forked from OSchip/llvm-project
628 lines
28 KiB
C
628 lines
28 KiB
C
/*===-- blake3.c - BLAKE3 C Implementation ------------------------*- C -*-===*\
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|* *|
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|* Released into the public domain with CC0 1.0 *|
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|* See 'llvm/lib/Support/BLAKE3/LICENSE' for info. *|
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|* SPDX-License-Identifier: CC0-1.0 *|
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|* *|
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\*===----------------------------------------------------------------------===*/
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#include <assert.h>
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#include <stdbool.h>
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#include <string.h>
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#include "blake3_impl.h"
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const char *llvm_blake3_version(void) { return BLAKE3_VERSION_STRING; }
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INLINE void chunk_state_init(blake3_chunk_state *self, const uint32_t key[8],
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uint8_t flags) {
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memcpy(self->cv, key, BLAKE3_KEY_LEN);
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self->chunk_counter = 0;
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memset(self->buf, 0, BLAKE3_BLOCK_LEN);
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self->buf_len = 0;
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self->blocks_compressed = 0;
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self->flags = flags;
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}
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INLINE void chunk_state_reset(blake3_chunk_state *self, const uint32_t key[8],
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uint64_t chunk_counter) {
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memcpy(self->cv, key, BLAKE3_KEY_LEN);
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self->chunk_counter = chunk_counter;
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self->blocks_compressed = 0;
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memset(self->buf, 0, BLAKE3_BLOCK_LEN);
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self->buf_len = 0;
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}
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INLINE size_t chunk_state_len(const blake3_chunk_state *self) {
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return (BLAKE3_BLOCK_LEN * (size_t)self->blocks_compressed) +
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((size_t)self->buf_len);
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}
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INLINE size_t chunk_state_fill_buf(blake3_chunk_state *self,
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const uint8_t *input, size_t input_len) {
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size_t take = BLAKE3_BLOCK_LEN - ((size_t)self->buf_len);
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if (take > input_len) {
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take = input_len;
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}
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uint8_t *dest = self->buf + ((size_t)self->buf_len);
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memcpy(dest, input, take);
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self->buf_len += (uint8_t)take;
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return take;
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}
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INLINE uint8_t chunk_state_maybe_start_flag(const blake3_chunk_state *self) {
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if (self->blocks_compressed == 0) {
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return CHUNK_START;
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} else {
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return 0;
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}
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}
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typedef struct {
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uint32_t input_cv[8];
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uint64_t counter;
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uint8_t block[BLAKE3_BLOCK_LEN];
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uint8_t block_len;
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uint8_t flags;
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} output_t;
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INLINE output_t make_output(const uint32_t input_cv[8],
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const uint8_t block[BLAKE3_BLOCK_LEN],
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uint8_t block_len, uint64_t counter,
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uint8_t flags) {
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output_t ret;
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memcpy(ret.input_cv, input_cv, 32);
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memcpy(ret.block, block, BLAKE3_BLOCK_LEN);
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ret.block_len = block_len;
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ret.counter = counter;
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ret.flags = flags;
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return ret;
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}
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// Chaining values within a given chunk (specifically the compress_in_place
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// interface) are represented as words. This avoids unnecessary bytes<->words
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// conversion overhead in the portable implementation. However, the hash_many
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// interface handles both user input and parent node blocks, so it accepts
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// bytes. For that reason, chaining values in the CV stack are represented as
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// bytes.
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INLINE void output_chaining_value(const output_t *self, uint8_t cv[32]) {
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uint32_t cv_words[8];
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memcpy(cv_words, self->input_cv, 32);
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blake3_compress_in_place(cv_words, self->block, self->block_len,
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self->counter, self->flags);
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store_cv_words(cv, cv_words);
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}
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INLINE void output_root_bytes(const output_t *self, uint64_t seek, uint8_t *out,
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size_t out_len) {
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uint64_t output_block_counter = seek / 64;
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size_t offset_within_block = seek % 64;
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uint8_t wide_buf[64];
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while (out_len > 0) {
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blake3_compress_xof(self->input_cv, self->block, self->block_len,
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output_block_counter, self->flags | ROOT, wide_buf);
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size_t available_bytes = 64 - offset_within_block;
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size_t memcpy_len;
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if (out_len > available_bytes) {
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memcpy_len = available_bytes;
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} else {
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memcpy_len = out_len;
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}
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memcpy(out, wide_buf + offset_within_block, memcpy_len);
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out += memcpy_len;
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out_len -= memcpy_len;
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output_block_counter += 1;
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offset_within_block = 0;
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}
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}
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INLINE void chunk_state_update(blake3_chunk_state *self, const uint8_t *input,
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size_t input_len) {
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if (self->buf_len > 0) {
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size_t take = chunk_state_fill_buf(self, input, input_len);
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input += take;
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input_len -= take;
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if (input_len > 0) {
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blake3_compress_in_place(
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self->cv, self->buf, BLAKE3_BLOCK_LEN, self->chunk_counter,
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self->flags | chunk_state_maybe_start_flag(self));
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self->blocks_compressed += 1;
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self->buf_len = 0;
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memset(self->buf, 0, BLAKE3_BLOCK_LEN);
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}
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}
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while (input_len > BLAKE3_BLOCK_LEN) {
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blake3_compress_in_place(self->cv, input, BLAKE3_BLOCK_LEN,
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self->chunk_counter,
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self->flags | chunk_state_maybe_start_flag(self));
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self->blocks_compressed += 1;
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input += BLAKE3_BLOCK_LEN;
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input_len -= BLAKE3_BLOCK_LEN;
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}
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size_t take = chunk_state_fill_buf(self, input, input_len);
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input += take;
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input_len -= take;
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}
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INLINE output_t chunk_state_output(const blake3_chunk_state *self) {
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uint8_t block_flags =
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self->flags | chunk_state_maybe_start_flag(self) | CHUNK_END;
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return make_output(self->cv, self->buf, self->buf_len, self->chunk_counter,
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block_flags);
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}
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INLINE output_t parent_output(const uint8_t block[BLAKE3_BLOCK_LEN],
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const uint32_t key[8], uint8_t flags) {
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return make_output(key, block, BLAKE3_BLOCK_LEN, 0, flags | PARENT);
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}
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// Given some input larger than one chunk, return the number of bytes that
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// should go in the left subtree. This is the largest power-of-2 number of
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// chunks that leaves at least 1 byte for the right subtree.
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INLINE size_t left_len(size_t content_len) {
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// Subtract 1 to reserve at least one byte for the right side. content_len
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// should always be greater than BLAKE3_CHUNK_LEN.
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size_t full_chunks = (content_len - 1) / BLAKE3_CHUNK_LEN;
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return round_down_to_power_of_2(full_chunks) * BLAKE3_CHUNK_LEN;
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}
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// Use SIMD parallelism to hash up to MAX_SIMD_DEGREE chunks at the same time
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// on a single thread. Write out the chunk chaining values and return the
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// number of chunks hashed. These chunks are never the root and never empty;
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// those cases use a different codepath.
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INLINE size_t compress_chunks_parallel(const uint8_t *input, size_t input_len,
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const uint32_t key[8],
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uint64_t chunk_counter, uint8_t flags,
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uint8_t *out) {
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#if defined(BLAKE3_TESTING)
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assert(0 < input_len);
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assert(input_len <= MAX_SIMD_DEGREE * BLAKE3_CHUNK_LEN);
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#endif
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const uint8_t *chunks_array[MAX_SIMD_DEGREE];
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size_t input_position = 0;
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size_t chunks_array_len = 0;
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while (input_len - input_position >= BLAKE3_CHUNK_LEN) {
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chunks_array[chunks_array_len] = &input[input_position];
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input_position += BLAKE3_CHUNK_LEN;
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chunks_array_len += 1;
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}
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blake3_hash_many(chunks_array, chunks_array_len,
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BLAKE3_CHUNK_LEN / BLAKE3_BLOCK_LEN, key, chunk_counter,
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true, flags, CHUNK_START, CHUNK_END, out);
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// Hash the remaining partial chunk, if there is one. Note that the empty
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// chunk (meaning the empty message) is a different codepath.
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if (input_len > input_position) {
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uint64_t counter = chunk_counter + (uint64_t)chunks_array_len;
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blake3_chunk_state chunk_state;
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chunk_state_init(&chunk_state, key, flags);
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chunk_state.chunk_counter = counter;
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chunk_state_update(&chunk_state, &input[input_position],
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input_len - input_position);
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output_t output = chunk_state_output(&chunk_state);
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output_chaining_value(&output, &out[chunks_array_len * BLAKE3_OUT_LEN]);
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return chunks_array_len + 1;
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} else {
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return chunks_array_len;
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}
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}
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// Use SIMD parallelism to hash up to MAX_SIMD_DEGREE parents at the same time
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// on a single thread. Write out the parent chaining values and return the
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// number of parents hashed. (If there's an odd input chaining value left over,
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// return it as an additional output.) These parents are never the root and
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// never empty; those cases use a different codepath.
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INLINE size_t compress_parents_parallel(const uint8_t *child_chaining_values,
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size_t num_chaining_values,
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const uint32_t key[8], uint8_t flags,
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uint8_t *out) {
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#if defined(BLAKE3_TESTING)
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assert(2 <= num_chaining_values);
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assert(num_chaining_values <= 2 * MAX_SIMD_DEGREE_OR_2);
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#endif
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const uint8_t *parents_array[MAX_SIMD_DEGREE_OR_2];
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size_t parents_array_len = 0;
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while (num_chaining_values - (2 * parents_array_len) >= 2) {
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parents_array[parents_array_len] =
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&child_chaining_values[2 * parents_array_len * BLAKE3_OUT_LEN];
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parents_array_len += 1;
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}
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blake3_hash_many(parents_array, parents_array_len, 1, key,
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0, // Parents always use counter 0.
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false, flags | PARENT,
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0, // Parents have no start flags.
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0, // Parents have no end flags.
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out);
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// If there's an odd child left over, it becomes an output.
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if (num_chaining_values > 2 * parents_array_len) {
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memcpy(&out[parents_array_len * BLAKE3_OUT_LEN],
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&child_chaining_values[2 * parents_array_len * BLAKE3_OUT_LEN],
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BLAKE3_OUT_LEN);
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return parents_array_len + 1;
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} else {
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return parents_array_len;
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}
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}
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// The wide helper function returns (writes out) an array of chaining values
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// and returns the length of that array. The number of chaining values returned
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// is the dyanmically detected SIMD degree, at most MAX_SIMD_DEGREE. Or fewer,
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// if the input is shorter than that many chunks. The reason for maintaining a
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// wide array of chaining values going back up the tree, is to allow the
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// implementation to hash as many parents in parallel as possible.
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//
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// As a special case when the SIMD degree is 1, this function will still return
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// at least 2 outputs. This guarantees that this function doesn't perform the
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// root compression. (If it did, it would use the wrong flags, and also we
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// wouldn't be able to implement exendable ouput.) Note that this function is
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// not used when the whole input is only 1 chunk long; that's a different
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// codepath.
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//
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// Why not just have the caller split the input on the first update(), instead
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// of implementing this special rule? Because we don't want to limit SIMD or
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// multi-threading parallelism for that update().
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static size_t blake3_compress_subtree_wide(const uint8_t *input,
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size_t input_len,
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const uint32_t key[8],
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uint64_t chunk_counter,
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uint8_t flags, uint8_t *out) {
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// Note that the single chunk case does *not* bump the SIMD degree up to 2
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// when it is 1. If this implementation adds multi-threading in the future,
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// this gives us the option of multi-threading even the 2-chunk case, which
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// can help performance on smaller platforms.
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if (input_len <= blake3_simd_degree() * BLAKE3_CHUNK_LEN) {
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return compress_chunks_parallel(input, input_len, key, chunk_counter, flags,
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out);
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}
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// With more than simd_degree chunks, we need to recurse. Start by dividing
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// the input into left and right subtrees. (Note that this is only optimal
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// as long as the SIMD degree is a power of 2. If we ever get a SIMD degree
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// of 3 or something, we'll need a more complicated strategy.)
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size_t left_input_len = left_len(input_len);
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size_t right_input_len = input_len - left_input_len;
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const uint8_t *right_input = &input[left_input_len];
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uint64_t right_chunk_counter =
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chunk_counter + (uint64_t)(left_input_len / BLAKE3_CHUNK_LEN);
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// Make space for the child outputs. Here we use MAX_SIMD_DEGREE_OR_2 to
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// account for the special case of returning 2 outputs when the SIMD degree
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// is 1.
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uint8_t cv_array[2 * MAX_SIMD_DEGREE_OR_2 * BLAKE3_OUT_LEN];
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size_t degree = blake3_simd_degree();
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if (left_input_len > BLAKE3_CHUNK_LEN && degree == 1) {
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// The special case: We always use a degree of at least two, to make
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// sure there are two outputs. Except, as noted above, at the chunk
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// level, where we allow degree=1. (Note that the 1-chunk-input case is
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// a different codepath.)
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degree = 2;
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}
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uint8_t *right_cvs = &cv_array[degree * BLAKE3_OUT_LEN];
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// Recurse! If this implementation adds multi-threading support in the
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// future, this is where it will go.
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size_t left_n = blake3_compress_subtree_wide(input, left_input_len, key,
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chunk_counter, flags, cv_array);
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size_t right_n = blake3_compress_subtree_wide(
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right_input, right_input_len, key, right_chunk_counter, flags, right_cvs);
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// The special case again. If simd_degree=1, then we'll have left_n=1 and
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// right_n=1. Rather than compressing them into a single output, return
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// them directly, to make sure we always have at least two outputs.
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if (left_n == 1) {
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memcpy(out, cv_array, 2 * BLAKE3_OUT_LEN);
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return 2;
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}
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// Otherwise, do one layer of parent node compression.
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size_t num_chaining_values = left_n + right_n;
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return compress_parents_parallel(cv_array, num_chaining_values, key, flags,
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out);
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}
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// Hash a subtree with compress_subtree_wide(), and then condense the resulting
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// list of chaining values down to a single parent node. Don't compress that
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// last parent node, however. Instead, return its message bytes (the
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// concatenated chaining values of its children). This is necessary when the
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// first call to update() supplies a complete subtree, because the topmost
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// parent node of that subtree could end up being the root. It's also necessary
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// for extended output in the general case.
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//
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// As with compress_subtree_wide(), this function is not used on inputs of 1
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// chunk or less. That's a different codepath.
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INLINE void compress_subtree_to_parent_node(
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const uint8_t *input, size_t input_len, const uint32_t key[8],
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uint64_t chunk_counter, uint8_t flags, uint8_t out[2 * BLAKE3_OUT_LEN]) {
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#if defined(BLAKE3_TESTING)
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assert(input_len > BLAKE3_CHUNK_LEN);
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#endif
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uint8_t cv_array[MAX_SIMD_DEGREE_OR_2 * BLAKE3_OUT_LEN];
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size_t num_cvs = blake3_compress_subtree_wide(input, input_len, key,
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chunk_counter, flags, cv_array);
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assert(num_cvs <= MAX_SIMD_DEGREE_OR_2);
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// If MAX_SIMD_DEGREE is greater than 2 and there's enough input,
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// compress_subtree_wide() returns more than 2 chaining values. Condense
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// them into 2 by forming parent nodes repeatedly.
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uint8_t out_array[MAX_SIMD_DEGREE_OR_2 * BLAKE3_OUT_LEN / 2];
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// The second half of this loop condition is always true, and we just
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// asserted it above. But GCC can't tell that it's always true, and if NDEBUG
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// is set on platforms where MAX_SIMD_DEGREE_OR_2 == 2, GCC emits spurious
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// warnings here. GCC 8.5 is particularly sensitive, so if you're changing
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// this code, test it against that version.
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while (num_cvs > 2 && num_cvs <= MAX_SIMD_DEGREE_OR_2) {
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num_cvs =
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compress_parents_parallel(cv_array, num_cvs, key, flags, out_array);
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memcpy(cv_array, out_array, num_cvs * BLAKE3_OUT_LEN);
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}
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memcpy(out, cv_array, 2 * BLAKE3_OUT_LEN);
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}
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INLINE void hasher_init_base(blake3_hasher *self, const uint32_t key[8],
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uint8_t flags) {
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memcpy(self->key, key, BLAKE3_KEY_LEN);
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chunk_state_init(&self->chunk, key, flags);
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self->cv_stack_len = 0;
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}
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void llvm_blake3_hasher_init(blake3_hasher *self) { hasher_init_base(self, IV, 0); }
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void llvm_blake3_hasher_init_keyed(blake3_hasher *self,
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const uint8_t key[BLAKE3_KEY_LEN]) {
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uint32_t key_words[8];
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load_key_words(key, key_words);
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hasher_init_base(self, key_words, KEYED_HASH);
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}
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void llvm_blake3_hasher_init_derive_key_raw(blake3_hasher *self, const void *context,
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size_t context_len) {
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blake3_hasher context_hasher;
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hasher_init_base(&context_hasher, IV, DERIVE_KEY_CONTEXT);
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llvm_blake3_hasher_update(&context_hasher, context, context_len);
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uint8_t context_key[BLAKE3_KEY_LEN];
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llvm_blake3_hasher_finalize(&context_hasher, context_key, BLAKE3_KEY_LEN);
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uint32_t context_key_words[8];
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load_key_words(context_key, context_key_words);
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hasher_init_base(self, context_key_words, DERIVE_KEY_MATERIAL);
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}
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void llvm_blake3_hasher_init_derive_key(blake3_hasher *self, const char *context) {
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llvm_blake3_hasher_init_derive_key_raw(self, context, strlen(context));
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}
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// As described in hasher_push_cv() below, we do "lazy merging", delaying
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// merges until right before the next CV is about to be added. This is
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// different from the reference implementation. Another difference is that we
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// aren't always merging 1 chunk at a time. Instead, each CV might represent
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// any power-of-two number of chunks, as long as the smaller-above-larger stack
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// order is maintained. Instead of the "count the trailing 0-bits" algorithm
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// described in the spec, we use a "count the total number of 1-bits" variant
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// that doesn't require us to retain the subtree size of the CV on top of the
|
|
// stack. The principle is the same: each CV that should remain in the stack is
|
|
// represented by a 1-bit in the total number of chunks (or bytes) so far.
|
|
INLINE void hasher_merge_cv_stack(blake3_hasher *self, uint64_t total_len) {
|
|
size_t post_merge_stack_len = (size_t)popcnt(total_len);
|
|
while (self->cv_stack_len > post_merge_stack_len) {
|
|
uint8_t *parent_node =
|
|
&self->cv_stack[(self->cv_stack_len - 2) * BLAKE3_OUT_LEN];
|
|
output_t output = parent_output(parent_node, self->key, self->chunk.flags);
|
|
output_chaining_value(&output, parent_node);
|
|
self->cv_stack_len -= 1;
|
|
}
|
|
}
|
|
|
|
// In reference_impl.rs, we merge the new CV with existing CVs from the stack
|
|
// before pushing it. We can do that because we know more input is coming, so
|
|
// we know none of the merges are root.
|
|
//
|
|
// This setting is different. We want to feed as much input as possible to
|
|
// compress_subtree_wide(), without setting aside anything for the chunk_state.
|
|
// If the user gives us 64 KiB, we want to parallelize over all 64 KiB at once
|
|
// as a single subtree, if at all possible.
|
|
//
|
|
// This leads to two problems:
|
|
// 1) This 64 KiB input might be the only call that ever gets made to update.
|
|
// In this case, the root node of the 64 KiB subtree would be the root node
|
|
// of the whole tree, and it would need to be ROOT finalized. We can't
|
|
// compress it until we know.
|
|
// 2) This 64 KiB input might complete a larger tree, whose root node is
|
|
// similarly going to be the the root of the whole tree. For example, maybe
|
|
// we have 196 KiB (that is, 128 + 64) hashed so far. We can't compress the
|
|
// node at the root of the 256 KiB subtree until we know how to finalize it.
|
|
//
|
|
// The second problem is solved with "lazy merging". That is, when we're about
|
|
// to add a CV to the stack, we don't merge it with anything first, as the
|
|
// reference impl does. Instead we do merges using the *previous* CV that was
|
|
// added, which is sitting on top of the stack, and we put the new CV
|
|
// (unmerged) on top of the stack afterwards. This guarantees that we never
|
|
// merge the root node until finalize().
|
|
//
|
|
// Solving the first problem requires an additional tool,
|
|
// compress_subtree_to_parent_node(). That function always returns the top
|
|
// *two* chaining values of the subtree it's compressing. We then do lazy
|
|
// merging with each of them separately, so that the second CV will always
|
|
// remain unmerged. (That also helps us support extendable output when we're
|
|
// hashing an input all-at-once.)
|
|
INLINE void hasher_push_cv(blake3_hasher *self, uint8_t new_cv[BLAKE3_OUT_LEN],
|
|
uint64_t chunk_counter) {
|
|
hasher_merge_cv_stack(self, chunk_counter);
|
|
memcpy(&self->cv_stack[self->cv_stack_len * BLAKE3_OUT_LEN], new_cv,
|
|
BLAKE3_OUT_LEN);
|
|
self->cv_stack_len += 1;
|
|
}
|
|
|
|
void llvm_blake3_hasher_update(blake3_hasher *self, const void *input,
|
|
size_t input_len) {
|
|
// Explicitly checking for zero avoids causing UB by passing a null pointer
|
|
// to memcpy. This comes up in practice with things like:
|
|
// std::vector<uint8_t> v;
|
|
// blake3_hasher_update(&hasher, v.data(), v.size());
|
|
if (input_len == 0) {
|
|
return;
|
|
}
|
|
|
|
const uint8_t *input_bytes = (const uint8_t *)input;
|
|
|
|
// If we have some partial chunk bytes in the internal chunk_state, we need
|
|
// to finish that chunk first.
|
|
if (chunk_state_len(&self->chunk) > 0) {
|
|
size_t take = BLAKE3_CHUNK_LEN - chunk_state_len(&self->chunk);
|
|
if (take > input_len) {
|
|
take = input_len;
|
|
}
|
|
chunk_state_update(&self->chunk, input_bytes, take);
|
|
input_bytes += take;
|
|
input_len -= take;
|
|
// If we've filled the current chunk and there's more coming, finalize this
|
|
// chunk and proceed. In this case we know it's not the root.
|
|
if (input_len > 0) {
|
|
output_t output = chunk_state_output(&self->chunk);
|
|
uint8_t chunk_cv[32];
|
|
output_chaining_value(&output, chunk_cv);
|
|
hasher_push_cv(self, chunk_cv, self->chunk.chunk_counter);
|
|
chunk_state_reset(&self->chunk, self->key, self->chunk.chunk_counter + 1);
|
|
} else {
|
|
return;
|
|
}
|
|
}
|
|
|
|
// Now the chunk_state is clear, and we have more input. If there's more than
|
|
// a single chunk (so, definitely not the root chunk), hash the largest whole
|
|
// subtree we can, with the full benefits of SIMD (and maybe in the future,
|
|
// multi-threading) parallelism. Two restrictions:
|
|
// - The subtree has to be a power-of-2 number of chunks. Only subtrees along
|
|
// the right edge can be incomplete, and we don't know where the right edge
|
|
// is going to be until we get to finalize().
|
|
// - The subtree must evenly divide the total number of chunks up until this
|
|
// point (if total is not 0). If the current incomplete subtree is only
|
|
// waiting for 1 more chunk, we can't hash a subtree of 4 chunks. We have
|
|
// to complete the current subtree first.
|
|
// Because we might need to break up the input to form powers of 2, or to
|
|
// evenly divide what we already have, this part runs in a loop.
|
|
while (input_len > BLAKE3_CHUNK_LEN) {
|
|
size_t subtree_len = round_down_to_power_of_2(input_len);
|
|
uint64_t count_so_far = self->chunk.chunk_counter * BLAKE3_CHUNK_LEN;
|
|
// Shrink the subtree_len until it evenly divides the count so far. We know
|
|
// that subtree_len itself is a power of 2, so we can use a bitmasking
|
|
// trick instead of an actual remainder operation. (Note that if the caller
|
|
// consistently passes power-of-2 inputs of the same size, as is hopefully
|
|
// typical, this loop condition will always fail, and subtree_len will
|
|
// always be the full length of the input.)
|
|
//
|
|
// An aside: We don't have to shrink subtree_len quite this much. For
|
|
// example, if count_so_far is 1, we could pass 2 chunks to
|
|
// compress_subtree_to_parent_node. Since we'll get 2 CVs back, we'll still
|
|
// get the right answer in the end, and we might get to use 2-way SIMD
|
|
// parallelism. The problem with this optimization, is that it gets us
|
|
// stuck always hashing 2 chunks. The total number of chunks will remain
|
|
// odd, and we'll never graduate to higher degrees of parallelism. See
|
|
// https://github.com/BLAKE3-team/BLAKE3/issues/69.
|
|
while ((((uint64_t)(subtree_len - 1)) & count_so_far) != 0) {
|
|
subtree_len /= 2;
|
|
}
|
|
// The shrunken subtree_len might now be 1 chunk long. If so, hash that one
|
|
// chunk by itself. Otherwise, compress the subtree into a pair of CVs.
|
|
uint64_t subtree_chunks = subtree_len / BLAKE3_CHUNK_LEN;
|
|
if (subtree_len <= BLAKE3_CHUNK_LEN) {
|
|
blake3_chunk_state chunk_state;
|
|
chunk_state_init(&chunk_state, self->key, self->chunk.flags);
|
|
chunk_state.chunk_counter = self->chunk.chunk_counter;
|
|
chunk_state_update(&chunk_state, input_bytes, subtree_len);
|
|
output_t output = chunk_state_output(&chunk_state);
|
|
uint8_t cv[BLAKE3_OUT_LEN];
|
|
output_chaining_value(&output, cv);
|
|
hasher_push_cv(self, cv, chunk_state.chunk_counter);
|
|
} else {
|
|
// This is the high-performance happy path, though getting here depends
|
|
// on the caller giving us a long enough input.
|
|
uint8_t cv_pair[2 * BLAKE3_OUT_LEN];
|
|
compress_subtree_to_parent_node(input_bytes, subtree_len, self->key,
|
|
self->chunk.chunk_counter,
|
|
self->chunk.flags, cv_pair);
|
|
hasher_push_cv(self, cv_pair, self->chunk.chunk_counter);
|
|
hasher_push_cv(self, &cv_pair[BLAKE3_OUT_LEN],
|
|
self->chunk.chunk_counter + (subtree_chunks / 2));
|
|
}
|
|
self->chunk.chunk_counter += subtree_chunks;
|
|
input_bytes += subtree_len;
|
|
input_len -= subtree_len;
|
|
}
|
|
|
|
// If there's any remaining input less than a full chunk, add it to the chunk
|
|
// state. In that case, also do a final merge loop to make sure the subtree
|
|
// stack doesn't contain any unmerged pairs. The remaining input means we
|
|
// know these merges are non-root. This merge loop isn't strictly necessary
|
|
// here, because hasher_push_chunk_cv already does its own merge loop, but it
|
|
// simplifies blake3_hasher_finalize below.
|
|
if (input_len > 0) {
|
|
chunk_state_update(&self->chunk, input_bytes, input_len);
|
|
hasher_merge_cv_stack(self, self->chunk.chunk_counter);
|
|
}
|
|
}
|
|
|
|
void llvm_blake3_hasher_finalize(const blake3_hasher *self, uint8_t *out,
|
|
size_t out_len) {
|
|
llvm_blake3_hasher_finalize_seek(self, 0, out, out_len);
|
|
#if LLVM_MEMORY_SANITIZER_BUILD
|
|
// Avoid false positives due to uninstrumented assembly code.
|
|
__msan_unpoison(out, out_len);
|
|
#endif
|
|
}
|
|
|
|
void llvm_blake3_hasher_finalize_seek(const blake3_hasher *self, uint64_t seek,
|
|
uint8_t *out, size_t out_len) {
|
|
// Explicitly checking for zero avoids causing UB by passing a null pointer
|
|
// to memcpy. This comes up in practice with things like:
|
|
// std::vector<uint8_t> v;
|
|
// blake3_hasher_finalize(&hasher, v.data(), v.size());
|
|
if (out_len == 0) {
|
|
return;
|
|
}
|
|
|
|
// If the subtree stack is empty, then the current chunk is the root.
|
|
if (self->cv_stack_len == 0) {
|
|
output_t output = chunk_state_output(&self->chunk);
|
|
output_root_bytes(&output, seek, out, out_len);
|
|
return;
|
|
}
|
|
// If there are any bytes in the chunk state, finalize that chunk and do a
|
|
// roll-up merge between that chunk hash and every subtree in the stack. In
|
|
// this case, the extra merge loop at the end of blake3_hasher_update
|
|
// guarantees that none of the subtrees in the stack need to be merged with
|
|
// each other first. Otherwise, if there are no bytes in the chunk state,
|
|
// then the top of the stack is a chunk hash, and we start the merge from
|
|
// that.
|
|
output_t output;
|
|
size_t cvs_remaining;
|
|
if (chunk_state_len(&self->chunk) > 0) {
|
|
cvs_remaining = self->cv_stack_len;
|
|
output = chunk_state_output(&self->chunk);
|
|
} else {
|
|
// There are always at least 2 CVs in the stack in this case.
|
|
cvs_remaining = self->cv_stack_len - 2;
|
|
output = parent_output(&self->cv_stack[cvs_remaining * 32], self->key,
|
|
self->chunk.flags);
|
|
}
|
|
while (cvs_remaining > 0) {
|
|
cvs_remaining -= 1;
|
|
uint8_t parent_block[BLAKE3_BLOCK_LEN];
|
|
memcpy(parent_block, &self->cv_stack[cvs_remaining * 32], 32);
|
|
output_chaining_value(&output, &parent_block[32]);
|
|
output = parent_output(parent_block, self->key, self->chunk.flags);
|
|
}
|
|
output_root_bytes(&output, seek, out, out_len);
|
|
}
|
|
|
|
void llvm_blake3_hasher_reset(blake3_hasher *self) {
|
|
chunk_state_reset(&self->chunk, self->key, 0);
|
|
self->cv_stack_len = 0;
|
|
}
|