mirror of
https://github.com/moses-smt/mosesdecoder.git
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186 lines
5.6 KiB
C++
186 lines
5.6 KiB
C++
#ifndef UTIL_BIT_PACKING_H
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#define UTIL_BIT_PACKING_H
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/* Bit-level packing routines
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*
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* WARNING WARNING WARNING:
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* The write functions assume that memory is zero initially. This makes them
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* faster and is the appropriate case for mmapped language model construction.
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* These routines assume that unaligned access to uint64_t is fast. This is
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* the case on x86_64. I'm not sure how fast unaligned 64-bit access is on
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* x86 but my target audience is large language models for which 64-bit is
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* necessary.
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*
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* Call the BitPackingSanity function to sanity check. Calling once suffices,
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* but it may be called multiple times when that's inconvenient.
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*
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* ARM and MinGW ports contributed by Hideo Okuma and Tomoyuki Yoshimura at
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* NICT.
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*/
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#include <cassert>
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#ifdef __APPLE__
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#include <architecture/byte_order.h>
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#elif __linux__
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#include <endian.h>
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#elif !defined(_WIN32) && !defined(_WIN64)
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#include <arpa/nameser_compat.h>
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#endif
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#include <stdint.h>
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#include <cstring>
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namespace util {
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// Fun fact: __BYTE_ORDER is wrong on Solaris Sparc, but the version without __ is correct.
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#if BYTE_ORDER == LITTLE_ENDIAN
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inline uint8_t BitPackShift(uint8_t bit, uint8_t /*length*/) {
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return bit;
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}
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#elif BYTE_ORDER == BIG_ENDIAN
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inline uint8_t BitPackShift(uint8_t bit, uint8_t length) {
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return 64 - length - bit;
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}
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#else
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#error "Bit packing code isn't written for your byte order."
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#endif
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inline uint64_t ReadOff(const void *base, uint64_t bit_off) {
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#if defined(__arm) || defined(__arm__)
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const uint8_t *base_off = reinterpret_cast<const uint8_t*>(base) + (bit_off >> 3);
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uint64_t value64;
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memcpy(&value64, base_off, sizeof(value64));
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return value64;
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#else
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return *reinterpret_cast<const uint64_t*>(reinterpret_cast<const uint8_t*>(base) + (bit_off >> 3));
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#endif
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}
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/* Pack integers up to 57 bits using their least significant digits.
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* The length is specified using mask:
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* Assumes mask == (1 << length) - 1 where length <= 57.
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*/
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inline uint64_t ReadInt57(const void *base, uint64_t bit_off, uint8_t length, uint64_t mask) {
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return (ReadOff(base, bit_off) >> BitPackShift(bit_off & 7, length)) & mask;
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}
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/* Assumes value < (1 << length) and length <= 57.
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* Assumes the memory is zero initially.
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*/
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inline void WriteInt57(void *base, uint64_t bit_off, uint8_t length, uint64_t value) {
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#if defined(__arm) || defined(__arm__)
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uint8_t *base_off = reinterpret_cast<uint8_t*>(base) + (bit_off >> 3);
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uint64_t value64;
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memcpy(&value64, base_off, sizeof(value64));
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value64 |= (value << BitPackShift(bit_off & 7, length));
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memcpy(base_off, &value64, sizeof(value64));
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#else
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*reinterpret_cast<uint64_t*>(reinterpret_cast<uint8_t*>(base) + (bit_off >> 3)) |=
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(value << BitPackShift(bit_off & 7, length));
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#endif
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}
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/* Same caveats as above, but for a 25 bit limit. */
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inline uint32_t ReadInt25(const void *base, uint64_t bit_off, uint8_t length, uint32_t mask) {
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#if defined(__arm) || defined(__arm__)
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const uint8_t *base_off = reinterpret_cast<const uint8_t*>(base) + (bit_off >> 3);
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uint32_t value32;
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memcpy(&value32, base_off, sizeof(value32));
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return (value32 >> BitPackShift(bit_off & 7, length)) & mask;
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#else
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return (*reinterpret_cast<const uint32_t*>(reinterpret_cast<const uint8_t*>(base) + (bit_off >> 3)) >> BitPackShift(bit_off & 7, length)) & mask;
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#endif
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}
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inline void WriteInt25(void *base, uint64_t bit_off, uint8_t length, uint32_t value) {
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#if defined(__arm) || defined(__arm__)
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uint8_t *base_off = reinterpret_cast<uint8_t*>(base) + (bit_off >> 3);
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uint32_t value32;
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memcpy(&value32, base_off, sizeof(value32));
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value32 |= (value << BitPackShift(bit_off & 7, length));
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memcpy(base_off, &value32, sizeof(value32));
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#else
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*reinterpret_cast<uint32_t*>(reinterpret_cast<uint8_t*>(base) + (bit_off >> 3)) |=
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(value << BitPackShift(bit_off & 7, length));
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#endif
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}
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typedef union { float f; uint32_t i; } FloatEnc;
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inline float ReadFloat32(const void *base, uint64_t bit_off) {
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FloatEnc encoded;
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encoded.i = ReadOff(base, bit_off) >> BitPackShift(bit_off & 7, 32);
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return encoded.f;
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}
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inline void WriteFloat32(void *base, uint64_t bit_off, float value) {
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FloatEnc encoded;
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encoded.f = value;
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WriteInt57(base, bit_off, 32, encoded.i);
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}
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const uint32_t kSignBit = 0x80000000;
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inline void SetSign(float &to) {
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FloatEnc enc;
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enc.f = to;
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enc.i |= kSignBit;
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to = enc.f;
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}
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inline void UnsetSign(float &to) {
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FloatEnc enc;
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enc.f = to;
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enc.i &= ~kSignBit;
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to = enc.f;
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}
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inline float ReadNonPositiveFloat31(const void *base, uint64_t bit_off) {
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FloatEnc encoded;
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encoded.i = ReadOff(base, bit_off) >> BitPackShift(bit_off & 7, 31);
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// Sign bit set means negative.
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encoded.i |= kSignBit;
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return encoded.f;
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}
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inline void WriteNonPositiveFloat31(void *base, uint64_t bit_off, float value) {
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FloatEnc encoded;
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encoded.f = value;
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encoded.i &= ~kSignBit;
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WriteInt57(base, bit_off, 31, encoded.i);
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}
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void BitPackingSanity();
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// Return bits required to store integers upto max_value. Not the most
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// efficient implementation, but this is only called a few times to size tries.
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uint8_t RequiredBits(uint64_t max_value);
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struct BitsMask {
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static BitsMask ByMax(uint64_t max_value) {
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BitsMask ret;
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ret.FromMax(max_value);
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return ret;
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}
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static BitsMask ByBits(uint8_t bits) {
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BitsMask ret;
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ret.bits = bits;
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ret.mask = (1ULL << bits) - 1;
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return ret;
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}
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void FromMax(uint64_t max_value) {
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bits = RequiredBits(max_value);
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mask = (1ULL << bits) - 1;
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}
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uint8_t bits;
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uint64_t mask;
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};
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struct BitAddress {
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BitAddress(void *in_base, uint64_t in_offset) : base(in_base), offset(in_offset) {}
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void *base;
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uint64_t offset;
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};
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} // namespace util
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#endif // UTIL_BIT_PACKING_H
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