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/*
* zlib-deflate-nostdlib
*
* Copyright 2021 Birte Kristina Friesel
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include "lib/inflate.h"
/*
* The compressed (inflated) input data.
*/
unsigned char const *deflate_input_now;
unsigned char const *deflate_input_end;
/*
* The decompressed (deflated) output stream.
*/
unsigned char *deflate_output_now;
unsigned char *deflate_output_end;
/*
* The current bit offset in the input stream, if any.
*
* Deflate streams are read from least to most significant bit.
* An offset of 1 indicates that the least significant bit is skipped
* (i.e., only bits 7, 6, 5, 4, 3, 2, and 1 are read).
*/
uint8_t deflate_bit_offset = 0;
/*
* Base lengths for length codes (code 257 to 285).
* Code 257 corresponds to a copy of 3 bytes, etc.
*/
uint16_t const deflate_length_offsets[] = {
3, 4, 5, 6, 7, 8, 9, 10, 11, 13, 15, 17, 19, 23, 27, 31, 35, 43, 51, 59,
67, 83, 99, 115, 131, 163, 195, 227, 258
};
/*
* Extra bits for length codes (code 257 to 285).
* Code 257 has no extra bits, code 265 has 1 extra bit
* (and indicates a length of 11 or 12 depending on its value), etc.
*/
uint8_t const deflate_length_bits[] = {
0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 4, 4, 4, 4,
5, 5, 5, 5, 0
};
// can also be expressed as (index < 4 || index == 28) ? 0 : (index-4) >> 2
/*
* Base distances for distance codes (code 0 to 29).
* Code 0 indicates a distance of 1, etc.
*/
uint16_t const deflate_distance_offsets[] = {
1, 2, 3, 4, 5, 7, 9, 13, 17, 25, 33, 49, 65, 97, 129, 193, 257, 385,
513, 769, 1025, 1537, 2049, 3073, 4097, 6145, 8193, 12289, 16385, 24577
};
/*
* Extra bits for distance codes (code 0 to 29).
* Code 0 has no extra bits, code 4 has 1 bit, etc.
*/
uint8_t const deflate_distance_bits[] = {
0, 0, 0, 0, 1, 1, 2, 2, 3, 3, 4, 4, 5, 5, 6, 6, 7, 7, 8, 8, 9, 9, 10,
10, 11, 11, 12, 12, 13, 13
};
// can also be expressed as index < 2 ? 0 : (index-2) >> 1
/*
* In block type 2 (dynamic huffman codes), the code lengths of literal/length
* and distance alphabet are themselves stored as huffman codes. To save space
* in case only a few code lengths are used, the code length codes are stored
* in the following order. This allows a few bits to be saved if some code
* lengths are unused and the unused code lengths are at the end of the list.
*/
uint8_t const deflate_hclen_index[] = {
16, 17, 18, 0, 8, 7, 9, 6, 10, 5, 11, 4, 12, 3, 13, 2, 14, 1, 15
};
/*
* Code lengths of the "code length" code (see above).
*/
uint8_t deflate_hc_lengths[19];
/*
* Code lengths of the literal/length and distance alphabets.
* up to 288 literal/length codes + up to 30 distance codes.
*/
uint8_t deflate_lld_lengths[318];
#ifdef DEFLATE_WITH_LUT
uint16_t deflate_ll_codes[288];
uint16_t deflate_d_codes[30];
#endif
/*
* Bit length counts and next code entries for Literal/Length alphabet.
* Combined with the code lengths in deflate_lld_lengths, these make up the
* Literal/Length alphabet. See the algorithm in RFC 1951 section 3.2.2 for
* details.
*
* Assumption: There are no more than 255 huffman codes with the same length.
* As the largest alphabet (the literal/length alphabet) contains just 288
* codes in total, this should be reasonable.
*
* These variables are also used for the huffman alphabet in dynamic huffman
* blocks.
*/
uint8_t deflate_bl_count_ll[16];
uint16_t deflate_next_code_ll[16];
/*
* Bit length counts and next code entries for Distance alphabet. Note that,
* even though there are just 30 different distance codes, individual
* codes may be up to 16 bits long.
*/
uint8_t deflate_bl_count_d[16];
uint16_t deflate_next_code_d[16];
static uint16_t deflate_rev_word(uint16_t word, uint8_t bits)
{
uint16_t ret = 0;
uint16_t mask = 1;
for (uint16_t rmask = 1 << (bits - 1); rmask > 0; rmask >>= 1) {
if (word & rmask) {
ret |= mask;
}
mask <<= 1;
}
return ret;
}
static uint16_t deflate_bitmask(uint8_t bit_count)
{
return (1 << bit_count) - 1;
}
static uint16_t deflate_get_word()
{
uint16_t ret = 0;
ret |= (deflate_input_now[0] >> deflate_bit_offset);
ret |= (uint16_t) deflate_input_now[1] << (8 - deflate_bit_offset);
if (deflate_bit_offset) {
ret |=
(uint16_t) (deflate_input_now[2] &
deflate_bitmask(deflate_bit_offset)) << (16 -
deflate_bit_offset);
}
return ret;
}
static uint16_t deflate_get_bits(uint8_t num_bits)
{
uint16_t ret = deflate_get_word();
deflate_bit_offset += num_bits;
while (deflate_bit_offset >= 8) {
deflate_input_now++;
deflate_bit_offset -= 8;
}
return ret & deflate_bitmask(num_bits);
}
#ifdef DEFLATE_WITH_LUT
static void deflate_build_alphabet(uint8_t * lengths, uint16_t size,
uint8_t * bl_count, uint16_t * next_code,
uint16_t * codes)
#else
static void deflate_build_alphabet(uint8_t * lengths, uint16_t size,
uint8_t * bl_count, uint16_t * next_code)
#endif
{
uint16_t i;
uint16_t code = 0;
uint16_t max_len = 0;
for (i = 0; i < 16; i++) {
bl_count[i] = 0;
}
for (i = 0; i < size; i++) {
if (lengths[i]) {
bl_count[lengths[i]]++;
}
if (lengths[i] > max_len) {
max_len = lengths[i];
}
}
for (i = 1; i <= max_len; i++) {
code = (code + bl_count[i - 1]) << 1;
next_code[i] = code;
}
#ifdef DEFLATE_WITH_LUT
uint8_t j = 0;
code = 0;
for (j = 1; j <= max_len; j++) {
for (i = 0; i < size; i++) {
if (lengths[i] == j) {
codes[code++] = i;
}
}
}
#endif
}
#ifdef DEFLATE_WITH_LUT
static uint16_t deflate_huff(uint16_t * codes,
uint8_t * bl_count, uint16_t * next_code)
#else
/*
* This function trades speed for low memory requirements. Instead of building
* an actual huffman tree (at a cost of about 650 Bytes of RAM), we iterate
* through the code lengths whenever we have found a huffman code. This is
* very slow, but memory-efficient.
*/
static uint16_t deflate_huff(uint8_t * lengths, uint16_t size,
uint8_t * bl_count, uint16_t * next_code)
#endif
{
uint16_t next_word = deflate_get_word();
#ifdef DEFLATE_WITH_LUT
uint16_t code = 0;
#endif
for (uint8_t num_bits = 1; num_bits < 16; num_bits++) {
uint16_t next_bits = deflate_rev_word(next_word, num_bits);
if (bl_count[num_bits] && next_bits >= next_code[num_bits]
&& next_bits < next_code[num_bits] + bl_count[num_bits]) {
deflate_bit_offset += num_bits;
while (deflate_bit_offset >= 8) {
deflate_input_now++;
deflate_bit_offset -= 8;
}
#ifdef DEFLATE_WITH_LUT
return codes[code + (next_bits - next_code[num_bits])];
#else
uint8_t len_pos = next_bits;
uint8_t cur_pos = next_code[num_bits];
for (uint16_t i = 0; i < size; i++) {
if (lengths[i] == num_bits) {
if (cur_pos == len_pos) {
return i;
}
cur_pos++;
}
}
#endif
} else {
#ifdef DEFLATE_WITH_LUT
code += bl_count[num_bits];
#endif
}
}
return 65535;
}
#ifdef DEFLATE_WITH_LUT
static int8_t deflate_huffman(uint16_t * ll_codes, uint16_t * d_codes)
#else
static int8_t deflate_huffman(uint8_t * ll_lengths, uint16_t ll_size,
uint8_t * d_lengths, uint8_t d_size)
#endif
{
uint16_t code;
uint16_t dcode;
while (1) {
#ifdef DEFLATE_WITH_LUT
code =
deflate_huff(ll_codes, deflate_bl_count_ll,
deflate_next_code_ll);
#else
code =
deflate_huff(ll_lengths, ll_size, deflate_bl_count_ll,
deflate_next_code_ll);
#endif
if (code < 256) {
if (deflate_output_now == deflate_output_end) {
return DEFLATE_ERR_OUTPUT_LENGTH;
}
*deflate_output_now = code;
deflate_output_now++;
} else if (code == 256) {
return 0;
} else if (code == 65535) {
return DEFLATE_ERR_HUFFMAN;
} else {
uint16_t len_val = deflate_length_offsets[code - 257];
uint8_t extra_bits = deflate_length_bits[code - 257];
if (extra_bits) {
len_val += deflate_get_bits(extra_bits);
}
#ifdef DEFLATE_WITH_LUT
dcode =
deflate_huff(d_codes,
deflate_bl_count_d,
deflate_next_code_d);
#else
dcode =
deflate_huff(d_lengths, d_size,
deflate_bl_count_d,
deflate_next_code_d);
#endif
uint16_t dist_val = deflate_distance_offsets[dcode];
extra_bits = deflate_distance_bits[dcode];
if (extra_bits) {
dist_val += deflate_get_bits(extra_bits);
}
while (len_val--) {
if (deflate_output_now == deflate_output_end) {
return DEFLATE_ERR_OUTPUT_LENGTH;
}
deflate_output_now[0] =
*(deflate_output_now - dist_val);
deflate_output_now++;
}
}
if (deflate_input_now >= deflate_input_end - 4) {
return DEFLATE_ERR_INPUT_LENGTH;
}
}
}
static int8_t deflate_uncompressed()
{
if (deflate_bit_offset) {
deflate_input_now++;
deflate_bit_offset = 0;
}
uint16_t len =
((uint16_t) deflate_input_now[1] << 8) + deflate_input_now[0];
uint16_t nlen =
((uint16_t) deflate_input_now[3] << 8) + deflate_input_now[2];
if (len & nlen) {
return DEFLATE_ERR_NLEN;
}
deflate_input_now += 4;
if (deflate_input_now + len >= deflate_input_end) {
return DEFLATE_ERR_INPUT_LENGTH;
}
if (deflate_output_now + len >= deflate_output_end) {
return DEFLATE_ERR_OUTPUT_LENGTH;
}
for (uint16_t i = 0; i < len; i++) {
*(deflate_output_now++) = *(deflate_input_now++);
}
return 0;
}
static int8_t deflate_static_huffman()
{
uint16_t i;
for (i = 0; i <= 143; i++) {
deflate_lld_lengths[i] = 8;
}
for (i = 144; i <= 255; i++) {
deflate_lld_lengths[i] = 9;
}
for (i = 256; i <= 279; i++) {
deflate_lld_lengths[i] = 7;
}
for (i = 280; i <= 287; i++) {
deflate_lld_lengths[i] = 8;
}
for (i = 288; i <= 288 + 29; i++) {
deflate_lld_lengths[i] = 5;
}
#ifdef DEFLATE_WITH_LUT
deflate_build_alphabet(deflate_lld_lengths, 288, deflate_bl_count_ll,
deflate_next_code_ll, deflate_ll_codes);
deflate_build_alphabet(deflate_lld_lengths + 288, 29,
deflate_bl_count_d, deflate_next_code_d,
deflate_d_codes);
return deflate_huffman(deflate_ll_codes, deflate_d_codes);
#else
deflate_build_alphabet(deflate_lld_lengths, 288, deflate_bl_count_ll,
deflate_next_code_ll);
deflate_build_alphabet(deflate_lld_lengths + 288, 29,
deflate_bl_count_d, deflate_next_code_d);
return deflate_huffman(deflate_lld_lengths, 288,
deflate_lld_lengths + 288, 29);
#endif
}
static int8_t deflate_dynamic_huffman()
{
uint16_t hlit = 257 + deflate_get_bits(5);
uint8_t hdist = 1 + deflate_get_bits(5);
uint8_t hclen = 4 + deflate_get_bits(4);
for (uint8_t i = 0; i < hclen; i++) {
deflate_hc_lengths[deflate_hclen_index[i]] =
deflate_get_bits(3);
}
for (uint8_t i = hclen; i < sizeof(deflate_hc_lengths); i++) {
deflate_hc_lengths[deflate_hclen_index[i]] = 0;
}
#ifdef DEFLATE_WITH_LUT
deflate_build_alphabet(deflate_hc_lengths,
sizeof(deflate_hc_lengths),
deflate_bl_count_ll, deflate_next_code_ll,
deflate_ll_codes);
#else
deflate_build_alphabet(deflate_hc_lengths,
sizeof(deflate_hc_lengths),
deflate_bl_count_ll, deflate_next_code_ll);
#endif
uint16_t items_processed = 0;
while (items_processed < hlit + hdist) {
#ifdef DEFLATE_WITH_LUT
uint8_t code = deflate_huff(deflate_ll_codes,
deflate_bl_count_ll,
deflate_next_code_ll);
#else
uint8_t code =
deflate_huff(deflate_hc_lengths, sizeof(deflate_hc_lengths),
deflate_bl_count_ll,
deflate_next_code_ll);
#endif
if (code == 16) {
uint8_t copy_count = 3 + deflate_get_bits(2);
for (uint8_t i = 0; i < copy_count; i++) {
deflate_lld_lengths[items_processed] =
deflate_lld_lengths[items_processed - 1];
items_processed++;
}
} else if (code == 17) {
uint8_t null_count = 3 + deflate_get_bits(3);
for (uint8_t i = 0; i < null_count; i++) {
deflate_lld_lengths[items_processed] = 0;
items_processed++;
}
} else if (code == 18) {
uint8_t null_count = 11 + deflate_get_bits(7);
for (uint8_t i = 0; i < null_count; i++) {
deflate_lld_lengths[items_processed] = 0;
items_processed++;
}
} else {
deflate_lld_lengths[items_processed] = code;
items_processed++;
}
}
#ifdef DEFLATE_WITH_LUT
deflate_build_alphabet(deflate_lld_lengths, hlit,
deflate_bl_count_ll, deflate_next_code_ll,
deflate_ll_codes);
deflate_build_alphabet(deflate_lld_lengths + hlit, hdist,
deflate_bl_count_d, deflate_next_code_d,
deflate_d_codes);
return deflate_huffman(deflate_ll_codes, deflate_d_codes);
#else
deflate_build_alphabet(deflate_lld_lengths, hlit,
deflate_bl_count_ll, deflate_next_code_ll);
deflate_build_alphabet(deflate_lld_lengths + hlit, hdist,
deflate_bl_count_d, deflate_next_code_d);
return deflate_huffman(deflate_lld_lengths, hlit,
deflate_lld_lengths + hlit, hdist);
#endif
}
int16_t inflate(unsigned char const *input_buf, uint16_t input_len,
unsigned char *output_buf, uint16_t output_len)
{
deflate_input_now = input_buf;
deflate_input_end = input_buf + input_len;
deflate_bit_offset = 0;
deflate_output_now = output_buf;
deflate_output_end = output_buf + output_len;
while (1) {
uint8_t block_type = deflate_get_bits(3);
uint8_t is_final = block_type & 0x01;
int8_t ret;
block_type >>= 1;
switch (block_type) {
case 0:
ret = deflate_uncompressed();
break;
case 1:
ret = deflate_static_huffman();
break;
case 2:
ret = deflate_dynamic_huffman();
break;
default:
return DEFLATE_ERR_BLOCK;
}
if (ret < 0) {
return ret;
}
if (is_final) {
return deflate_output_now - output_buf;
}
}
}
int16_t inflate_zlib(unsigned char const *input_buf, uint16_t input_len,
unsigned char *output_buf, uint16_t output_len)
{
if (input_len < 4) {
return DEFLATE_ERR_INPUT_LENGTH;
}
uint8_t zlib_method = input_buf[0] & 0x0f;
uint8_t zlib_flags = input_buf[1];
if (zlib_method != 8) {
return DEFLATE_ERR_METHOD;
}
if (zlib_flags & 0x20) {
return DEFLATE_ERR_FDICT;
}
if ((((uint16_t) input_buf[0] << 8) | input_buf[1]) % 31) {
return DEFLATE_ERR_FCHECK;
}
int16_t ret =
inflate(input_buf + 2, input_len - 2, output_buf, output_len);
#ifdef DEFLATE_CHECKSUM
if (ret >= 0) {
uint16_t deflate_s1 = 1;
uint16_t deflate_s2 = 0;
deflate_output_end = deflate_output_now;
for (deflate_output_now = output_buf;
deflate_output_now < deflate_output_end;
deflate_output_now++) {
deflate_s1 =
((uint32_t) deflate_s1 +
(uint32_t) (*deflate_output_now)) % 65521;
deflate_s2 =
((uint32_t) deflate_s2 +
(uint32_t) deflate_s1) % 65521;
}
if (deflate_bit_offset) {
deflate_input_now++;
}
if ((deflate_s2 !=
(((uint16_t) deflate_input_now[0] << 8) | (uint16_t)
deflate_input_now[1]))
|| (deflate_s1 !=
(((uint16_t) deflate_input_now[2] << 8) | (uint16_t)
deflate_input_now[3]))) {
return DEFLATE_ERR_CHECKSUM;
}
}
#endif
return ret;
}
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