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MWEB: Adding dependencies

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David Burkett 2022-01-29 11:55:22 -05:00 committed by Loshan T
parent c87e3f7448
commit e735822f3d
33 changed files with 31505 additions and 1 deletions
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1
Makefile.am
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@ -190,6 +190,7 @@ LCOV_FILTER_PATTERN = \
-p "src/bench/" \
-p "src/univalue" \
-p "src/crypto/ctaes" \
-p "src/crypto/blake3" \
-p "src/secp256k1-zkp" \
-p "depends"

3
configure.ac
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@ -1414,6 +1414,9 @@ if test "x$use_zmq" = xyes; then
esac
fi
AC_CHECK_LIB([fmt],[main],MWEB_LIBS=-lfmt,AC_MSG_ERROR(libfmt missing))
dnl univalue check
need_bundled_univalue=yes

5
depends/cmake/mingw-w64-x86_64.cmake Normal file
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@ -0,0 +1,5 @@
set(CMAKE_SYSTEM_NAME Windows)
set(TOOLCHAIN_PREFIX x86_64-w64-mingw32)
set(CMAKE_C_COMPILER ${TOOLCHAIN_PREFIX}-gcc-posix)
set(CMAKE_CXX_COMPILER ${TOOLCHAIN_PREFIX}-g++-posix)

21
depends/packages/libfmt.mk Normal file
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@ -0,0 +1,21 @@
package=libfmt
$(package)_version=7.1.3
$(package)_download_path=https://github.com/fmtlib/fmt/archive/
$(package)_file_name=$($(package)_version).tar.gz
$(package)_sha256_hash=5cae7072042b3043e12d53d50ef404bbb76949dad1de368d7f993a15c8c05ecc
define $(package)_set_vars
$(package)_config_opts_x86_64_mingw32=-DCMAKE_TOOLCHAIN_FILE=$(BASEDIR)/cmake/mingw-w64-x86_64.cmake
endef
define $(package)_config_cmds
cmake -DCMAKE_POSITION_INDEPENDENT_CODE:BOOL=true $($(package)_config_opts) .
endef
define $(package)_build_cmds
$(MAKE) && \
mkdir -p $($(package)_staging_dir)$(host_prefix)/include && \
cp -a include/* $($(package)_staging_dir)$(host_prefix)/include/ && \
mkdir -p $($(package)_staging_dir)$(host_prefix)/lib && \
cp -a libfmt.a $($(package)_staging_dir)$(host_prefix)/lib/
endef

2
depends/packages/packages.mk
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@ -1,4 +1,4 @@
packages:=boost openssl libevent
packages:=boost openssl libevent libfmt
qt_packages = zlib

3
src/crypto/blake3/.gitignore vendored Normal file
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@ -0,0 +1,3 @@
blake3
example
*.o

78
src/crypto/blake3/Makefile.testing Normal file
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@ -0,0 +1,78 @@
# This Makefile is only for testing. C callers should follow the instructions
# in ./README.md to incorporate these C files into their existing build.
NAME=blake3
CC=gcc
CFLAGS=-O3 -Wall -Wextra -std=c11 -pedantic -fstack-protector-strong -D_FORTIFY_SOURCE=2 -fPIE -fvisibility=hidden
LDFLAGS=-pie -Wl,-z,relro,-z,now
TARGETS=
ASM_TARGETS=
EXTRAFLAGS=-Wa,--noexecstack
ifdef BLAKE3_NO_SSE2
EXTRAFLAGS += -DBLAKE3_NO_SSE2
else
TARGETS += blake3_sse2.o
ASM_TARGETS += blake3_sse2_x86-64_unix.S
endif
ifdef BLAKE3_NO_SSE41
EXTRAFLAGS += -DBLAKE3_NO_SSE41
else
TARGETS += blake3_sse41.o
ASM_TARGETS += blake3_sse41_x86-64_unix.S
endif
ifdef BLAKE3_NO_AVX2
EXTRAFLAGS += -DBLAKE3_NO_AVX2
else
TARGETS += blake3_avx2.o
ASM_TARGETS += blake3_avx2_x86-64_unix.S
endif
ifdef BLAKE3_NO_AVX512
EXTRAFLAGS += -DBLAKE3_NO_AVX512
else
TARGETS += blake3_avx512.o
ASM_TARGETS += blake3_avx512_x86-64_unix.S
endif
ifdef BLAKE3_USE_NEON
EXTRAFLAGS += -DBLAKE3_USE_NEON
TARGETS += blake3_neon.o
endif
all: blake3.c blake3_dispatch.c blake3_portable.c main.c $(TARGETS)
$(CC) $(CFLAGS) $(EXTRAFLAGS) $^ -o $(NAME) $(LDFLAGS)
blake3_sse2.o: blake3_sse2.c
$(CC) $(CFLAGS) $(EXTRAFLAGS) -c $^ -o $@ -msse2
blake3_sse41.o: blake3_sse41.c
$(CC) $(CFLAGS) $(EXTRAFLAGS) -c $^ -o $@ -msse4.1
blake3_avx2.o: blake3_avx2.c
$(CC) $(CFLAGS) $(EXTRAFLAGS) -c $^ -o $@ -mavx2
blake3_avx512.o: blake3_avx512.c
$(CC) $(CFLAGS) $(EXTRAFLAGS) -c $^ -o $@ -mavx512f -mavx512vl
blake3_neon.o: blake3_neon.c
$(CC) $(CFLAGS) $(EXTRAFLAGS) -c $^ -o $@
test: CFLAGS += -DBLAKE3_TESTING -fsanitize=address,undefined
test: all
./test.py
asm: blake3.c blake3_dispatch.c blake3_portable.c main.c $(ASM_TARGETS)
$(CC) $(CFLAGS) $(EXTRAFLAGS) $^ -o $(NAME) $(LDFLAGS)
test_asm: CFLAGS += -DBLAKE3_TESTING -fsanitize=address,undefined
test_asm: asm
./test.py
example: example.c blake3.c blake3_dispatch.c blake3_portable.c $(ASM_TARGETS)
$(CC) $(CFLAGS) $(EXTRAFLAGS) $^ -o $@ $(LDFLAGS)
clean:
rm -f $(NAME) *.o

282
src/crypto/blake3/README.md Normal file
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@ -0,0 +1,282 @@
The official C implementation of BLAKE3.
# Example
An example program that hashes bytes from standard input and prints the
result:
```c
#include "blake3.h"
#include <stdio.h>
#include <unistd.h>
int main() {
// Initialize the hasher.
blake3_hasher hasher;
blake3_hasher_init(&hasher);
// Read input bytes from stdin.
unsigned char buf[65536];
ssize_t n;
while ((n = read(STDIN_FILENO, buf, sizeof(buf))) > 0) {
blake3_hasher_update(&hasher, buf, n);
}
// Finalize the hash. BLAKE3_OUT_LEN is the default output length, 32 bytes.
uint8_t output[BLAKE3_OUT_LEN];
blake3_hasher_finalize(&hasher, output, BLAKE3_OUT_LEN);
// Print the hash as hexadecimal.
for (size_t i = 0; i < BLAKE3_OUT_LEN; i++) {
printf("%02x", output[i]);
}
printf("\n");
return 0;
}
```
The code above is included in this directory as `example.c`. If you're
on x86\_64 with a Unix-like OS, you can compile a working binary like
this:
```bash
gcc -O3 -o example example.c blake3.c blake3_dispatch.c blake3_portable.c \
blake3_sse2_x86-64_unix.S blake3_sse41_x86-64_unix.S blake3_avx2_x86-64_unix.S \
blake3_avx512_x86-64_unix.S
```
# API
## The Struct
```c
typedef struct {
// private fields
} blake3_hasher;
```
An incremental BLAKE3 hashing state, which can accept any number of
updates. This implementation doesn't allocate any heap memory, but
`sizeof(blake3_hasher)` itself is relatively large, currently 1912 bytes
on x86-64. This size can be reduced by restricting the maximum input
length, as described in Section 5.4 of [the BLAKE3
spec](https://github.com/BLAKE3-team/BLAKE3-specs/blob/master/blake3.pdf),
but this implementation doesn't currently support that strategy.
## Common API Functions
```c
void blake3_hasher_init(
blake3_hasher *self);
```
Initialize a `blake3_hasher` in the default hashing mode.
---
```c
void blake3_hasher_update(
blake3_hasher *self,
const void *input,
size_t input_len);
```
Add input to the hasher. This can be called any number of times.
---
```c
void blake3_hasher_finalize(
const blake3_hasher *self,
uint8_t *out,
size_t out_len);
```
Finalize the hasher and return an output of any length, given in bytes.
This doesn't modify the hasher itself, and it's possible to finalize
again after adding more input. The constant `BLAKE3_OUT_LEN` provides
the default output length, 32 bytes, which is recommended for most
callers.
Outputs shorter than the default length of 32 bytes (256 bits) provide
less security. An N-bit BLAKE3 output is intended to provide N bits of
first and second preimage resistance and N/2 bits of collision
resistance, for any N up to 256. Longer outputs don't provide any
additional security.
Shorter BLAKE3 outputs are prefixes of longer ones. Explicitly
requesting a short output is equivalent to truncating the default-length
output. (Note that this is different between BLAKE2 and BLAKE3.)
## Less Common API Functions
```c
void blake3_hasher_init_keyed(
blake3_hasher *self,
const uint8_t key[BLAKE3_KEY_LEN]);
```
Initialize a `blake3_hasher` in the keyed hashing mode. The key must be
exactly 32 bytes.
---
```c
void blake3_hasher_init_derive_key(
blake3_hasher *self,
const char *context);
```
Initialize a `blake3_hasher` in the key derivation mode. The context
string is given as an initialization parameter, and afterwards input key
material should be given with `blake3_hasher_update`. The context string
is a null-terminated C string which should be **hardcoded, globally
unique, and application-specific**. The context string should not
include any dynamic input like salts, nonces, or identifiers read from a
database at runtime. A good default format for the context string is
`"[application] [commit timestamp] [purpose]"`, e.g., `"example.com
2019-12-25 16:18:03 session tokens v1"`.
This function is intended for application code written in C. For
language bindings, see `blake3_hasher_init_derive_key_raw` below.
---
```c
void blake3_hasher_init_derive_key_raw(
blake3_hasher *self,
const void *context,
size_t context_len);
```
As `blake3_hasher_init_derive_key` above, except that the context string
is given as a pointer to an array of arbitrary bytes with a provided
length. This is intended for writing language bindings, where C string
conversion would add unnecessary overhead and new error cases. Unicode
strings should be encoded as UTF-8.
Application code in C should prefer `blake3_hasher_init_derive_key`,
which takes the context as a C string. If you need to use arbitrary
bytes as a context string in application code, consider whether you're
violating the requirement that context strings should be hardcoded.
---
```c
void blake3_hasher_finalize_seek(
const blake3_hasher *self,
uint64_t seek,
uint8_t *out,
size_t out_len);
```
The same as `blake3_hasher_finalize`, but with an additional `seek`
parameter for the starting byte position in the output stream. To
efficiently stream a large output without allocating memory, call this
function in a loop, incrementing `seek` by the output length each time.
# Building
This implementation is just C and assembly files. It doesn't include a
public-facing build system. (The `Makefile` in this directory is only
for testing.) Instead, the intention is that you can include these files
in whatever build system you're already using. This section describes
the commands your build system should execute, or which you can execute
by hand. Note that these steps may change in future versions.
## x86
Dynamic dispatch is enabled by default on x86. The implementation will
query the CPU at runtime to detect SIMD support, and it will use the
widest instruction set available. By default, `blake3_dispatch.c`
expects to be linked with code for five different instruction sets:
portable C, SSE2, SSE4.1, AVX2, and AVX-512.
For each of the x86 SIMD instruction sets, four versions are available:
three flavors of assembly (Unix, Windows MSVC, and Windows GNU) and one
version using C intrinsics. The assembly versions are generally
preferred. They perform better, they perform more consistently across
different compilers, and they build more quickly. On the other hand, the
assembly versions are x86\_64-only, and you need to select the right
flavor for your target platform.
Here's an example of building a shared library on x86\_64 Linux using
the assembly implementations:
```bash
gcc -shared -O3 -o libblake3.so blake3.c blake3_dispatch.c blake3_portable.c \
blake3_sse2_x86-64_unix.S blake3_sse41_x86-64_unix.S blake3_avx2_x86-64_unix.S \
blake3_avx512_x86-64_unix.S
```
When building the intrinsics-based implementations, you need to build
each implementation separately, with the corresponding instruction set
explicitly enabled in the compiler. Here's the same shared library using
the intrinsics-based implementations:
```bash
gcc -c -fPIC -O3 -msse2 blake3_sse2.c -o blake3_sse2.o
gcc -c -fPIC -O3 -msse4.1 blake3_sse41.c -o blake3_sse41.o
gcc -c -fPIC -O3 -mavx2 blake3_avx2.c -o blake3_avx2.o
gcc -c -fPIC -O3 -mavx512f -mavx512vl blake3_avx512.c -o blake3_avx512.o
gcc -shared -O3 -o libblake3.so blake3.c blake3_dispatch.c blake3_portable.c \
blake3_avx2.o blake3_avx512.o blake3_sse41.o blake3_sse2.o
```
Note above that building `blake3_avx512.c` requires both `-mavx512f` and
`-mavx512vl` under GCC and Clang. Under MSVC, the single `/arch:AVX512`
flag is sufficient. The MSVC equivalent of `-mavx2` is `/arch:AVX2`.
MSVC enables SSE2 and SSE4.1 by defaut, and it doesn't have a
corresponding flag.
If you want to omit SIMD code entirely, you need to explicitly disable
each instruction set. Here's an example of building a shared library on
x86 with only portable code:
```bash
gcc -shared -O3 -o libblake3.so -DBLAKE3_NO_SSE2 -DBLAKE3_NO_SSE41 -DBLAKE3_NO_AVX2 \
-DBLAKE3_NO_AVX512 blake3.c blake3_dispatch.c blake3_portable.c
```
## ARM NEON
The NEON implementation is not enabled by default on ARM, since not all
ARM targets support it. To enable it, set `BLAKE3_USE_NEON=1`. Here's an
example of building a shared library on ARM Linux with NEON support:
```bash
gcc -shared -O3 -o libblake3.so -DBLAKE3_USE_NEON blake3.c blake3_dispatch.c \
blake3_portable.c blake3_neon.c
```
Note that on some targets (ARMv7 in particular), extra flags may be
required to activate NEON support in the compiler. If you see an error
like...
```
/usr/lib/gcc/armv7l-unknown-linux-gnueabihf/9.2.0/include/arm_neon.h:635:1: error: inlining failed
in call to always_inline vaddq_u32: target specific option mismatch
```
...then you may need to add something like `-mfpu=neon-vfpv4
-mfloat-abi=hard`.
## Other Platforms
The portable implementation should work on most other architectures. For
example:
```bash
gcc -shared -O3 -o libblake3.so blake3.c blake3_dispatch.c blake3_portable.c
```
# Multithreading
Unlike the Rust implementation, the C implementation doesn't currently support
multithreading. A future version of this library could add support by taking an
optional dependency on OpenMP or similar. Alternatively, we could expose a
lower-level API to allow callers to implement concurrency themselves. The
former would be more convenient and less error-prone, but the latter would give
callers the maximum possible amount of control. The best choice here depends on
the specific use case, so if you have a use case for multithreaded hashing in
C, please file a GitHub issue and let us know.

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src/crypto/blake3/blake3.c Normal file
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#include <assert.h>
#include <stdbool.h>
#include <string.h>
#include "blake3.h"
#include "blake3_impl.h"
const char *blake3_version(void) { return BLAKE3_VERSION_STRING; }
INLINE void chunk_state_init(blake3_chunk_state *self, const uint32_t key[8],
uint8_t flags) {
memcpy(self->cv, key, BLAKE3_KEY_LEN);
self->chunk_counter = 0;
memset(self->buf, 0, BLAKE3_BLOCK_LEN);
self->buf_len = 0;
self->blocks_compressed = 0;
self->flags = flags;
}
INLINE void chunk_state_reset(blake3_chunk_state *self, const uint32_t key[8],
uint64_t chunk_counter) {
memcpy(self->cv, key, BLAKE3_KEY_LEN);
self->chunk_counter = chunk_counter;
self->blocks_compressed = 0;
memset(self->buf, 0, BLAKE3_BLOCK_LEN);
self->buf_len = 0;
}
INLINE size_t chunk_state_len(const blake3_chunk_state *self) {
return (BLAKE3_BLOCK_LEN * (size_t)self->blocks_compressed) +
((size_t)self->buf_len);
}
INLINE size_t chunk_state_fill_buf(blake3_chunk_state *self,
const uint8_t *input, size_t input_len) {
size_t take = BLAKE3_BLOCK_LEN - ((size_t)self->buf_len);
if (take > input_len) {
take = input_len;
}
uint8_t *dest = self->buf + ((size_t)self->buf_len);
memcpy(dest, input, take);
self->buf_len += (uint8_t)take;
return take;
}
INLINE uint8_t chunk_state_maybe_start_flag(const blake3_chunk_state *self) {
if (self->blocks_compressed == 0) {
return CHUNK_START;
} else {
return 0;
}
}
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;
INLINE output_t make_output(const uint32_t input_cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
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.
INLINE void output_chaining_value(const output_t *self, uint8_t cv[32]) {
uint32_t cv_words[8];
memcpy(cv_words, self->input_cv, 32);
blake3_compress_in_place(cv_words, self->block, self->block_len,
self->counter, self->flags);
store_cv_words(cv, cv_words);
}
INLINE void output_root_bytes(const output_t *self, 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) {
blake3_compress_xof(self->input_cv, self->block, self->block_len,
output_block_counter, self->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;
}
}
INLINE void chunk_state_update(blake3_chunk_state *self, const uint8_t *input,
size_t input_len) {
if (self->buf_len > 0) {
size_t take = chunk_state_fill_buf(self, input, input_len);
input += take;
input_len -= take;
if (input_len > 0) {
blake3_compress_in_place(
self->cv, self->buf, BLAKE3_BLOCK_LEN, self->chunk_counter,
self->flags | chunk_state_maybe_start_flag(self));
self->blocks_compressed += 1;
self->buf_len = 0;
memset(self->buf, 0, BLAKE3_BLOCK_LEN);
}
}
while (input_len > BLAKE3_BLOCK_LEN) {
blake3_compress_in_place(self->cv, input, BLAKE3_BLOCK_LEN,
self->chunk_counter,
self->flags | chunk_state_maybe_start_flag(self));
self->blocks_compressed += 1;
input += BLAKE3_BLOCK_LEN;
input_len -= BLAKE3_BLOCK_LEN;
}
size_t take = chunk_state_fill_buf(self, input, input_len);
input += take;
input_len -= take;
}
INLINE output_t chunk_state_output(const blake3_chunk_state *self) {
uint8_t block_flags =
self->flags | chunk_state_maybe_start_flag(self) | CHUNK_END;
return make_output(self->cv, self->buf, self->buf_len, self->chunk_counter,
block_flags);
}
INLINE 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.
INLINE 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.
INLINE size_t compress_chunks_parallel(const uint8_t *input, size_t input_len,
const uint32_t key[8],
uint64_t chunk_counter, uint8_t flags,
uint8_t *out) {
#if defined(BLAKE3_TESTING)
assert(0 < input_len);
assert(input_len <= MAX_SIMD_DEGREE * BLAKE3_CHUNK_LEN);
#endif
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;
}
blake3_hash_many(chunks_array, chunks_array_len,
BLAKE3_CHUNK_LEN / BLAKE3_BLOCK_LEN, key, chunk_counter,
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 chunk_state;
chunk_state_init(&chunk_state, key, flags);
chunk_state.chunk_counter = counter;
chunk_state_update(&chunk_state, &input[input_position],
input_len - input_position);
output_t output = chunk_state_output(&chunk_state);
output_chaining_value(&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.
INLINE size_t compress_parents_parallel(const uint8_t *child_chaining_values,
size_t num_chaining_values,
const uint32_t key[8], uint8_t flags,
uint8_t *out) {
#if defined(BLAKE3_TESTING)
assert(2 <= num_chaining_values);
assert(num_chaining_values <= 2 * MAX_SIMD_DEGREE_OR_2);
#endif
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;
}
blake3_hash_many(parents_array, parents_array_len, 1, key,
0, // Parents always use counter 0.
false, flags | PARENT,
0, // Parents have no start flags.
0, // Parents have no end flags.
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 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 <= blake3_simd_degree() * BLAKE3_CHUNK_LEN) {
return compress_chunks_parallel(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 = blake3_simd_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(input, left_input_len, key,
chunk_counter, flags, cv_array);
size_t right_n = blake3_compress_subtree_wide(
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(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.
INLINE void compress_subtree_to_parent_node(
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]) {
#if defined(BLAKE3_TESTING)
assert(input_len > BLAKE3_CHUNK_LEN);
#endif
uint8_t cv_array[MAX_SIMD_DEGREE_OR_2 * BLAKE3_OUT_LEN];
size_t num_cvs = blake3_compress_subtree_wide(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(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);
}
INLINE void hasher_init_base(blake3_hasher *self, const uint32_t key[8],
uint8_t flags) {
memcpy(self->key, key, BLAKE3_KEY_LEN);
chunk_state_init(&self->chunk, key, flags);
self->cv_stack_len = 0;
}
void blake3_hasher_init(blake3_hasher *self) { hasher_init_base(self, IV, 0); }
void blake3_hasher_init_keyed(blake3_hasher *self,
const uint8_t key[BLAKE3_KEY_LEN]) {
uint32_t key_words[8];
load_key_words(key, key_words);
hasher_init_base(self, key_words, KEYED_HASH);
}
void blake3_hasher_init_derive_key_raw(blake3_hasher *self, const void *context,
size_t context_len) {
blake3_hasher context_hasher;
hasher_init_base(&context_hasher, IV, DERIVE_KEY_CONTEXT);
blake3_hasher_update(&context_hasher, context, context_len);
uint8_t context_key[BLAKE3_KEY_LEN];
blake3_hasher_finalize(&context_hasher, context_key, BLAKE3_KEY_LEN);
uint32_t context_key_words[8];
load_key_words(context_key, context_key_words);
hasher_init_base(self, context_key_words, DERIVE_KEY_MATERIAL);
}
void blake3_hasher_init_derive_key(blake3_hasher *self, const char *context) {
blake3_hasher_init_derive_key_raw(self, context, strlen(context));
}
// 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.
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 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 blake3_hasher_finalize(const blake3_hasher *self, uint8_t *out,
size_t out_len) {
blake3_hasher_finalize_seek(self, 0, out, out_len);
}
void 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);
}

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src/crypto/blake3/blake3.h Normal file
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#ifndef BLAKE3_H
#define BLAKE3_H
#include <stddef.h>
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
#define BLAKE3_VERSION_STRING "0.3.7"
#define BLAKE3_KEY_LEN 32
#define BLAKE3_OUT_LEN 32
#define BLAKE3_BLOCK_LEN 64
#define BLAKE3_CHUNK_LEN 1024
#define BLAKE3_MAX_DEPTH 54
// This struct is a private implementation detail. It has to be here because
// it's part of blake3_hasher below.
typedef struct {
uint32_t cv[8];
uint64_t chunk_counter;
uint8_t buf[BLAKE3_BLOCK_LEN];
uint8_t buf_len;
uint8_t blocks_compressed;
uint8_t flags;
} blake3_chunk_state;
typedef struct {
uint32_t key[8];
blake3_chunk_state chunk;
uint8_t cv_stack_len;
// The stack size is MAX_DEPTH + 1 because we do lazy merging. For example,
// with 7 chunks, we have 3 entries in the stack. Adding an 8th chunk
// requires a 4th entry, rather than merging everything down to 1, because we
// don't know whether more input is coming. This is different from how the
// reference implementation does things.
uint8_t cv_stack[(BLAKE3_MAX_DEPTH + 1) * BLAKE3_OUT_LEN];
} blake3_hasher;
const char *blake3_version(void);
void blake3_hasher_init(blake3_hasher *self);
void blake3_hasher_init_keyed(blake3_hasher *self,
const uint8_t key[BLAKE3_KEY_LEN]);
void blake3_hasher_init_derive_key(blake3_hasher *self, const char *context);
void blake3_hasher_init_derive_key_raw(blake3_hasher *self, const void *context,
size_t context_len);
void blake3_hasher_update(blake3_hasher *self, const void *input,
size_t input_len);
void blake3_hasher_finalize(const blake3_hasher *self, uint8_t *out,
size_t out_len);
void blake3_hasher_finalize_seek(const blake3_hasher *self, uint64_t seek,
uint8_t *out, size_t out_len);
#ifdef __cplusplus
}
#endif
#endif /* BLAKE3_H */

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src/crypto/blake3/blake3_avx2.c Normal file
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#include "blake3_impl.h"
#include <immintrin.h>
#define DEGREE 8
INLINE __m256i loadu(const uint8_t src[32]) {
return _mm256_loadu_si256((const __m256i *)src);
}
INLINE void storeu(__m256i src, uint8_t dest[16]) {
_mm256_storeu_si256((__m256i *)dest, src);
}
INLINE __m256i addv(__m256i a, __m256i b) { return _mm256_add_epi32(a, b); }
// Note that clang-format doesn't like the name "xor" for some reason.
INLINE __m256i xorv(__m256i a, __m256i b) { return _mm256_xor_si256(a, b); }
INLINE __m256i set1(uint32_t x) { return _mm256_set1_epi32((int32_t)x); }
INLINE __m256i rot16(__m256i x) {
return _mm256_shuffle_epi8(
x, _mm256_set_epi8(13, 12, 15, 14, 9, 8, 11, 10, 5, 4, 7, 6, 1, 0, 3, 2,
13, 12, 15, 14, 9, 8, 11, 10, 5, 4, 7, 6, 1, 0, 3, 2));
}
INLINE __m256i rot12(__m256i x) {
return _mm256_or_si256(_mm256_srli_epi32(x, 12), _mm256_slli_epi32(x, 32 - 12));
}
INLINE __m256i rot8(__m256i x) {
return _mm256_shuffle_epi8(
x, _mm256_set_epi8(12, 15, 14, 13, 8, 11, 10, 9, 4, 7, 6, 5, 0, 3, 2, 1,
12, 15, 14, 13, 8, 11, 10, 9, 4, 7, 6, 5, 0, 3, 2, 1));
}
INLINE __m256i rot7(__m256i x) {
return _mm256_or_si256(_mm256_srli_epi32(x, 7), _mm256_slli_epi32(x, 32 - 7));
}
INLINE void round_fn(__m256i v[16], __m256i m[16], size_t r) {
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][0]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][2]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][4]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][6]]);
v[0] = addv(v[0], v[4]);
v[1] = addv(v[1], v[5]);
v[2] = addv(v[2], v[6]);
v[3] = addv(v[3], v[7]);
v[12] = xorv(v[12], v[0]);
v[13] = xorv(v[13], v[1]);
v[14] = xorv(v[14], v[2]);
v[15] = xorv(v[15], v[3]);
v[12] = rot16(v[12]);
v[13] = rot16(v[13]);
v[14] = rot16(v[14]);
v[15] = rot16(v[15]);
v[8] = addv(v[8], v[12]);
v[9] = addv(v[9], v[13]);
v[10] = addv(v[10], v[14]);
v[11] = addv(v[11], v[15]);
v[4] = xorv(v[4], v[8]);
v[5] = xorv(v[5], v[9]);
v[6] = xorv(v[6], v[10]);
v[7] = xorv(v[7], v[11]);
v[4] = rot12(v[4]);
v[5] = rot12(v[5]);
v[6] = rot12(v[6]);
v[7] = rot12(v[7]);
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][1]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][3]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][5]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][7]]);
v[0] = addv(v[0], v[4]);
v[1] = addv(v[1], v[5]);
v[2] = addv(v[2], v[6]);
v[3] = addv(v[3], v[7]);
v[12] = xorv(v[12], v[0]);
v[13] = xorv(v[13], v[1]);
v[14] = xorv(v[14], v[2]);
v[15] = xorv(v[15], v[3]);
v[12] = rot8(v[12]);
v[13] = rot8(v[13]);
v[14] = rot8(v[14]);
v[15] = rot8(v[15]);
v[8] = addv(v[8], v[12]);
v[9] = addv(v[9], v[13]);
v[10] = addv(v[10], v[14]);
v[11] = addv(v[11], v[15]);
v[4] = xorv(v[4], v[8]);
v[5] = xorv(v[5], v[9]);
v[6] = xorv(v[6], v[10]);
v[7] = xorv(v[7], v[11]);
v[4] = rot7(v[4]);
v[5] = rot7(v[5]);
v[6] = rot7(v[6]);
v[7] = rot7(v[7]);
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][8]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][10]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][12]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][14]]);
v[0] = addv(v[0], v[5]);
v[1] = addv(v[1], v[6]);
v[2] = addv(v[2], v[7]);
v[3] = addv(v[3], v[4]);
v[15] = xorv(v[15], v[0]);
v[12] = xorv(v[12], v[1]);
v[13] = xorv(v[13], v[2]);
v[14] = xorv(v[14], v[3]);
v[15] = rot16(v[15]);
v[12] = rot16(v[12]);
v[13] = rot16(v[13]);
v[14] = rot16(v[14]);
v[10] = addv(v[10], v[15]);
v[11] = addv(v[11], v[12]);
v[8] = addv(v[8], v[13]);
v[9] = addv(v[9], v[14]);
v[5] = xorv(v[5], v[10]);
v[6] = xorv(v[6], v[11]);
v[7] = xorv(v[7], v[8]);
v[4] = xorv(v[4], v[9]);
v[5] = rot12(v[5]);
v[6] = rot12(v[6]);
v[7] = rot12(v[7]);
v[4] = rot12(v[4]);
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][9]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][11]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][13]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][15]]);
v[0] = addv(v[0], v[5]);
v[1] = addv(v[1], v[6]);
v[2] = addv(v[2], v[7]);
v[3] = addv(v[3], v[4]);
v[15] = xorv(v[15], v[0]);
v[12] = xorv(v[12], v[1]);
v[13] = xorv(v[13], v[2]);
v[14] = xorv(v[14], v[3]);
v[15] = rot8(v[15]);
v[12] = rot8(v[12]);
v[13] = rot8(v[13]);
v[14] = rot8(v[14]);
v[10] = addv(v[10], v[15]);
v[11] = addv(v[11], v[12]);
v[8] = addv(v[8], v[13]);
v[9] = addv(v[9], v[14]);
v[5] = xorv(v[5], v[10]);
v[6] = xorv(v[6], v[11]);
v[7] = xorv(v[7], v[8]);
v[4] = xorv(v[4], v[9]);
v[5] = rot7(v[5]);
v[6] = rot7(v[6]);
v[7] = rot7(v[7]);
v[4] = rot7(v[4]);
}
INLINE void transpose_vecs(__m256i vecs[DEGREE]) {
// Interleave 32-bit lanes. The low unpack is lanes 00/11/44/55, and the high
// is 22/33/66/77.
__m256i ab_0145 = _mm256_unpacklo_epi32(vecs[0], vecs[1]);
__m256i ab_2367 = _mm256_unpackhi_epi32(vecs[0], vecs[1]);
__m256i cd_0145 = _mm256_unpacklo_epi32(vecs[2], vecs[3]);
__m256i cd_2367 = _mm256_unpackhi_epi32(vecs[2], vecs[3]);
__m256i ef_0145 = _mm256_unpacklo_epi32(vecs[4], vecs[5]);
__m256i ef_2367 = _mm256_unpackhi_epi32(vecs[4], vecs[5]);
__m256i gh_0145 = _mm256_unpacklo_epi32(vecs[6], vecs[7]);
__m256i gh_2367 = _mm256_unpackhi_epi32(vecs[6], vecs[7]);
// Interleave 64-bit lates. The low unpack is lanes 00/22 and the high is
// 11/33.
__m256i abcd_04 = _mm256_unpacklo_epi64(ab_0145, cd_0145);
__m256i abcd_15 = _mm256_unpackhi_epi64(ab_0145, cd_0145);
__m256i abcd_26 = _mm256_unpacklo_epi64(ab_2367, cd_2367);
__m256i abcd_37 = _mm256_unpackhi_epi64(ab_2367, cd_2367);
__m256i efgh_04 = _mm256_unpacklo_epi64(ef_0145, gh_0145);
__m256i efgh_15 = _mm256_unpackhi_epi64(ef_0145, gh_0145);
__m256i efgh_26 = _mm256_unpacklo_epi64(ef_2367, gh_2367);
__m256i efgh_37 = _mm256_unpackhi_epi64(ef_2367, gh_2367);
// Interleave 128-bit lanes.
vecs[0] = _mm256_permute2x128_si256(abcd_04, efgh_04, 0x20);
vecs[1] = _mm256_permute2x128_si256(abcd_15, efgh_15, 0x20);
vecs[2] = _mm256_permute2x128_si256(abcd_26, efgh_26, 0x20);
vecs[3] = _mm256_permute2x128_si256(abcd_37, efgh_37, 0x20);
vecs[4] = _mm256_permute2x128_si256(abcd_04, efgh_04, 0x31);
vecs[5] = _mm256_permute2x128_si256(abcd_15, efgh_15, 0x31);
vecs[6] = _mm256_permute2x128_si256(abcd_26, efgh_26, 0x31);
vecs[7] = _mm256_permute2x128_si256(abcd_37, efgh_37, 0x31);
}
INLINE void transpose_msg_vecs(const uint8_t *const *inputs,
size_t block_offset, __m256i out[16]) {
out[0] = loadu(&inputs[0][block_offset + 0 * sizeof(__m256i)]);
out[1] = loadu(&inputs[1][block_offset + 0 * sizeof(__m256i)]);
out[2] = loadu(&inputs[2][block_offset + 0 * sizeof(__m256i)]);
out[3] = loadu(&inputs[3][block_offset + 0 * sizeof(__m256i)]);
out[4] = loadu(&inputs[4][block_offset + 0 * sizeof(__m256i)]);
out[5] = loadu(&inputs[5][block_offset + 0 * sizeof(__m256i)]);
out[6] = loadu(&inputs[6][block_offset + 0 * sizeof(__m256i)]);
out[7] = loadu(&inputs[7][block_offset + 0 * sizeof(__m256i)]);
out[8] = loadu(&inputs[0][block_offset + 1 * sizeof(__m256i)]);
out[9] = loadu(&inputs[1][block_offset + 1 * sizeof(__m256i)]);
out[10] = loadu(&inputs[2][block_offset + 1 * sizeof(__m256i)]);
out[11] = loadu(&inputs[3][block_offset + 1 * sizeof(__m256i)]);
out[12] = loadu(&inputs[4][block_offset + 1 * sizeof(__m256i)]);
out[13] = loadu(&inputs[5][block_offset + 1 * sizeof(__m256i)]);
out[14] = loadu(&inputs[6][block_offset + 1 * sizeof(__m256i)]);
out[15] = loadu(&inputs[7][block_offset + 1 * sizeof(__m256i)]);
for (size_t i = 0; i < 8; ++i) {
_mm_prefetch(&inputs[i][block_offset + 256], _MM_HINT_T0);
}
transpose_vecs(&out[0]);
transpose_vecs(&out[8]);
}
INLINE void load_counters(uint64_t counter, bool increment_counter,
__m256i *out_lo, __m256i *out_hi) {
const __m256i mask = _mm256_set1_epi32(-(int32_t)increment_counter);
const __m256i add0 = _mm256_set_epi32(7, 6, 5, 4, 3, 2, 1, 0);
const __m256i add1 = _mm256_and_si256(mask, add0);
__m256i l = _mm256_add_epi32(_mm256_set1_epi32(counter), add1);
__m256i carry = _mm256_cmpgt_epi32(_mm256_xor_si256(add1, _mm256_set1_epi32(0x80000000)),
_mm256_xor_si256( l, _mm256_set1_epi32(0x80000000)));
__m256i h = _mm256_sub_epi32(_mm256_set1_epi32(counter >> 32), carry);
*out_lo = l;
*out_hi = h;
}
void blake3_hash8_avx2(const uint8_t *const *inputs, size_t blocks,
const uint32_t key[8], uint64_t counter,
bool increment_counter, uint8_t flags,
uint8_t flags_start, uint8_t flags_end, uint8_t *out) {
__m256i h_vecs[8] = {
set1(key[0]), set1(key[1]), set1(key[2]), set1(key[3]),
set1(key[4]), set1(key[5]), set1(key[6]), set1(key[7]),
};
__m256i counter_low_vec, counter_high_vec;
load_counters(counter, increment_counter, &counter_low_vec,
&counter_high_vec);
uint8_t block_flags = flags | flags_start;
for (size_t block = 0; block < blocks; block++) {
if (block + 1 == blocks) {
block_flags |= flags_end;
}
__m256i block_len_vec = set1(BLAKE3_BLOCK_LEN);
__m256i block_flags_vec = set1(block_flags);
__m256i msg_vecs[16];
transpose_msg_vecs(inputs, block * BLAKE3_BLOCK_LEN, msg_vecs);
__m256i v[16] = {
h_vecs[0], h_vecs[1], h_vecs[2], h_vecs[3],
h_vecs[4], h_vecs[5], h_vecs[6], h_vecs[7],
set1(IV[0]), set1(IV[1]), set1(IV[2]), set1(IV[3]),
counter_low_vec, counter_high_vec, block_len_vec, block_flags_vec,
};
round_fn(v, msg_vecs, 0);
round_fn(v, msg_vecs, 1);
round_fn(v, msg_vecs, 2);
round_fn(v, msg_vecs, 3);
round_fn(v, msg_vecs, 4);
round_fn(v, msg_vecs, 5);
round_fn(v, msg_vecs, 6);
h_vecs[0] = xorv(v[0], v[8]);
h_vecs[1] = xorv(v[1], v[9]);
h_vecs[2] = xorv(v[2], v[10]);
h_vecs[3] = xorv(v[3], v[11]);
h_vecs[4] = xorv(v[4], v[12]);
h_vecs[5] = xorv(v[5], v[13]);
h_vecs[6] = xorv(v[6], v[14]);
h_vecs[7] = xorv(v[7], v[15]);
block_flags = flags;
}
transpose_vecs(h_vecs);
storeu(h_vecs[0], &out[0 * sizeof(__m256i)]);
storeu(h_vecs[1], &out[1 * sizeof(__m256i)]);
storeu(h_vecs[2], &out[2 * sizeof(__m256i)]);
storeu(h_vecs[3], &out[3 * sizeof(__m256i)]);
storeu(h_vecs[4], &out[4 * sizeof(__m256i)]);
storeu(h_vecs[5], &out[5 * sizeof(__m256i)]);
storeu(h_vecs[6], &out[6 * sizeof(__m256i)]);
storeu(h_vecs[7], &out[7 * sizeof(__m256i)]);
}
#if !defined(BLAKE3_NO_SSE41)
void blake3_hash_many_sse41(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out);
#else
void blake3_hash_many_portable(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out);
#endif
void blake3_hash_many_avx2(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out) {
while (num_inputs >= DEGREE) {
blake3_hash8_avx2(inputs, blocks, key, counter, increment_counter, flags,
flags_start, flags_end, out);
if (increment_counter) {
counter += DEGREE;
}
inputs += DEGREE;
num_inputs -= DEGREE;
out = &out[DEGREE * BLAKE3_OUT_LEN];
}
#if !defined(BLAKE3_NO_SSE41)
blake3_hash_many_sse41(inputs, num_inputs, blocks, key, counter,
increment_counter, flags, flags_start, flags_end, out);
#else
blake3_hash_many_portable(inputs, num_inputs, blocks, key, counter,
increment_counter, flags, flags_start, flags_end,
out);
#endif
}

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#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>
#include "blake3_impl.h"
#if defined(IS_X86)
#if defined(_MSC_VER)
#include <intrin.h>
#elif defined(__GNUC__)
#include <immintrin.h>
#else
#error "Unimplemented!"
#endif
#endif
#define MAYBE_UNUSED(x) (void)((x))
#if defined(IS_X86)
static uint64_t xgetbv() {
#if defined(_MSC_VER)
return _xgetbv(0);
#else
uint32_t eax = 0, edx = 0;
__asm__ __volatile__("xgetbv\n" : "=a"(eax), "=d"(edx) : "c"(0));
return ((uint64_t)edx << 32) | eax;
#endif
}
static void cpuid(uint32_t out[4], uint32_t id) {
#if defined(_MSC_VER)
__cpuid((int *)out, id);
#elif defined(__i386__) || defined(_M_IX86)
__asm__ __volatile__("movl %%ebx, %1\n"
"cpuid\n"
"xchgl %1, %%ebx\n"
: "=a"(out[0]), "=r"(out[1]), "=c"(out[2]), "=d"(out[3])
: "a"(id));
#else
__asm__ __volatile__("cpuid\n"
: "=a"(out[0]), "=b"(out[1]), "=c"(out[2]), "=d"(out[3])
: "a"(id));
#endif
}
static void cpuidex(uint32_t out[4], uint32_t id, uint32_t sid) {
#if defined(_MSC_VER)
__cpuidex((int *)out, id, sid);
#elif defined(__i386__) || defined(_M_IX86)
__asm__ __volatile__("movl %%ebx, %1\n"
"cpuid\n"
"xchgl %1, %%ebx\n"
: "=a"(out[0]), "=r"(out[1]), "=c"(out[2]), "=d"(out[3])
: "a"(id), "c"(sid));
#else
__asm__ __volatile__("cpuid\n"
: "=a"(out[0]), "=b"(out[1]), "=c"(out[2]), "=d"(out[3])
: "a"(id), "c"(sid));
#endif
}
#endif
enum cpu_feature {
SSE2 = 1 << 0,
SSSE3 = 1 << 1,
SSE41 = 1 << 2,
AVX = 1 << 3,
AVX2 = 1 << 4,
AVX512F = 1 << 5,
AVX512VL = 1 << 6,
/* ... */
UNDEFINED = 1 << 30
};
#if !defined(BLAKE3_TESTING)
static /* Allow the variable to be controlled manually for testing */
#endif
int g_cpu_features = UNDEFINED;
#if !defined(BLAKE3_TESTING)
static
#endif
int
get_cpu_features() {
if (g_cpu_features != UNDEFINED) {
return g_cpu_features;
} else {
#if defined(IS_X86)
uint32_t regs[4] = {0};
uint32_t *eax = &regs[0], *ebx = &regs[1], *ecx = &regs[2], *edx = &regs[3];
(void)edx;
int features = 0;
cpuid(regs, 0);
const int max_id = *eax;
cpuid(regs, 1);
#if defined(__amd64__) || defined(_M_X64)
features |= SSE2;
#else
if (*edx & (1UL << 26))
features |= SSE2;
#endif
if (*ecx & (1UL << 0))
features |= SSSE3;
if (*ecx & (1UL << 19))
features |= SSE41;
if (*ecx & (1UL << 27)) { // OSXSAVE
const uint64_t mask = xgetbv();
if ((mask & 6) == 6) { // SSE and AVX states
if (*ecx & (1UL << 28))
features |= AVX;
if (max_id >= 7) {
cpuidex(regs, 7, 0);
if (*ebx & (1UL << 5))
features |= AVX2;
if ((mask & 224) == 224) { // Opmask, ZMM_Hi256, Hi16_Zmm
if (*ebx & (1UL << 31))
features |= AVX512VL;
if (*ebx & (1UL << 16))
features |= AVX512F;
}
}
}
}
g_cpu_features = features;
return features;
#else
/* How to detect NEON? */
return 0;
#endif
}
}
void blake3_compress_in_place(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags) {
#if defined(IS_X86)
const int features = get_cpu_features();
MAYBE_UNUSED(features);
#if !defined(BLAKE3_NO_AVX512)
if (features & AVX512VL) {
blake3_compress_in_place_avx512(cv, block, block_len, counter, flags);
return;
}
#endif
#if !defined(BLAKE3_NO_SSE41)
if (features & SSE41) {
blake3_compress_in_place_sse41(cv, block, block_len, counter, flags);
return;
}
#endif
#if !defined(BLAKE3_NO_SSE2)
if (features & SSE2) {
blake3_compress_in_place_sse2(cv, block, block_len, counter, flags);
return;
}
#endif
#endif
blake3_compress_in_place_portable(cv, block, block_len, counter, flags);
}
void blake3_compress_xof(const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter, uint8_t flags,
uint8_t out[64]) {
#if defined(IS_X86)
const int features = get_cpu_features();
MAYBE_UNUSED(features);
#if !defined(BLAKE3_NO_AVX512)
if (features & AVX512VL) {
blake3_compress_xof_avx512(cv, block, block_len, counter, flags, out);
return;
}
#endif
#if !defined(BLAKE3_NO_SSE41)
if (features & SSE41) {
blake3_compress_xof_sse41(cv, block, block_len, counter, flags, out);
return;
}
#endif
#if !defined(BLAKE3_NO_SSE2)
if (features & SSE2) {
blake3_compress_xof_sse2(cv, block, block_len, counter, flags, out);
return;
}
#endif
#endif
blake3_compress_xof_portable(cv, block, block_len, counter, flags, out);
}
void blake3_hash_many(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8], uint64_t counter,
bool increment_counter, uint8_t flags,
uint8_t flags_start, uint8_t flags_end, uint8_t *out) {
#if defined(IS_X86)
const int features = get_cpu_features();
MAYBE_UNUSED(features);
#if !defined(BLAKE3_NO_AVX512)
if ((features & (AVX512F|AVX512VL)) == (AVX512F|AVX512VL)) {
blake3_hash_many_avx512(inputs, num_inputs, blocks, key, counter,
increment_counter, flags, flags_start, flags_end,
out);
return;
}
#endif
#if !defined(BLAKE3_NO_AVX2)
if (features & AVX2) {
blake3_hash_many_avx2(inputs, num_inputs, blocks, key, counter,
increment_counter, flags, flags_start, flags_end,
out);
return;
}
#endif
#if !defined(BLAKE3_NO_SSE41)
if (features & SSE41) {
blake3_hash_many_sse41(inputs, num_inputs, blocks, key, counter,
increment_counter, flags, flags_start, flags_end,
out);
return;
}
#endif
#if !defined(BLAKE3_NO_SSE2)
if (features & SSE2) {
blake3_hash_many_sse2(inputs, num_inputs, blocks, key, counter,
increment_counter, flags, flags_start, flags_end,
out);
return;
}
#endif
#endif
#if defined(BLAKE3_USE_NEON)
blake3_hash_many_neon(inputs, num_inputs, blocks, key, counter,
increment_counter, flags, flags_start, flags_end, out);
return;
#endif
blake3_hash_many_portable(inputs, num_inputs, blocks, key, counter,
increment_counter, flags, flags_start, flags_end,
out);
}
// The dynamically detected SIMD degree of the current platform.
size_t blake3_simd_degree(void) {
#if defined(IS_X86)
const int features = get_cpu_features();
MAYBE_UNUSED(features);
#if !defined(BLAKE3_NO_AVX512)
if ((features & (AVX512F|AVX512VL)) == (AVX512F|AVX512VL)) {
return 16;
}
#endif
#if !defined(BLAKE3_NO_AVX2)
if (features & AVX2) {
return 8;
}
#endif
#if !defined(BLAKE3_NO_SSE41)
if (features & SSE41) {
return 4;
}
#endif
#if !defined(BLAKE3_NO_SSE2)
if (features & SSE2) {
return 4;
}
#endif
#endif
#if defined(BLAKE3_USE_NEON)
return 4;
#endif
return 1;
}

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#ifndef BLAKE3_IMPL_H
#define BLAKE3_IMPL_H
#include <assert.h>
#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>
#include <string.h>
#include "blake3.h"
// 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,
};
// This C implementation tries to support recent versions of GCC, Clang, and
// MSVC.
#if defined(_MSC_VER)
#define INLINE static __forceinline
#else
#define INLINE static inline __attribute__((always_inline))
#endif
#if defined(__x86_64__) || defined(_M_X64)
#define IS_X86
#define IS_X86_64
#endif
#if defined(__i386__) || defined(_M_IX86)
#define IS_X86
#define IS_X86_32
#endif
#if defined(IS_X86)
#if defined(_MSC_VER)
#include <intrin.h>
#endif
#include <immintrin.h>
#endif
#if defined(IS_X86)
#define MAX_SIMD_DEGREE 16
#elif defined(BLAKE3_USE_NEON)
#define MAX_SIMD_DEGREE 4
#else
#define MAX_SIMD_DEGREE 1
#endif
// There are some places where we want a static size that's equal to the
// MAX_SIMD_DEGREE, but also at least 2.
#define MAX_SIMD_DEGREE_OR_2 (MAX_SIMD_DEGREE > 2 ? MAX_SIMD_DEGREE : 2)
static const uint32_t IV[8] = {0x6A09E667UL, 0xBB67AE85UL, 0x3C6EF372UL,
0xA54FF53AUL, 0x510E527FUL, 0x9B05688CUL,
0x1F83D9ABUL, 0x5BE0CD19UL};
static const uint8_t MSG_SCHEDULE[7][16] = {
{0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15},
{2, 6, 3, 10, 7, 0, 4, 13, 1, 11, 12, 5, 9, 14, 15, 8},
{3, 4, 10, 12, 13, 2, 7, 14, 6, 5, 9, 0, 11, 15, 8, 1},
{10, 7, 12, 9, 14, 3, 13, 15, 4, 0, 11, 2, 5, 8, 1, 6},
{12, 13, 9, 11, 15, 10, 14, 8, 7, 2, 5, 3, 0, 1, 6, 4},
{9, 14, 11, 5, 8, 12, 15, 1, 13, 3, 0, 10, 2, 6, 4, 7},
{11, 15, 5, 0, 1, 9, 8, 6, 14, 10, 2, 12, 3, 4, 7, 13},
};
/* Find index of the highest set bit */
/* x is assumed to be nonzero. */
static unsigned int highest_one(uint64_t x) {
#if defined(__GNUC__) || defined(__clang__)
return 63 ^ __builtin_clzll(x);
#elif defined(_MSC_VER) && defined(IS_X86_64)
unsigned long index;
_BitScanReverse64(&index, x);
return index;
#elif defined(_MSC_VER) && defined(IS_X86_32)
if(x >> 32) {
unsigned long index;
_BitScanReverse(&index, x >> 32);
return 32 + index;
} else {
unsigned long index;
_BitScanReverse(&index, x);
return index;
}
#else
unsigned int c = 0;
if(x & 0xffffffff00000000ULL) { x >>= 32; c += 32; }
if(x & 0x00000000ffff0000ULL) { x >>= 16; c += 16; }
if(x & 0x000000000000ff00ULL) { x >>= 8; c += 8; }
if(x & 0x00000000000000f0ULL) { x >>= 4; c += 4; }
if(x & 0x000000000000000cULL) { x >>= 2; c += 2; }
if(x & 0x0000000000000002ULL) { c += 1; }
return c;
#endif
}
// Count the number of 1 bits.
INLINE unsigned int popcnt(uint64_t x) {
#if defined(__GNUC__) || defined(__clang__)
return __builtin_popcountll(x);
#else
unsigned int count = 0;
while (x != 0) {
count += 1;
x &= x - 1;
}
return count;
#endif
}
// Largest power of two less than or equal to x. As a special case, returns 1
// when x is 0.
INLINE uint64_t round_down_to_power_of_2(uint64_t x) {
return 1ULL << highest_one(x | 1);
}
INLINE uint32_t counter_low(uint64_t counter) { return (uint32_t)counter; }
INLINE uint32_t counter_high(uint64_t counter) {
return (uint32_t)(counter >> 32);
}
INLINE uint32_t load32(const void *src) {
const uint8_t *p = (const uint8_t *)src;
return ((uint32_t)(p[0]) << 0) | ((uint32_t)(p[1]) << 8) |
((uint32_t)(p[2]) << 16) | ((uint32_t)(p[3]) << 24);
}
INLINE void load_key_words(const uint8_t key[BLAKE3_KEY_LEN],
uint32_t key_words[8]) {
key_words[0] = load32(&key[0 * 4]);
key_words[1] = load32(&key[1 * 4]);
key_words[2] = load32(&key[2 * 4]);
key_words[3] = load32(&key[3 * 4]);
key_words[4] = load32(&key[4 * 4]);
key_words[5] = load32(&key[5 * 4]);
key_words[6] = load32(&key[6 * 4]);
key_words[7] = load32(&key[7 * 4]);
}
INLINE void store32(void *dst, uint32_t w) {
uint8_t *p = (uint8_t *)dst;
p[0] = (uint8_t)(w >> 0);
p[1] = (uint8_t)(w >> 8);
p[2] = (uint8_t)(w >> 16);
p[3] = (uint8_t)(w >> 24);
}
INLINE void store_cv_words(uint8_t bytes_out[32], uint32_t cv_words[8]) {
store32(&bytes_out[0 * 4], cv_words[0]);
store32(&bytes_out[1 * 4], cv_words[1]);
store32(&bytes_out[2 * 4], cv_words[2]);
store32(&bytes_out[3 * 4], cv_words[3]);
store32(&bytes_out[4 * 4], cv_words[4]);
store32(&bytes_out[5 * 4], cv_words[5]);
store32(&bytes_out[6 * 4], cv_words[6]);
store32(&bytes_out[7 * 4], cv_words[7]);
}
void blake3_compress_in_place(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags);
void blake3_compress_xof(const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter, uint8_t flags,
uint8_t out[64]);
void blake3_hash_many(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8], uint64_t counter,
bool increment_counter, uint8_t flags,
uint8_t flags_start, uint8_t flags_end, uint8_t *out);
size_t blake3_simd_degree(void);
// Declarations for implementation-specific functions.
void blake3_compress_in_place_portable(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags);
void blake3_compress_xof_portable(const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags, uint8_t out[64]);
void blake3_hash_many_portable(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out);
#if defined(IS_X86)
#if !defined(BLAKE3_NO_SSE2)
void blake3_compress_in_place_sse2(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags);
void blake3_compress_xof_sse2(const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags, uint8_t out[64]);
void blake3_hash_many_sse2(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out);
#endif
#if !defined(BLAKE3_NO_SSE41)
void blake3_compress_in_place_sse41(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags);
void blake3_compress_xof_sse41(const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags, uint8_t out[64]);
void blake3_hash_many_sse41(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out);
#endif
#if !defined(BLAKE3_NO_AVX2)
void blake3_hash_many_avx2(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out);
#endif
#if !defined(BLAKE3_NO_AVX512)
void blake3_compress_in_place_avx512(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags);
void blake3_compress_xof_avx512(const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags, uint8_t out[64]);
void blake3_hash_many_avx512(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out);
#endif
#endif
#if defined(BLAKE3_USE_NEON)
void blake3_hash_many_neon(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out);
#endif
#endif /* BLAKE3_IMPL_H */

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#include "blake3_impl.h"
#include <arm_neon.h>
// TODO: This is probably incorrect for big-endian ARM. How should that work?
INLINE uint32x4_t loadu_128(const uint8_t src[16]) {
// vld1q_u32 has alignment requirements. Don't use it.
uint32x4_t x;
memcpy(&x, src, 16);
return x;
}
INLINE void storeu_128(uint32x4_t src, uint8_t dest[16]) {
// vst1q_u32 has alignment requirements. Don't use it.
memcpy(dest, &src, 16);
}
INLINE uint32x4_t add_128(uint32x4_t a, uint32x4_t b) {
return vaddq_u32(a, b);
}
INLINE uint32x4_t xor_128(uint32x4_t a, uint32x4_t b) {
return veorq_u32(a, b);
}
INLINE uint32x4_t set1_128(uint32_t x) { return vld1q_dup_u32(&x); }
INLINE uint32x4_t set4(uint32_t a, uint32_t b, uint32_t c, uint32_t d) {
uint32_t array[4] = {a, b, c, d};
return vld1q_u32(array);
}
INLINE uint32x4_t rot16_128(uint32x4_t x) {
return vorrq_u32(vshrq_n_u32(x, 16), vshlq_n_u32(x, 32 - 16));
}
INLINE uint32x4_t rot12_128(uint32x4_t x) {
return vorrq_u32(vshrq_n_u32(x, 12), vshlq_n_u32(x, 32 - 12));
}
INLINE uint32x4_t rot8_128(uint32x4_t x) {
return vorrq_u32(vshrq_n_u32(x, 8), vshlq_n_u32(x, 32 - 8));
}
INLINE uint32x4_t rot7_128(uint32x4_t x) {
return vorrq_u32(vshrq_n_u32(x, 7), vshlq_n_u32(x, 32 - 7));
}
// TODO: compress_neon
// TODO: hash2_neon
/*
* ----------------------------------------------------------------------------
* hash4_neon
* ----------------------------------------------------------------------------
*/
INLINE void round_fn4(uint32x4_t v[16], uint32x4_t m[16], size_t r) {
v[0] = add_128(v[0], m[(size_t)MSG_SCHEDULE[r][0]]);
v[1] = add_128(v[1], m[(size_t)MSG_SCHEDULE[r][2]]);
v[2] = add_128(v[2], m[(size_t)MSG_SCHEDULE[r][4]]);
v[3] = add_128(v[3], m[(size_t)MSG_SCHEDULE[r][6]]);
v[0] = add_128(v[0], v[4]);
v[1] = add_128(v[1], v[5]);
v[2] = add_128(v[2], v[6]);
v[3] = add_128(v[3], v[7]);
v[12] = xor_128(v[12], v[0]);
v[13] = xor_128(v[13], v[1]);
v[14] = xor_128(v[14], v[2]);
v[15] = xor_128(v[15], v[3]);
v[12] = rot16_128(v[12]);
v[13] = rot16_128(v[13]);
v[14] = rot16_128(v[14]);
v[15] = rot16_128(v[15]);
v[8] = add_128(v[8], v[12]);
v[9] = add_128(v[9], v[13]);
v[10] = add_128(v[10], v[14]);
v[11] = add_128(v[11], v[15]);
v[4] = xor_128(v[4], v[8]);
v[5] = xor_128(v[5], v[9]);
v[6] = xor_128(v[6], v[10]);
v[7] = xor_128(v[7], v[11]);
v[4] = rot12_128(v[4]);
v[5] = rot12_128(v[5]);
v[6] = rot12_128(v[6]);
v[7] = rot12_128(v[7]);
v[0] = add_128(v[0], m[(size_t)MSG_SCHEDULE[r][1]]);
v[1] = add_128(v[1], m[(size_t)MSG_SCHEDULE[r][3]]);
v[2] = add_128(v[2], m[(size_t)MSG_SCHEDULE[r][5]]);
v[3] = add_128(v[3], m[(size_t)MSG_SCHEDULE[r][7]]);
v[0] = add_128(v[0], v[4]);
v[1] = add_128(v[1], v[5]);
v[2] = add_128(v[2], v[6]);
v[3] = add_128(v[3], v[7]);
v[12] = xor_128(v[12], v[0]);
v[13] = xor_128(v[13], v[1]);
v[14] = xor_128(v[14], v[2]);
v[15] = xor_128(v[15], v[3]);
v[12] = rot8_128(v[12]);
v[13] = rot8_128(v[13]);
v[14] = rot8_128(v[14]);
v[15] = rot8_128(v[15]);
v[8] = add_128(v[8], v[12]);
v[9] = add_128(v[9], v[13]);
v[10] = add_128(v[10], v[14]);
v[11] = add_128(v[11], v[15]);
v[4] = xor_128(v[4], v[8]);
v[5] = xor_128(v[5], v[9]);
v[6] = xor_128(v[6], v[10]);
v[7] = xor_128(v[7], v[11]);
v[4] = rot7_128(v[4]);
v[5] = rot7_128(v[5]);
v[6] = rot7_128(v[6]);
v[7] = rot7_128(v[7]);
v[0] = add_128(v[0], m[(size_t)MSG_SCHEDULE[r][8]]);
v[1] = add_128(v[1], m[(size_t)MSG_SCHEDULE[r][10]]);
v[2] = add_128(v[2], m[(size_t)MSG_SCHEDULE[r][12]]);
v[3] = add_128(v[3], m[(size_t)MSG_SCHEDULE[r][14]]);
v[0] = add_128(v[0], v[5]);
v[1] = add_128(v[1], v[6]);
v[2] = add_128(v[2], v[7]);
v[3] = add_128(v[3], v[4]);
v[15] = xor_128(v[15], v[0]);
v[12] = xor_128(v[12], v[1]);
v[13] = xor_128(v[13], v[2]);
v[14] = xor_128(v[14], v[3]);
v[15] = rot16_128(v[15]);
v[12] = rot16_128(v[12]);
v[13] = rot16_128(v[13]);
v[14] = rot16_128(v[14]);
v[10] = add_128(v[10], v[15]);
v[11] = add_128(v[11], v[12]);
v[8] = add_128(v[8], v[13]);
v[9] = add_128(v[9], v[14]);
v[5] = xor_128(v[5], v[10]);
v[6] = xor_128(v[6], v[11]);
v[7] = xor_128(v[7], v[8]);
v[4] = xor_128(v[4], v[9]);
v[5] = rot12_128(v[5]);
v[6] = rot12_128(v[6]);
v[7] = rot12_128(v[7]);
v[4] = rot12_128(v[4]);
v[0] = add_128(v[0], m[(size_t)MSG_SCHEDULE[r][9]]);
v[1] = add_128(v[1], m[(size_t)MSG_SCHEDULE[r][11]]);
v[2] = add_128(v[2], m[(size_t)MSG_SCHEDULE[r][13]]);
v[3] = add_128(v[3], m[(size_t)MSG_SCHEDULE[r][15]]);
v[0] = add_128(v[0], v[5]);
v[1] = add_128(v[1], v[6]);
v[2] = add_128(v[2], v[7]);
v[3] = add_128(v[3], v[4]);
v[15] = xor_128(v[15], v[0]);
v[12] = xor_128(v[12], v[1]);
v[13] = xor_128(v[13], v[2]);
v[14] = xor_128(v[14], v[3]);
v[15] = rot8_128(v[15]);
v[12] = rot8_128(v[12]);
v[13] = rot8_128(v[13]);
v[14] = rot8_128(v[14]);
v[10] = add_128(v[10], v[15]);
v[11] = add_128(v[11], v[12]);
v[8] = add_128(v[8], v[13]);
v[9] = add_128(v[9], v[14]);
v[5] = xor_128(v[5], v[10]);
v[6] = xor_128(v[6], v[11]);
v[7] = xor_128(v[7], v[8]);
v[4] = xor_128(v[4], v[9]);
v[5] = rot7_128(v[5]);
v[6] = rot7_128(v[6]);
v[7] = rot7_128(v[7]);
v[4] = rot7_128(v[4]);
}
INLINE void transpose_vecs_128(uint32x4_t vecs[4]) {
// Individually transpose the four 2x2 sub-matrices in each corner.
uint32x4x2_t rows01 = vtrnq_u32(vecs[0], vecs[1]);
uint32x4x2_t rows23 = vtrnq_u32(vecs[2], vecs[3]);
// Swap the top-right and bottom-left 2x2s (which just got transposed).
vecs[0] =
vcombine_u32(vget_low_u32(rows01.val[0]), vget_low_u32(rows23.val[0]));
vecs[1] =
vcombine_u32(vget_low_u32(rows01.val[1]), vget_low_u32(rows23.val[1]));
vecs[2] =
vcombine_u32(vget_high_u32(rows01.val[0]), vget_high_u32(rows23.val[0]));
vecs[3] =
vcombine_u32(vget_high_u32(rows01.val[1]), vget_high_u32(rows23.val[1]));
}
INLINE void transpose_msg_vecs4(const uint8_t *const *inputs,
size_t block_offset, uint32x4_t out[16]) {
out[0] = loadu_128(&inputs[0][block_offset + 0 * sizeof(uint32x4_t)]);
out[1] = loadu_128(&inputs[1][block_offset + 0 * sizeof(uint32x4_t)]);
out[2] = loadu_128(&inputs[2][block_offset + 0 * sizeof(uint32x4_t)]);
out[3] = loadu_128(&inputs[3][block_offset + 0 * sizeof(uint32x4_t)]);
out[4] = loadu_128(&inputs[0][block_offset + 1 * sizeof(uint32x4_t)]);
out[5] = loadu_128(&inputs[1][block_offset + 1 * sizeof(uint32x4_t)]);
out[6] = loadu_128(&inputs[2][block_offset + 1 * sizeof(uint32x4_t)]);
out[7] = loadu_128(&inputs[3][block_offset + 1 * sizeof(uint32x4_t)]);
out[8] = loadu_128(&inputs[0][block_offset + 2 * sizeof(uint32x4_t)]);
out[9] = loadu_128(&inputs[1][block_offset + 2 * sizeof(uint32x4_t)]);
out[10] = loadu_128(&inputs[2][block_offset + 2 * sizeof(uint32x4_t)]);
out[11] = loadu_128(&inputs[3][block_offset + 2 * sizeof(uint32x4_t)]);
out[12] = loadu_128(&inputs[0][block_offset + 3 * sizeof(uint32x4_t)]);
out[13] = loadu_128(&inputs[1][block_offset + 3 * sizeof(uint32x4_t)]);
out[14] = loadu_128(&inputs[2][block_offset + 3 * sizeof(uint32x4_t)]);
out[15] = loadu_128(&inputs[3][block_offset + 3 * sizeof(uint32x4_t)]);
transpose_vecs_128(&out[0]);
transpose_vecs_128(&out[4]);
transpose_vecs_128(&out[8]);
transpose_vecs_128(&out[12]);
}
INLINE void load_counters4(uint64_t counter, bool increment_counter,
uint32x4_t *out_low, uint32x4_t *out_high) {
uint64_t mask = (increment_counter ? ~0 : 0);
*out_low = set4(
counter_low(counter + (mask & 0)), counter_low(counter + (mask & 1)),
counter_low(counter + (mask & 2)), counter_low(counter + (mask & 3)));
*out_high = set4(
counter_high(counter + (mask & 0)), counter_high(counter + (mask & 1)),
counter_high(counter + (mask & 2)), counter_high(counter + (mask & 3)));
}
void blake3_hash4_neon(const uint8_t *const *inputs, size_t blocks,
const uint32_t key[8], uint64_t counter,
bool increment_counter, uint8_t flags,
uint8_t flags_start, uint8_t flags_end, uint8_t *out) {
uint32x4_t h_vecs[8] = {
set1_128(key[0]), set1_128(key[1]), set1_128(key[2]), set1_128(key[3]),
set1_128(key[4]), set1_128(key[5]), set1_128(key[6]), set1_128(key[7]),
};
uint32x4_t counter_low_vec, counter_high_vec;
load_counters4(counter, increment_counter, &counter_low_vec,
&counter_high_vec);
uint8_t block_flags = flags | flags_start;
for (size_t block = 0; block < blocks; block++) {
if (block + 1 == blocks) {
block_flags |= flags_end;
}
uint32x4_t block_len_vec = set1_128(BLAKE3_BLOCK_LEN);
uint32x4_t block_flags_vec = set1_128(block_flags);
uint32x4_t msg_vecs[16];
transpose_msg_vecs4(inputs, block * BLAKE3_BLOCK_LEN, msg_vecs);
uint32x4_t v[16] = {
h_vecs[0], h_vecs[1], h_vecs[2], h_vecs[3],
h_vecs[4], h_vecs[5], h_vecs[6], h_vecs[7],
set1_128(IV[0]), set1_128(IV[1]), set1_128(IV[2]), set1_128(IV[3]),
counter_low_vec, counter_high_vec, block_len_vec, block_flags_vec,
};
round_fn4(v, msg_vecs, 0);
round_fn4(v, msg_vecs, 1);
round_fn4(v, msg_vecs, 2);
round_fn4(v, msg_vecs, 3);
round_fn4(v, msg_vecs, 4);
round_fn4(v, msg_vecs, 5);
round_fn4(v, msg_vecs, 6);
h_vecs[0] = xor_128(v[0], v[8]);
h_vecs[1] = xor_128(v[1], v[9]);
h_vecs[2] = xor_128(v[2], v[10]);
h_vecs[3] = xor_128(v[3], v[11]);
h_vecs[4] = xor_128(v[4], v[12]);
h_vecs[5] = xor_128(v[5], v[13]);
h_vecs[6] = xor_128(v[6], v[14]);
h_vecs[7] = xor_128(v[7], v[15]);
block_flags = flags;
}
transpose_vecs_128(&h_vecs[0]);
transpose_vecs_128(&h_vecs[4]);
// The first four vecs now contain the first half of each output, and the
// second four vecs contain the second half of each output.
storeu_128(h_vecs[0], &out[0 * sizeof(uint32x4_t)]);
storeu_128(h_vecs[4], &out[1 * sizeof(uint32x4_t)]);
storeu_128(h_vecs[1], &out[2 * sizeof(uint32x4_t)]);
storeu_128(h_vecs[5], &out[3 * sizeof(uint32x4_t)]);
storeu_128(h_vecs[2], &out[4 * sizeof(uint32x4_t)]);
storeu_128(h_vecs[6], &out[5 * sizeof(uint32x4_t)]);
storeu_128(h_vecs[3], &out[6 * sizeof(uint32x4_t)]);
storeu_128(h_vecs[7], &out[7 * sizeof(uint32x4_t)]);
}
/*
* ----------------------------------------------------------------------------
* hash_many_neon
* ----------------------------------------------------------------------------
*/
void blake3_compress_in_place_portable(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags);
INLINE void hash_one_neon(const uint8_t *input, size_t blocks,
const uint32_t key[8], uint64_t counter,
uint8_t flags, uint8_t flags_start, uint8_t flags_end,
uint8_t out[BLAKE3_OUT_LEN]) {
uint32_t cv[8];
memcpy(cv, key, BLAKE3_KEY_LEN);
uint8_t block_flags = flags | flags_start;
while (blocks > 0) {
if (blocks == 1) {
block_flags |= flags_end;
}
// TODO: Implement compress_neon. However note that according to
// https://github.com/BLAKE2/BLAKE2/commit/7965d3e6e1b4193438b8d3a656787587d2579227,
// compress_neon might not be any faster than compress_portable.
blake3_compress_in_place_portable(cv, input, BLAKE3_BLOCK_LEN, counter,
block_flags);
input = &input[BLAKE3_BLOCK_LEN];
blocks -= 1;
block_flags = flags;
}
memcpy(out, cv, BLAKE3_OUT_LEN);
}
void blake3_hash_many_neon(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out) {
while (num_inputs >= 4) {
blake3_hash4_neon(inputs, blocks, key, counter, increment_counter, flags,
flags_start, flags_end, out);
if (increment_counter) {
counter += 4;
}
inputs += 4;
num_inputs -= 4;
out = &out[4 * BLAKE3_OUT_LEN];
}
while (num_inputs > 0) {
hash_one_neon(inputs[0], blocks, key, counter, flags, flags_start,
flags_end, out);
if (increment_counter) {
counter += 1;
}
inputs += 1;
num_inputs -= 1;
out = &out[BLAKE3_OUT_LEN];
}
}

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#include "blake3_impl.h"
#include <string.h>
INLINE uint32_t rotr32(uint32_t w, uint32_t c) {
return (w >> c) | (w << (32 - c));
}
INLINE void g(uint32_t *state, size_t a, size_t b, size_t c, size_t d,
uint32_t x, uint32_t y) {
state[a] = state[a] + state[b] + x;
state[d] = rotr32(state[d] ^ state[a], 16);
state[c] = state[c] + state[d];
state[b] = rotr32(state[b] ^ state[c], 12);
state[a] = state[a] + state[b] + y;
state[d] = rotr32(state[d] ^ state[a], 8);
state[c] = state[c] + state[d];
state[b] = rotr32(state[b] ^ state[c], 7);
}
INLINE void round_fn(uint32_t state[16], const uint32_t *msg, size_t round) {
// Select the message schedule based on the round.
const uint8_t *schedule = MSG_SCHEDULE[round];
// Mix the columns.
g(state, 0, 4, 8, 12, msg[schedule[0]], msg[schedule[1]]);
g(state, 1, 5, 9, 13, msg[schedule[2]], msg[schedule[3]]);
g(state, 2, 6, 10, 14, msg[schedule[4]], msg[schedule[5]]);
g(state, 3, 7, 11, 15, msg[schedule[6]], msg[schedule[7]]);
// Mix the rows.
g(state, 0, 5, 10, 15, msg[schedule[8]], msg[schedule[9]]);
g(state, 1, 6, 11, 12, msg[schedule[10]], msg[schedule[11]]);
g(state, 2, 7, 8, 13, msg[schedule[12]], msg[schedule[13]]);
g(state, 3, 4, 9, 14, msg[schedule[14]], msg[schedule[15]]);
}
INLINE void compress_pre(uint32_t state[16], const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter, uint8_t flags) {
uint32_t block_words[16];
block_words[0] = load32(block + 4 * 0);
block_words[1] = load32(block + 4 * 1);
block_words[2] = load32(block + 4 * 2);
block_words[3] = load32(block + 4 * 3);
block_words[4] = load32(block + 4 * 4);
block_words[5] = load32(block + 4 * 5);
block_words[6] = load32(block + 4 * 6);
block_words[7] = load32(block + 4 * 7);
block_words[8] = load32(block + 4 * 8);
block_words[9] = load32(block + 4 * 9);
block_words[10] = load32(block + 4 * 10);
block_words[11] = load32(block + 4 * 11);
block_words[12] = load32(block + 4 * 12);
block_words[13] = load32(block + 4 * 13);
block_words[14] = load32(block + 4 * 14);
block_words[15] = load32(block + 4 * 15);
state[0] = cv[0];
state[1] = cv[1];
state[2] = cv[2];
state[3] = cv[3];
state[4] = cv[4];
state[5] = cv[5];
state[6] = cv[6];
state[7] = cv[7];
state[8] = IV[0];
state[9] = IV[1];
state[10] = IV[2];
state[11] = IV[3];
state[12] = counter_low(counter);
state[13] = counter_high(counter);
state[14] = (uint32_t)block_len;
state[15] = (uint32_t)flags;
round_fn(state, &block_words[0], 0);
round_fn(state, &block_words[0], 1);
round_fn(state, &block_words[0], 2);
round_fn(state, &block_words[0], 3);
round_fn(state, &block_words[0], 4);
round_fn(state, &block_words[0], 5);
round_fn(state, &block_words[0], 6);
}
void blake3_compress_in_place_portable(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags) {
uint32_t state[16];
compress_pre(state, cv, block, block_len, counter, flags);
cv[0] = state[0] ^ state[8];
cv[1] = state[1] ^ state[9];
cv[2] = state[2] ^ state[10];
cv[3] = state[3] ^ state[11];
cv[4] = state[4] ^ state[12];
cv[5] = state[5] ^ state[13];
cv[6] = state[6] ^ state[14];
cv[7] = state[7] ^ state[15];
}
void blake3_compress_xof_portable(const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags, uint8_t out[64]) {
uint32_t state[16];
compress_pre(state, cv, block, block_len, counter, flags);
store32(&out[0 * 4], state[0] ^ state[8]);
store32(&out[1 * 4], state[1] ^ state[9]);
store32(&out[2 * 4], state[2] ^ state[10]);
store32(&out[3 * 4], state[3] ^ state[11]);
store32(&out[4 * 4], state[4] ^ state[12]);
store32(&out[5 * 4], state[5] ^ state[13]);
store32(&out[6 * 4], state[6] ^ state[14]);
store32(&out[7 * 4], state[7] ^ state[15]);
store32(&out[8 * 4], state[8] ^ cv[0]);
store32(&out[9 * 4], state[9] ^ cv[1]);
store32(&out[10 * 4], state[10] ^ cv[2]);
store32(&out[11 * 4], state[11] ^ cv[3]);
store32(&out[12 * 4], state[12] ^ cv[4]);
store32(&out[13 * 4], state[13] ^ cv[5]);
store32(&out[14 * 4], state[14] ^ cv[6]);
store32(&out[15 * 4], state[15] ^ cv[7]);
}
INLINE void hash_one_portable(const uint8_t *input, size_t blocks,
const uint32_t key[8], uint64_t counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t out[BLAKE3_OUT_LEN]) {
uint32_t cv[8];
memcpy(cv, key, BLAKE3_KEY_LEN);
uint8_t block_flags = flags | flags_start;
while (blocks > 0) {
if (blocks == 1) {
block_flags |= flags_end;
}
blake3_compress_in_place_portable(cv, input, BLAKE3_BLOCK_LEN, counter,
block_flags);
input = &input[BLAKE3_BLOCK_LEN];
blocks -= 1;
block_flags = flags;
}
store_cv_words(out, cv);
}
void blake3_hash_many_portable(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out) {
while (num_inputs > 0) {
hash_one_portable(inputs[0], blocks, key, counter, flags, flags_start,
flags_end, out);
if (increment_counter) {
counter += 1;
}
inputs += 1;
num_inputs -= 1;
out = &out[BLAKE3_OUT_LEN];
}
}

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#include "blake3_impl.h"
#include <immintrin.h>
#define DEGREE 4
#define _mm_shuffle_ps2(a, b, c) \
(_mm_castps_si128( \
_mm_shuffle_ps(_mm_castsi128_ps(a), _mm_castsi128_ps(b), (c))))
INLINE __m128i loadu(const uint8_t src[16]) {
return _mm_loadu_si128((const __m128i *)src);
}
INLINE void storeu(__m128i src, uint8_t dest[16]) {
_mm_storeu_si128((__m128i *)dest, src);
}
INLINE __m128i addv(__m128i a, __m128i b) { return _mm_add_epi32(a, b); }
// Note that clang-format doesn't like the name "xor" for some reason.
INLINE __m128i xorv(__m128i a, __m128i b) { return _mm_xor_si128(a, b); }
INLINE __m128i set1(uint32_t x) { return _mm_set1_epi32((int32_t)x); }
INLINE __m128i set4(uint32_t a, uint32_t b, uint32_t c, uint32_t d) {
return _mm_setr_epi32((int32_t)a, (int32_t)b, (int32_t)c, (int32_t)d);
}
INLINE __m128i rot16(__m128i x) {
return _mm_shufflehi_epi16(_mm_shufflelo_epi16(x, 0xB1), 0xB1);
}
INLINE __m128i rot12(__m128i x) {
return xorv(_mm_srli_epi32(x, 12), _mm_slli_epi32(x, 32 - 12));
}
INLINE __m128i rot8(__m128i x) {
return xorv(_mm_srli_epi32(x, 8), _mm_slli_epi32(x, 32 - 8));
}
INLINE __m128i rot7(__m128i x) {
return xorv(_mm_srli_epi32(x, 7), _mm_slli_epi32(x, 32 - 7));
}
INLINE void g1(__m128i *row0, __m128i *row1, __m128i *row2, __m128i *row3,
__m128i m) {
*row0 = addv(addv(*row0, m), *row1);
*row3 = xorv(*row3, *row0);
*row3 = rot16(*row3);
*row2 = addv(*row2, *row3);
*row1 = xorv(*row1, *row2);
*row1 = rot12(*row1);
}
INLINE void g2(__m128i *row0, __m128i *row1, __m128i *row2, __m128i *row3,
__m128i m) {
*row0 = addv(addv(*row0, m), *row1);
*row3 = xorv(*row3, *row0);
*row3 = rot8(*row3);
*row2 = addv(*row2, *row3);
*row1 = xorv(*row1, *row2);
*row1 = rot7(*row1);
}
// Note the optimization here of leaving row1 as the unrotated row, rather than
// row0. All the message loads below are adjusted to compensate for this. See
// discussion at https://github.com/sneves/blake2-avx2/pull/4
INLINE void diagonalize(__m128i *row0, __m128i *row2, __m128i *row3) {
*row0 = _mm_shuffle_epi32(*row0, _MM_SHUFFLE(2, 1, 0, 3));
*row3 = _mm_shuffle_epi32(*row3, _MM_SHUFFLE(1, 0, 3, 2));
*row2 = _mm_shuffle_epi32(*row2, _MM_SHUFFLE(0, 3, 2, 1));
}
INLINE void undiagonalize(__m128i *row0, __m128i *row2, __m128i *row3) {
*row0 = _mm_shuffle_epi32(*row0, _MM_SHUFFLE(0, 3, 2, 1));
*row3 = _mm_shuffle_epi32(*row3, _MM_SHUFFLE(1, 0, 3, 2));
*row2 = _mm_shuffle_epi32(*row2, _MM_SHUFFLE(2, 1, 0, 3));
}
INLINE __m128i blend_epi16(__m128i a, __m128i b, const int imm8) {
const __m128i bits = _mm_set_epi16(0x80, 0x40, 0x20, 0x10, 0x08, 0x04, 0x02, 0x01);
__m128i mask = _mm_set1_epi16(imm8);
mask = _mm_and_si128(mask, bits);
mask = _mm_cmpeq_epi16(mask, bits);
return _mm_or_si128(_mm_and_si128(mask, b), _mm_andnot_si128(mask, a));
}
INLINE void compress_pre(__m128i rows[4], const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter, uint8_t flags) {
rows[0] = loadu((uint8_t *)&cv[0]);
rows[1] = loadu((uint8_t *)&cv[4]);
rows[2] = set4(IV[0], IV[1], IV[2], IV[3]);
rows[3] = set4(counter_low(counter), counter_high(counter),
(uint32_t)block_len, (uint32_t)flags);
__m128i m0 = loadu(&block[sizeof(__m128i) * 0]);
__m128i m1 = loadu(&block[sizeof(__m128i) * 1]);
__m128i m2 = loadu(&block[sizeof(__m128i) * 2]);
__m128i m3 = loadu(&block[sizeof(__m128i) * 3]);
__m128i t0, t1, t2, t3, tt;
// Round 1. The first round permutes the message words from the original
// input order, into the groups that get mixed in parallel.
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(2, 0, 2, 0)); // 6 4 2 0
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 3, 1)); // 7 5 3 1
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(2, 0, 2, 0)); // 14 12 10 8
t2 = _mm_shuffle_epi32(t2, _MM_SHUFFLE(2, 1, 0, 3)); // 12 10 8 14
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 1, 3, 1)); // 15 13 11 9
t3 = _mm_shuffle_epi32(t3, _MM_SHUFFLE(2, 1, 0, 3)); // 13 11 9 15
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 2. This round and all following rounds apply a fixed permutation
// to the message words from the round before.
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 3
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 4
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 5
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 6
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 7
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
}
void blake3_compress_in_place_sse2(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags) {
__m128i rows[4];
compress_pre(rows, cv, block, block_len, counter, flags);
storeu(xorv(rows[0], rows[2]), (uint8_t *)&cv[0]);
storeu(xorv(rows[1], rows[3]), (uint8_t *)&cv[4]);
}
void blake3_compress_xof_sse2(const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags, uint8_t out[64]) {
__m128i rows[4];
compress_pre(rows, cv, block, block_len, counter, flags);
storeu(xorv(rows[0], rows[2]), &out[0]);
storeu(xorv(rows[1], rows[3]), &out[16]);
storeu(xorv(rows[2], loadu((uint8_t *)&cv[0])), &out[32]);
storeu(xorv(rows[3], loadu((uint8_t *)&cv[4])), &out[48]);
}
INLINE void round_fn(__m128i v[16], __m128i m[16], size_t r) {
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][0]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][2]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][4]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][6]]);
v[0] = addv(v[0], v[4]);
v[1] = addv(v[1], v[5]);
v[2] = addv(v[2], v[6]);
v[3] = addv(v[3], v[7]);
v[12] = xorv(v[12], v[0]);
v[13] = xorv(v[13], v[1]);
v[14] = xorv(v[14], v[2]);
v[15] = xorv(v[15], v[3]);
v[12] = rot16(v[12]);
v[13] = rot16(v[13]);
v[14] = rot16(v[14]);
v[15] = rot16(v[15]);
v[8] = addv(v[8], v[12]);
v[9] = addv(v[9], v[13]);
v[10] = addv(v[10], v[14]);
v[11] = addv(v[11], v[15]);
v[4] = xorv(v[4], v[8]);
v[5] = xorv(v[5], v[9]);
v[6] = xorv(v[6], v[10]);
v[7] = xorv(v[7], v[11]);
v[4] = rot12(v[4]);
v[5] = rot12(v[5]);
v[6] = rot12(v[6]);
v[7] = rot12(v[7]);
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][1]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][3]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][5]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][7]]);
v[0] = addv(v[0], v[4]);
v[1] = addv(v[1], v[5]);
v[2] = addv(v[2], v[6]);
v[3] = addv(v[3], v[7]);
v[12] = xorv(v[12], v[0]);
v[13] = xorv(v[13], v[1]);
v[14] = xorv(v[14], v[2]);
v[15] = xorv(v[15], v[3]);
v[12] = rot8(v[12]);
v[13] = rot8(v[13]);
v[14] = rot8(v[14]);
v[15] = rot8(v[15]);
v[8] = addv(v[8], v[12]);
v[9] = addv(v[9], v[13]);
v[10] = addv(v[10], v[14]);
v[11] = addv(v[11], v[15]);
v[4] = xorv(v[4], v[8]);
v[5] = xorv(v[5], v[9]);
v[6] = xorv(v[6], v[10]);
v[7] = xorv(v[7], v[11]);
v[4] = rot7(v[4]);
v[5] = rot7(v[5]);
v[6] = rot7(v[6]);
v[7] = rot7(v[7]);
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][8]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][10]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][12]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][14]]);
v[0] = addv(v[0], v[5]);
v[1] = addv(v[1], v[6]);
v[2] = addv(v[2], v[7]);
v[3] = addv(v[3], v[4]);
v[15] = xorv(v[15], v[0]);
v[12] = xorv(v[12], v[1]);
v[13] = xorv(v[13], v[2]);
v[14] = xorv(v[14], v[3]);
v[15] = rot16(v[15]);
v[12] = rot16(v[12]);
v[13] = rot16(v[13]);
v[14] = rot16(v[14]);
v[10] = addv(v[10], v[15]);
v[11] = addv(v[11], v[12]);
v[8] = addv(v[8], v[13]);
v[9] = addv(v[9], v[14]);
v[5] = xorv(v[5], v[10]);
v[6] = xorv(v[6], v[11]);
v[7] = xorv(v[7], v[8]);
v[4] = xorv(v[4], v[9]);
v[5] = rot12(v[5]);
v[6] = rot12(v[6]);
v[7] = rot12(v[7]);
v[4] = rot12(v[4]);
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][9]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][11]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][13]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][15]]);
v[0] = addv(v[0], v[5]);
v[1] = addv(v[1], v[6]);
v[2] = addv(v[2], v[7]);
v[3] = addv(v[3], v[4]);
v[15] = xorv(v[15], v[0]);
v[12] = xorv(v[12], v[1]);
v[13] = xorv(v[13], v[2]);
v[14] = xorv(v[14], v[3]);
v[15] = rot8(v[15]);
v[12] = rot8(v[12]);
v[13] = rot8(v[13]);
v[14] = rot8(v[14]);
v[10] = addv(v[10], v[15]);
v[11] = addv(v[11], v[12]);
v[8] = addv(v[8], v[13]);
v[9] = addv(v[9], v[14]);
v[5] = xorv(v[5], v[10]);
v[6] = xorv(v[6], v[11]);
v[7] = xorv(v[7], v[8]);
v[4] = xorv(v[4], v[9]);
v[5] = rot7(v[5]);
v[6] = rot7(v[6]);
v[7] = rot7(v[7]);
v[4] = rot7(v[4]);
}
INLINE void transpose_vecs(__m128i vecs[DEGREE]) {
// Interleave 32-bit lates. The low unpack is lanes 00/11 and the high is
// 22/33. Note that this doesn't split the vector into two lanes, as the
// AVX2 counterparts do.
__m128i ab_01 = _mm_unpacklo_epi32(vecs[0], vecs[1]);
__m128i ab_23 = _mm_unpackhi_epi32(vecs[0], vecs[1]);
__m128i cd_01 = _mm_unpacklo_epi32(vecs[2], vecs[3]);
__m128i cd_23 = _mm_unpackhi_epi32(vecs[2], vecs[3]);
// Interleave 64-bit lanes.
__m128i abcd_0 = _mm_unpacklo_epi64(ab_01, cd_01);
__m128i abcd_1 = _mm_unpackhi_epi64(ab_01, cd_01);
__m128i abcd_2 = _mm_unpacklo_epi64(ab_23, cd_23);
__m128i abcd_3 = _mm_unpackhi_epi64(ab_23, cd_23);
vecs[0] = abcd_0;
vecs[1] = abcd_1;
vecs[2] = abcd_2;
vecs[3] = abcd_3;
}
INLINE void transpose_msg_vecs(const uint8_t *const *inputs,
size_t block_offset, __m128i out[16]) {
out[0] = loadu(&inputs[0][block_offset + 0 * sizeof(__m128i)]);
out[1] = loadu(&inputs[1][block_offset + 0 * sizeof(__m128i)]);
out[2] = loadu(&inputs[2][block_offset + 0 * sizeof(__m128i)]);
out[3] = loadu(&inputs[3][block_offset + 0 * sizeof(__m128i)]);
out[4] = loadu(&inputs[0][block_offset + 1 * sizeof(__m128i)]);
out[5] = loadu(&inputs[1][block_offset + 1 * sizeof(__m128i)]);
out[6] = loadu(&inputs[2][block_offset + 1 * sizeof(__m128i)]);
out[7] = loadu(&inputs[3][block_offset + 1 * sizeof(__m128i)]);
out[8] = loadu(&inputs[0][block_offset + 2 * sizeof(__m128i)]);
out[9] = loadu(&inputs[1][block_offset + 2 * sizeof(__m128i)]);
out[10] = loadu(&inputs[2][block_offset + 2 * sizeof(__m128i)]);
out[11] = loadu(&inputs[3][block_offset + 2 * sizeof(__m128i)]);
out[12] = loadu(&inputs[0][block_offset + 3 * sizeof(__m128i)]);
out[13] = loadu(&inputs[1][block_offset + 3 * sizeof(__m128i)]);
out[14] = loadu(&inputs[2][block_offset + 3 * sizeof(__m128i)]);
out[15] = loadu(&inputs[3][block_offset + 3 * sizeof(__m128i)]);
for (size_t i = 0; i < 4; ++i) {
_mm_prefetch(&inputs[i][block_offset + 256], _MM_HINT_T0);
}
transpose_vecs(&out[0]);
transpose_vecs(&out[4]);
transpose_vecs(&out[8]);
transpose_vecs(&out[12]);
}
INLINE void load_counters(uint64_t counter, bool increment_counter,
__m128i *out_lo, __m128i *out_hi) {
const __m128i mask = _mm_set1_epi32(-(int32_t)increment_counter);
const __m128i add0 = _mm_set_epi32(3, 2, 1, 0);
const __m128i add1 = _mm_and_si128(mask, add0);
__m128i l = _mm_add_epi32(_mm_set1_epi32(counter), add1);
__m128i carry = _mm_cmpgt_epi32(_mm_xor_si128(add1, _mm_set1_epi32(0x80000000)),
_mm_xor_si128( l, _mm_set1_epi32(0x80000000)));
__m128i h = _mm_sub_epi32(_mm_set1_epi32(counter >> 32), carry);
*out_lo = l;
*out_hi = h;
}
void blake3_hash4_sse2(const uint8_t *const *inputs, size_t blocks,
const uint32_t key[8], uint64_t counter,
bool increment_counter, uint8_t flags,
uint8_t flags_start, uint8_t flags_end, uint8_t *out) {
__m128i h_vecs[8] = {
set1(key[0]), set1(key[1]), set1(key[2]), set1(key[3]),
set1(key[4]), set1(key[5]), set1(key[6]), set1(key[7]),
};
__m128i counter_low_vec, counter_high_vec;
load_counters(counter, increment_counter, &counter_low_vec,
&counter_high_vec);
uint8_t block_flags = flags | flags_start;
for (size_t block = 0; block < blocks; block++) {
if (block + 1 == blocks) {
block_flags |= flags_end;
}
__m128i block_len_vec = set1(BLAKE3_BLOCK_LEN);
__m128i block_flags_vec = set1(block_flags);
__m128i msg_vecs[16];
transpose_msg_vecs(inputs, block * BLAKE3_BLOCK_LEN, msg_vecs);
__m128i v[16] = {
h_vecs[0], h_vecs[1], h_vecs[2], h_vecs[3],
h_vecs[4], h_vecs[5], h_vecs[6], h_vecs[7],
set1(IV[0]), set1(IV[1]), set1(IV[2]), set1(IV[3]),
counter_low_vec, counter_high_vec, block_len_vec, block_flags_vec,
};
round_fn(v, msg_vecs, 0);
round_fn(v, msg_vecs, 1);
round_fn(v, msg_vecs, 2);
round_fn(v, msg_vecs, 3);
round_fn(v, msg_vecs, 4);
round_fn(v, msg_vecs, 5);
round_fn(v, msg_vecs, 6);
h_vecs[0] = xorv(v[0], v[8]);
h_vecs[1] = xorv(v[1], v[9]);
h_vecs[2] = xorv(v[2], v[10]);
h_vecs[3] = xorv(v[3], v[11]);
h_vecs[4] = xorv(v[4], v[12]);
h_vecs[5] = xorv(v[5], v[13]);
h_vecs[6] = xorv(v[6], v[14]);
h_vecs[7] = xorv(v[7], v[15]);
block_flags = flags;
}
transpose_vecs(&h_vecs[0]);
transpose_vecs(&h_vecs[4]);
// The first four vecs now contain the first half of each output, and the
// second four vecs contain the second half of each output.
storeu(h_vecs[0], &out[0 * sizeof(__m128i)]);
storeu(h_vecs[4], &out[1 * sizeof(__m128i)]);
storeu(h_vecs[1], &out[2 * sizeof(__m128i)]);
storeu(h_vecs[5], &out[3 * sizeof(__m128i)]);
storeu(h_vecs[2], &out[4 * sizeof(__m128i)]);
storeu(h_vecs[6], &out[5 * sizeof(__m128i)]);
storeu(h_vecs[3], &out[6 * sizeof(__m128i)]);
storeu(h_vecs[7], &out[7 * sizeof(__m128i)]);
}
INLINE void hash_one_sse2(const uint8_t *input, size_t blocks,
const uint32_t key[8], uint64_t counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t out[BLAKE3_OUT_LEN]) {
uint32_t cv[8];
memcpy(cv, key, BLAKE3_KEY_LEN);
uint8_t block_flags = flags | flags_start;
while (blocks > 0) {
if (blocks == 1) {
block_flags |= flags_end;
}
blake3_compress_in_place_sse2(cv, input, BLAKE3_BLOCK_LEN, counter,
block_flags);
input = &input[BLAKE3_BLOCK_LEN];
blocks -= 1;
block_flags = flags;
}
memcpy(out, cv, BLAKE3_OUT_LEN);
}
void blake3_hash_many_sse2(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out) {
while (num_inputs >= DEGREE) {
blake3_hash4_sse2(inputs, blocks, key, counter, increment_counter, flags,
flags_start, flags_end, out);
if (increment_counter) {
counter += DEGREE;
}
inputs += DEGREE;
num_inputs -= DEGREE;
out = &out[DEGREE * BLAKE3_OUT_LEN];
}
while (num_inputs > 0) {
hash_one_sse2(inputs[0], blocks, key, counter, flags, flags_start,
flags_end, out);
if (increment_counter) {
counter += 1;
}
inputs += 1;
num_inputs -= 1;
out = &out[BLAKE3_OUT_LEN];
}
}

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#include "blake3_impl.h"
#include <immintrin.h>
#define DEGREE 4
#define _mm_shuffle_ps2(a, b, c) \
(_mm_castps_si128( \
_mm_shuffle_ps(_mm_castsi128_ps(a), _mm_castsi128_ps(b), (c))))
INLINE __m128i loadu(const uint8_t src[16]) {
return _mm_loadu_si128((const __m128i *)src);
}
INLINE void storeu(__m128i src, uint8_t dest[16]) {
_mm_storeu_si128((__m128i *)dest, src);
}
INLINE __m128i addv(__m128i a, __m128i b) { return _mm_add_epi32(a, b); }
// Note that clang-format doesn't like the name "xor" for some reason.
INLINE __m128i xorv(__m128i a, __m128i b) { return _mm_xor_si128(a, b); }
INLINE __m128i set1(uint32_t x) { return _mm_set1_epi32((int32_t)x); }
INLINE __m128i set4(uint32_t a, uint32_t b, uint32_t c, uint32_t d) {
return _mm_setr_epi32((int32_t)a, (int32_t)b, (int32_t)c, (int32_t)d);
}
INLINE __m128i rot16(__m128i x) {
return _mm_shuffle_epi8(
x, _mm_set_epi8(13, 12, 15, 14, 9, 8, 11, 10, 5, 4, 7, 6, 1, 0, 3, 2));
}
INLINE __m128i rot12(__m128i x) {
return xorv(_mm_srli_epi32(x, 12), _mm_slli_epi32(x, 32 - 12));
}
INLINE __m128i rot8(__m128i x) {
return _mm_shuffle_epi8(
x, _mm_set_epi8(12, 15, 14, 13, 8, 11, 10, 9, 4, 7, 6, 5, 0, 3, 2, 1));
}
INLINE __m128i rot7(__m128i x) {
return xorv(_mm_srli_epi32(x, 7), _mm_slli_epi32(x, 32 - 7));
}
INLINE void g1(__m128i *row0, __m128i *row1, __m128i *row2, __m128i *row3,
__m128i m) {
*row0 = addv(addv(*row0, m), *row1);
*row3 = xorv(*row3, *row0);
*row3 = rot16(*row3);
*row2 = addv(*row2, *row3);
*row1 = xorv(*row1, *row2);
*row1 = rot12(*row1);
}
INLINE void g2(__m128i *row0, __m128i *row1, __m128i *row2, __m128i *row3,
__m128i m) {
*row0 = addv(addv(*row0, m), *row1);
*row3 = xorv(*row3, *row0);
*row3 = rot8(*row3);
*row2 = addv(*row2, *row3);
*row1 = xorv(*row1, *row2);
*row1 = rot7(*row1);
}
// Note the optimization here of leaving row1 as the unrotated row, rather than
// row0. All the message loads below are adjusted to compensate for this. See
// discussion at https://github.com/sneves/blake2-avx2/pull/4
INLINE void diagonalize(__m128i *row0, __m128i *row2, __m128i *row3) {
*row0 = _mm_shuffle_epi32(*row0, _MM_SHUFFLE(2, 1, 0, 3));
*row3 = _mm_shuffle_epi32(*row3, _MM_SHUFFLE(1, 0, 3, 2));
*row2 = _mm_shuffle_epi32(*row2, _MM_SHUFFLE(0, 3, 2, 1));
}
INLINE void undiagonalize(__m128i *row0, __m128i *row2, __m128i *row3) {
*row0 = _mm_shuffle_epi32(*row0, _MM_SHUFFLE(0, 3, 2, 1));
*row3 = _mm_shuffle_epi32(*row3, _MM_SHUFFLE(1, 0, 3, 2));
*row2 = _mm_shuffle_epi32(*row2, _MM_SHUFFLE(2, 1, 0, 3));
}
INLINE void compress_pre(__m128i rows[4], const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter, uint8_t flags) {
rows[0] = loadu((uint8_t *)&cv[0]);
rows[1] = loadu((uint8_t *)&cv[4]);
rows[2] = set4(IV[0], IV[1], IV[2], IV[3]);
rows[3] = set4(counter_low(counter), counter_high(counter),
(uint32_t)block_len, (uint32_t)flags);
__m128i m0 = loadu(&block[sizeof(__m128i) * 0]);
__m128i m1 = loadu(&block[sizeof(__m128i) * 1]);
__m128i m2 = loadu(&block[sizeof(__m128i) * 2]);
__m128i m3 = loadu(&block[sizeof(__m128i) * 3]);
__m128i t0, t1, t2, t3, tt;
// Round 1. The first round permutes the message words from the original
// input order, into the groups that get mixed in parallel.
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(2, 0, 2, 0)); // 6 4 2 0
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 3, 1)); // 7 5 3 1
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(2, 0, 2, 0)); // 14 12 10 8
t2 = _mm_shuffle_epi32(t2, _MM_SHUFFLE(2, 1, 0, 3)); // 12 10 8 14
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 1, 3, 1)); // 15 13 11 9
t3 = _mm_shuffle_epi32(t3, _MM_SHUFFLE(2, 1, 0, 3)); // 13 11 9 15
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 2. This round and all following rounds apply a fixed permutation
// to the message words from the round before.
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = _mm_blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = _mm_blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 3
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = _mm_blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = _mm_blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 4
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = _mm_blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = _mm_blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 5
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = _mm_blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = _mm_blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 6
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = _mm_blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = _mm_blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
m0 = t0;
m1 = t1;
m2 = t2;
m3 = t3;
// Round 7
t0 = _mm_shuffle_ps2(m0, m1, _MM_SHUFFLE(3, 1, 1, 2));
t0 = _mm_shuffle_epi32(t0, _MM_SHUFFLE(0, 3, 2, 1));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t0);
t1 = _mm_shuffle_ps2(m2, m3, _MM_SHUFFLE(3, 3, 2, 2));
tt = _mm_shuffle_epi32(m0, _MM_SHUFFLE(0, 0, 3, 3));
t1 = _mm_blend_epi16(tt, t1, 0xCC);
g2(&rows[0], &rows[1], &rows[2], &rows[3], t1);
diagonalize(&rows[0], &rows[2], &rows[3]);
t2 = _mm_unpacklo_epi64(m3, m1);
tt = _mm_blend_epi16(t2, m2, 0xC0);
t2 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(1, 3, 2, 0));
g1(&rows[0], &rows[1], &rows[2], &rows[3], t2);
t3 = _mm_unpackhi_epi32(m1, m3);
tt = _mm_unpacklo_epi32(m2, t3);
t3 = _mm_shuffle_epi32(tt, _MM_SHUFFLE(0, 1, 3, 2));
g2(&rows[0], &rows[1], &rows[2], &rows[3], t3);
undiagonalize(&rows[0], &rows[2], &rows[3]);
}
void blake3_compress_in_place_sse41(uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags) {
__m128i rows[4];
compress_pre(rows, cv, block, block_len, counter, flags);
storeu(xorv(rows[0], rows[2]), (uint8_t *)&cv[0]);
storeu(xorv(rows[1], rows[3]), (uint8_t *)&cv[4]);
}
void blake3_compress_xof_sse41(const uint32_t cv[8],
const uint8_t block[BLAKE3_BLOCK_LEN],
uint8_t block_len, uint64_t counter,
uint8_t flags, uint8_t out[64]) {
__m128i rows[4];
compress_pre(rows, cv, block, block_len, counter, flags);
storeu(xorv(rows[0], rows[2]), &out[0]);
storeu(xorv(rows[1], rows[3]), &out[16]);
storeu(xorv(rows[2], loadu((uint8_t *)&cv[0])), &out[32]);
storeu(xorv(rows[3], loadu((uint8_t *)&cv[4])), &out[48]);
}
INLINE void round_fn(__m128i v[16], __m128i m[16], size_t r) {
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][0]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][2]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][4]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][6]]);
v[0] = addv(v[0], v[4]);
v[1] = addv(v[1], v[5]);
v[2] = addv(v[2], v[6]);
v[3] = addv(v[3], v[7]);
v[12] = xorv(v[12], v[0]);
v[13] = xorv(v[13], v[1]);
v[14] = xorv(v[14], v[2]);
v[15] = xorv(v[15], v[3]);
v[12] = rot16(v[12]);
v[13] = rot16(v[13]);
v[14] = rot16(v[14]);
v[15] = rot16(v[15]);
v[8] = addv(v[8], v[12]);
v[9] = addv(v[9], v[13]);
v[10] = addv(v[10], v[14]);
v[11] = addv(v[11], v[15]);
v[4] = xorv(v[4], v[8]);
v[5] = xorv(v[5], v[9]);
v[6] = xorv(v[6], v[10]);
v[7] = xorv(v[7], v[11]);
v[4] = rot12(v[4]);
v[5] = rot12(v[5]);
v[6] = rot12(v[6]);
v[7] = rot12(v[7]);
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][1]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][3]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][5]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][7]]);
v[0] = addv(v[0], v[4]);
v[1] = addv(v[1], v[5]);
v[2] = addv(v[2], v[6]);
v[3] = addv(v[3], v[7]);
v[12] = xorv(v[12], v[0]);
v[13] = xorv(v[13], v[1]);
v[14] = xorv(v[14], v[2]);
v[15] = xorv(v[15], v[3]);
v[12] = rot8(v[12]);
v[13] = rot8(v[13]);
v[14] = rot8(v[14]);
v[15] = rot8(v[15]);
v[8] = addv(v[8], v[12]);
v[9] = addv(v[9], v[13]);
v[10] = addv(v[10], v[14]);
v[11] = addv(v[11], v[15]);
v[4] = xorv(v[4], v[8]);
v[5] = xorv(v[5], v[9]);
v[6] = xorv(v[6], v[10]);
v[7] = xorv(v[7], v[11]);
v[4] = rot7(v[4]);
v[5] = rot7(v[5]);
v[6] = rot7(v[6]);
v[7] = rot7(v[7]);
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][8]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][10]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][12]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][14]]);
v[0] = addv(v[0], v[5]);
v[1] = addv(v[1], v[6]);
v[2] = addv(v[2], v[7]);
v[3] = addv(v[3], v[4]);
v[15] = xorv(v[15], v[0]);
v[12] = xorv(v[12], v[1]);
v[13] = xorv(v[13], v[2]);
v[14] = xorv(v[14], v[3]);
v[15] = rot16(v[15]);
v[12] = rot16(v[12]);
v[13] = rot16(v[13]);
v[14] = rot16(v[14]);
v[10] = addv(v[10], v[15]);
v[11] = addv(v[11], v[12]);
v[8] = addv(v[8], v[13]);
v[9] = addv(v[9], v[14]);
v[5] = xorv(v[5], v[10]);
v[6] = xorv(v[6], v[11]);
v[7] = xorv(v[7], v[8]);
v[4] = xorv(v[4], v[9]);
v[5] = rot12(v[5]);
v[6] = rot12(v[6]);
v[7] = rot12(v[7]);
v[4] = rot12(v[4]);
v[0] = addv(v[0], m[(size_t)MSG_SCHEDULE[r][9]]);
v[1] = addv(v[1], m[(size_t)MSG_SCHEDULE[r][11]]);
v[2] = addv(v[2], m[(size_t)MSG_SCHEDULE[r][13]]);
v[3] = addv(v[3], m[(size_t)MSG_SCHEDULE[r][15]]);
v[0] = addv(v[0], v[5]);
v[1] = addv(v[1], v[6]);
v[2] = addv(v[2], v[7]);
v[3] = addv(v[3], v[4]);
v[15] = xorv(v[15], v[0]);
v[12] = xorv(v[12], v[1]);
v[13] = xorv(v[13], v[2]);
v[14] = xorv(v[14], v[3]);
v[15] = rot8(v[15]);
v[12] = rot8(v[12]);
v[13] = rot8(v[13]);
v[14] = rot8(v[14]);
v[10] = addv(v[10], v[15]);
v[11] = addv(v[11], v[12]);
v[8] = addv(v[8], v[13]);
v[9] = addv(v[9], v[14]);
v[5] = xorv(v[5], v[10]);
v[6] = xorv(v[6], v[11]);
v[7] = xorv(v[7], v[8]);
v[4] = xorv(v[4], v[9]);
v[5] = rot7(v[5]);
v[6] = rot7(v[6]);
v[7] = rot7(v[7]);
v[4] = rot7(v[4]);
}
INLINE void transpose_vecs(__m128i vecs[DEGREE]) {
// Interleave 32-bit lates. The low unpack is lanes 00/11 and the high is
// 22/33. Note that this doesn't split the vector into two lanes, as the
// AVX2 counterparts do.
__m128i ab_01 = _mm_unpacklo_epi32(vecs[0], vecs[1]);
__m128i ab_23 = _mm_unpackhi_epi32(vecs[0], vecs[1]);
__m128i cd_01 = _mm_unpacklo_epi32(vecs[2], vecs[3]);
__m128i cd_23 = _mm_unpackhi_epi32(vecs[2], vecs[3]);
// Interleave 64-bit lanes.
__m128i abcd_0 = _mm_unpacklo_epi64(ab_01, cd_01);
__m128i abcd_1 = _mm_unpackhi_epi64(ab_01, cd_01);
__m128i abcd_2 = _mm_unpacklo_epi64(ab_23, cd_23);
__m128i abcd_3 = _mm_unpackhi_epi64(ab_23, cd_23);
vecs[0] = abcd_0;
vecs[1] = abcd_1;
vecs[2] = abcd_2;
vecs[3] = abcd_3;
}
INLINE void transpose_msg_vecs(const uint8_t *const *inputs,
size_t block_offset, __m128i out[16]) {
out[0] = loadu(&inputs[0][block_offset + 0 * sizeof(__m128i)]);
out[1] = loadu(&inputs[1][block_offset + 0 * sizeof(__m128i)]);
out[2] = loadu(&inputs[2][block_offset + 0 * sizeof(__m128i)]);
out[3] = loadu(&inputs[3][block_offset + 0 * sizeof(__m128i)]);
out[4] = loadu(&inputs[0][block_offset + 1 * sizeof(__m128i)]);
out[5] = loadu(&inputs[1][block_offset + 1 * sizeof(__m128i)]);
out[6] = loadu(&inputs[2][block_offset + 1 * sizeof(__m128i)]);
out[7] = loadu(&inputs[3][block_offset + 1 * sizeof(__m128i)]);
out[8] = loadu(&inputs[0][block_offset + 2 * sizeof(__m128i)]);
out[9] = loadu(&inputs[1][block_offset + 2 * sizeof(__m128i)]);
out[10] = loadu(&inputs[2][block_offset + 2 * sizeof(__m128i)]);
out[11] = loadu(&inputs[3][block_offset + 2 * sizeof(__m128i)]);
out[12] = loadu(&inputs[0][block_offset + 3 * sizeof(__m128i)]);
out[13] = loadu(&inputs[1][block_offset + 3 * sizeof(__m128i)]);
out[14] = loadu(&inputs[2][block_offset + 3 * sizeof(__m128i)]);
out[15] = loadu(&inputs[3][block_offset + 3 * sizeof(__m128i)]);
for (size_t i = 0; i < 4; ++i) {
_mm_prefetch(&inputs[i][block_offset + 256], _MM_HINT_T0);
}
transpose_vecs(&out[0]);
transpose_vecs(&out[4]);
transpose_vecs(&out[8]);
transpose_vecs(&out[12]);
}
INLINE void load_counters(uint64_t counter, bool increment_counter,
__m128i *out_lo, __m128i *out_hi) {
const __m128i mask = _mm_set1_epi32(-(int32_t)increment_counter);
const __m128i add0 = _mm_set_epi32(3, 2, 1, 0);
const __m128i add1 = _mm_and_si128(mask, add0);
__m128i l = _mm_add_epi32(_mm_set1_epi32(counter), add1);
__m128i carry = _mm_cmpgt_epi32(_mm_xor_si128(add1, _mm_set1_epi32(0x80000000)),
_mm_xor_si128( l, _mm_set1_epi32(0x80000000)));
__m128i h = _mm_sub_epi32(_mm_set1_epi32(counter >> 32), carry);
*out_lo = l;
*out_hi = h;
}
void blake3_hash4_sse41(const uint8_t *const *inputs, size_t blocks,
const uint32_t key[8], uint64_t counter,
bool increment_counter, uint8_t flags,
uint8_t flags_start, uint8_t flags_end, uint8_t *out) {
__m128i h_vecs[8] = {
set1(key[0]), set1(key[1]), set1(key[2]), set1(key[3]),
set1(key[4]), set1(key[5]), set1(key[6]), set1(key[7]),
};
__m128i counter_low_vec, counter_high_vec;
load_counters(counter, increment_counter, &counter_low_vec,
&counter_high_vec);
uint8_t block_flags = flags | flags_start;
for (size_t block = 0; block < blocks; block++) {
if (block + 1 == blocks) {
block_flags |= flags_end;
}
__m128i block_len_vec = set1(BLAKE3_BLOCK_LEN);
__m128i block_flags_vec = set1(block_flags);
__m128i msg_vecs[16];
transpose_msg_vecs(inputs, block * BLAKE3_BLOCK_LEN, msg_vecs);
__m128i v[16] = {
h_vecs[0], h_vecs[1], h_vecs[2], h_vecs[3],
h_vecs[4], h_vecs[5], h_vecs[6], h_vecs[7],
set1(IV[0]), set1(IV[1]), set1(IV[2]), set1(IV[3]),
counter_low_vec, counter_high_vec, block_len_vec, block_flags_vec,
};
round_fn(v, msg_vecs, 0);
round_fn(v, msg_vecs, 1);
round_fn(v, msg_vecs, 2);
round_fn(v, msg_vecs, 3);
round_fn(v, msg_vecs, 4);
round_fn(v, msg_vecs, 5);
round_fn(v, msg_vecs, 6);
h_vecs[0] = xorv(v[0], v[8]);
h_vecs[1] = xorv(v[1], v[9]);
h_vecs[2] = xorv(v[2], v[10]);
h_vecs[3] = xorv(v[3], v[11]);
h_vecs[4] = xorv(v[4], v[12]);
h_vecs[5] = xorv(v[5], v[13]);
h_vecs[6] = xorv(v[6], v[14]);
h_vecs[7] = xorv(v[7], v[15]);
block_flags = flags;
}
transpose_vecs(&h_vecs[0]);
transpose_vecs(&h_vecs[4]);
// The first four vecs now contain the first half of each output, and the
// second four vecs contain the second half of each output.
storeu(h_vecs[0], &out[0 * sizeof(__m128i)]);
storeu(h_vecs[4], &out[1 * sizeof(__m128i)]);
storeu(h_vecs[1], &out[2 * sizeof(__m128i)]);
storeu(h_vecs[5], &out[3 * sizeof(__m128i)]);
storeu(h_vecs[2], &out[4 * sizeof(__m128i)]);
storeu(h_vecs[6], &out[5 * sizeof(__m128i)]);
storeu(h_vecs[3], &out[6 * sizeof(__m128i)]);
storeu(h_vecs[7], &out[7 * sizeof(__m128i)]);
}
INLINE void hash_one_sse41(const uint8_t *input, size_t blocks,
const uint32_t key[8], uint64_t counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t out[BLAKE3_OUT_LEN]) {
uint32_t cv[8];
memcpy(cv, key, BLAKE3_KEY_LEN);
uint8_t block_flags = flags | flags_start;
while (blocks > 0) {
if (blocks == 1) {
block_flags |= flags_end;
}
blake3_compress_in_place_sse41(cv, input, BLAKE3_BLOCK_LEN, counter,
block_flags);
input = &input[BLAKE3_BLOCK_LEN];
blocks -= 1;
block_flags = flags;
}
memcpy(out, cv, BLAKE3_OUT_LEN);
}
void blake3_hash_many_sse41(const uint8_t *const *inputs, size_t num_inputs,
size_t blocks, const uint32_t key[8],
uint64_t counter, bool increment_counter,
uint8_t flags, uint8_t flags_start,
uint8_t flags_end, uint8_t *out) {
while (num_inputs >= DEGREE) {
blake3_hash4_sse41(inputs, blocks, key, counter, increment_counter, flags,
flags_start, flags_end, out);
if (increment_counter) {
counter += DEGREE;
}
inputs += DEGREE;
num_inputs -= DEGREE;
out = &out[DEGREE * BLAKE3_OUT_LEN];
}
while (num_inputs > 0) {
hash_one_sse41(inputs[0], blocks, key, counter, flags, flags_start,
flags_end, out);
if (increment_counter) {
counter += 1;
}
inputs += 1;
num_inputs -= 1;
out = &out[BLAKE3_OUT_LEN];
}
}

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#include "blake3.h"
#include <stdio.h>
#include <unistd.h>
int main() {
// Initialize the hasher.
blake3_hasher hasher;
blake3_hasher_init(&hasher);
// Read input bytes from stdin.
unsigned char buf[65536];
ssize_t n;
while ((n = read(STDIN_FILENO, buf, sizeof(buf))) > 0) {
blake3_hasher_update(&hasher, buf, n);
}
// Finalize the hash. BLAKE3_OUT_LEN is the default output length, 32 bytes.
uint8_t output[BLAKE3_OUT_LEN];
blake3_hasher_finalize(&hasher, output, BLAKE3_OUT_LEN);
// Print the hash as hexadecimal.
for (size_t i = 0; i < BLAKE3_OUT_LEN; i++) {
printf("%02x", output[i]);
}
printf("\n");
return 0;
}

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/*
* This main file is intended for testing via `make test`. It does not build in
* other settings. See README.md in this directory for examples of how to build
* C code.
*/
#include <assert.h>
#include <errno.h>
#include <stdbool.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include "blake3.h"
#include "blake3_impl.h"
#define HASH_MODE 0
#define KEYED_HASH_MODE 1
#define DERIVE_KEY_MODE 2
static void hex_char_value(uint8_t c, uint8_t *value, bool *valid) {
if ('0' <= c && c <= '9') {
*value = c - '0';
*valid = true;
} else if ('a' <= c && c <= 'f') {
*value = 10 + c - 'a';
*valid = true;
} else {
*valid = false;
}
}
static int parse_key(char *hex_key, uint8_t out[BLAKE3_KEY_LEN]) {
size_t hex_len = strlen(hex_key);
if (hex_len != 64) {
fprintf(stderr, "Expected a 64-char hexadecimal key, got %zu chars.\n",
hex_len);
return 1;
}
for (size_t i = 0; i < 64; i++) {
uint8_t value;
bool valid;
hex_char_value(hex_key[i], &value, &valid);
if (!valid) {
fprintf(stderr, "Invalid hex char.\n");
return 1;
}
if (i % 2 == 0) {
out[i / 2] = 0;
value <<= 4;
}
out[i / 2] += value;
}
return 0;
}
/* A little repetition here */
enum cpu_feature {
SSE2 = 1 << 0,
SSSE3 = 1 << 1,
SSE41 = 1 << 2,
AVX = 1 << 3,
AVX2 = 1 << 4,
AVX512F = 1 << 5,
AVX512VL = 1 << 6,
/* ... */
UNDEFINED = 1 << 30
};
extern enum cpu_feature g_cpu_features;
enum cpu_feature get_cpu_features();
int main(int argc, char **argv) {
size_t out_len = BLAKE3_OUT_LEN;
uint8_t key[BLAKE3_KEY_LEN];
char *context = "";
uint8_t mode = HASH_MODE;
while (argc > 1) {
if (argc <= 2) {
fprintf(stderr, "Odd number of arguments.\n");
return 1;
}
if (strcmp("--length", argv[1]) == 0) {
char *endptr = NULL;
errno = 0;
unsigned long long out_len_ll = strtoull(argv[2], &endptr, 10);
if (errno != 0 || out_len > SIZE_MAX || endptr == argv[2] ||
*endptr != 0) {
fprintf(stderr, "Bad length argument.\n");
return 1;
}
out_len = (size_t)out_len_ll;
} else if (strcmp("--keyed", argv[1]) == 0) {
mode = KEYED_HASH_MODE;
int ret = parse_key(argv[2], key);
if (ret != 0) {
return ret;
}
} else if (strcmp("--derive-key", argv[1]) == 0) {
mode = DERIVE_KEY_MODE;
context = argv[2];
} else {
fprintf(stderr, "Unknown flag.\n");
return 1;
}
argc -= 2;
argv += 2;
}
/*
* We're going to hash the input multiple times, so we need to buffer it all.
* This is just for test cases, so go ahead and assume that the input is less
* than 1 MiB.
*/
size_t buf_capacity = 1 << 20;
uint8_t *buf = malloc(buf_capacity);
assert(buf != NULL);
size_t buf_len = 0;
while (1) {
size_t n = fread(&buf[buf_len], 1, buf_capacity - buf_len, stdin);
if (n == 0) {
break;
}
buf_len += n;
assert(buf_len < buf_capacity);
}
const int mask = get_cpu_features();
int feature = 0;
do {
fprintf(stderr, "Testing 0x%08X\n", feature);
g_cpu_features = feature;
blake3_hasher hasher;
switch (mode) {
case HASH_MODE:
blake3_hasher_init(&hasher);
break;
case KEYED_HASH_MODE:
blake3_hasher_init_keyed(&hasher, key);
break;
case DERIVE_KEY_MODE:
blake3_hasher_init_derive_key(&hasher, context);
break;
default:
abort();
}
blake3_hasher_update(&hasher, buf, buf_len);
/* TODO: An incremental output reader API to avoid this allocation. */
uint8_t *out = malloc(out_len);
if (out_len > 0 && out == NULL) {
fprintf(stderr, "malloc() failed.\n");
return 1;
}
blake3_hasher_finalize(&hasher, out, out_len);
for (size_t i = 0; i < out_len; i++) {
printf("%02x", out[i]);
}
printf("\n");
free(out);
feature = (feature - mask) & mask;
} while (feature != 0);
free(buf);
return 0;
}

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#! /usr/bin/env python3
from binascii import hexlify
import json
from os import path
import subprocess
HERE = path.dirname(__file__)
TEST_VECTORS_PATH = path.join(HERE, "..", "test_vectors", "test_vectors.json")
TEST_VECTORS = json.load(open(TEST_VECTORS_PATH))
def run_blake3(args, input):
output = subprocess.run([path.join(HERE, "blake3")] + args,
input=input,
stdout=subprocess.PIPE,
check=True)
return output.stdout.decode().strip()
# Fill the input with a repeating byte pattern. We use a cycle length of 251,
# because that's the largets prime number less than 256. This makes it unlikely
# to swapping any two adjacent input blocks or chunks will give the same
# answer.
def make_test_input(length):
i = 0
buf = bytearray()
while len(buf) < length:
buf.append(i)
i = (i + 1) % 251
return buf
def main():
for case in TEST_VECTORS["cases"]:
input_len = case["input_len"]
input = make_test_input(input_len)
hex_key = hexlify(TEST_VECTORS["key"].encode())
context_string = TEST_VECTORS["context_string"]
expected_hash_xof = case["hash"]
expected_hash = expected_hash_xof[:64]
expected_keyed_hash_xof = case["keyed_hash"]
expected_keyed_hash = expected_keyed_hash_xof[:64]
expected_derive_key_xof = case["derive_key"]
expected_derive_key = expected_derive_key_xof[:64]
# Test the default hash.
test_hash = run_blake3([], input)
for line in test_hash.splitlines():
assert expected_hash == line, \
"hash({}): {} != {}".format(input_len, expected_hash, line)
# Test the extended hash.
xof_len = len(expected_hash_xof) // 2
test_hash_xof = run_blake3(["--length", str(xof_len)], input)
for line in test_hash_xof.splitlines():
assert expected_hash_xof == line, \
"hash_xof({}): {} != {}".format(
input_len, expected_hash_xof, line)
# Test the default keyed hash.
test_keyed_hash = run_blake3(["--keyed", hex_key], input)
for line in test_keyed_hash.splitlines():
assert expected_keyed_hash == line, \
"keyed_hash({}): {} != {}".format(
input_len, expected_keyed_hash, line)
# Test the extended keyed hash.
xof_len = len(expected_keyed_hash_xof) // 2
test_keyed_hash_xof = run_blake3(
["--keyed", hex_key, "--length",
str(xof_len)], input)
for line in test_keyed_hash_xof.splitlines():
assert expected_keyed_hash_xof == line, \
"keyed_hash_xof({}): {} != {}".format(
input_len, expected_keyed_hash_xof, line)
# Test the default derive key.
test_derive_key = run_blake3(["--derive-key", context_string], input)
for line in test_derive_key.splitlines():
assert expected_derive_key == line, \
"derive_key({}): {} != {}".format(
input_len, expected_derive_key, line)
# Test the extended derive key.
xof_len = len(expected_derive_key_xof) // 2
test_derive_key_xof = run_blake3(
["--derive-key", context_string, "--length",
str(xof_len)], input)
for line in test_derive_key_xof.splitlines():
assert expected_derive_key_xof == line, \
"derive_key_xof({}): {} != {}".format(
input_len, expected_derive_key_xof, line)
if __name__ == "__main__":
main()