mirror_zfs/module/icp/algs/blake3/blake3.c
Richard Yao 6a42939fcd
Cleanup: Address Clang's static analyzer's unused code complaints
These were categorized as the following:

 * Dead assignment		23
 * Dead increment		4
 * Dead initialization		6
 * Dead nested assignment	18

Most of these are harmless, but since actual issues can hide among them,
we correct them.

That said, there were a few return values that were being ignored that
appeared to merit some correction:

 * `destroy_callback()` in `cmd/zfs/zfs_main.c` ignored the error from
   `destroy_batched()`. We handle it by returning -1 if there is an
   error.

 * `zfs_do_upgrade()` in `cmd/zfs/zfs_main.c` ignored the error from
   `zfs_for_each()`. We handle it by doing a binary OR of the error
   value from the subsequent `zfs_for_each()` call to the existing
   value. This is how errors are mostly handled inside `zfs_for_each()`.
   The error value here is passed to exit from the zfs command, so doing
   a binary or on it is better than what we did previously.

 * `get_zap_prop()` in `module/zfs/zcp_get.c` ignored the error from
   `dsl_prop_get_ds()` when the property is not of type string. We
   return an error when it does. There is a small concern that the
   `zfs_get_temporary_prop()` call would handle things, but in the case
   that it does not, we would be pushing an uninitialized numval onto
   the lua stack. It is expected that `dsl_prop_get_ds()` will succeed
   anytime that `zfs_get_temporary_prop()` does, so that not giving it a
   chance to fix things is not a problem.

 * `draid_merge_impl()` in `tests/zfs-tests/cmd/draid.c` used
   `nvlist_add_nvlist()` twice in ways in which errors are expected to
   be impossible, so we switch to `fnvlist_add_nvlist()`.

A few notable ones did not merit use of the return value, so we
suppressed it with `(void)`:

 * `write_free_diffs()` in `lib/libzfs/libzfs_diff.c` ignored the error
   value from `describe_free()`. A look through the commit history
   revealed that this was intentional.

 * `arc_evict_hdr()` in `module/zfs/arc.c` did not need to use the
   returned handle from `arc_hdr_realloc()` because it is already
   referenced in lists.

 * `spa_vdev_detach()` in `module/zfs/spa.c` has a comment explicitly
   saying not to use the error from `vdev_label_init()` because whatever
   causes the error could be the reason why a detach is being done.

Unfortunately, I am not presently able to analyze the kernel modules
with Clang's static analyzer, so I could have missed some cases of this.
In cases where reports were present in code that is duplicated between
Linux and FreeBSD, I made a conscious effort to fix the FreeBSD version
too.

After this commit is merged, regressions like dee8934 should become
extremely obvious with Clang's static analyzer since a regression would
appear in the results as the only instance of unused code. That assumes
that Coverity does not catch the issue first.

My local branch with fixes from all of my outstanding non-draft pull
requests shows 118 reports from Clang's static anlayzer after this
patch. That is down by 51 from 169.

Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov>
Reviewed-by: Cedric Berger <cedric@precidata.com>
Signed-off-by: Richard Yao <richard.yao@alumni.stonybrook.edu>
Closes #13986
2022-10-14 13:37:54 -07:00

731 lines
26 KiB
C

/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or https://opensource.org/licenses/CDDL-1.0.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Based on BLAKE3 v1.3.1, https://github.com/BLAKE3-team/BLAKE3
* Copyright (c) 2019-2020 Samuel Neves and Jack O'Connor
* Copyright (c) 2021-2022 Tino Reichardt <milky-zfs@mcmilk.de>
*/
#include <sys/zfs_context.h>
#include <sys/blake3.h>
#include "blake3_impl.h"
/*
* We need 1056 byte stack for blake3_compress_subtree_wide()
* - we define this pragma to make gcc happy
*/
#if defined(__GNUC__)
#pragma GCC diagnostic ignored "-Wframe-larger-than="
#endif
/* internal used */
typedef struct {
uint32_t input_cv[8];
uint64_t counter;
uint8_t block[BLAKE3_BLOCK_LEN];
uint8_t block_len;
uint8_t flags;
} output_t;
/* internal flags */
enum blake3_flags {
CHUNK_START = 1 << 0,
CHUNK_END = 1 << 1,
PARENT = 1 << 2,
ROOT = 1 << 3,
KEYED_HASH = 1 << 4,
DERIVE_KEY_CONTEXT = 1 << 5,
DERIVE_KEY_MATERIAL = 1 << 6,
};
/* internal start */
static void chunk_state_init(blake3_chunk_state_t *ctx,
const uint32_t key[8], uint8_t flags)
{
memcpy(ctx->cv, key, BLAKE3_KEY_LEN);
ctx->chunk_counter = 0;
memset(ctx->buf, 0, BLAKE3_BLOCK_LEN);
ctx->buf_len = 0;
ctx->blocks_compressed = 0;
ctx->flags = flags;
}
static void chunk_state_reset(blake3_chunk_state_t *ctx,
const uint32_t key[8], uint64_t chunk_counter)
{
memcpy(ctx->cv, key, BLAKE3_KEY_LEN);
ctx->chunk_counter = chunk_counter;
ctx->blocks_compressed = 0;
memset(ctx->buf, 0, BLAKE3_BLOCK_LEN);
ctx->buf_len = 0;
}
static size_t chunk_state_len(const blake3_chunk_state_t *ctx)
{
return (BLAKE3_BLOCK_LEN * (size_t)ctx->blocks_compressed) +
((size_t)ctx->buf_len);
}
static size_t chunk_state_fill_buf(blake3_chunk_state_t *ctx,
const uint8_t *input, size_t input_len)
{
size_t take = BLAKE3_BLOCK_LEN - ((size_t)ctx->buf_len);
if (take > input_len) {
take = input_len;
}
uint8_t *dest = ctx->buf + ((size_t)ctx->buf_len);
memcpy(dest, input, take);
ctx->buf_len += (uint8_t)take;
return (take);
}
static uint8_t chunk_state_maybe_start_flag(const blake3_chunk_state_t *ctx)
{
if (ctx->blocks_compressed == 0) {
return (CHUNK_START);
} else {
return (0);
}
}
static output_t make_output(const uint32_t input_cv[8],
const uint8_t *block, uint8_t block_len,
uint64_t counter, uint8_t flags)
{
output_t ret;
memcpy(ret.input_cv, input_cv, 32);
memcpy(ret.block, block, BLAKE3_BLOCK_LEN);
ret.block_len = block_len;
ret.counter = counter;
ret.flags = flags;
return (ret);
}
/*
* Chaining values within a given chunk (specifically the compress_in_place
* interface) are represented as words. This avoids unnecessary bytes<->words
* conversion overhead in the portable implementation. However, the hash_many
* interface handles both user input and parent node blocks, so it accepts
* bytes. For that reason, chaining values in the CV stack are represented as
* bytes.
*/
static void output_chaining_value(const blake3_ops_t *ops,
const output_t *ctx, uint8_t cv[32])
{
uint32_t cv_words[8];
memcpy(cv_words, ctx->input_cv, 32);
ops->compress_in_place(cv_words, ctx->block, ctx->block_len,
ctx->counter, ctx->flags);
store_cv_words(cv, cv_words);
}
static void output_root_bytes(const blake3_ops_t *ops, const output_t *ctx,
uint64_t seek, uint8_t *out, size_t out_len)
{
uint64_t output_block_counter = seek / 64;
size_t offset_within_block = seek % 64;
uint8_t wide_buf[64];
while (out_len > 0) {
ops->compress_xof(ctx->input_cv, ctx->block, ctx->block_len,
output_block_counter, ctx->flags | ROOT, wide_buf);
size_t available_bytes = 64 - offset_within_block;
size_t memcpy_len;
if (out_len > available_bytes) {
memcpy_len = available_bytes;
} else {
memcpy_len = out_len;
}
memcpy(out, wide_buf + offset_within_block, memcpy_len);
out += memcpy_len;
out_len -= memcpy_len;
output_block_counter += 1;
offset_within_block = 0;
}
}
static void chunk_state_update(const blake3_ops_t *ops,
blake3_chunk_state_t *ctx, const uint8_t *input, size_t input_len)
{
if (ctx->buf_len > 0) {
size_t take = chunk_state_fill_buf(ctx, input, input_len);
input += take;
input_len -= take;
if (input_len > 0) {
ops->compress_in_place(ctx->cv, ctx->buf,
BLAKE3_BLOCK_LEN, ctx->chunk_counter,
ctx->flags|chunk_state_maybe_start_flag(ctx));
ctx->blocks_compressed += 1;
ctx->buf_len = 0;
memset(ctx->buf, 0, BLAKE3_BLOCK_LEN);
}
}
while (input_len > BLAKE3_BLOCK_LEN) {
ops->compress_in_place(ctx->cv, input, BLAKE3_BLOCK_LEN,
ctx->chunk_counter,
ctx->flags|chunk_state_maybe_start_flag(ctx));
ctx->blocks_compressed += 1;
input += BLAKE3_BLOCK_LEN;
input_len -= BLAKE3_BLOCK_LEN;
}
chunk_state_fill_buf(ctx, input, input_len);
}
static output_t chunk_state_output(const blake3_chunk_state_t *ctx)
{
uint8_t block_flags =
ctx->flags | chunk_state_maybe_start_flag(ctx) | CHUNK_END;
return (make_output(ctx->cv, ctx->buf, ctx->buf_len, ctx->chunk_counter,
block_flags));
}
static output_t parent_output(const uint8_t block[BLAKE3_BLOCK_LEN],
const uint32_t key[8], uint8_t flags)
{
return (make_output(key, block, BLAKE3_BLOCK_LEN, 0, flags | PARENT));
}
/*
* Given some input larger than one chunk, return the number of bytes that
* should go in the left subtree. This is the largest power-of-2 number of
* chunks that leaves at least 1 byte for the right subtree.
*/
static size_t left_len(size_t content_len)
{
/*
* Subtract 1 to reserve at least one byte for the right side.
* content_len
* should always be greater than BLAKE3_CHUNK_LEN.
*/
size_t full_chunks = (content_len - 1) / BLAKE3_CHUNK_LEN;
return (round_down_to_power_of_2(full_chunks) * BLAKE3_CHUNK_LEN);
}
/*
* Use SIMD parallelism to hash up to MAX_SIMD_DEGREE chunks at the same time
* on a single thread. Write out the chunk chaining values and return the
* number of chunks hashed. These chunks are never the root and never empty;
* those cases use a different codepath.
*/
static size_t compress_chunks_parallel(const blake3_ops_t *ops,
const uint8_t *input, size_t input_len, const uint32_t key[8],
uint64_t chunk_counter, uint8_t flags, uint8_t *out)
{
const uint8_t *chunks_array[MAX_SIMD_DEGREE];
size_t input_position = 0;
size_t chunks_array_len = 0;
while (input_len - input_position >= BLAKE3_CHUNK_LEN) {
chunks_array[chunks_array_len] = &input[input_position];
input_position += BLAKE3_CHUNK_LEN;
chunks_array_len += 1;
}
ops->hash_many(chunks_array, chunks_array_len, BLAKE3_CHUNK_LEN /
BLAKE3_BLOCK_LEN, key, chunk_counter, B_TRUE, flags, CHUNK_START,
CHUNK_END, out);
/*
* Hash the remaining partial chunk, if there is one. Note that the
* empty chunk (meaning the empty message) is a different codepath.
*/
if (input_len > input_position) {
uint64_t counter = chunk_counter + (uint64_t)chunks_array_len;
blake3_chunk_state_t chunk_state;
chunk_state_init(&chunk_state, key, flags);
chunk_state.chunk_counter = counter;
chunk_state_update(ops, &chunk_state, &input[input_position],
input_len - input_position);
output_t output = chunk_state_output(&chunk_state);
output_chaining_value(ops, &output, &out[chunks_array_len *
BLAKE3_OUT_LEN]);
return (chunks_array_len + 1);
} else {
return (chunks_array_len);
}
}
/*
* Use SIMD parallelism to hash up to MAX_SIMD_DEGREE parents at the same time
* on a single thread. Write out the parent chaining values and return the
* number of parents hashed. (If there's an odd input chaining value left over,
* return it as an additional output.) These parents are never the root and
* never empty; those cases use a different codepath.
*/
static size_t compress_parents_parallel(const blake3_ops_t *ops,
const uint8_t *child_chaining_values, size_t num_chaining_values,
const uint32_t key[8], uint8_t flags, uint8_t *out)
{
const uint8_t *parents_array[MAX_SIMD_DEGREE_OR_2];
size_t parents_array_len = 0;
while (num_chaining_values - (2 * parents_array_len) >= 2) {
parents_array[parents_array_len] = &child_chaining_values[2 *
parents_array_len * BLAKE3_OUT_LEN];
parents_array_len += 1;
}
ops->hash_many(parents_array, parents_array_len, 1, key, 0, B_FALSE,
flags | PARENT, 0, 0, out);
/* If there's an odd child left over, it becomes an output. */
if (num_chaining_values > 2 * parents_array_len) {
memcpy(&out[parents_array_len * BLAKE3_OUT_LEN],
&child_chaining_values[2 * parents_array_len *
BLAKE3_OUT_LEN], BLAKE3_OUT_LEN);
return (parents_array_len + 1);
} else {
return (parents_array_len);
}
}
/*
* The wide helper function returns (writes out) an array of chaining values
* and returns the length of that array. The number of chaining values returned
* is the dyanmically detected SIMD degree, at most MAX_SIMD_DEGREE. Or fewer,
* if the input is shorter than that many chunks. The reason for maintaining a
* wide array of chaining values going back up the tree, is to allow the
* implementation to hash as many parents in parallel as possible.
*
* As a special case when the SIMD degree is 1, this function will still return
* at least 2 outputs. This guarantees that this function doesn't perform the
* root compression. (If it did, it would use the wrong flags, and also we
* wouldn't be able to implement exendable ouput.) Note that this function is
* not used when the whole input is only 1 chunk long; that's a different
* codepath.
*
* Why not just have the caller split the input on the first update(), instead
* of implementing this special rule? Because we don't want to limit SIMD or
* multi-threading parallelism for that update().
*/
static size_t blake3_compress_subtree_wide(const blake3_ops_t *ops,
const uint8_t *input, size_t input_len, const uint32_t key[8],
uint64_t chunk_counter, uint8_t flags, uint8_t *out)
{
/*
* Note that the single chunk case does *not* bump the SIMD degree up
* to 2 when it is 1. If this implementation adds multi-threading in
* the future, this gives us the option of multi-threading even the
* 2-chunk case, which can help performance on smaller platforms.
*/
if (input_len <= (size_t)(ops->degree * BLAKE3_CHUNK_LEN)) {
return (compress_chunks_parallel(ops, input, input_len, key,
chunk_counter, flags, out));
}
/*
* With more than simd_degree chunks, we need to recurse. Start by
* dividing the input into left and right subtrees. (Note that this is
* only optimal as long as the SIMD degree is a power of 2. If we ever
* get a SIMD degree of 3 or something, we'll need a more complicated
* strategy.)
*/
size_t left_input_len = left_len(input_len);
size_t right_input_len = input_len - left_input_len;
const uint8_t *right_input = &input[left_input_len];
uint64_t right_chunk_counter = chunk_counter +
(uint64_t)(left_input_len / BLAKE3_CHUNK_LEN);
/*
* Make space for the child outputs. Here we use MAX_SIMD_DEGREE_OR_2
* to account for the special case of returning 2 outputs when the
* SIMD degree is 1.
*/
uint8_t cv_array[2 * MAX_SIMD_DEGREE_OR_2 * BLAKE3_OUT_LEN];
size_t degree = ops->degree;
if (left_input_len > BLAKE3_CHUNK_LEN && degree == 1) {
/*
* The special case: We always use a degree of at least two,
* to make sure there are two outputs. Except, as noted above,
* at the chunk level, where we allow degree=1. (Note that the
* 1-chunk-input case is a different codepath.)
*/
degree = 2;
}
uint8_t *right_cvs = &cv_array[degree * BLAKE3_OUT_LEN];
/*
* Recurse! If this implementation adds multi-threading support in the
* future, this is where it will go.
*/
size_t left_n = blake3_compress_subtree_wide(ops, input, left_input_len,
key, chunk_counter, flags, cv_array);
size_t right_n = blake3_compress_subtree_wide(ops, right_input,
right_input_len, key, right_chunk_counter, flags, right_cvs);
/*
* The special case again. If simd_degree=1, then we'll have left_n=1
* and right_n=1. Rather than compressing them into a single output,
* return them directly, to make sure we always have at least two
* outputs.
*/
if (left_n == 1) {
memcpy(out, cv_array, 2 * BLAKE3_OUT_LEN);
return (2);
}
/* Otherwise, do one layer of parent node compression. */
size_t num_chaining_values = left_n + right_n;
return compress_parents_parallel(ops, cv_array,
num_chaining_values, key, flags, out);
}
/*
* Hash a subtree with compress_subtree_wide(), and then condense the resulting
* list of chaining values down to a single parent node. Don't compress that
* last parent node, however. Instead, return its message bytes (the
* concatenated chaining values of its children). This is necessary when the
* first call to update() supplies a complete subtree, because the topmost
* parent node of that subtree could end up being the root. It's also necessary
* for extended output in the general case.
*
* As with compress_subtree_wide(), this function is not used on inputs of 1
* chunk or less. That's a different codepath.
*/
static void compress_subtree_to_parent_node(const blake3_ops_t *ops,
const uint8_t *input, size_t input_len, const uint32_t key[8],
uint64_t chunk_counter, uint8_t flags, uint8_t out[2 * BLAKE3_OUT_LEN])
{
uint8_t cv_array[MAX_SIMD_DEGREE_OR_2 * BLAKE3_OUT_LEN];
size_t num_cvs = blake3_compress_subtree_wide(ops, input, input_len,
key, chunk_counter, flags, cv_array);
/*
* If MAX_SIMD_DEGREE is greater than 2 and there's enough input,
* compress_subtree_wide() returns more than 2 chaining values. Condense
* them into 2 by forming parent nodes repeatedly.
*/
uint8_t out_array[MAX_SIMD_DEGREE_OR_2 * BLAKE3_OUT_LEN / 2];
while (num_cvs > 2) {
num_cvs = compress_parents_parallel(ops, cv_array, num_cvs, key,
flags, out_array);
memcpy(cv_array, out_array, num_cvs * BLAKE3_OUT_LEN);
}
memcpy(out, cv_array, 2 * BLAKE3_OUT_LEN);
}
static void hasher_init_base(BLAKE3_CTX *ctx, const uint32_t key[8],
uint8_t flags)
{
memcpy(ctx->key, key, BLAKE3_KEY_LEN);
chunk_state_init(&ctx->chunk, key, flags);
ctx->cv_stack_len = 0;
ctx->ops = blake3_impl_get_ops();
}
/*
* As described in hasher_push_cv() below, we do "lazy merging", delaying
* merges until right before the next CV is about to be added. This is
* different from the reference implementation. Another difference is that we
* aren't always merging 1 chunk at a time. Instead, each CV might represent
* any power-of-two number of chunks, as long as the smaller-above-larger
* stack order is maintained. Instead of the "count the trailing 0-bits"
* algorithm described in the spec, we use a "count the total number of
* 1-bits" variant 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.
*/
static void hasher_merge_cv_stack(BLAKE3_CTX *ctx, uint64_t total_len)
{
size_t post_merge_stack_len = (size_t)popcnt(total_len);
while (ctx->cv_stack_len > post_merge_stack_len) {
uint8_t *parent_node =
&ctx->cv_stack[(ctx->cv_stack_len - 2) * BLAKE3_OUT_LEN];
output_t output =
parent_output(parent_node, ctx->key, ctx->chunk.flags);
output_chaining_value(ctx->ops, &output, parent_node);
ctx->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.)
*/
static void hasher_push_cv(BLAKE3_CTX *ctx, uint8_t new_cv[BLAKE3_OUT_LEN],
uint64_t chunk_counter)
{
hasher_merge_cv_stack(ctx, chunk_counter);
memcpy(&ctx->cv_stack[ctx->cv_stack_len * BLAKE3_OUT_LEN], new_cv,
BLAKE3_OUT_LEN);
ctx->cv_stack_len += 1;
}
void
Blake3_Init(BLAKE3_CTX *ctx)
{
hasher_init_base(ctx, BLAKE3_IV, 0);
}
void
Blake3_InitKeyed(BLAKE3_CTX *ctx, const uint8_t key[BLAKE3_KEY_LEN])
{
uint32_t key_words[8];
load_key_words(key, key_words);
hasher_init_base(ctx, key_words, KEYED_HASH);
}
static void
Blake3_Update2(BLAKE3_CTX *ctx, 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(&ctx->chunk) > 0) {
size_t take = BLAKE3_CHUNK_LEN - chunk_state_len(&ctx->chunk);
if (take > input_len) {
take = input_len;
}
chunk_state_update(ctx->ops, &ctx->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(&ctx->chunk);
uint8_t chunk_cv[32];
output_chaining_value(ctx->ops, &output, chunk_cv);
hasher_push_cv(ctx, chunk_cv, ctx->chunk.chunk_counter);
chunk_state_reset(&ctx->chunk, ctx->key,
ctx->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 =
ctx->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_t chunk_state;
chunk_state_init(&chunk_state, ctx->key,
ctx->chunk.flags);
chunk_state.chunk_counter = ctx->chunk.chunk_counter;
chunk_state_update(ctx->ops, &chunk_state, input_bytes,
subtree_len);
output_t output = chunk_state_output(&chunk_state);
uint8_t cv[BLAKE3_OUT_LEN];
output_chaining_value(ctx->ops, &output, cv);
hasher_push_cv(ctx, 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(ctx->ops, input_bytes,
subtree_len, ctx->key, ctx-> chunk.chunk_counter,
ctx->chunk.flags, cv_pair);
hasher_push_cv(ctx, cv_pair, ctx->chunk.chunk_counter);
hasher_push_cv(ctx, &cv_pair[BLAKE3_OUT_LEN],
ctx->chunk.chunk_counter + (subtree_chunks / 2));
}
ctx->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(ctx->ops, &ctx->chunk, input_bytes,
input_len);
hasher_merge_cv_stack(ctx, ctx->chunk.chunk_counter);
}
}
void
Blake3_Update(BLAKE3_CTX *ctx, const void *input, size_t todo)
{
size_t done = 0;
const uint8_t *data = input;
const size_t block_max = 1024 * 64;
/* max feed buffer to leave the stack size small */
while (todo != 0) {
size_t block = (todo >= block_max) ? block_max : todo;
Blake3_Update2(ctx, data + done, block);
done += block;
todo -= block;
}
}
void
Blake3_Final(const BLAKE3_CTX *ctx, uint8_t *out)
{
Blake3_FinalSeek(ctx, 0, out, BLAKE3_OUT_LEN);
}
void
Blake3_FinalSeek(const BLAKE3_CTX *ctx, 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 (ctx->cv_stack_len == 0) {
output_t output = chunk_state_output(&ctx->chunk);
output_root_bytes(ctx->ops, &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(&ctx->chunk) > 0) {
cvs_remaining = ctx->cv_stack_len;
output = chunk_state_output(&ctx->chunk);
} else {
/* There are always at least 2 CVs in the stack in this case. */
cvs_remaining = ctx->cv_stack_len - 2;
output = parent_output(&ctx->cv_stack[cvs_remaining * 32],
ctx->key, ctx->chunk.flags);
}
while (cvs_remaining > 0) {
cvs_remaining -= 1;
uint8_t parent_block[BLAKE3_BLOCK_LEN];
memcpy(parent_block, &ctx->cv_stack[cvs_remaining * 32], 32);
output_chaining_value(ctx->ops, &output, &parent_block[32]);
output = parent_output(parent_block, ctx->key,
ctx->chunk.flags);
}
output_root_bytes(ctx->ops, &output, seek, out, out_len);
}