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/**
* Copyright Amazon.com, Inc. or its affiliates. All Rights Reserved.
* SPDX-License-Identifier: Apache-2.0.
*/
#include <aws/compression/huffman.h>
#define BITSIZEOF(val) (sizeof(val) * 8)
static uint8_t MAX_PATTERN_BITS = BITSIZEOF(((struct aws_huffman_code *)0)->pattern);
void aws_huffman_encoder_init(struct aws_huffman_encoder *encoder, struct aws_huffman_symbol_coder *coder) {
AWS_ASSERT(encoder);
AWS_ASSERT(coder);
AWS_ZERO_STRUCT(*encoder);
encoder->coder = coder;
encoder->eos_padding = UINT8_MAX;
}
void aws_huffman_encoder_reset(struct aws_huffman_encoder *encoder) {
AWS_ASSERT(encoder);
AWS_ZERO_STRUCT(encoder->overflow_bits);
}
void aws_huffman_decoder_init(struct aws_huffman_decoder *decoder, struct aws_huffman_symbol_coder *coder) {
AWS_ASSERT(decoder);
AWS_ASSERT(coder);
AWS_ZERO_STRUCT(*decoder);
decoder->coder = coder;
}
void aws_huffman_decoder_reset(struct aws_huffman_decoder *decoder) {
decoder->working_bits = 0;
decoder->num_bits = 0;
}
void aws_huffman_decoder_allow_growth(struct aws_huffman_decoder *decoder, bool allow_growth) {
decoder->allow_growth = allow_growth;
}
/* Much of encode is written in a helper function,
so this struct helps avoid passing all the parameters through by hand */
struct encoder_state {
struct aws_huffman_encoder *encoder;
struct aws_byte_buf *output_buf;
uint8_t working;
uint8_t bit_pos;
};
/* Helper function to write a single bit_pattern to memory (or working_bits if
* out of buffer space) */
static int encode_write_bit_pattern(struct encoder_state *state, struct aws_huffman_code bit_pattern) {
AWS_PRECONDITION(state->output_buf->len < state->output_buf->capacity);
if (bit_pattern.num_bits == 0) {
return aws_raise_error(AWS_ERROR_COMPRESSION_UNKNOWN_SYMBOL);
}
uint8_t bits_to_write = bit_pattern.num_bits;
while (bits_to_write > 0) {
uint8_t bits_for_current = bits_to_write > state->bit_pos ? state->bit_pos : bits_to_write;
/* Chop off the top 0s and bits that have already been read */
uint8_t bits_to_cut =
(BITSIZEOF(bit_pattern.pattern) - bit_pattern.num_bits) + (bit_pattern.num_bits - bits_to_write);
/* Write the appropiate number of bits to this byte
Shift to the left to cut any unneeded bits
Shift to the right to position the bits correctly */
state->working |= (bit_pattern.pattern << bits_to_cut) >> (MAX_PATTERN_BITS - state->bit_pos);
bits_to_write -= bits_for_current;
state->bit_pos -= bits_for_current;
if (state->bit_pos == 0) {
/* Save the whole byte */
aws_byte_buf_write_u8(state->output_buf, state->working);
state->bit_pos = 8;
state->working = 0;
if (state->output_buf->len == state->output_buf->capacity) {
state->encoder->overflow_bits.num_bits = bits_to_write;
if (bits_to_write) {
/* If buffer is full and there are remaining bits, save them to overflow and return */
bits_to_cut += bits_for_current;
state->encoder->overflow_bits.pattern =
(bit_pattern.pattern << bits_to_cut) >> (MAX_PATTERN_BITS - bits_to_write);
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
}
}
}
return AWS_OP_SUCCESS;
}
size_t aws_huffman_get_encoded_length(struct aws_huffman_encoder *encoder, struct aws_byte_cursor to_encode) {
AWS_PRECONDITION(encoder);
AWS_PRECONDITION(aws_byte_cursor_is_valid(&to_encode));
size_t num_bits = 0;
while (to_encode.len) {
uint8_t new_byte = 0;
aws_byte_cursor_read_u8(&to_encode, &new_byte);
struct aws_huffman_code code_point = encoder->coder->encode(new_byte, encoder->coder->userdata);
num_bits += code_point.num_bits;
}
size_t length = num_bits / 8;
/* Round up */
if (num_bits % 8) {
++length;
}
return length;
}
int aws_huffman_encode(
struct aws_huffman_encoder *encoder,
struct aws_byte_cursor *to_encode,
struct aws_byte_buf *output) {
AWS_ASSERT(encoder);
AWS_ASSERT(encoder->coder);
AWS_ASSERT(to_encode);
AWS_ASSERT(output);
struct encoder_state state = {
.working = 0,
.bit_pos = 8,
};
state.encoder = encoder;
state.output_buf = output;
/* Write any bits leftover from previous invocation */
if (encoder->overflow_bits.num_bits) {
if (output->len == output->capacity) {
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
if (encode_write_bit_pattern(&state, encoder->overflow_bits)) {
return AWS_OP_ERR;
}
encoder->overflow_bits.num_bits = 0;
}
while (to_encode->len) {
if (output->len == output->capacity) {
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
uint8_t new_byte = 0;
aws_byte_cursor_read_u8(to_encode, &new_byte);
struct aws_huffman_code code_point = encoder->coder->encode(new_byte, encoder->coder->userdata);
if (encode_write_bit_pattern(&state, code_point)) {
return AWS_OP_ERR;
}
}
/* The following code only runs when the buffer has written successfully */
/* If whole buffer processed, write EOS */
if (state.bit_pos != 8) {
struct aws_huffman_code eos_cp;
eos_cp.pattern = encoder->eos_padding;
eos_cp.num_bits = state.bit_pos;
encode_write_bit_pattern(&state, eos_cp);
AWS_ASSERT(state.bit_pos == 8);
}
return AWS_OP_SUCCESS;
}
/* Decode's reading is written in a helper function,
so this struct helps avoid passing all the parameters through by hand */
struct huffman_decoder_state {
struct aws_huffman_decoder *decoder;
struct aws_byte_cursor *input_cursor;
};
static void decode_fill_working_bits(struct huffman_decoder_state *state) {
/* Read from bytes in the buffer until there are enough bytes to process */
while (state->decoder->num_bits < MAX_PATTERN_BITS && state->input_cursor->len) {
/* Read the appropiate number of bits from this byte */
uint8_t new_byte = 0;
aws_byte_cursor_read_u8(state->input_cursor, &new_byte);
uint64_t positioned = ((uint64_t)new_byte)
<< (BITSIZEOF(state->decoder->working_bits) - 8 - state->decoder->num_bits);
state->decoder->working_bits |= positioned;
state->decoder->num_bits += 8;
}
}
int aws_huffman_decode(
struct aws_huffman_decoder *decoder,
struct aws_byte_cursor *to_decode,
struct aws_byte_buf *output) {
AWS_ASSERT(decoder);
AWS_ASSERT(decoder->coder);
AWS_ASSERT(to_decode);
AWS_ASSERT(output);
struct huffman_decoder_state state;
state.decoder = decoder;
state.input_cursor = to_decode;
/* Measures how much of the input was read */
size_t bits_left = decoder->num_bits + to_decode->len * 8;
while (1) {
decode_fill_working_bits(&state);
uint8_t symbol;
uint8_t bits_read = decoder->coder->decode(
(uint32_t)(decoder->working_bits >> (BITSIZEOF(decoder->working_bits) - MAX_PATTERN_BITS)),
&symbol,
decoder->coder->userdata);
if (bits_read == 0) {
if (bits_left < MAX_PATTERN_BITS) {
/* More input is needed to continue */
return AWS_OP_SUCCESS;
}
/* Unknown symbol found */
return aws_raise_error(AWS_ERROR_COMPRESSION_UNKNOWN_SYMBOL);
}
if (bits_read > bits_left) {
/* Check if the buffer has been overrun.
Note: because of the check in decode_fill_working_bits,
the buffer won't actually overrun, instead there will
be 0's in the bottom of working_bits. */
return AWS_OP_SUCCESS;
}
if (output->len == output->capacity) {
/* Check if we've hit the end of the output buffer.
* Grow buffer, or raise error, depending on settings */
if (decoder->allow_growth) {
/* Double the capacity */
if (aws_byte_buf_reserve_relative(output, output->capacity)) {
return AWS_OP_ERR;
}
} else {
return aws_raise_error(AWS_ERROR_SHORT_BUFFER);
}
}
bits_left -= bits_read;
decoder->working_bits <<= bits_read;
decoder->num_bits -= bits_read;
/* Store the found symbol */
aws_byte_buf_write_u8(output, symbol);
/* Successfully decoded whole buffer */
if (bits_left == 0) {
return AWS_OP_SUCCESS;
}
}
/* This case is unreachable */
AWS_ASSERT(0);
}
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