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apache / doris / refs/heads/variant-sparse-merge / . / be / src / util / rle_encoding.h
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// Licensed to the Apache Software Foundation (ASF) under one
// or more contributor license agreements. See the NOTICE file
// distributed with this work for additional information
// regarding copyright ownership. The ASF licenses this file
// to you under the Apache License, Version 2.0 (the
// "License"); you may not use this file except in compliance
// with the License. You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing,
// software distributed under the License is distributed on an
// "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
// KIND, either express or implied. See the License for the
// specific language governing permissions and limitations
// under the License.
#pragma once
#include <glog/logging.h>
#include <limits> // IWYU pragma: keep
#include "common/cast_set.h"
#include "util/bit_stream_utils.inline.h"
#include "util/bit_util.h"
namespace doris {
#include "common/compile_check_begin.h"
// Utility classes to do run length encoding (RLE) for fixed bit width values. If runs
// are sufficiently long, RLE is used, otherwise, the values are just bit-packed
// (literal encoding).
// For both types of runs, there is a byte-aligned indicator which encodes the length
// of the run and the type of the run.
// This encoding has the benefit that when there aren't any long enough runs, values
// are always decoded at fixed (can be precomputed) bit offsets OR both the value and
// the run length are byte aligned. This allows for very efficient decoding
// implementations.
// The encoding is:
// encoded-block := run*
// run := literal-run | repeated-run
// literal-run := literal-indicator < literal bytes >
// repeated-run := repeated-indicator < repeated value. padded to byte boundary >
// literal-indicator := varint_encode( number_of_groups << 1 | 1)
// repeated-indicator := varint_encode( number_of_repetitions << 1 )
//
// Each run is preceded by a varint. The varint's least significant bit is
// used to indicate whether the run is a literal run or a repeated run. The rest
// of the varint is used to determine the length of the run (eg how many times the
// value repeats).
//
// In the case of literal runs, the run length is always a multiple of 8 (i.e. encode
// in groups of 8), so that no matter the bit-width of the value, the sequence will end
// on a byte boundary without padding.
// Given that we know it is a multiple of 8, we store the number of 8-groups rather than
// the actual number of encoded ints. (This means that the total number of encoded values
// can not be determined from the encoded data, since the number of values in the last
// group may not be a multiple of 8).
// There is a break-even point when it is more storage efficient to do run length
// encoding. For 1 bit-width values, that point is 8 values. They require 2 bytes
// for both the repeated encoding or the literal encoding. This value can always
// be computed based on the bit-width.
// TODO: think about how to use this for strings. The bit packing isn't quite the same.
//
// Examples with bit-width 1 (eg encoding booleans):
// ----------------------------------------
// 100 1s followed by 100 0s:
// <varint(100 << 1)> <1, padded to 1 byte> <varint(100 << 1)> <0, padded to 1 byte>
// - (total 4 bytes)
//
// alternating 1s and 0s (200 total):
// 200 ints = 25 groups of 8
// <varint((25 << 1) | 1)> <25 bytes of values, bitpacked>
// (total 26 bytes, 1 byte overhead)
//
// Decoder class for RLE encoded data.
//
// NOTE: the encoded format does not have any length prefix or any other way of
// indicating that the encoded sequence ends at a certain point, so the Decoder
// methods may return some extra bits at the end before the read methods start
// to return 0/false.
template <typename T>
class RleDecoder {
public:
// Create a decoder object. buffer/buffer_len is the decoded data.
// bit_width is the width of each value (before encoding).
RleDecoder(const uint8_t* buffer, int buffer_len, int bit_width)
: bit_reader_(buffer, buffer_len),
bit_width_(bit_width),
current_value_(0),
repeat_count_(0),
literal_count_(0),
rewind_state_(CANT_REWIND) {
DCHECK_GE(bit_width_, 1);
DCHECK_LE(bit_width_, 64);
}
RleDecoder() {}
// Skip n values, and returns the number of non-zero entries skipped.
size_t Skip(size_t to_skip);
// Gets the next value. Returns false if there are no more.
bool Get(T* val);
// Seek to the previous value.
void RewindOne();
// Gets the next run of the same 'val'. Returns 0 if there is no
// more data to be decoded. Will return a run of at most 'max_run'
// values. If there are more values than this, the next call to
// GetNextRun will return more from the same run.
size_t GetNextRun(T* val, size_t max_run);
size_t get_values(T* values, size_t num_values);
// Get the count of current repeated value
size_t repeated_count();
// Get current repeated value, make sure that count equals repeated_count()
T get_repeated_value(size_t count);
const BitReader& bit_reader() const { return bit_reader_; }
private:
bool ReadHeader();
enum RewindState { REWIND_LITERAL, REWIND_RUN, CANT_REWIND };
BitReader bit_reader_;
int bit_width_;
uint64_t current_value_;
uint32_t repeat_count_;
uint32_t literal_count_;
RewindState rewind_state_;
};
// Class to incrementally build the rle data.
// The encoding has two modes: encoding repeated runs and literal runs.
// If the run is sufficiently short, it is more efficient to encode as a literal run.
// This class does so by buffering 8 values at a time. If they are not all the same
// they are added to the literal run. If they are the same, they are added to the
// repeated run. When we switch modes, the previous run is flushed out.
template <typename T>
class RleEncoder {
public:
// buffer: buffer to write bits to.
// bit_width: max number of bits for value.
// TODO: consider adding a min_repeated_run_length so the caller can control
// when values should be encoded as repeated runs. Currently this is derived
// based on the bit_width, which can determine a storage optimal choice.
explicit RleEncoder(faststring* buffer, int bit_width)
: bit_width_(bit_width), bit_writer_(buffer) {
DCHECK_GE(bit_width_, 1);
DCHECK_LE(bit_width_, 64);
Clear();
}
// Reserve 'num_bytes' bytes for a plain encoded header, set each
// byte with 'val': this is used for the RLE-encoded data blocks in
// order to be able to able to store the initial ordinal position
// and number of elements. This is a part of RleEncoder in order to
// maintain the correct offset in 'buffer'.
void Reserve(int num_bytes, uint8_t val);
// Encode value. This value must be representable with bit_width_ bits.
void Put(T value, size_t run_length = 1);
// Flushes any pending values to the underlying buffer.
// Returns the total number of bytes written
int Flush();
// Resets all the state in the encoder.
void Clear();
int32_t len() const { return bit_writer_.bytes_written(); }
private:
// Flushes any buffered values. If this is part of a repeated run, this is largely
// a no-op.
// If it is part of a literal run, this will call FlushLiteralRun, which writes
// out the buffered literal values.
// If 'done' is true, the current run would be written even if it would normally
// have been buffered more. This should only be called at the end, when the
// encoder has received all values even if it would normally continue to be
// buffered.
void FlushBufferedValues(bool done);
// Flushes literal values to the underlying buffer. If update_indicator_byte,
// then the current literal run is complete and the indicator byte is updated.
void FlushLiteralRun(bool update_indicator_byte);
// Flushes a repeated run to the underlying buffer.
void FlushRepeatedRun();
// Number of bits needed to encode the value.
const int bit_width_;
// Underlying buffer.
BitWriter bit_writer_;
// We need to buffer at most 8 values for literals. This happens when the
// bit_width is 1 (so 8 values fit in one byte).
// TODO: generalize this to other bit widths
uint64_t buffered_values_[8];
// Number of values in buffered_values_
int num_buffered_values_;
// The current (also last) value that was written and the count of how
// many times in a row that value has been seen. This is maintained even
// if we are in a literal run. If the repeat_count_ get high enough, we switch
// to encoding repeated runs.
uint64_t current_value_;
int repeat_count_;
// Number of literals in the current run. This does not include the literals
// that might be in buffered_values_. Only after we've got a group big enough
// can we decide if they should part of the literal_count_ or repeat_count_
int literal_count_;
// Index of a byte in the underlying buffer that stores the indicator byte.
// This is reserved as soon as we need a literal run but the value is written
// when the literal run is complete. We maintain an index rather than a pointer
// into the underlying buffer because the pointer value may become invalid if
// the underlying buffer is resized.
int literal_indicator_byte_idx_;
};
template <typename T>
bool RleDecoder<T>::ReadHeader() {
DCHECK(bit_reader_.is_initialized());
if (literal_count_ == 0 && repeat_count_ == 0) [[unlikely]] {
// Read the next run's indicator int, it could be a literal or repeated run
// The int is encoded as a vlq-encoded value.
uint32_t indicator_value = 0;
bool result = bit_reader_.GetVlqInt(&indicator_value);
if (!result) [[unlikely]] {
return false;
}
// lsb indicates if it is a literal run or repeated run
bool is_literal = indicator_value & 1;
if (is_literal) {
literal_count_ = (indicator_value >> 1) * 8;
DCHECK_GT(literal_count_, 0);
} else {
repeat_count_ = indicator_value >> 1;
DCHECK_GT(repeat_count_, 0);
bool result1 = bit_reader_.GetAligned<T>(BitUtil::Ceil(bit_width_, 8),
reinterpret_cast<T*>(&current_value_));
DCHECK(result1);
}
}
return true;
}
template <typename T>
bool RleDecoder<T>::Get(T* val) {
DCHECK(bit_reader_.is_initialized());
if (!ReadHeader()) [[unlikely]] {
return false;
}
if (repeat_count_ > 0) [[likely]] {
*val = cast_set<T>(current_value_);
--repeat_count_;
rewind_state_ = REWIND_RUN;
} else {
DCHECK(literal_count_ > 0);
bool result = bit_reader_.GetValue(bit_width_, val);
DCHECK(result);
--literal_count_;
rewind_state_ = REWIND_LITERAL;
}
return true;
}
template <typename T>
void RleDecoder<T>::RewindOne() {
DCHECK(bit_reader_.is_initialized());
switch (rewind_state_) {
case CANT_REWIND:
throw Exception(Status::FatalError("Can't rewind more than once after each read!"));
break;
case REWIND_RUN:
++repeat_count_;
break;
case REWIND_LITERAL: {
bit_reader_.Rewind(bit_width_);
++literal_count_;
break;
}
}
rewind_state_ = CANT_REWIND;
}
template <typename T>
size_t RleDecoder<T>::GetNextRun(T* val, size_t max_run) {
DCHECK(bit_reader_.is_initialized());
DCHECK_GT(max_run, 0);
size_t ret = 0;
size_t rem = max_run;
while (ReadHeader()) {
if (repeat_count_ > 0) [[likely]] {
if (ret > 0 && *val != current_value_) [[unlikely]] {
return ret;
}
*val = cast_set<T>(current_value_);
if (repeat_count_ >= rem) {
// The next run is longer than the amount of remaining data
// that the caller wants to read. Only consume it partially.
repeat_count_ -= rem;
ret += rem;
return ret;
}
ret += repeat_count_;
rem -= repeat_count_;
repeat_count_ = 0;
} else {
DCHECK(literal_count_ > 0);
if (ret == 0) {
bool has_more = bit_reader_.GetValue(bit_width_, val);
DCHECK(has_more);
literal_count_--;
ret++;
rem--;
}
while (literal_count_ > 0) {
bool result = bit_reader_.GetValue(bit_width_, &current_value_);
DCHECK(result);
if (current_value_ != *val || rem == 0) {
bit_reader_.Rewind(bit_width_);
return ret;
}
ret++;
rem--;
literal_count_--;
}
}
}
return ret;
}
template <typename T>
size_t RleDecoder<T>::get_values(T* values, size_t num_values) {
size_t read_num = 0;
while (read_num < num_values) {
size_t read_this_time = num_values - read_num;
if (LIKELY(repeat_count_ > 0)) {
read_this_time = std::min((size_t)repeat_count_, read_this_time);
std::fill(values, values + read_this_time, current_value_);
values += read_this_time;
repeat_count_ -= read_this_time;
read_num += read_this_time;
} else if (literal_count_ > 0) {
read_this_time = std::min((size_t)literal_count_, read_this_time);
for (int i = 0; i < read_this_time; ++i) {
bool result = bit_reader_.GetValue(bit_width_, values);
DCHECK(result);
values++;
}
literal_count_ -= read_this_time;
read_num += read_this_time;
} else {
if (!ReadHeader()) {
return read_num;
}
}
}
return read_num;
}
template <typename T>
size_t RleDecoder<T>::repeated_count() {
if (repeat_count_ > 0) {
return repeat_count_;
}
if (literal_count_ == 0) {
ReadHeader();
}
return repeat_count_;
}
template <typename T>
T RleDecoder<T>::get_repeated_value(size_t count) {
DCHECK_GE(repeat_count_, count);
repeat_count_ -= count;
return current_value_;
}
template <typename T>
size_t RleDecoder<T>::Skip(size_t to_skip) {
DCHECK(bit_reader_.is_initialized());
size_t set_count = 0;
while (to_skip > 0) {
bool result = ReadHeader();
DCHECK(result);
if (repeat_count_ > 0) [[likely]] {
size_t nskip = (repeat_count_ < to_skip) ? repeat_count_ : to_skip;
repeat_count_ -= nskip;
to_skip -= nskip;
if (current_value_ != 0) {
set_count += nskip;
}
} else {
DCHECK(literal_count_ > 0);
size_t nskip = (literal_count_ < to_skip) ? literal_count_ : to_skip;
literal_count_ -= nskip;
to_skip -= nskip;
for (; nskip > 0; nskip--) {
T value = 0;
bool result1 = bit_reader_.GetValue(bit_width_, &value);
DCHECK(result1);
if (value != 0) {
set_count++;
}
}
}
}
return set_count;
}
// This function buffers input values 8 at a time. After seeing all 8 values,
// it decides whether they should be encoded as a literal or repeated run.
template <typename T>
void RleEncoder<T>::Put(T value, size_t run_length) {
DCHECK(bit_width_ == 64 || value < (1LL << bit_width_));
// TODO(perf): remove the loop and use the repeat_count_
for (; run_length > 0; run_length--) {
if (current_value_ == value) [[likely]] {
++repeat_count_;
if (repeat_count_ > 8) {
// This is just a continuation of the current run, no need to buffer the
// values.
// Note that this is the fast path for long repeated runs.
continue;
}
} else {
if (repeat_count_ >= 8) {
// We had a run that was long enough but it has ended. Flush the
// current repeated run.
DCHECK_EQ(literal_count_, 0);
FlushRepeatedRun();
}
repeat_count_ = 1;
current_value_ = value;
}
buffered_values_[num_buffered_values_] = value;
if (++num_buffered_values_ == 8) {
DCHECK_EQ(literal_count_ % 8, 0);
FlushBufferedValues(false);
}
}
}
template <typename T>
void RleEncoder<T>::FlushLiteralRun(bool update_indicator_byte) {
if (literal_indicator_byte_idx_ < 0) {
// The literal indicator byte has not been reserved yet, get one now.
literal_indicator_byte_idx_ = cast_set<int>(bit_writer_.GetByteIndexAndAdvance(1));
DCHECK_GE(literal_indicator_byte_idx_, 0);
}
// Write all the buffered values as bit packed literals
for (int i = 0; i < num_buffered_values_; ++i) {
bit_writer_.PutValue(buffered_values_[i], bit_width_);
}
num_buffered_values_ = 0;
if (update_indicator_byte) {
// At this point we need to write the indicator byte for the literal run.
// We only reserve one byte, to allow for streaming writes of literal values.
// The logic makes sure we flush literal runs often enough to not overrun
// the 1 byte.
int num_groups = BitUtil::Ceil(literal_count_, 8);
int32_t indicator_value = (num_groups << 1) | 1;
DCHECK_EQ(indicator_value & 0xFFFFFF00, 0);
bit_writer_.buffer()->data()[literal_indicator_byte_idx_] =
cast_set<uint8_t>(indicator_value);
literal_indicator_byte_idx_ = -1;
literal_count_ = 0;
}
}
template <typename T>
void RleEncoder<T>::FlushRepeatedRun() {
DCHECK_GT(repeat_count_, 0);
// The lsb of 0 indicates this is a repeated run
int32_t indicator_value = repeat_count_ << 1 | 0;
bit_writer_.PutVlqInt(indicator_value);
bit_writer_.PutAligned(current_value_, BitUtil::Ceil(bit_width_, 8));
num_buffered_values_ = 0;
repeat_count_ = 0;
}
// Flush the values that have been buffered. At this point we decide whether
// we need to switch between the run types or continue the current one.
template <typename T>
void RleEncoder<T>::FlushBufferedValues(bool done) {
if (repeat_count_ >= 8) {
// Clear the buffered values. They are part of the repeated run now and we
// don't want to flush them out as literals.
num_buffered_values_ = 0;
if (literal_count_ != 0) {
// There was a current literal run. All the values in it have been flushed
// but we still need to update the indicator byte.
DCHECK_EQ(literal_count_ % 8, 0);
DCHECK_EQ(repeat_count_, 8);
FlushLiteralRun(true);
}
DCHECK_EQ(literal_count_, 0);
return;
}
literal_count_ += num_buffered_values_;
int num_groups = BitUtil::Ceil(literal_count_, 8);
if (num_groups + 1 >= (1 << 6)) {
// We need to start a new literal run because the indicator byte we've reserved
// cannot store more values.
DCHECK_GE(literal_indicator_byte_idx_, 0);
FlushLiteralRun(true);
} else {
FlushLiteralRun(done);
}
repeat_count_ = 0;
}
template <typename T>
void RleEncoder<T>::Reserve(int num_bytes, uint8_t val) {
for (int i = 0; i < num_bytes; ++i) {
bit_writer_.PutValue(val, 8);
}
}
template <typename T>
int RleEncoder<T>::Flush() {
if (literal_count_ > 0 || repeat_count_ > 0 || num_buffered_values_ > 0) {
bool all_repeat = literal_count_ == 0 &&
(repeat_count_ == num_buffered_values_ || num_buffered_values_ == 0);
// There is something pending, figure out if it's a repeated or literal run
if (repeat_count_ > 0 && all_repeat) {
FlushRepeatedRun();
} else {
literal_count_ += num_buffered_values_;
FlushLiteralRun(true);
repeat_count_ = 0;
}
}
bit_writer_.Flush();
DCHECK_EQ(num_buffered_values_, 0);
DCHECK_EQ(literal_count_, 0);
DCHECK_EQ(repeat_count_, 0);
return bit_writer_.bytes_written();
}
template <typename T>
void RleEncoder<T>::Clear() {
current_value_ = 0;
repeat_count_ = 0;
num_buffered_values_ = 0;
literal_count_ = 0;
literal_indicator_byte_idx_ = -1;
bit_writer_.Clear();
}
// Copy from https://github.com/apache/impala/blob/master/be/src/util/rle-encoding.h
// Utility classes to do run length encoding (RLE) for fixed bit width values. If runs
// are sufficiently long, RLE is used, otherwise, the values are just bit-packed
// (literal encoding).
//
// For both types of runs, there is a byte-aligned indicator which encodes the length
// of the run and the type of the run.
//
// This encoding has the benefit that when there aren't any long enough runs, values
// are always decoded at fixed (can be precomputed) bit offsets OR both the value and
// the run length are byte aligned. This allows for very efficient decoding
// implementations.
// The encoding is:
// encoded-block := run*
// run := literal-run | repeated-run
// literal-run := literal-indicator < literal bytes >
// repeated-run := repeated-indicator < repeated value. padded to byte boundary >
// literal-indicator := varint_encode( number_of_groups << 1 | 1)
// repeated-indicator := varint_encode( number_of_repetitions << 1 )
//
// Each run is preceded by a varint. The varint's least significant bit is
// used to indicate whether the run is a literal run or a repeated run. The rest
// of the varint is used to determine the length of the run (eg how many times the
// value repeats).
//
// In the case of literal runs, the run length is always a multiple of 8 (i.e. encode
// in groups of 8), so that no matter the bit-width of the value, the sequence will end
// on a byte boundary without padding.
// Given that we know it is a multiple of 8, we store the number of 8-groups rather than
// the actual number of encoded ints. (This means that the total number of encoded values
// can not be determined from the encoded data, since the number of values in the last
// group may not be a multiple of 8). For the last group of literal runs, we pad
// the group to 8 with zeros. This allows for 8 at a time decoding on the read side
// without the need for additional checks.
//
// There is a break-even point when it is more storage efficient to do run length
// encoding. For 1 bit-width values, that point is 8 values. They require 2 bytes
// for both the repeated encoding or the literal encoding. This value can always
// be computed based on the bit-width.
// TODO: For 1 bit-width values it can be optimal to use 16 or 24 values, but more
// investigation is needed to do this efficiently, see the reverted IMPALA-6658.
// TODO: think about how to use this for strings. The bit packing isn't quite the same.
//
// Examples with bit-width 1 (eg encoding booleans):
// ----------------------------------------
// 100 1s followed by 100 0s:
// <varint(100 << 1)> <1, padded to 1 byte> <varint(100 << 1)> <0, padded to 1 byte>
// - (total 4 bytes)
//
// alternating 1s and 0s (200 total):
// 200 ints = 25 groups of 8
// <varint((25 << 1) | 1)> <25 bytes of values, bitpacked>
// (total 26 bytes, 1 byte overhead)
// RLE decoder with a batch-oriented interface that enables fast decoding.
// Users of this class must first initialize the class to point to a buffer of
// RLE-encoded data, passed into the constructor or Reset(). The provided
// bit_width must be at most min(sizeof(T) * 8, BatchedBitReader::MAX_BITWIDTH).
// Then they can decode data by checking NextNumRepeats()/NextNumLiterals() to
// see if the next run is a repeated or literal run, then calling
// GetRepeatedValue() or GetLiteralValues() respectively to read the values.
//
// End-of-input is signalled by NextNumRepeats() == NextNumLiterals() == 0.
// Other decoding errors are signalled by functions returning false. If an
// error is encountered then it is not valid to read any more data until
// Reset() is called.
//bit-packed-run-len and rle-run-len must be in the range [1, 2^31 - 1].
// This means that a Parquet implementation can always store the run length in a signed 32-bit integer.
template <typename T>
class RleBatchDecoder {
public:
RleBatchDecoder(uint8_t* buffer, int buffer_len, int bit_width) {
Reset(buffer, buffer_len, bit_width);
}
RleBatchDecoder() = default;
// Reset the decoder to read from a new buffer.
void Reset(uint8_t* buffer, int buffer_len, int bit_width);
// Return the size of the current repeated run. Returns zero if the current run is
// a literal run or if no more runs can be read from the input.
int32_t NextNumRepeats();
// Get the value of the current repeated run and consume the given number of repeats.
// Only valid to call when NextNumRepeats() > 0. The given number of repeats cannot
// be greater than the remaining number of repeats in the run. 'num_repeats_to_consume'
// can be set to 0 to peek at the value without consuming repeats.
T GetRepeatedValue(int32_t num_repeats_to_consume);
// Return the size of the current literal run. Returns zero if the current run is
// a repeated run or if no more runs can be read from the input.
int32_t NextNumLiterals();
// Consume 'num_literals_to_consume' literals from the current literal run,
// copying the values to 'values'. 'num_literals_to_consume' must be <=
// NextNumLiterals(). Returns true if the requested number of literals were
// successfully read or false if an error was encountered, e.g. the input was
// truncated.
bool GetLiteralValues(int32_t num_literals_to_consume, T* values) WARN_UNUSED_RESULT;
// Consume 'num_values_to_consume' values and copy them to 'values'.
// Returns the number of consumed values or 0 if an error occurred.
uint32_t GetBatch(T* values, uint32_t batch_num);
private:
// Called when both 'literal_count_' and 'repeat_count_' have been exhausted.
// Sets either 'literal_count_' or 'repeat_count_' to the size of the next literal
// or repeated run, or leaves both at 0 if no more values can be read (either because
// the end of the input was reached or an error was encountered decoding).
void NextCounts();
/// Fill the literal buffer. Invalid to call if there are already buffered literals.
/// Return false if the input was truncated. This does not advance 'literal_count_'.
bool FillLiteralBuffer() WARN_UNUSED_RESULT;
bool HaveBufferedLiterals() const { return literal_buffer_pos_ < num_buffered_literals_; }
/// Output buffered literals, advancing 'literal_buffer_pos_' and decrementing
/// 'literal_count_'. Returns the number of literals outputted.
int32_t OutputBufferedLiterals(int32_t max_to_output, T* values);
BatchedBitReader bit_reader_;
// Number of bits needed to encode the value. Must be between 0 and 64 after
// the decoder is initialized with a buffer. -1 indicates the decoder was not
// initialized.
int bit_width_ = -1;
// If a repeated run, the number of repeats remaining in the current run to be read.
// If the current run is a literal run, this is 0.
int32_t repeat_count_ = 0;
// If a literal run, the number of literals remaining in the current run to be read.
// If the current run is a repeated run, this is 0.
int32_t literal_count_ = 0;
// If a repeated run, the current repeated value.
T repeated_value_;
// Size of buffer for literal values. Large enough to decode a full batch of 32
// literals. The buffer is needed to allow clients to read in batches that are not
// multiples of 32.
static constexpr int LITERAL_BUFFER_LEN = 32;
// Buffer containing 'num_buffered_literals_' values. 'literal_buffer_pos_' is the
// position of the next literal to be read from the buffer.
T literal_buffer_[LITERAL_BUFFER_LEN];
int num_buffered_literals_ = 0;
int literal_buffer_pos_ = 0;
};
template <typename T>
int32_t RleBatchDecoder<T>::OutputBufferedLiterals(int32_t max_to_output, T* values) {
int32_t num_to_output =
std::min<int32_t>(max_to_output, num_buffered_literals_ - literal_buffer_pos_);
memcpy(values, &literal_buffer_[literal_buffer_pos_], sizeof(T) * num_to_output);
literal_buffer_pos_ += num_to_output;
literal_count_ -= num_to_output;
return num_to_output;
}
template <typename T>
void RleBatchDecoder<T>::Reset(uint8_t* buffer, int buffer_len, int bit_width) {
bit_reader_.Reset(buffer, buffer_len);
bit_width_ = bit_width;
repeat_count_ = 0;
literal_count_ = 0;
num_buffered_literals_ = 0;
literal_buffer_pos_ = 0;
}
template <typename T>
int32_t RleBatchDecoder<T>::NextNumRepeats() {
if (repeat_count_ > 0) return repeat_count_;
if (literal_count_ == 0) NextCounts();
return repeat_count_;
}
template <typename T>
void RleBatchDecoder<T>::NextCounts() {
// Read the next run's indicator int, it could be a literal or repeated run.
// The int is encoded as a ULEB128-encoded value.
uint32_t indicator_value = 0;
if (UNLIKELY(!bit_reader_.GetUleb128<uint32_t>(&indicator_value))) {
return;
}
// lsb indicates if it is a literal run or repeated run
bool is_literal = indicator_value & 1;
// Don't try to handle run lengths that don't fit in an int32_t - just fail gracefully.
// The Parquet standard does not allow longer runs - see PARQUET-1290.
uint32_t run_len = indicator_value >> 1;
if (is_literal) {
// Use int64_t to avoid overflowing multiplication.
int64_t literal_count = static_cast<int64_t>(run_len) * 8;
if (UNLIKELY(literal_count > std::numeric_limits<int32_t>::max())) return;
literal_count_ = cast_set<int32_t>(literal_count);
} else {
if (UNLIKELY(run_len == 0)) return;
bool result = bit_reader_.GetBytes<T>(BitUtil::Ceil(bit_width_, 8), &repeated_value_);
if (UNLIKELY(!result)) return;
repeat_count_ = run_len;
}
}
template <typename T>
T RleBatchDecoder<T>::GetRepeatedValue(int32_t num_repeats_to_consume) {
repeat_count_ -= num_repeats_to_consume;
return repeated_value_;
}
template <typename T>
int32_t RleBatchDecoder<T>::NextNumLiterals() {
if (literal_count_ > 0) return literal_count_;
if (repeat_count_ == 0) NextCounts();
return literal_count_;
}
template <typename T>
bool RleBatchDecoder<T>::GetLiteralValues(int32_t num_literals_to_consume, T* values) {
int32_t num_consumed = 0;
// Copy any buffered literals left over from previous calls.
if (HaveBufferedLiterals()) {
num_consumed = OutputBufferedLiterals(num_literals_to_consume, values);
}
int32_t num_remaining = num_literals_to_consume - num_consumed;
// Copy literals directly to the output, bypassing 'literal_buffer_' when possible.
// Need to round to a batch of 32 if the caller is consuming only part of the current
// run avoid ending on a non-byte boundary.
int32_t num_to_bypass =
std::min<int32_t>(literal_count_, BitUtil::RoundDownToPowerOf2(num_remaining, 32));
if (num_to_bypass > 0) {
int num_read = bit_reader_.UnpackBatch(bit_width_, num_to_bypass, values + num_consumed);
// If we couldn't read the expected number, that means the input was truncated.
if (num_read < num_to_bypass) return false;
literal_count_ -= num_to_bypass;
num_consumed += num_to_bypass;
num_remaining = num_literals_to_consume - num_consumed;
}
if (num_remaining > 0) {
// We weren't able to copy all the literals requested directly from the input.
// Buffer literals and copy over the requested number.
if (UNLIKELY(!FillLiteralBuffer())) return false;
OutputBufferedLiterals(num_remaining, values + num_consumed);
}
return true;
}
template <typename T>
bool RleBatchDecoder<T>::FillLiteralBuffer() {
int32_t num_to_buffer = std::min<int32_t>(LITERAL_BUFFER_LEN, literal_count_);
num_buffered_literals_ = bit_reader_.UnpackBatch(bit_width_, num_to_buffer, literal_buffer_);
// If we couldn't read the expected number, that means the input was truncated.
if (UNLIKELY(num_buffered_literals_ < num_to_buffer)) return false;
literal_buffer_pos_ = 0;
return true;
}
template <typename T>
uint32_t RleBatchDecoder<T>::GetBatch(T* values, uint32_t batch_num) {
uint32_t num_consumed = 0;
while (num_consumed < batch_num) {
// Add RLE encoded values by repeating the current value this number of times.
uint32_t num_repeats = NextNumRepeats();
if (num_repeats > 0) {
int32_t num_repeats_to_set = std::min(num_repeats, batch_num - num_consumed);
T repeated_value = GetRepeatedValue(num_repeats_to_set);
for (int i = 0; i < num_repeats_to_set; ++i) {
values[num_consumed + i] = repeated_value;
}
num_consumed += num_repeats_to_set;
continue;
}
// Add remaining literal values, if any.
uint32_t num_literals = NextNumLiterals();
if (num_literals == 0) {
break;
}
uint32_t num_literals_to_set = std::min(num_literals, batch_num - num_consumed);
if (!GetLiteralValues(num_literals_to_set, values + num_consumed)) {
return 0;
}
num_consumed += num_literals_to_set;
}
return num_consumed;
}
#include "common/compile_check_end.h"
} // namespace doris