// SPDX-License-Identifier: 0BSD /////////////////////////////////////////////////////////////////////////////// // /// \file lzma_decoder.c /// \brief LZMA decoder /// // Authors: Igor Pavlov // Lasse Collin // Jia Tan // /////////////////////////////////////////////////////////////////////////////// #include "lz_decoder.h" #include "lzma_common.h" #include "lzma_decoder.h" #include "range_decoder.h" // The macros unroll loops with switch statements. // Silence warnings about missing fall-through comments. #if TUKLIB_GNUC_REQ(7, 0) # pragma GCC diagnostic ignored "-Wimplicit-fallthrough" #endif // Minimum number of input bytes to safely decode one LZMA symbol. // The worst case is that we decode 22 bits using probabilities and 26 // direct bits. This may decode at maximum 20 bytes of input. #define LZMA_IN_REQUIRED 20 // Macros for (somewhat) size-optimized code. // This is used to decode the match length (how many bytes must be repeated // from the dictionary). This version is used in the Resumable mode and // does not unroll any loops. #define len_decode(target, ld, pos_state, seq) \ do { \ case seq ## _CHOICE: \ rc_if_0_safe(ld.choice, seq ## _CHOICE) { \ rc_update_0(ld.choice); \ probs = ld.low[pos_state];\ limit = LEN_LOW_SYMBOLS; \ target = MATCH_LEN_MIN; \ } else { \ rc_update_1(ld.choice); \ case seq ## _CHOICE2: \ rc_if_0_safe(ld.choice2, seq ## _CHOICE2) { \ rc_update_0(ld.choice2); \ probs = ld.mid[pos_state]; \ limit = LEN_MID_SYMBOLS; \ target = MATCH_LEN_MIN + LEN_LOW_SYMBOLS; \ } else { \ rc_update_1(ld.choice2); \ probs = ld.high; \ limit = LEN_HIGH_SYMBOLS; \ target = MATCH_LEN_MIN + LEN_LOW_SYMBOLS \ + LEN_MID_SYMBOLS; \ } \ } \ symbol = 1; \ case seq ## _BITTREE: \ do { \ rc_bit_safe(probs[symbol], , , seq ## _BITTREE); \ } while (symbol < limit); \ target += symbol - limit; \ } while (0) // This is the faster version of the match length decoder that does not // worry about being resumable. It unrolls the bittree decoding loop. #define len_decode_fast(target, ld, pos_state) \ do { \ symbol = 1; \ rc_if_0(ld.choice) { \ rc_update_0(ld.choice); \ rc_bittree3(ld.low[pos_state], \ -LEN_LOW_SYMBOLS + MATCH_LEN_MIN); \ target = symbol; \ } else { \ rc_update_1(ld.choice); \ rc_if_0(ld.choice2) { \ rc_update_0(ld.choice2); \ rc_bittree3(ld.mid[pos_state], -LEN_MID_SYMBOLS \ + MATCH_LEN_MIN + LEN_LOW_SYMBOLS); \ target = symbol; \ } else { \ rc_update_1(ld.choice2); \ rc_bittree8(ld.high, -LEN_HIGH_SYMBOLS \ + MATCH_LEN_MIN \ + LEN_LOW_SYMBOLS + LEN_MID_SYMBOLS); \ target = symbol; \ } \ } \ } while (0) /// Length decoder probabilities; see comments in lzma_common.h. typedef struct { probability choice; probability choice2; probability low[POS_STATES_MAX][LEN_LOW_SYMBOLS]; probability mid[POS_STATES_MAX][LEN_MID_SYMBOLS]; probability high[LEN_HIGH_SYMBOLS]; } lzma_length_decoder; typedef struct { /////////////////// // Probabilities // /////////////////// /// Literals; see comments in lzma_common.h. probability literal[LITERAL_CODERS_MAX][LITERAL_CODER_SIZE]; /// If 1, it's a match. Otherwise it's a single 8-bit literal. probability is_match[STATES][POS_STATES_MAX]; /// If 1, it's a repeated match. The distance is one of rep0 .. rep3. probability is_rep[STATES]; /// If 0, distance of a repeated match is rep0. /// Otherwise check is_rep1. probability is_rep0[STATES]; /// If 0, distance of a repeated match is rep1. /// Otherwise check is_rep2. probability is_rep1[STATES]; /// If 0, distance of a repeated match is rep2. Otherwise it is rep3. probability is_rep2[STATES]; /// If 1, the repeated match has length of one byte. Otherwise /// the length is decoded from rep_len_decoder. probability is_rep0_long[STATES][POS_STATES_MAX]; /// Probability tree for the highest two bits of the match distance. /// There is a separate probability tree for match lengths of /// 2 (i.e. MATCH_LEN_MIN), 3, 4, and [5, 273]. probability dist_slot[DIST_STATES][DIST_SLOTS]; /// Probability trees for additional bits for match distance when the /// distance is in the range [4, 127]. probability pos_special[FULL_DISTANCES - DIST_MODEL_END]; /// Probability tree for the lowest four bits of a match distance /// that is equal to or greater than 128. probability pos_align[ALIGN_SIZE]; /// Length of a normal match lzma_length_decoder match_len_decoder; /// Length of a repeated match lzma_length_decoder rep_len_decoder; /////////////////// // Decoder state // /////////////////// // Range coder lzma_range_decoder rc; // Types of the most recently seen LZMA symbols lzma_lzma_state state; uint32_t rep0; ///< Distance of the latest match uint32_t rep1; ///< Distance of second latest match uint32_t rep2; ///< Distance of third latest match uint32_t rep3; ///< Distance of fourth latest match uint32_t pos_mask; // (1U << pb) - 1 uint32_t literal_context_bits; uint32_t literal_pos_mask; /// Uncompressed size as bytes, or LZMA_VLI_UNKNOWN if end of /// payload marker is expected. lzma_vli uncompressed_size; /// True if end of payload marker (EOPM) is allowed even when /// uncompressed_size is known; false if EOPM must not be present. /// This is ignored if uncompressed_size == LZMA_VLI_UNKNOWN. bool allow_eopm; //////////////////////////////// // State of incomplete symbol // //////////////////////////////// /// Position where to continue the decoder loop enum { SEQ_NORMALIZE, SEQ_IS_MATCH, SEQ_LITERAL, SEQ_LITERAL_MATCHED, SEQ_LITERAL_WRITE, SEQ_IS_REP, SEQ_MATCH_LEN_CHOICE, SEQ_MATCH_LEN_CHOICE2, SEQ_MATCH_LEN_BITTREE, SEQ_DIST_SLOT, SEQ_DIST_MODEL, SEQ_DIRECT, SEQ_ALIGN, SEQ_EOPM, SEQ_IS_REP0, SEQ_SHORTREP, SEQ_IS_REP0_LONG, SEQ_IS_REP1, SEQ_IS_REP2, SEQ_REP_LEN_CHOICE, SEQ_REP_LEN_CHOICE2, SEQ_REP_LEN_BITTREE, SEQ_COPY, } sequence; /// Base of the current probability tree probability *probs; /// Symbol being decoded. This is also used as an index variable in /// bittree decoders: probs[symbol] uint32_t symbol; /// Used as a loop termination condition on bittree decoders and /// direct bits decoder. uint32_t limit; /// Matched literal decoder: 0x100 or 0 to help avoiding branches. /// Bittree reverse decoders: Offset of the next bit: 1 << offset uint32_t offset; /// If decoding a literal: match byte. /// If decoding a match: length of the match. uint32_t len; } lzma_lzma1_decoder; static lzma_ret lzma_decode(void *coder_ptr, lzma_dict *restrict dictptr, const uint8_t *restrict in, size_t *restrict in_pos, size_t in_size) { lzma_lzma1_decoder *restrict coder = coder_ptr; //////////////////// // Initialization // //////////////////// { const lzma_ret ret = rc_read_init( &coder->rc, in, in_pos, in_size); if (ret != LZMA_STREAM_END) return ret; } /////////////// // Variables // /////////////// // Making local copies of often-used variables improves both // speed and readability. lzma_dict dict = *dictptr; const size_t dict_start = dict.pos; // Range decoder rc_to_local(coder->rc, *in_pos); // State uint32_t state = coder->state; uint32_t rep0 = coder->rep0; uint32_t rep1 = coder->rep1; uint32_t rep2 = coder->rep2; uint32_t rep3 = coder->rep3; const uint32_t pos_mask = coder->pos_mask; // These variables are actually needed only if we last time ran // out of input in the middle of the decoder loop. probability *probs = coder->probs; uint32_t symbol = coder->symbol; uint32_t limit = coder->limit; uint32_t offset = coder->offset; uint32_t len = coder->len; const uint32_t literal_pos_mask = coder->literal_pos_mask; const uint32_t literal_context_bits = coder->literal_context_bits; // Temporary variables uint32_t pos_state = dict.pos & pos_mask; lzma_ret ret = LZMA_OK; // This is true when the next LZMA symbol is allowed to be EOPM. // That is, if this is false, then EOPM is considered // an invalid symbol and we will return LZMA_DATA_ERROR. // // EOPM is always required (not just allowed) when // the uncompressed size isn't known. When uncompressed size // is known, eopm_is_valid may be set to true later. bool eopm_is_valid = coder->uncompressed_size == LZMA_VLI_UNKNOWN; // If uncompressed size is known and there is enough output space // to decode all the data, limit the available buffer space so that // the main loop won't try to decode past the end of the stream. bool might_finish_without_eopm = false; if (coder->uncompressed_size != LZMA_VLI_UNKNOWN && coder->uncompressed_size <= dict.limit - dict.pos) { dict.limit = dict.pos + (size_t)(coder->uncompressed_size); might_finish_without_eopm = true; } // The main decoder loop. The "switch" is used to resume the decoder at // correct location. Once resumed, the "switch" is no longer used. // The decoder loops is split into two modes: // // 1 - Non-resumable mode (fast). This is used when it is guaranteed // there is enough input to decode the next symbol. If the output // limit is reached, then the decoder loop will save the place // for the resumable mode to continue. This mode is not used if // HAVE_SMALL is defined. This is faster than Resumable mode // because it reduces the number of branches needed and allows // for more compiler optimizations. // // 2 - Resumable mode (slow). This is used when a previous decoder // loop did not have enough space in the input or output buffers // to complete. It uses sequence enum values to set remind // coder->sequence where to resume in the decoder loop. This // is the only mode used when HAVE_SMALL is defined. switch (coder->sequence) while (true) { // Calculate new pos_state. This is skipped on the first loop // since we already calculated it when setting up the local // variables. pos_state = dict.pos & pos_mask; #ifndef HAVE_SMALL /////////////////////////////// // Non-resumable Mode (fast) // /////////////////////////////// // If there is not enough room for another LZMA symbol // go to Resumable mode. if (unlikely(rc_in_end - rc_in_ptr < LZMA_IN_REQUIRED || dict.pos == dict.limit)) goto slow; // Decode the first bit from the next LZMA symbol. // If the bit is a 0, then we handle it as a literal. // If the bit is a 1, then it is a match of previously // decoded data. rc_if_0(coder->is_match[state][pos_state]) { ///////////////////// // Decode literal. // ///////////////////// // Update the RC that we have decoded a 0. rc_update_0(coder->is_match[state][pos_state]); // Get the correct probability array from lp and // lc params. probs = literal_subcoder(coder->literal, literal_context_bits, literal_pos_mask, dict.pos, dict_get0(&dict)); if (is_literal_state(state)) { update_literal_normal(state); // Decode literal without match byte. rc_bittree8(probs, 0); } else { update_literal_matched(state); // Decode literal with match byte. rc_matched_literal(probs, dict_get(&dict, rep0)); } // Write decoded literal to dictionary dict_put(&dict, symbol); continue; } /////////////////// // Decode match. // /////////////////// // Instead of a new byte we are going to decode a // distance-length pair. The distance represents how far // back in the dictionary to begin copying. The length // represents how many bytes to copy. rc_update_1(coder->is_match[state][pos_state]); rc_if_0(coder->is_rep[state]) { /////////////////// // Simple match. // /////////////////// // Not a repeated match. In this case, // the length (how many bytes to copy) must be // decoded first. Then, the distance (where to // start copying) is decoded. // // This is also how we know when we are done // decoding. If the distance decodes to UINT32_MAX, // then we know to stop decoding (end of payload // marker). rc_update_0(coder->is_rep[state]); update_match(state); // The latest three match distances are kept in // memory in case there are repeated matches. rep3 = rep2; rep2 = rep1; rep1 = rep0; // Decode the length of the match. len_decode_fast(len, coder->match_len_decoder, pos_state); // Next, decode the distance into rep0. // The next 6 bits determine how to decode the // rest of the distance. probs = coder->dist_slot[get_dist_state(len)]; rc_bittree6(probs, -DIST_SLOTS); assert(symbol <= 63); if (symbol < DIST_MODEL_START) { // If the decoded symbol is < DIST_MODEL_START // then we use its value directly as the // match distance. No other bits are needed. // The only possible distance values // are [0, 3]. rep0 = symbol; } else { // Use the first two bits of symbol as the // highest bits of the match distance. // "limit" represents the number of low bits // to decode. limit = (symbol >> 1) - 1; assert(limit >= 1 && limit <= 30); rep0 = 2 + (symbol & 1); if (symbol < DIST_MODEL_END) { // When symbol is > DIST_MODEL_START, // but symbol < DIST_MODEL_END, then // it can decode distances between // [4, 127]. assert(limit <= 5); rep0 <<= limit; assert(rep0 <= 96); // -1 is fine, because we start // decoding at probs[1], not probs[0]. // NOTE: This violates the C standard, // since we are doing pointer // arithmetic past the beginning of // the array. assert((int32_t)(rep0 - symbol - 1) >= -1); assert((int32_t)(rep0 - symbol - 1) <= 82); probs = coder->pos_special + rep0 - symbol - 1; symbol = 1; offset = 1; // Variable number (1-5) of bits // from a reverse bittree. This // isn't worth manual unrolling. do { rc_bit_add_if_1(probs, rep0, offset); offset <<= 1; } while (--limit > 0); } else { // The distance is >= 128. Decode the // lower bits without probabilities // except the lowest four bits. assert(symbol >= 14); assert(limit >= 6); limit -= ALIGN_BITS; assert(limit >= 2); rc_direct(rep0, limit); // Decode the lowest four bits using // probabilities. rep0 <<= ALIGN_BITS; rc_bittree_rev4(coder->pos_align); rep0 += symbol; // If the end of payload marker (EOPM) // is detected, jump to the safe code. // The EOPM handling isn't speed // critical at all. // // A final normalization is needed // after the EOPM (there can be a // dummy byte to read in some cases). // If the normalization was done here // in the fast code, it would need to // be taken into account in the value // of LZMA_IN_REQUIRED. Using the // safe code allows keeping // LZMA_IN_REQUIRED as 20 instead of // 21. if (rep0 == UINT32_MAX) goto eopm; } } // Validate the distance we just decoded. if (unlikely(!dict_is_distance_valid(&dict, rep0))) { ret = LZMA_DATA_ERROR; goto out; } } else { rc_update_1(coder->is_rep[state]); ///////////////////// // Repeated match. // ///////////////////// // The match distance is a value that we have decoded // recently. The latest four match distances are // available as rep0, rep1, rep2 and rep3. We will // now decode which of them is the new distance. // // There cannot be a match if we haven't produced // any output, so check that first. if (unlikely(!dict_is_distance_valid(&dict, 0))) { ret = LZMA_DATA_ERROR; goto out; } rc_if_0(coder->is_rep0[state]) { rc_update_0(coder->is_rep0[state]); // The distance is rep0. // Decode the next bit to determine if 1 byte // should be copied from rep0 distance or // if the number of bytes needs to be decoded. // If the next bit is 0, then it is a // "Short Rep Match" and only 1 bit is copied. // Otherwise, the length of the match is // decoded after the "else" statement. rc_if_0(coder->is_rep0_long[state][pos_state]) { rc_update_0(coder->is_rep0_long[ state][pos_state]); update_short_rep(state); dict_put(&dict, dict_get(&dict, rep0)); continue; } // Repeating more than one byte at // distance of rep0. rc_update_1(coder->is_rep0_long[ state][pos_state]); } else { rc_update_1(coder->is_rep0[state]); // The distance is rep1, rep2 or rep3. Once // we find out which one of these three, it // is stored to rep0 and rep1, rep2 and rep3 // are updated accordingly. There is no // "Short Rep Match" option, so the length // of the match must always be decoded next. rc_if_0(coder->is_rep1[state]) { // The distance is rep1. rc_update_0(coder->is_rep1[state]); const uint32_t distance = rep1; rep1 = rep0; rep0 = distance; } else { rc_update_1(coder->is_rep1[state]); rc_if_0(coder->is_rep2[state]) { // The distance is rep2. rc_update_0(coder->is_rep2[ state]); const uint32_t distance = rep2; rep2 = rep1; rep1 = rep0; rep0 = distance; } else { // The distance is rep3. rc_update_1(coder->is_rep2[ state]); const uint32_t distance = rep3; rep3 = rep2; rep2 = rep1; rep1 = rep0; rep0 = distance; } } } update_long_rep(state); // Decode the length of the repeated match. len_decode_fast(len, coder->rep_len_decoder, pos_state); } ///////////////////////////////// // Repeat from history buffer. // ///////////////////////////////// // The length is always between these limits. There is no way // to trigger the algorithm to set len outside this range. assert(len >= MATCH_LEN_MIN); assert(len <= MATCH_LEN_MAX); // Repeat len bytes from distance of rep0. if (unlikely(dict_repeat(&dict, rep0, &len))) { coder->sequence = SEQ_COPY; goto out; } continue; slow: #endif /////////////////////////// // Resumable Mode (slow) // /////////////////////////// // This is very similar to Non-resumable Mode, so most of the // comments are not repeated. The main differences are: // - case labels are used to resume at the correct location. // - Loops are not unrolled. // - Range coder macros take an extra sequence argument // so they can save to coder->sequence the location to // resume in case there is not enough input. case SEQ_NORMALIZE: case SEQ_IS_MATCH: if (unlikely(might_finish_without_eopm && dict.pos == dict.limit)) { // In rare cases there is a useless byte that needs // to be read anyway. rc_normalize_safe(SEQ_NORMALIZE); // If the range decoder state is such that we can // be at the end of the LZMA stream, then the // decoding is finished. if (rc_is_finished(rc)) { ret = LZMA_STREAM_END; goto out; } // If the caller hasn't allowed EOPM to be present // together with known uncompressed size, then the // LZMA stream is corrupt. if (!coder->allow_eopm) { ret = LZMA_DATA_ERROR; goto out; } // Otherwise continue decoding with the expectation // that the next LZMA symbol is EOPM. eopm_is_valid = true; } rc_if_0_safe(coder->is_match[state][pos_state], SEQ_IS_MATCH) { ///////////////////// // Decode literal. // ///////////////////// rc_update_0(coder->is_match[state][pos_state]); probs = literal_subcoder(coder->literal, literal_context_bits, literal_pos_mask, dict.pos, dict_get0(&dict)); symbol = 1; if (is_literal_state(state)) { update_literal_normal(state); // Decode literal without match byte. // The "slow" version does not unroll // the loop. case SEQ_LITERAL: do { rc_bit_safe(probs[symbol], , , SEQ_LITERAL); } while (symbol < (1 << 8)); } else { update_literal_matched(state); // Decode literal with match byte. len = (uint32_t)(dict_get(&dict, rep0)) << 1; offset = 0x100; case SEQ_LITERAL_MATCHED: do { const uint32_t match_bit = len & offset; const uint32_t subcoder_index = offset + match_bit + symbol; rc_bit_safe(probs[subcoder_index], offset &= ~match_bit, offset &= match_bit, SEQ_LITERAL_MATCHED); // It seems to be faster to do this // here instead of putting it to the // beginning of the loop and then // putting the "case" in the middle // of the loop. len <<= 1; } while (symbol < (1 << 8)); } case SEQ_LITERAL_WRITE: if (dict_put_safe(&dict, symbol)) { coder->sequence = SEQ_LITERAL_WRITE; goto out; } continue; } /////////////////// // Decode match. // /////////////////// rc_update_1(coder->is_match[state][pos_state]); case SEQ_IS_REP: rc_if_0_safe(coder->is_rep[state], SEQ_IS_REP) { /////////////////// // Simple match. // /////////////////// rc_update_0(coder->is_rep[state]); update_match(state); rep3 = rep2; rep2 = rep1; rep1 = rep0; len_decode(len, coder->match_len_decoder, pos_state, SEQ_MATCH_LEN); probs = coder->dist_slot[get_dist_state(len)]; symbol = 1; case SEQ_DIST_SLOT: do { rc_bit_safe(probs[symbol], , , SEQ_DIST_SLOT); } while (symbol < DIST_SLOTS); symbol -= DIST_SLOTS; assert(symbol <= 63); if (symbol < DIST_MODEL_START) { rep0 = symbol; } else { limit = (symbol >> 1) - 1; assert(limit >= 1 && limit <= 30); rep0 = 2 + (symbol & 1); if (symbol < DIST_MODEL_END) { assert(limit <= 5); rep0 <<= limit; assert(rep0 <= 96); // -1 is fine, because we start // decoding at probs[1], not probs[0]. // NOTE: This violates the C standard, // since we are doing pointer // arithmetic past the beginning of // the array. assert((int32_t)(rep0 - symbol - 1) >= -1); assert((int32_t)(rep0 - symbol - 1) <= 82); probs = coder->pos_special + rep0 - symbol - 1; symbol = 1; offset = 0; case SEQ_DIST_MODEL: do { rc_bit_safe(probs[symbol], , rep0 += 1U << offset, SEQ_DIST_MODEL); } while (++offset < limit); } else { assert(symbol >= 14); assert(limit >= 6); limit -= ALIGN_BITS; assert(limit >= 2); case SEQ_DIRECT: rc_direct_safe(rep0, limit, SEQ_DIRECT); rep0 <<= ALIGN_BITS; symbol = 0; offset = 1; case SEQ_ALIGN: do { rc_bit_last_safe( coder->pos_align[ offset + symbol], , symbol += offset, SEQ_ALIGN); offset <<= 1; } while (offset < ALIGN_SIZE); rep0 += symbol; if (rep0 == UINT32_MAX) { // End of payload marker was // found. It may only be // present if // - uncompressed size is // unknown or // - after known uncompressed // size amount of bytes has // been decompressed and // caller has indicated // that EOPM might be used // (it's not allowed in // LZMA2). eopm: if (!eopm_is_valid) { ret = LZMA_DATA_ERROR; goto out; } case SEQ_EOPM: // LZMA1 stream with // end-of-payload marker. rc_normalize_safe(SEQ_EOPM); ret = rc_is_finished(rc) ? LZMA_STREAM_END : LZMA_DATA_ERROR; goto out; } } } if (unlikely(!dict_is_distance_valid(&dict, rep0))) { ret = LZMA_DATA_ERROR; goto out; } } else { ///////////////////// // Repeated match. // ///////////////////// rc_update_1(coder->is_rep[state]); if (unlikely(!dict_is_distance_valid(&dict, 0))) { ret = LZMA_DATA_ERROR; goto out; } case SEQ_IS_REP0: rc_if_0_safe(coder->is_rep0[state], SEQ_IS_REP0) { rc_update_0(coder->is_rep0[state]); case SEQ_IS_REP0_LONG: rc_if_0_safe(coder->is_rep0_long [state][pos_state], SEQ_IS_REP0_LONG) { rc_update_0(coder->is_rep0_long[ state][pos_state]); update_short_rep(state); case SEQ_SHORTREP: if (dict_put_safe(&dict, dict_get(&dict, rep0))) { coder->sequence = SEQ_SHORTREP; goto out; } continue; } rc_update_1(coder->is_rep0_long[ state][pos_state]); } else { rc_update_1(coder->is_rep0[state]); case SEQ_IS_REP1: rc_if_0_safe(coder->is_rep1[state], SEQ_IS_REP1) { rc_update_0(coder->is_rep1[state]); const uint32_t distance = rep1; rep1 = rep0; rep0 = distance; } else { rc_update_1(coder->is_rep1[state]); case SEQ_IS_REP2: rc_if_0_safe(coder->is_rep2[state], SEQ_IS_REP2) { rc_update_0(coder->is_rep2[ state]); const uint32_t distance = rep2; rep2 = rep1; rep1 = rep0; rep0 = distance; } else { rc_update_1(coder->is_rep2[ state]); const uint32_t distance = rep3; rep3 = rep2; rep2 = rep1; rep1 = rep0; rep0 = distance; } } } update_long_rep(state); len_decode(len, coder->rep_len_decoder, pos_state, SEQ_REP_LEN); } ///////////////////////////////// // Repeat from history buffer. // ///////////////////////////////// assert(len >= MATCH_LEN_MIN); assert(len <= MATCH_LEN_MAX); case SEQ_COPY: if (unlikely(dict_repeat(&dict, rep0, &len))) { coder->sequence = SEQ_COPY; goto out; } } out: // Save state // NOTE: Must not copy dict.limit. dictptr->pos = dict.pos; dictptr->full = dict.full; rc_from_local(coder->rc, *in_pos); coder->state = state; coder->rep0 = rep0; coder->rep1 = rep1; coder->rep2 = rep2; coder->rep3 = rep3; coder->probs = probs; coder->symbol = symbol; coder->limit = limit; coder->offset = offset; coder->len = len; // Update the remaining amount of uncompressed data if uncompressed // size was known. if (coder->uncompressed_size != LZMA_VLI_UNKNOWN) { coder->uncompressed_size -= dict.pos - dict_start; // If we have gotten all the output but the decoder wants // to write more output, the file is corrupt. There are // three SEQ values where output is produced. if (coder->uncompressed_size == 0 && ret == LZMA_OK && (coder->sequence == SEQ_LITERAL_WRITE || coder->sequence == SEQ_SHORTREP || coder->sequence == SEQ_COPY)) ret = LZMA_DATA_ERROR; } if (ret == LZMA_STREAM_END) { // Reset the range decoder so that it is ready to reinitialize // for a new LZMA2 chunk. rc_reset(coder->rc); coder->sequence = SEQ_IS_MATCH; } return ret; } static void lzma_decoder_uncompressed(void *coder_ptr, lzma_vli uncompressed_size, bool allow_eopm) { lzma_lzma1_decoder *coder = coder_ptr; coder->uncompressed_size = uncompressed_size; coder->allow_eopm = allow_eopm; } static void lzma_decoder_reset(void *coder_ptr, const void *opt) { lzma_lzma1_decoder *coder = coder_ptr; const lzma_options_lzma *options = opt; // NOTE: We assume that lc/lp/pb are valid since they were // successfully decoded with lzma_lzma_decode_properties(). // Calculate pos_mask. We don't need pos_bits as is for anything. coder->pos_mask = (1U << options->pb) - 1; // Initialize the literal decoder. literal_init(coder->literal, options->lc, options->lp); coder->literal_context_bits = options->lc; coder->literal_pos_mask = (1U << options->lp) - 1; // State coder->state = STATE_LIT_LIT; coder->rep0 = 0; coder->rep1 = 0; coder->rep2 = 0; coder->rep3 = 0; coder->pos_mask = (1U << options->pb) - 1; // Range decoder rc_reset(coder->rc); // Bit and bittree decoders for (uint32_t i = 0; i < STATES; ++i) { for (uint32_t j = 0; j <= coder->pos_mask; ++j) { bit_reset(coder->is_match[i][j]); bit_reset(coder->is_rep0_long[i][j]); } bit_reset(coder->is_rep[i]); bit_reset(coder->is_rep0[i]); bit_reset(coder->is_rep1[i]); bit_reset(coder->is_rep2[i]); } for (uint32_t i = 0; i < DIST_STATES; ++i) bittree_reset(coder->dist_slot[i], DIST_SLOT_BITS); for (uint32_t i = 0; i < FULL_DISTANCES - DIST_MODEL_END; ++i) bit_reset(coder->pos_special[i]); bittree_reset(coder->pos_align, ALIGN_BITS); // Len decoders (also bit/bittree) const uint32_t num_pos_states = 1U << options->pb; bit_reset(coder->match_len_decoder.choice); bit_reset(coder->match_len_decoder.choice2); bit_reset(coder->rep_len_decoder.choice); bit_reset(coder->rep_len_decoder.choice2); for (uint32_t pos_state = 0; pos_state < num_pos_states; ++pos_state) { bittree_reset(coder->match_len_decoder.low[pos_state], LEN_LOW_BITS); bittree_reset(coder->match_len_decoder.mid[pos_state], LEN_MID_BITS); bittree_reset(coder->rep_len_decoder.low[pos_state], LEN_LOW_BITS); bittree_reset(coder->rep_len_decoder.mid[pos_state], LEN_MID_BITS); } bittree_reset(coder->match_len_decoder.high, LEN_HIGH_BITS); bittree_reset(coder->rep_len_decoder.high, LEN_HIGH_BITS); coder->sequence = SEQ_IS_MATCH; coder->probs = NULL; coder->symbol = 0; coder->limit = 0; coder->offset = 0; coder->len = 0; return; } extern lzma_ret lzma_lzma_decoder_create(lzma_lz_decoder *lz, const lzma_allocator *allocator, const lzma_options_lzma *options, lzma_lz_options *lz_options) { if (lz->coder == NULL) { lz->coder = lzma_alloc(sizeof(lzma_lzma1_decoder), allocator); if (lz->coder == NULL) return LZMA_MEM_ERROR; lz->code = &lzma_decode; lz->reset = &lzma_decoder_reset; lz->set_uncompressed = &lzma_decoder_uncompressed; } // All dictionary sizes are OK here. LZ decoder will take care of // the special cases. lz_options->dict_size = options->dict_size; lz_options->preset_dict = options->preset_dict; lz_options->preset_dict_size = options->preset_dict_size; return LZMA_OK; } /// Allocate and initialize LZMA decoder. This is used only via LZ /// initialization (lzma_lzma_decoder_init() passes function pointer to /// the LZ initialization). static lzma_ret lzma_decoder_init(lzma_lz_decoder *lz, const lzma_allocator *allocator, lzma_vli id, const void *options, lzma_lz_options *lz_options) { if (!is_lclppb_valid(options)) return LZMA_PROG_ERROR; lzma_vli uncomp_size = LZMA_VLI_UNKNOWN; bool allow_eopm = true; if (id == LZMA_FILTER_LZMA1EXT) { const lzma_options_lzma *opt = options; // Only one flag is supported. if (opt->ext_flags & ~LZMA_LZMA1EXT_ALLOW_EOPM) return LZMA_OPTIONS_ERROR; // FIXME? Using lzma_vli instead of uint64_t is weird because // this has nothing to do with .xz headers and variable-length // integer encoding. On the other hand, using LZMA_VLI_UNKNOWN // instead of UINT64_MAX is clearer when unknown size is // meant. A problem with using lzma_vli is that now we // allow > LZMA_VLI_MAX which is fine in this file but // it's still confusing. Note that alone_decoder.c also // allows > LZMA_VLI_MAX when setting uncompressed size. uncomp_size = opt->ext_size_low + ((uint64_t)(opt->ext_size_high) << 32); allow_eopm = (opt->ext_flags & LZMA_LZMA1EXT_ALLOW_EOPM) != 0 || uncomp_size == LZMA_VLI_UNKNOWN; } return_if_error(lzma_lzma_decoder_create( lz, allocator, options, lz_options)); lzma_decoder_reset(lz->coder, options); lzma_decoder_uncompressed(lz->coder, uncomp_size, allow_eopm); return LZMA_OK; } extern lzma_ret lzma_lzma_decoder_init(lzma_next_coder *next, const lzma_allocator *allocator, const lzma_filter_info *filters) { // LZMA can only be the last filter in the chain. This is enforced // by the raw_decoder initialization. assert(filters[1].init == NULL); return lzma_lz_decoder_init(next, allocator, filters, &lzma_decoder_init); } extern bool lzma_lzma_lclppb_decode(lzma_options_lzma *options, uint8_t byte) { if (byte > (4 * 5 + 4) * 9 + 8) return true; // See the file format specification to understand this. options->pb = byte / (9 * 5); byte -= options->pb * 9 * 5; options->lp = byte / 9; options->lc = byte - options->lp * 9; return options->lc + options->lp > LZMA_LCLP_MAX; } extern uint64_t lzma_lzma_decoder_memusage_nocheck(const void *options) { const lzma_options_lzma *const opt = options; return sizeof(lzma_lzma1_decoder) + lzma_lz_decoder_memusage(opt->dict_size); } extern uint64_t lzma_lzma_decoder_memusage(const void *options) { if (!is_lclppb_valid(options)) return UINT64_MAX; return lzma_lzma_decoder_memusage_nocheck(options); } extern lzma_ret lzma_lzma_props_decode(void **options, const lzma_allocator *allocator, const uint8_t *props, size_t props_size) { if (props_size != 5) return LZMA_OPTIONS_ERROR; lzma_options_lzma *opt = lzma_alloc(sizeof(lzma_options_lzma), allocator); if (opt == NULL) return LZMA_MEM_ERROR; if (lzma_lzma_lclppb_decode(opt, props[0])) goto error; // All dictionary sizes are accepted, including zero. LZ decoder // will automatically use a dictionary at least a few KiB even if // a smaller dictionary is requested. opt->dict_size = read32le(props + 1); opt->preset_dict = NULL; opt->preset_dict_size = 0; *options = opt; return LZMA_OK; error: lzma_free(opt, allocator); return LZMA_OPTIONS_ERROR; }