// SPDX-License-Identifier: 0BSD
///////////////////////////////////////////////////////////////////////////////
//
/// \file string_conversion.c
/// \brief Conversion of strings to filter chain and vice versa
//
// Author: Lasse Collin
//
///////////////////////////////////////////////////////////////////////////////
#include "filter_common.h"
/////////////////////
// String building //
/////////////////////
/// How much memory to allocate for strings. For now, no realloc is used
/// so this needs to be big enough even though there of course is
/// an overflow check still.
///
/// FIXME? Using a fixed size is wasteful if the application doesn't free
/// the string fairly quickly but this can be improved later if needed.
#define STR_ALLOC_SIZE 800
typedef struct {
char *buf;
size_t pos;
} lzma_str;
static lzma_ret
str_init(lzma_str *str, const lzma_allocator *allocator)
{
str->buf = lzma_alloc(STR_ALLOC_SIZE, allocator);
if (str->buf == NULL)
return LZMA_MEM_ERROR;
str->pos = 0;
return LZMA_OK;
}
static void
str_free(lzma_str *str, const lzma_allocator *allocator)
{
lzma_free(str->buf, allocator);
return;
}
static bool
str_is_full(const lzma_str *str)
{
return str->pos == STR_ALLOC_SIZE - 1;
}
static lzma_ret
str_finish(char **dest, lzma_str *str, const lzma_allocator *allocator)
{
if (str_is_full(str)) {
// The preallocated buffer was too small.
// This shouldn't happen as STR_ALLOC_SIZE should
// be adjusted if new filters are added.
lzma_free(str->buf, allocator);
*dest = NULL;
assert(0);
return LZMA_PROG_ERROR;
}
str->buf[str->pos] = '\0';
*dest = str->buf;
return LZMA_OK;
}
static void
str_append_str(lzma_str *str, const char *s)
{
const size_t len = strlen(s);
const size_t limit = STR_ALLOC_SIZE - 1 - str->pos;
const size_t copy_size = my_min(len, limit);
memcpy(str->buf + str->pos, s, copy_size);
str->pos += copy_size;
return;
}
static void
str_append_u32(lzma_str *str, uint32_t v, bool use_byte_suffix)
{
if (v == 0) {
str_append_str(str, "0");
} else {
// NOTE: Don't use plain "B" because xz and the parser in this
// file don't support it and at glance it may look like 8
// (there cannot be a space before the suffix).
static const char suffixes[4][4] = { "", "KiB", "MiB", "GiB" };
size_t suf = 0;
if (use_byte_suffix) {
while ((v & 1023) == 0
&& suf < ARRAY_SIZE(suffixes) - 1) {
v >>= 10;
++suf;
}
}
// UINT32_MAX in base 10 would need 10 + 1 bytes. Remember
// that initializing to "" initializes all elements to
// zero so '\0'-termination gets handled by this.
char buf[16] = "";
size_t pos = sizeof(buf) - 1;
do {
buf[--pos] = '0' + (v % 10);
v /= 10;
} while (v != 0);
str_append_str(str, buf + pos);
str_append_str(str, suffixes[suf]);
}
return;
}
//////////////////////////////////////////////
// Parsing and stringification declarations //
//////////////////////////////////////////////
/// Maximum length for filter and option names.
/// 11 chars + terminating '\0' + sizeof(uint32_t) = 16 bytes
#define NAME_LEN_MAX 11
/// For option_map.flags: Use .u.map to do convert the input value
/// to an integer. Without this flag, .u.range.{min,max} are used
/// as the allowed range for the integer.
#define OPTMAP_USE_NAME_VALUE_MAP 0x01
/// For option_map.flags: Allow KiB/MiB/GiB in input string and use them in
/// the stringified output if the value is an exact multiple of these.
/// This is used e.g. for LZMA1/2 dictionary size.
#define OPTMAP_USE_BYTE_SUFFIX 0x02
/// For option_map.flags: If the integer value is zero then this option
/// won't be included in the stringified output. It's used e.g. for
/// BCJ filter start offset which usually is zero.
#define OPTMAP_NO_STRFY_ZERO 0x04
/// Possible values for option_map.type. Since OPTMAP_TYPE_UINT32 is 0,
/// it doesn't need to be specified in the initializers as it is
/// the implicit value.
enum {
OPTMAP_TYPE_UINT32,
OPTMAP_TYPE_LZMA_MODE,
OPTMAP_TYPE_LZMA_MATCH_FINDER,
OPTMAP_TYPE_LZMA_PRESET,
};
/// This is for mapping string values in options to integers.
/// The last element of an array must have "" as the name.
/// It's used e.g. for match finder names in LZMA1/2.
typedef struct {
const char name[NAME_LEN_MAX + 1];
const uint32_t value;
} name_value_map;
/// Each filter that has options needs an array of option_map structures.
/// The array doesn't need to be terminated as the functions take the
/// length of the array as an argument.
///
/// When converting a string to filter options structure, option values
/// will be handled in a few different ways:
///
/// (1) If .type equals OPTMAP_TYPE_LZMA_PRESET then LZMA1/2 preset string
/// is handled specially.
///
/// (2) If .flags has OPTMAP_USE_NAME_VALUE_MAP set then the string is
/// converted to an integer using the name_value_map pointed by .u.map.
/// The last element in .u.map must have .name = "" as the terminator.
///
/// (3) Otherwise the string is treated as a non-negative unsigned decimal
/// integer which must be in the range set in .u.range. If .flags has
/// OPTMAP_USE_BYTE_SUFFIX then KiB, MiB, and GiB suffixes are allowed.
///
/// The integer value from (2) or (3) is then stored to filter_options
/// at the offset specified in .offset using the type specified in .type
/// (default is uint32_t).
///
/// Stringifying a filter is done by processing a given number of options
/// in order from the beginning of an option_map array. The integer is
/// read from filter_options at .offset using the type from .type.
///
/// If the integer is zero and .flags has OPTMAP_NO_STRFY_ZERO then the
/// option is skipped.
///
/// If .flags has OPTMAP_USE_NAME_VALUE_MAP set then .u.map will be used
/// to convert the option to a string. If the map doesn't contain a string
/// for the integer value then "UNKNOWN" is used.
///
/// If .flags doesn't have OPTMAP_USE_NAME_VALUE_MAP set then the integer is
/// converted to a decimal value. If OPTMAP_USE_BYTE_SUFFIX is used then KiB,
/// MiB, or GiB suffix is used if the value is an exact multiple of these.
/// Plain "B" suffix is never used.
typedef struct {
char name[NAME_LEN_MAX + 1];
uint8_t type;
uint8_t flags;
uint16_t offset;
union {
// NVHPC has problems with unions that contain pointers that
// are not the first members, so keep "map" at the top.
const name_value_map *map;
struct {
uint32_t min;
uint32_t max;
} range;
} u;
} option_map;
static const char *parse_options(const char **const str, const char *str_end,
void *filter_options,
const option_map *const optmap, const size_t optmap_size);
/////////
// BCJ //
/////////
#if defined(HAVE_ENCODER_X86) \
|| defined(HAVE_DECODER_X86) \
|| defined(HAVE_ENCODER_ARM) \
|| defined(HAVE_DECODER_ARM) \
|| defined(HAVE_ENCODER_ARMTHUMB) \
|| defined(HAVE_DECODER_ARMTHUMB) \
|| defined(HAVE_ENCODER_ARM64) \
|| defined(HAVE_DECODER_ARM64) \
|| defined(HAVE_ENCODER_POWERPC) \
|| defined(HAVE_DECODER_POWERPC) \
|| defined(HAVE_ENCODER_IA64) \
|| defined(HAVE_DECODER_IA64) \
|| defined(HAVE_ENCODER_SPARC) \
|| defined(HAVE_DECODER_SPARC) \
|| defined(HAVE_ENCODER_RISCV) \
|| defined(HAVE_DECODER_RISCV)
static const option_map bcj_optmap[] = {
{
.name = "start",
.flags = OPTMAP_NO_STRFY_ZERO | OPTMAP_USE_BYTE_SUFFIX,
.offset = offsetof(lzma_options_bcj, start_offset),
.u.range.min = 0,
.u.range.max = UINT32_MAX,
}
};
static const char *
parse_bcj(const char **const str, const char *str_end, void *filter_options)
{
// filter_options was zeroed on allocation and that is enough
// for the default value.
return parse_options(str, str_end, filter_options,
bcj_optmap, ARRAY_SIZE(bcj_optmap));
}
#endif
///////////
// Delta //
///////////
#if defined(HAVE_ENCODER_DELTA) || defined(HAVE_DECODER_DELTA)
static const option_map delta_optmap[] = {
{
.name = "dist",
.offset = offsetof(lzma_options_delta, dist),
.u.range.min = LZMA_DELTA_DIST_MIN,
.u.range.max = LZMA_DELTA_DIST_MAX,
}
};
static const char *
parse_delta(const char **const str, const char *str_end, void *filter_options)
{
lzma_options_delta *opts = filter_options;
opts->type = LZMA_DELTA_TYPE_BYTE;
opts->dist = LZMA_DELTA_DIST_MIN;
return parse_options(str, str_end, filter_options,
delta_optmap, ARRAY_SIZE(delta_optmap));
}
#endif
///////////////////
// LZMA1 & LZMA2 //
///////////////////
/// Help string for presets
#define LZMA12_PRESET_STR "0-9[e]"
static const char *
parse_lzma12_preset(const char **const str, const char *str_end,
uint32_t *preset)
{
assert(*str < str_end);
*preset = (uint32_t)(**str - '0');
// NOTE: Remember to update LZMA12_PRESET_STR if this is modified!
while (++*str < str_end) {
switch (**str) {
case 'e':
*preset |= LZMA_PRESET_EXTREME;
break;
default:
return "Unsupported preset flag";
}
}
return NULL;
}
static const char *
set_lzma12_preset(const char **const str, const char *str_end,
void *filter_options)
{
uint32_t preset;
const char *errmsg = parse_lzma12_preset(str, str_end, &preset);
if (errmsg != NULL)
return errmsg;
lzma_options_lzma *opts = filter_options;
if (lzma_lzma_preset(opts, preset))
return "Unsupported preset";
return NULL;
}
static const name_value_map lzma12_mode_map[] = {
{ "fast", LZMA_MODE_FAST },
{ "normal", LZMA_MODE_NORMAL },
{ "", 0 }
};
static const name_value_map lzma12_mf_map[] = {
{ "hc3", LZMA_MF_HC3 },
{ "hc4", LZMA_MF_HC4 },
{ "bt2", LZMA_MF_BT2 },
{ "bt3", LZMA_MF_BT3 },
{ "bt4", LZMA_MF_BT4 },
{ "", 0 }
};
static const option_map lzma12_optmap[] = {
{
.name = "preset",
.type = OPTMAP_TYPE_LZMA_PRESET,
}, {
.name = "dict",
.flags = OPTMAP_USE_BYTE_SUFFIX,
.offset = offsetof(lzma_options_lzma, dict_size),
.u.range.min = LZMA_DICT_SIZE_MIN,
// FIXME? The max is really max for encoding but decoding
// would allow 4 GiB - 1 B.
.u.range.max = (UINT32_C(1) << 30) + (UINT32_C(1) << 29),
}, {
.name = "lc",
.offset = offsetof(lzma_options_lzma, lc),
.u.range.min = LZMA_LCLP_MIN,
.u.range.max = LZMA_LCLP_MAX,
}, {
.name = "lp",
.offset = offsetof(lzma_options_lzma, lp),
.u.range.min = LZMA_LCLP_MIN,
.u.range.max = LZMA_LCLP_MAX,
}, {
.name = "pb",
.offset = offsetof(lzma_options_lzma, pb),
.u.range.min = LZMA_PB_MIN,
.u.range.max = LZMA_PB_MAX,
}, {
.name = "mode",
.type = OPTMAP_TYPE_LZMA_MODE,
.flags = OPTMAP_USE_NAME_VALUE_MAP,
.offset = offsetof(lzma_options_lzma, mode),
.u.map = lzma12_mode_map,
}, {
.name = "nice",
.offset = offsetof(lzma_options_lzma, nice_len),
.u.range.min = 2,
.u.range.max = 273,
}, {
.name = "mf",
.type = OPTMAP_TYPE_LZMA_MATCH_FINDER,
.flags = OPTMAP_USE_NAME_VALUE_MAP,
.offset = offsetof(lzma_options_lzma, mf),
.u.map = lzma12_mf_map,
}, {
.name = "depth",
.offset = offsetof(lzma_options_lzma, depth),
.u.range.min = 0,
.u.range.max = UINT32_MAX,
}
};
static const char *
parse_lzma12(const char **const str, const char *str_end, void *filter_options)
{
lzma_options_lzma *opts = filter_options;
// It cannot fail.
const bool preset_ret = lzma_lzma_preset(opts, LZMA_PRESET_DEFAULT);
assert(!preset_ret);
(void)preset_ret;
const char *errmsg = parse_options(str, str_end, filter_options,
lzma12_optmap, ARRAY_SIZE(lzma12_optmap));
if (errmsg != NULL)
return errmsg;
if (opts->lc + opts->lp > LZMA_LCLP_MAX)
return "The sum of lc and lp must not exceed 4";
return NULL;
}
/////////////////////////////////////////
// Generic parsing and stringification //
/////////////////////////////////////////
static const struct {
/// Name of the filter
char name[NAME_LEN_MAX + 1];
/// For lzma_str_to_filters:
/// Size of the filter-specific options structure.
uint32_t opts_size;
/// Filter ID
lzma_vli id;
/// For lzma_str_to_filters:
/// Function to parse the filter-specific options. The filter_options
/// will already have been allocated using lzma_alloc_zero().
const char *(*parse)(const char **str, const char *str_end,
void *filter_options);
/// For lzma_str_from_filters:
/// If the flag LZMA_STR_ENCODER is used then the first
/// strfy_encoder elements of optmap are stringified.
/// With LZMA_STR_DECODER strfy_decoder is used.
/// Currently encoders use all options that decoders do but if
/// that changes then this needs to be changed too, for example,
/// add a new OPTMAP flag to skip printing some decoder-only options.
const option_map *optmap;
uint8_t strfy_encoder;
uint8_t strfy_decoder;
/// For lzma_str_from_filters:
/// If true, lzma_filter.options is allowed to be NULL. In that case,
/// only the filter name is printed without any options.
bool allow_null;
} filter_name_map[] = {
#if defined (HAVE_ENCODER_LZMA1) || defined(HAVE_DECODER_LZMA1)
{ "lzma1", sizeof(lzma_options_lzma), LZMA_FILTER_LZMA1,
&parse_lzma12, lzma12_optmap, 9, 5, false },
#endif
#if defined(HAVE_ENCODER_LZMA2) || defined(HAVE_DECODER_LZMA2)
{ "lzma2", sizeof(lzma_options_lzma), LZMA_FILTER_LZMA2,
&parse_lzma12, lzma12_optmap, 9, 2, false },
#endif
#if defined(HAVE_ENCODER_X86) || defined(HAVE_DECODER_X86)
{ "x86", sizeof(lzma_options_bcj), LZMA_FILTER_X86,
&parse_bcj, bcj_optmap, 1, 1, true },
#endif
#if defined(HAVE_ENCODER_ARM) || defined(HAVE_DECODER_ARM)
{ "arm", sizeof(lzma_options_bcj), LZMA_FILTER_ARM,
&parse_bcj, bcj_optmap, 1, 1, true },
#endif
#if defined(HAVE_ENCODER_ARMTHUMB) || defined(HAVE_DECODER_ARMTHUMB)
{ "armthumb", sizeof(lzma_options_bcj), LZMA_FILTER_ARMTHUMB,
&parse_bcj, bcj_optmap, 1, 1, true },
#endif
#if defined(HAVE_ENCODER_ARM64) || defined(HAVE_DECODER_ARM64)
{ "arm64", sizeof(lzma_options_bcj), LZMA_FILTER_ARM64,
&parse_bcj, bcj_optmap, 1, 1, true },
#endif
#if defined(HAVE_ENCODER_RISCV) || defined(HAVE_DECODER_RISCV)
{ "riscv", sizeof(lzma_options_bcj), LZMA_FILTER_RISCV,
&parse_bcj, bcj_optmap, 1, 1, true },
#endif
#if defined(HAVE_ENCODER_POWERPC) || defined(HAVE_DECODER_POWERPC)
{ "powerpc", sizeof(lzma_options_bcj), LZMA_FILTER_POWERPC,
&parse_bcj, bcj_optmap, 1, 1, true },
#endif
#if defined(HAVE_ENCODER_IA64) || defined(HAVE_DECODER_IA64)
{ "ia64", sizeof(lzma_options_bcj), LZMA_FILTER_IA64,
&parse_bcj, bcj_optmap, 1, 1, true },
#endif
#if defined(HAVE_ENCODER_SPARC) || defined(HAVE_DECODER_SPARC)
{ "sparc", sizeof(lzma_options_bcj), LZMA_FILTER_SPARC,
&parse_bcj, bcj_optmap, 1, 1, true },
#endif
#if defined(HAVE_ENCODER_DELTA) || defined(HAVE_DECODER_DELTA)
{ "delta", sizeof(lzma_options_delta), LZMA_FILTER_DELTA,
&parse_delta, delta_optmap, 1, 1, false },
#endif
};
/// Decodes options from a string for one filter (name1=value1,name2=value2).
/// Caller must have allocated memory for filter_options already and set
/// the initial default values. This is called from the filter-specific
/// parse_* functions.
///
/// The input string starts at *str and the address in str_end is the first
/// char that is not part of the string anymore. So no '\0' terminator is
/// used. *str is advanced every time something has been decoded successfully.
static const char *
parse_options(const char **const str, const char *str_end,
void *filter_options,
const option_map *const optmap, const size_t optmap_size)
{
while (*str < str_end && **str != '\0') {
// Each option is of the form name=value.
// Commas (',') separate options. Extra commas are ignored.
// Ignoring extra commas makes it simpler if an optional
// option stored in a shell variable which can be empty.
if (**str == ',') {
++*str;
continue;
}
// Find where the next name=value ends.
const size_t str_len = (size_t)(str_end - *str);
const char *name_eq_value_end = memchr(*str, ',', str_len);
if (name_eq_value_end == NULL)
name_eq_value_end = str_end;
const char *equals_sign = memchr(*str, '=',
(size_t)(name_eq_value_end - *str));
// Fail if the '=' wasn't found or the option name is missing
// (the first char is '=').
if (equals_sign == NULL || **str == '=')
return "Options must be 'name=value' pairs separated "
"with commas";
// Reject a too long option name so that the memcmp()
// in the loop below won't read past the end of the
// string in optmap[i].name.
const size_t name_len = (size_t)(equals_sign - *str);
if (name_len > NAME_LEN_MAX)
return "Unknown option name";
// Find the option name from optmap[].
size_t i = 0;
while (true) {
if (i == optmap_size)
return "Unknown option name";
if (memcmp(*str, optmap[i].name, name_len) == 0
&& optmap[i].name[name_len] == '\0')
break;
++i;
}
// The input string is good at least until the start of
// the option value.
*str = equals_sign + 1;
// The code assumes that the option value isn't an empty
// string so check it here.
const size_t value_len = (size_t)(name_eq_value_end - *str);
if (value_len == 0)
return "Option value cannot be empty";
// LZMA1/2 preset has its own parsing function.
if (optmap[i].type == OPTMAP_TYPE_LZMA_PRESET) {
const char *errmsg = set_lzma12_preset(str,
name_eq_value_end, filter_options);
if (errmsg != NULL)
return errmsg;
continue;
}
// It's an integer value.
uint32_t v;
if (optmap[i].flags & OPTMAP_USE_NAME_VALUE_MAP) {
// The integer is picked from a string-to-integer map.
//
// Reject a too long value string so that the memcmp()
// in the loop below won't read past the end of the
// string in optmap[i].u.map[j].name.
if (value_len > NAME_LEN_MAX)
return "Invalid option value";
const name_value_map *map = optmap[i].u.map;
size_t j = 0;
while (true) {
// The array is terminated with an empty name.
if (map[j].name[0] == '\0')
return "Invalid option value";
if (memcmp(*str, map[j].name, value_len) == 0
&& map[j].name[value_len]
== '\0') {
v = map[j].value;
break;
}
++j;
}
} else if (**str < '0' || **str > '9') {
// Note that "max" isn't supported while it is
// supported in xz. It's not useful here.
return "Value is not a non-negative decimal integer";
} else {
// strtoul() has locale-specific behavior so it cannot
// be relied on to get reproducible results since we
// cannot change the locate in a thread-safe library.
// It also needs '\0'-termination.
//
// Use a temporary pointer so that *str will point
// to the beginning of the value string in case
// an error occurs.
const char *p = *str;
v = 0;
do {
if (v > UINT32_MAX / 10)
return "Value out of range";
v *= 10;
const uint32_t add = (uint32_t)(*p - '0');
if (UINT32_MAX - add < v)
return "Value out of range";
v += add;
++p;
} while (p < name_eq_value_end
&& *p >= '0' && *p <= '9');
if (p < name_eq_value_end) {
// Remember this position so that it can be
// used for error messages that are
// specifically about the suffix. (Out of
// range values are about the whole value
// and those error messages point to the
// beginning of the number part,
// not to the suffix.)
const char *multiplier_start = p;
// If multiplier suffix shouldn't be used
// then don't allow them even if the value
// would stay within limits. This is a somewhat
// unnecessary check but it rejects silly
// things like lzma2:pb=0MiB which xz allows.
if ((optmap[i].flags & OPTMAP_USE_BYTE_SUFFIX)
== 0) {
*str = multiplier_start;
return "This option does not support "
"any integer suffixes";
}
uint32_t shift;
switch (*p) {
case 'k':
case 'K':
shift = 10;
break;
case 'm':
case 'M':
shift = 20;
break;
case 'g':
case 'G':
shift = 30;
break;
default:
*str = multiplier_start;
return "Invalid multiplier suffix "
"(KiB, MiB, or GiB)";
}
++p;
// Allow "M", "Mi", "MB", "MiB" and the same
// for the other five characters from the
// switch-statement above. All are handled
// as base-2 (perhaps a mistake, perhaps not).
// Note that 'i' and 'B' are case sensitive.
if (p < name_eq_value_end && *p == 'i')
++p;
if (p < name_eq_value_end && *p == 'B')
++p;
// Now we must have no chars remaining.
if (p < name_eq_value_end) {
*str = multiplier_start;
return "Invalid multiplier suffix "
"(KiB, MiB, or GiB)";
}
if (v > (UINT32_MAX >> shift))
return "Value out of range";
v <<= shift;
}
if (v < optmap[i].u.range.min
|| v > optmap[i].u.range.max)
return "Value out of range";
}
// Set the value in filter_options. Enums are handled
// specially since the underlying type isn't the same
// as uint32_t on all systems.
void *ptr = (char *)filter_options + optmap[i].offset;
switch (optmap[i].type) {
case OPTMAP_TYPE_LZMA_MODE:
*(lzma_mode *)ptr = (lzma_mode)v;
break;
case OPTMAP_TYPE_LZMA_MATCH_FINDER:
*(lzma_match_finder *)ptr = (lzma_match_finder)v;
break;
default:
*(uint32_t *)ptr = v;
break;
}
// This option has been successfully handled.
*str = name_eq_value_end;
}
// No errors.
return NULL;
}
/// Finds the name of the filter at the beginning of the string and
/// calls filter_name_map[i].parse() to decode the filter-specific options.
/// The caller must have set str_end so that exactly one filter and its
/// options are present without any trailing characters.
static const char *
parse_filter(const char **const str, const char *str_end, lzma_filter *filter,
const lzma_allocator *allocator, bool only_xz)
{
// Search for a colon or equals sign that would separate the filter
// name from filter options. If neither is found, then the input
// string only contains a filter name and there are no options.
//
// First assume that a colon or equals sign won't be found:
const char *name_end = str_end;
const char *opts_start = str_end;
for (const char *p = *str; p < str_end; ++p) {
if (*p == ':' || *p == '=') {
name_end = p;
// Filter options (name1=value1,name2=value2,...)
// begin after the colon or equals sign.
opts_start = p + 1;
break;
}
}
// Reject a too long filter name so that the memcmp()
// in the loop below won't read past the end of the
// string in filter_name_map[i].name.
const size_t name_len = (size_t)(name_end - *str);
if (name_len > NAME_LEN_MAX)
return "Unknown filter name";
for (size_t i = 0; i < ARRAY_SIZE(filter_name_map); ++i) {
if (memcmp(*str, filter_name_map[i].name, name_len) == 0
&& filter_name_map[i].name[name_len] == '\0') {
if (only_xz && filter_name_map[i].id
>= LZMA_FILTER_RESERVED_START)
return "This filter cannot be used in "
"the .xz format";
// Allocate the filter-specific options and
// initialize the memory with zeros.
void *options = lzma_alloc_zero(
filter_name_map[i].opts_size,
allocator);
if (options == NULL)
return "Memory allocation failed";
// Filter name was found so the input string is good
// at least this far.
*str = opts_start;
const char *errmsg = filter_name_map[i].parse(
str, str_end, options);
if (errmsg != NULL) {
lzma_free(options, allocator);
return errmsg;
}
// *filter is modified only when parsing is successful.
filter->id = filter_name_map[i].id;
filter->options = options;
return NULL;
}
}
return "Unknown filter name";
}
/// Converts the string to a filter chain (array of lzma_filter structures).
///
/// *str is advanced every time something has been decoded successfully.
/// This way the caller knows where in the string a possible error occurred.
static const char *
str_to_filters(const char **const str, lzma_filter *filters, uint32_t flags,
const lzma_allocator *allocator)
{
const char *errmsg;
// Skip leading spaces.
while (**str == ' ')
++*str;
if (**str == '\0')
return "Empty string is not allowed, "
"try \"6\" if a default value is needed";
// Detect the type of the string.
//
// A string beginning with a digit or a string beginning with
// one dash and a digit are treated as presets. Trailing spaces
// will be ignored too (leading spaces were already ignored above).
//
// For example, "6", "7 ", "-9e", or " -3 " are treated as presets.
// Strings like "-" or "- " aren't preset.
#define MY_IS_DIGIT(c) ((c) >= '0' && (c) <= '9')
if (MY_IS_DIGIT(**str) || (**str == '-' && MY_IS_DIGIT((*str)[1]))) {
if (**str == '-')
++*str;
// Ignore trailing spaces.
const size_t str_len = strlen(*str);
const char *str_end = memchr(*str, ' ', str_len);
if (str_end != NULL) {
// There is at least one trailing space. Check that
// there are no chars other than spaces.
for (size_t i = 1; str_end[i] != '\0'; ++i)
if (str_end[i] != ' ')
return "Unsupported preset";
} else {
// There are no trailing spaces. Use the whole string.
str_end = *str + str_len;
}
uint32_t preset;
errmsg = parse_lzma12_preset(str, str_end, &preset);
if (errmsg != NULL)
return errmsg;
lzma_options_lzma *opts = lzma_alloc(sizeof(*opts), allocator);
if (opts == NULL)
return "Memory allocation failed";
if (lzma_lzma_preset(opts, preset)) {
lzma_free(opts, allocator);
return "Unsupported preset";
}
filters[0].id = LZMA_FILTER_LZMA2;
filters[0].options = opts;
filters[1].id = LZMA_VLI_UNKNOWN;
filters[1].options = NULL;
return NULL;
}
// Not a preset so it must be a filter chain.
//
// If LZMA_STR_ALL_FILTERS isn't used we allow only filters that
// can be used in .xz.
const bool only_xz = (flags & LZMA_STR_ALL_FILTERS) == 0;
// Use a temporary array so that we don't modify the caller-supplied
// one until we know that no errors occurred.
lzma_filter temp_filters[LZMA_FILTERS_MAX + 1];
size_t i = 0;
do {
if (i == LZMA_FILTERS_MAX) {
errmsg = "The maximum number of filters is four";
goto error;
}
// Skip "--" if present.
if ((*str)[0] == '-' && (*str)[1] == '-')
*str += 2;
// Locate the end of "filter:name1=value1,name2=value2",
// stopping at the first "--" or a single space.
const char *filter_end = *str;
while (filter_end[0] != '\0') {
if ((filter_end[0] == '-' && filter_end[1] == '-')
|| filter_end[0] == ' ')
break;
++filter_end;
}
// Inputs that have "--" at the end or "-- " in the middle
// will result in an empty filter name.
if (filter_end == *str) {
errmsg = "Filter name is missing";
goto error;
}
errmsg = parse_filter(str, filter_end, &temp_filters[i],
allocator, only_xz);
if (errmsg != NULL)
goto error;
// Skip trailing spaces.
while (**str == ' ')
++*str;
++i;
} while (**str != '\0');
// Seems to be good, terminate the array so that
// basic validation can be done.
temp_filters[i].id = LZMA_VLI_UNKNOWN;
temp_filters[i].options = NULL;
// Do basic validation if the application didn't prohibit it.
if ((flags & LZMA_STR_NO_VALIDATION) == 0) {
size_t dummy;
const lzma_ret ret = lzma_validate_chain(temp_filters, &dummy);
assert(ret == LZMA_OK || ret == LZMA_OPTIONS_ERROR);
if (ret != LZMA_OK) {
errmsg = "Invalid filter chain "
"('lzma2' missing at the end?)";
goto error;
}
}
// All good. Copy the filters to the application supplied array.
memcpy(filters, temp_filters, (i + 1) * sizeof(lzma_filter));
return NULL;
error:
// Free the filter options that were successfully decoded.
while (i-- > 0)
lzma_free(temp_filters[i].options, allocator);
return errmsg;
}
extern LZMA_API(const char *)
lzma_str_to_filters(const char *str, int *error_pos, lzma_filter *filters,
uint32_t flags, const lzma_allocator *allocator)
{
if (str == NULL || filters == NULL)
return "Unexpected NULL pointer argument(s) "
"to lzma_str_to_filters()";
// Validate the flags.
const uint32_t supported_flags
= LZMA_STR_ALL_FILTERS
| LZMA_STR_NO_VALIDATION;
if (flags & ~supported_flags)
return "Unsupported flags to lzma_str_to_filters()";
const char *used = str;
const char *errmsg = str_to_filters(&used, filters, flags, allocator);
if (error_pos != NULL) {
const size_t n = (size_t)(used - str);
*error_pos = n > INT_MAX ? INT_MAX : (int)n;
}
return errmsg;
}
/// Converts options of one filter to a string.
///
/// The caller must have already put the filter name in the destination
/// string. Since it is possible that no options will be needed, the caller
/// won't have put a delimiter character (':' or '=') in the string yet.
/// We will add it if at least one option will be added to the string.
static void
strfy_filter(lzma_str *dest, const char *delimiter,
const option_map *optmap, size_t optmap_count,
const void *filter_options)
{
for (size_t i = 0; i < optmap_count; ++i) {
// No attempt is made to reverse LZMA1/2 preset.
if (optmap[i].type == OPTMAP_TYPE_LZMA_PRESET)
continue;
// All options have integer values, some just are mapped
// to a string with a name_value_map. LZMA1/2 preset
// isn't reversed back to preset=PRESET form.
uint32_t v;
const void *ptr
= (const char *)filter_options + optmap[i].offset;
switch (optmap[i].type) {
case OPTMAP_TYPE_LZMA_MODE:
v = *(const lzma_mode *)ptr;
break;
case OPTMAP_TYPE_LZMA_MATCH_FINDER:
v = *(const lzma_match_finder *)ptr;
break;
default:
v = *(const uint32_t *)ptr;
break;
}
// Skip this if this option should be omitted from
// the string when the value is zero.
if (v == 0 && (optmap[i].flags & OPTMAP_NO_STRFY_ZERO))
continue;
// Before the first option we add whatever delimiter
// the caller gave us. For later options a comma is used.
str_append_str(dest, delimiter);
delimiter = ",";
// Add the option name and equals sign.
str_append_str(dest, optmap[i].name);
str_append_str(dest, "=");
if (optmap[i].flags & OPTMAP_USE_NAME_VALUE_MAP) {
const name_value_map *map = optmap[i].u.map;
size_t j = 0;
while (true) {
if (map[j].name[0] == '\0') {
str_append_str(dest, "UNKNOWN");
break;
}
if (map[j].value == v) {
str_append_str(dest, map[j].name);
break;
}
++j;
}
} else {
str_append_u32(dest, v,
optmap[i].flags & OPTMAP_USE_BYTE_SUFFIX);
}
}
return;
}
extern LZMA_API(lzma_ret)
lzma_str_from_filters(char **output_str, const lzma_filter *filters,
uint32_t flags, const lzma_allocator *allocator)
{
// On error *output_str is always set to NULL.
// Do it as the very first step.
if (output_str == NULL)
return LZMA_PROG_ERROR;
*output_str = NULL;
if (filters == NULL)
return LZMA_PROG_ERROR;
// Validate the flags.
const uint32_t supported_flags
= LZMA_STR_ENCODER
| LZMA_STR_DECODER
| LZMA_STR_GETOPT_LONG
| LZMA_STR_NO_SPACES;
if (flags & ~supported_flags)
return LZMA_OPTIONS_ERROR;
// There must be at least one filter.
if (filters[0].id == LZMA_VLI_UNKNOWN)
return LZMA_OPTIONS_ERROR;
// Allocate memory for the output string.
lzma_str dest;
return_if_error(str_init(&dest, allocator));
const bool show_opts = (flags & (LZMA_STR_ENCODER | LZMA_STR_DECODER));
const char *opt_delim = (flags & LZMA_STR_GETOPT_LONG) ? "=" : ":";
for (size_t i = 0; filters[i].id != LZMA_VLI_UNKNOWN; ++i) {
// If we reach LZMA_FILTERS_MAX, then the filters array
// is too large since the ID cannot be LZMA_VLI_UNKNOWN here.
if (i == LZMA_FILTERS_MAX) {
str_free(&dest, allocator);
return LZMA_OPTIONS_ERROR;
}
// Don't add a space between filters if the caller
// doesn't want them.
if (i > 0 && !(flags & LZMA_STR_NO_SPACES))
str_append_str(&dest, " ");
// Use dashes for xz getopt_long() compatible syntax but also
// use dashes to separate filters when spaces weren't wanted.
if ((flags & LZMA_STR_GETOPT_LONG)
|| (i > 0 && (flags & LZMA_STR_NO_SPACES)))
str_append_str(&dest, "--");
size_t j = 0;
while (true) {
if (j == ARRAY_SIZE(filter_name_map)) {
// Filter ID in filters[i].id isn't supported.
str_free(&dest, allocator);
return LZMA_OPTIONS_ERROR;
}
if (filter_name_map[j].id == filters[i].id) {
// Add the filter name.
str_append_str(&dest, filter_name_map[j].name);
// If only the filter names were wanted then
// skip to the next filter. In this case
// .options is ignored and may be NULL even
// when the filter doesn't allow NULL options.
if (!show_opts)
break;
if (filters[i].options == NULL) {
if (!filter_name_map[j].allow_null) {
// Filter-specific options
// are missing but with
// this filter the options
// structure is mandatory.
str_free(&dest, allocator);
return LZMA_OPTIONS_ERROR;
}
// .options is allowed to be NULL.
// There is no need to add any
// options to the string.
break;
}
// Options structure is available. Add
// the filter options to the string.
const size_t optmap_count
= (flags & LZMA_STR_ENCODER)
? filter_name_map[j].strfy_encoder
: filter_name_map[j].strfy_decoder;
strfy_filter(&dest, opt_delim,
filter_name_map[j].optmap,
optmap_count,
filters[i].options);
break;
}
++j;
}
}
return str_finish(output_str, &dest, allocator);
}
extern LZMA_API(lzma_ret)
lzma_str_list_filters(char **output_str, lzma_vli filter_id, uint32_t flags,
const lzma_allocator *allocator)
{
// On error *output_str is always set to NULL.
// Do it as the very first step.
if (output_str == NULL)
return LZMA_PROG_ERROR;
*output_str = NULL;
// Validate the flags.
const uint32_t supported_flags
= LZMA_STR_ALL_FILTERS
| LZMA_STR_ENCODER
| LZMA_STR_DECODER
| LZMA_STR_GETOPT_LONG;
if (flags & ~supported_flags)
return LZMA_OPTIONS_ERROR;
// Allocate memory for the output string.
lzma_str dest;
return_if_error(str_init(&dest, allocator));
// If only listing the filter names then separate them with spaces.
// Otherwise use newlines.
const bool show_opts = (flags & (LZMA_STR_ENCODER | LZMA_STR_DECODER));
const char *filter_delim = show_opts ? "\n" : " ";
const char *opt_delim = (flags & LZMA_STR_GETOPT_LONG) ? "=" : ":";
bool first_filter_printed = false;
for (size_t i = 0; i < ARRAY_SIZE(filter_name_map); ++i) {
// If we are printing only one filter then skip others.
if (filter_id != LZMA_VLI_UNKNOWN
&& filter_id != filter_name_map[i].id)
continue;
// If we are printing only .xz filters then skip the others.
if (filter_name_map[i].id >= LZMA_FILTER_RESERVED_START
&& (flags & LZMA_STR_ALL_FILTERS) == 0
&& filter_id == LZMA_VLI_UNKNOWN)
continue;
// Add a new line if this isn't the first filter being
// written to the string.
if (first_filter_printed)
str_append_str(&dest, filter_delim);
first_filter_printed = true;
if (flags & LZMA_STR_GETOPT_LONG)
str_append_str(&dest, "--");
str_append_str(&dest, filter_name_map[i].name);
// If only the filter names were wanted then continue
// to the next filter.
if (!show_opts)
continue;
const option_map *optmap = filter_name_map[i].optmap;
const char *d = opt_delim;
const size_t end = (flags & LZMA_STR_ENCODER)
? filter_name_map[i].strfy_encoder
: filter_name_map[i].strfy_decoder;
for (size_t j = 0; j < end; ++j) {
// The first option is delimited from the filter
// name using "=" or ":" and the rest of the options
// are separated with ",".
str_append_str(&dest, d);
d = ",";
// optname=<possible_values>
str_append_str(&dest, optmap[j].name);
str_append_str(&dest, "=<");
if (optmap[j].type == OPTMAP_TYPE_LZMA_PRESET) {
// LZMA1/2 preset has its custom help string.
str_append_str(&dest, LZMA12_PRESET_STR);
} else if (optmap[j].flags
& OPTMAP_USE_NAME_VALUE_MAP) {
// Separate the possible option values by "|".
const name_value_map *m = optmap[j].u.map;
for (size_t k = 0; m[k].name[0] != '\0'; ++k) {
if (k > 0)
str_append_str(&dest, "|");
str_append_str(&dest, m[k].name);
}
} else {
// Integer range is shown as min-max.
const bool use_byte_suffix = optmap[j].flags
& OPTMAP_USE_BYTE_SUFFIX;
str_append_u32(&dest, optmap[j].u.range.min,
use_byte_suffix);
str_append_str(&dest, "-");
str_append_u32(&dest, optmap[j].u.range.max,
use_byte_suffix);
}
str_append_str(&dest, ">");
}
}
// If no filters were added to the string then it must be because
// the caller provided an unsupported Filter ID.
if (!first_filter_printed) {
str_free(&dest, allocator);
return LZMA_OPTIONS_ERROR;
}
return str_finish(output_str, &dest, allocator);
}