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#include "lm/binary_format.hh"
#include "lm/lm_exception.hh"
#include "util/file_piece.hh"
#include <limits>
#include <string>
#include <fcntl.h>
#include <errno.h>
#include <stdlib.h>
#include <sys/mman.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <unistd.h>
namespace lm {
namespace ngram {
namespace {
const char kMagicBeforeVersion[] = "mmap lm http://kheafield.com/code format version";
const char kMagicBytes[] = "mmap lm http://kheafield.com/code format version 3\n\0";
const long int kMagicVersion = 2;
// Test values.
struct Sanity {
char magic[sizeof(kMagicBytes)];
float zero_f, one_f, minus_half_f;
WordIndex one_word_index, max_word_index;
uint64_t one_uint64;
void SetToReference() {
std::memcpy(magic, kMagicBytes, sizeof(magic));
zero_f = 0.0; one_f = 1.0; minus_half_f = -0.5;
one_word_index = 1;
max_word_index = std::numeric_limits<WordIndex>::max();
one_uint64 = 1;
}
};
const char *kModelNames[3] = {"hashed n-grams with probing", "hashed n-grams with sorted uniform find", "bit packed trie"};
std::size_t Align8(std::size_t in) {
std::size_t off = in % 8;
if (!off) return in;
return in + 8 - off;
}
std::size_t TotalHeaderSize(unsigned char order) {
return Align8(sizeof(Sanity) + sizeof(FixedWidthParameters) + sizeof(uint64_t) * order);
}
void ReadLoop(int fd, void *to_void, std::size_t size) {
uint8_t *to = static_cast<uint8_t*>(to_void);
while (size) {
ssize_t ret = read(fd, to, size);
if (ret == -1) UTIL_THROW(util::ErrnoException, "Failed to read from binary file");
if (ret == 0) UTIL_THROW(util::ErrnoException, "Binary file too short");
to += ret;
size -= ret;
}
}
void WriteHeader(void *to, const Parameters ¶ms) {
Sanity header = Sanity();
header.SetToReference();
memcpy(to, &header, sizeof(Sanity));
char *out = reinterpret_cast<char*>(to) + sizeof(Sanity);
*reinterpret_cast<FixedWidthParameters*>(out) = params.fixed;
out += sizeof(FixedWidthParameters);
uint64_t *counts = reinterpret_cast<uint64_t*>(out);
for (std::size_t i = 0; i < params.counts.size(); ++i) {
counts[i] = params.counts[i];
}
}
} // namespace
uint8_t *SetupJustVocab(const Config &config, uint8_t order, std::size_t memory_size, Backing &backing) {
if (config.write_mmap) {
std::size_t total = TotalHeaderSize(order) + memory_size;
backing.vocab.reset(util::MapZeroedWrite(config.write_mmap, total, backing.file), total, util::scoped_memory::MMAP_ALLOCATED);
return reinterpret_cast<uint8_t*>(backing.vocab.get()) + TotalHeaderSize(order);
} else {
backing.vocab.reset(util::MapAnonymous(memory_size), memory_size, util::scoped_memory::MMAP_ALLOCATED);
return reinterpret_cast<uint8_t*>(backing.vocab.get());
}
}
uint8_t *GrowForSearch(const Config &config, ModelType model_type, const std::vector<uint64_t> &counts, std::size_t memory_size, Backing &backing) {
if (config.write_mmap) {
// header and vocab share the same mmap. The header is written here because we know the counts.
Parameters params;
params.counts = counts;
params.fixed.order = counts.size();
params.fixed.probing_multiplier = config.probing_multiplier;
params.fixed.model_type = model_type;
params.fixed.has_vocabulary = config.include_vocab;
WriteHeader(backing.vocab.get(), params);
// Grow the file to accomodate the search, using zeros.
if (-1 == ftruncate(backing.file.get(), backing.vocab.size() + memory_size))
UTIL_THROW(util::ErrnoException, "ftruncate on " << config.write_mmap << " to " << (backing.vocab.size() + memory_size) << " failed");
// We're skipping over the header and vocab for the search space mmap. mmap likes page aligned offsets, so some arithmetic to round the offset down.
off_t page_size = sysconf(_SC_PAGE_SIZE);
off_t alignment_cruft = backing.vocab.size() % page_size;
backing.search.reset(util::MapOrThrow(alignment_cruft + memory_size, true, util::kFileFlags, false, backing.file.get(), backing.vocab.size() - alignment_cruft), alignment_cruft + memory_size, util::scoped_memory::MMAP_ALLOCATED);
return reinterpret_cast<uint8_t*>(backing.search.get()) + alignment_cruft;
} else {
backing.search.reset(util::MapAnonymous(memory_size), memory_size, util::scoped_memory::MMAP_ALLOCATED);
return reinterpret_cast<uint8_t*>(backing.search.get());
}
}
namespace detail {
bool IsBinaryFormat(int fd) {
const off_t size = util::SizeFile(fd);
if (size == util::kBadSize || (size <= static_cast<off_t>(sizeof(Sanity)))) return false;
// Try reading the header.
util::scoped_memory memory;
try {
util::MapRead(util::LAZY, fd, 0, sizeof(Sanity), memory);
} catch (const util::Exception &e) {
return false;
}
Sanity reference_header = Sanity();
reference_header.SetToReference();
if (!memcmp(memory.get(), &reference_header, sizeof(Sanity))) return true;
if (!memcmp(memory.get(), kMagicBeforeVersion, strlen(kMagicBeforeVersion))) {
char *end_ptr;
const char *begin_version = static_cast<const char*>(memory.get()) + strlen(kMagicBeforeVersion);
long int version = strtol(begin_version, &end_ptr, 10);
if ((end_ptr != begin_version) && version != kMagicVersion) {
UTIL_THROW(FormatLoadException, "Binary file has version " << version << " but this implementation expects version " << kMagicVersion << " so you'll have to rebuild your binary LM from the ARPA. Sorry.");
}
UTIL_THROW(FormatLoadException, "File looks like it should be loaded with mmap, but the test values don't match. Try rebuilding the binary format LM using the same code revision, compiler, and architecture.");
}
return false;
}
void ReadHeader(int fd, Parameters &out) {
if ((off_t)-1 == lseek(fd, sizeof(Sanity), SEEK_SET)) UTIL_THROW(util::ErrnoException, "Seek failed in binary file");
ReadLoop(fd, &out.fixed, sizeof(out.fixed));
if (out.fixed.probing_multiplier < 1.0)
UTIL_THROW(FormatLoadException, "Binary format claims to have a probing multiplier of " << out.fixed.probing_multiplier << " which is < 1.0.");
out.counts.resize(static_cast<std::size_t>(out.fixed.order));
ReadLoop(fd, &*out.counts.begin(), sizeof(uint64_t) * out.fixed.order);
}
void MatchCheck(ModelType model_type, const Parameters ¶ms) {
if (params.fixed.model_type != model_type) {
if (static_cast<unsigned int>(params.fixed.model_type) >= (sizeof(kModelNames) / sizeof(const char *)))
UTIL_THROW(FormatLoadException, "The binary file claims to be model type " << static_cast<unsigned int>(params.fixed.model_type) << " but this is not implemented for in this inference code.");
UTIL_THROW(FormatLoadException, "The binary file was built for " << kModelNames[params.fixed.model_type] << " but the inference code is trying to load " << kModelNames[model_type]);
}
}
uint8_t *SetupBinary(const Config &config, const Parameters ¶ms, std::size_t memory_size, Backing &backing) {
const off_t file_size = util::SizeFile(backing.file.get());
// The header is smaller than a page, so we have to map the whole header as well.
std::size_t total_map = TotalHeaderSize(params.counts.size()) + memory_size;
if (file_size != util::kBadSize && static_cast<uint64_t>(file_size) < total_map)
UTIL_THROW(FormatLoadException, "Binary file has size " << file_size << " but the headers say it should be at least " << total_map);
util::MapRead(config.load_method, backing.file.get(), 0, total_map, backing.search);
if (config.enumerate_vocab && !params.fixed.has_vocabulary)
UTIL_THROW(FormatLoadException, "The decoder requested all the vocabulary strings, but this binary file does not have them. You may need to rebuild the binary file with an updated version of build_binary.");
if (config.enumerate_vocab) {
if ((off_t)-1 == lseek(backing.file.get(), total_map, SEEK_SET))
UTIL_THROW(util::ErrnoException, "Failed to seek in binary file to vocab words");
}
return reinterpret_cast<uint8_t*>(backing.search.get()) + TotalHeaderSize(params.counts.size());
}
void ComplainAboutARPA(const Config &config, ModelType model_type) {
if (config.write_mmap || !config.messages) return;
if (config.arpa_complain == Config::ALL) {
*config.messages << "Loading the LM will be faster if you build a binary file." << std::endl;
} else if (config.arpa_complain == Config::EXPENSIVE && model_type == TRIE_SORTED) {
*config.messages << "Building " << kModelNames[model_type] << " from ARPA is expensive. Save time by building a binary format." << std::endl;
}
}
} // namespace detail
bool RecognizeBinary(const char *file, ModelType &recognized) {
util::scoped_fd fd(util::OpenReadOrThrow(file));
if (!detail::IsBinaryFormat(fd.get())) return false;
Parameters params;
detail::ReadHeader(fd.get(), params);
recognized = params.fixed.model_type;
return true;
}
} // namespace ngram
} // namespace lm
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