have been
written */
int sectors;
} system_area;
struct iso_state_path_tables
{
/* how many sectors in the path table area have been
written */
int sectors;
} path_tables;
struct iso_state_dir_records
{
/* how many sectors in the directory records area have
been written */
int sectors;
} dir_records;
struct iso_state_files
{
/* how many sectors in the current file have been
written */
int sectors;
} files;
} state_data;
};
#endif /* __WRITER */