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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.
*/
#ifndef ENCODING_TS2DIFF_ENCODER_H
#define ENCODING_TS2DIFF_ENCODER_H
#include <sys/types.h>
#include <cmath>
#include <limits>
#include <vector>
#include "common/allocator/alloc_base.h"
#include "common/allocator/byte_stream.h"
#include "encoder.h"
#ifdef ENABLE_SIMD
#include "simde/x86/avx2.h"
#endif
namespace storage {
template <typename T>
struct SIMDOps;
template <>
struct SIMDOps<int32_t> {
#ifdef ENABLE_SIMD
static void rebase(int32_t* arr, int32_t min_val, size_t size) {
const simde__m128i min_vec = simde_mm_set1_epi32(min_val);
size_t i = 0;
for (; i + 3 < size; i += 4) {
simde__m128i vec = simde_mm_loadu_si128(
reinterpret_cast<const simde__m128i*>(arr + i));
vec = simde_mm_sub_epi32(vec, min_vec);
simde_mm_storeu_si128(reinterpret_cast<simde__m128i*>(arr + i),
vec);
}
for (; i < size; ++i) {
arr[i] -= min_val;
}
}
#else
static void rebase(int32_t* arr, int32_t min_val, size_t size) {
for (size_t i = 0; i < size; ++i) {
arr[i] -= min_val;
}
}
#endif
};
template <>
struct SIMDOps<int64_t> {
#ifdef ENABLE_SIMD
static void rebase(int64_t* arr, int64_t min_val, size_t size) {
const simde__m256i min_vec = simde_mm256_set1_epi64x(min_val);
size_t i = 0;
for (; i + 3 < size; i += 4) {
simde__m256i vec = simde_mm256_loadu_si256(
reinterpret_cast<const simde__m256i*>(arr + i));
vec = simde_mm256_sub_epi64(vec, min_vec);
simde_mm256_storeu_si256(reinterpret_cast<simde__m256i*>(arr + i),
vec);
}
for (; i < size; ++i) {
arr[i] -= min_val;
}
}
#else
static void rebase(int64_t* arr, int64_t min_val, size_t size) {
for (size_t i = 0; i < size; ++i) {
arr[i] -= min_val;
}
}
#endif
};
template <typename T>
class TS2DIFFEncoder : public Encoder {
public:
TS2DIFFEncoder() { init(); }
~TS2DIFFEncoder() { destroy(); }
void reset() override { write_index_ = -1; }
void init() {
block_size_ = 128;
// block_size_ = 16;
delta_arr_ = (T*)common::mem_alloc(sizeof(T) * block_size_,
common::MOD_TS2DIFF_OBJ);
write_index_ = -1;
bits_left_ = 8;
buffer_ = 0;
delta_arr_min_ = 0;
delta_arr_max_ = 0;
first_value_ = 0;
previous_value_ = 0;
}
void destroy() override {
if (delta_arr_ != nullptr) {
common::mem_free(delta_arr_);
delta_arr_ = nullptr;
}
}
void write_bits(int64_t value, int bits, common::ByteStream& out_stream) {
while (bits > 0) {
int shift = bits - bits_left_;
if (shift >= 0) {
buffer_ |=
(uint8_t)((value >> shift) & ((1 << bits_left_) - 1));
bits -= bits_left_;
bits_left_ = 0;
} else {
shift = bits_left_ - bits;
buffer_ |= (uint8_t)(value << shift);
bits_left_ -= bits;
bits = 0;
}
flush_byte_if_full(out_stream);
}
}
void flush_remaining(common::ByteStream& out_stream) {
// FIXME bits_left_ != 0 does not means something to be flushed. (=8)
if (bits_left_ != 0 && bits_left_ != 8) {
bits_left_ = 0;
flush_byte_if_full(out_stream);
}
}
void flush_byte_if_full(common::ByteStream& out_stream) {
if (bits_left_ == 0) {
out_stream.write_buf(&buffer_, 1);
buffer_ = 0;
bits_left_ = 8;
}
}
void rebase_arr(int i) { delta_arr_[i] = delta_arr_[i] - delta_arr_min_; }
int cal_bit_width(T n) {
int bit_width = 0;
while (n > 0) {
bit_width++;
n >>= 1;
}
return bit_width;
}
// Batch bit-pack `count` values (each `bit_width` bits, MSB-first within
// byte) into a single contiguous buffer and write it to out_stream in one
// call. Avoids the per-byte write_buf overhead of the scalar write_bits
// loop.
//
// Result codes:
// E_OK → written successfully.
// -1 → caller must fall back to write_bits + flush_remaining because
// bit_width exceeds the safe accumulator width.
// any other non-zero value → real write_buf error; the caller must
// propagate it instead of treating the flush as successful.
template <typename U>
static int pack_bits_msb(const U* values, int count, int bit_width,
common::ByteStream& out_stream) {
if (count <= 0 || bit_width <= 0) return common::E_OK;
if (bit_width > 56) return -1; // fall back
size_t total_bytes = ((size_t)count * (size_t)bit_width + 7) / 8;
std::vector<uint8_t> buf(total_bytes, 0);
uint64_t accum = 0;
int bits_in_accum = 0;
size_t pos = 0;
const uint64_t mask = (1ULL << bit_width) - 1;
for (int i = 0; i < count; i++) {
uint64_t v = static_cast<uint64_t>(values[i]) & mask;
accum = (accum << bit_width) | v;
bits_in_accum += bit_width;
while (bits_in_accum >= 8) {
buf[pos++] = static_cast<uint8_t>(accum >> (bits_in_accum - 8));
bits_in_accum -= 8;
}
if (bits_in_accum > 0) {
accum &= ((1ULL << bits_in_accum) - 1);
} else {
accum = 0;
}
}
if (bits_in_accum > 0) {
buf[pos++] = static_cast<uint8_t>(accum << (8 - bits_in_accum));
}
// Surface write failures. Previously the return code was dropped on
// the floor and flush() returned E_OK, then reset() wiped the
// encoder state — the on-disk page ended up missing its delta block
// but the caller thought the data was safe.
return out_stream.write_buf(buf.data(), pos);
}
int do_encode(T value, common::ByteStream& out_stream);
int encode(bool value, common::ByteStream& out_stream) override;
int encode(int32_t value, common::ByteStream& out_stream) override;
int encode(int64_t value, common::ByteStream& out_stream) override;
int encode(float value, common::ByteStream& out_stream) override;
int encode(double value, common::ByteStream& out_stream) override;
int encode(common::String value, common::ByteStream& out_stream) override;
int encode_batch(const int32_t* values, uint32_t count,
common::ByteStream& out_stream) override;
int encode_batch(const int64_t* values, uint32_t count,
common::ByteStream& out_stream) override;
int flush(common::ByteStream& out_stream) override;
int get_max_byte_size() override {
// The meaning of 24 is: index(4)+width(4)+minDeltaBase(8)+firstValue(8)
return 24 + write_index_ * 8;
}
public:
int block_size_;
T* delta_arr_;
T first_value_;
T previous_value_;
T delta_arr_min_;
T delta_arr_max_;
uint8_t buffer_;
int bits_left_;
int write_index_;
};
template <typename T>
int TS2DIFFEncoder<T>::do_encode(T value, common::ByteStream& out_stream) {
if (write_index_ == -1) {
first_value_ = value;
previous_value_ = first_value_;
write_index_++;
return common::E_OK;
}
// Calculate the delta between the current value and the previous_value_
T delta = value - previous_value_;
previous_value_ = value;
if (write_index_ == 0) {
delta_arr_max_ = delta;
delta_arr_min_ = delta;
}
if (delta > delta_arr_max_) {
delta_arr_max_ = delta;
}
if (delta < delta_arr_min_) {
delta_arr_min_ = delta;
}
delta_arr_[write_index_] = delta;
write_index_++;
if (write_index_ >= block_size_) {
return flush(out_stream);
}
return common::E_OK;
}
template <>
inline int TS2DIFFEncoder<int32_t>::flush(common::ByteStream& out_stream) {
int ret = common::E_OK;
if (write_index_ == -1) {
return common::E_OK;
}
// Subtract the minimum value for each delta_arr_ item
SIMDOps<int32_t>::rebase(delta_arr_, delta_arr_min_, write_index_);
// Calculate the bit length of each value to writer
int bit_width = cal_bit_width(delta_arr_max_ - delta_arr_min_);
// Header writes can fail too (back-pressure / OOM on the underlying
// stream); a half-written header followed by reset() leaves the page
// corrupted but the caller thinking the data was flushed.
if (RET_FAIL(
common::SerializationUtil::write_ui32(write_index_, out_stream))) {
return ret;
}
if (RET_FAIL(
common::SerializationUtil::write_ui32(bit_width, out_stream))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_ui32(delta_arr_min_,
out_stream))) {
return ret;
}
if (RET_FAIL(
common::SerializationUtil::write_ui32(first_value_, out_stream))) {
return ret;
}
// writer data — batched bit-pack + single write_buf for the common case;
// fall back to per-bit path for the rare wide bit_width.
const int pack_ret =
pack_bits_msb(delta_arr_, write_index_, bit_width, out_stream);
if (pack_ret == -1) {
for (int i = 0; i < write_index_; i++) {
write_bits(delta_arr_[i], bit_width, out_stream);
}
flush_remaining(out_stream);
} else if (pack_ret != common::E_OK) {
// Real write failure — don't clear encoder state so the higher
// layer can detect the page is poisoned.
return pack_ret;
}
reset();
return ret;
}
template <>
inline int TS2DIFFEncoder<int64_t>::flush(common::ByteStream& out_stream) {
int ret = common::E_OK;
if (write_index_ == -1) {
return common::E_OK;
}
// Subtract the minimum value for each delta_arr_ item
SIMDOps<int64_t>::rebase(delta_arr_, delta_arr_min_, write_index_);
// Calculate the bit length of each value to writer
int bit_width = cal_bit_width(delta_arr_max_ - delta_arr_min_);
// Header writes can fail too — see int32 specialization for rationale.
if (RET_FAIL(
common::SerializationUtil::write_i32(write_index_, out_stream))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_i32(bit_width, out_stream))) {
return ret;
}
if (RET_FAIL(
common::SerializationUtil::write_i64(delta_arr_min_, out_stream))) {
return ret;
}
if (RET_FAIL(
common::SerializationUtil::write_i64(first_value_, out_stream))) {
return ret;
}
// writer data — batched bit-pack + single write_buf for the common case;
// fall back to per-bit path for the rare wide bit_width (>56).
const int pack_ret =
pack_bits_msb(delta_arr_, write_index_, bit_width, out_stream);
if (pack_ret == -1) {
for (int i = 0; i < write_index_; i++) {
write_bits(delta_arr_[i], bit_width, out_stream);
}
flush_remaining(out_stream);
} else if (pack_ret != common::E_OK) {
return pack_ret;
}
reset(); // 语义,writeIndex=-1;
return ret;
}
// ============================================================================
// Batch encode: INT32
// Adjacent-difference removes sequential dependency; SIMD for delta + min/max.
// ============================================================================
template <>
inline int TS2DIFFEncoder<int32_t>::encode_batch(
const int32_t* values, uint32_t count, common::ByteStream& out_stream) {
int ret = common::E_OK;
uint32_t offset = 0;
while (offset < count) {
// Start of new block: store first_value
if (write_index_ == -1) {
first_value_ = values[offset];
previous_value_ = first_value_;
write_index_ = 0;
offset++;
continue;
}
// How many deltas fit in current block
uint32_t space = static_cast<uint32_t>(block_size_) - write_index_;
uint32_t batch = std::min(count - offset, space);
// ── Adjacent difference: delta[i] = values[i] - values[i-1] ──
// First delta uses previous_value_
delta_arr_[write_index_] = values[offset] - previous_value_;
uint32_t i = 1;
#ifdef ENABLE_SIMD
// SIMD: 4 adjacent differences at a time
for (; i + 3 < batch; i += 4) {
simde__m128i cur = simde_mm_loadu_si128(
reinterpret_cast<const simde__m128i*>(values + offset + i));
simde__m128i prv = simde_mm_loadu_si128(
reinterpret_cast<const simde__m128i*>(values + offset + i - 1));
simde__m128i diff = simde_mm_sub_epi32(cur, prv);
simde_mm_storeu_si128(
reinterpret_cast<simde__m128i*>(delta_arr_ + write_index_ + i),
diff);
}
#endif
for (; i < batch; i++) {
delta_arr_[write_index_ + i] =
values[offset + i] - values[offset + i - 1];
}
previous_value_ = values[offset + batch - 1];
// ── Min/max of new deltas ──
int32_t local_min = delta_arr_[write_index_];
int32_t local_max = delta_arr_[write_index_];
uint32_t j = 1;
#ifdef ENABLE_SIMD
if (batch >= 5) {
simde__m128i vmin = simde_mm_set1_epi32(local_min);
simde__m128i vmax = vmin;
for (; j + 3 < batch; j += 4) {
simde__m128i v =
simde_mm_loadu_si128(reinterpret_cast<const simde__m128i*>(
delta_arr_ + write_index_ + j));
vmin = simde_mm_min_epi32(vmin, v);
vmax = simde_mm_max_epi32(vmax, v);
}
// Horizontal reduce
int32_t tmp[4];
simde_mm_storeu_si128(reinterpret_cast<simde__m128i*>(tmp), vmin);
for (int k = 0; k < 4; k++)
if (tmp[k] < local_min) local_min = tmp[k];
simde_mm_storeu_si128(reinterpret_cast<simde__m128i*>(tmp), vmax);
for (int k = 0; k < 4; k++)
if (tmp[k] > local_max) local_max = tmp[k];
}
#endif
for (; j < batch; j++) {
int32_t d = delta_arr_[write_index_ + j];
if (d < local_min) local_min = d;
if (d > local_max) local_max = d;
}
// Merge with block min/max
if (write_index_ == 0) {
delta_arr_min_ = local_min;
delta_arr_max_ = local_max;
} else {
if (local_min < delta_arr_min_) delta_arr_min_ = local_min;
if (local_max > delta_arr_max_) delta_arr_max_ = local_max;
}
write_index_ += batch;
offset += batch;
if (write_index_ >= block_size_) {
if (RET_FAIL(flush(out_stream))) return ret;
}
}
return ret;
}
// ============================================================================
// Batch encode: INT64
// ============================================================================
template <>
inline int TS2DIFFEncoder<int64_t>::encode_batch(
const int64_t* values, uint32_t count, common::ByteStream& out_stream) {
int ret = common::E_OK;
uint32_t offset = 0;
while (offset < count) {
if (write_index_ == -1) {
first_value_ = values[offset];
previous_value_ = first_value_;
write_index_ = 0;
offset++;
continue;
}
uint32_t space = static_cast<uint32_t>(block_size_) - write_index_;
uint32_t batch = std::min(count - offset, space);
// Adjacent difference
delta_arr_[write_index_] = values[offset] - previous_value_;
uint32_t i = 1;
#ifdef ENABLE_SIMD
// SIMD: 2 adjacent differences at a time (128-bit, native NEON)
for (; i + 1 < batch; i += 2) {
simde__m128i cur = simde_mm_loadu_si128(
reinterpret_cast<const simde__m128i*>(values + offset + i));
simde__m128i prv = simde_mm_loadu_si128(
reinterpret_cast<const simde__m128i*>(values + offset + i - 1));
simde__m128i diff = simde_mm_sub_epi64(cur, prv);
simde_mm_storeu_si128(
reinterpret_cast<simde__m128i*>(delta_arr_ + write_index_ + i),
diff);
}
#endif
for (; i < batch; i++) {
delta_arr_[write_index_ + i] =
values[offset + i] - values[offset + i - 1];
}
previous_value_ = values[offset + batch - 1];
// Min/max (scalar — no efficient 64-bit SIMD min/max before AVX-512)
int64_t local_min = delta_arr_[write_index_];
int64_t local_max = delta_arr_[write_index_];
for (uint32_t j = 1; j < batch; j++) {
int64_t d = delta_arr_[write_index_ + j];
if (d < local_min) local_min = d;
if (d > local_max) local_max = d;
}
if (write_index_ == 0) {
delta_arr_min_ = local_min;
delta_arr_max_ = local_max;
} else {
if (local_min < delta_arr_min_) delta_arr_min_ = local_min;
if (local_max > delta_arr_max_) delta_arr_max_ = local_max;
}
write_index_ += batch;
offset += batch;
if (write_index_ >= block_size_) {
if (RET_FAIL(flush(out_stream))) return ret;
}
}
return ret;
}
// Default: unsupported types fall back to base class loop
template <typename T>
int TS2DIFFEncoder<T>::encode_batch(const int32_t* values, uint32_t count,
common::ByteStream& out) {
return Encoder::encode_batch(values, count, out);
}
template <typename T>
int TS2DIFFEncoder<T>::encode_batch(const int64_t* values, uint32_t count,
common::ByteStream& out) {
return Encoder::encode_batch(values, count, out);
}
class FloatTS2DIFFEncoder : public TS2DIFFEncoder<int32_t> {
public:
FloatTS2DIFFEncoder() : max_point_number_(2), max_point_value_(100.0) {}
int do_encode(float value, common::ByteStream& out_stream) {
int32_t value_int = convert_float_to_int(value);
return TS2DIFFEncoder<int32_t>::do_encode(value_int, out_stream);
}
// PageWriter resets the encoder between pages without going through a
// successful flush() (e.g. when the prior page was aborted). The base
// reset() only clears write_index_; underflow_flags_ would otherwise
// leak the prior page's overflow markers into the next page's bitmap.
void reset() override {
TS2DIFFEncoder<int32_t>::reset();
underflow_flags_.clear();
}
int flush(common::ByteStream& out_stream) override;
int encode(bool value, common::ByteStream& out_stream);
int encode(int32_t value, common::ByteStream& out_stream);
int encode(int64_t value, common::ByteStream& out_stream);
int encode(float value, common::ByteStream& out_stream);
int encode(double value, common::ByteStream& out_stream);
private:
int32_t convert_float_to_int(float value) {
const double scaled = static_cast<double>(value) * max_point_value_;
if (scaled > static_cast<double>(std::numeric_limits<int32_t>::max()) ||
scaled < static_cast<double>(std::numeric_limits<int32_t>::min())) {
if (std::isnan(value) ||
value >
static_cast<float>(std::numeric_limits<int32_t>::max()) ||
value <
static_cast<float>(std::numeric_limits<int32_t>::min())) {
underflow_flags_.push_back(-1);
return common::float_to_int(value);
}
underflow_flags_.push_back(0);
return static_cast<int32_t>(std::lround(value));
}
if (std::isnan(value)) {
underflow_flags_.push_back(-1);
return common::float_to_int(value);
}
underflow_flags_.push_back(1);
return static_cast<int32_t>(std::lround(scaled));
}
bool has_overflow() const {
for (int8_t f : underflow_flags_) {
if (f != 1) {
return true;
}
}
return false;
}
private:
int max_point_number_;
double max_point_value_;
std::vector<int8_t> underflow_flags_;
};
class DoubleTS2DIFFEncoder : public TS2DIFFEncoder<int64_t> {
public:
DoubleTS2DIFFEncoder() : max_point_number_(2), max_point_value_(100.0) {}
int do_encode(double value, common::ByteStream& out_stream) {
int64_t value_long = convert_double_to_long(value);
return TS2DIFFEncoder<int64_t>::do_encode(value_long, out_stream);
}
// See FloatTS2DIFFEncoder::reset for rationale — the prior page's
// overflow markers must not bleed into the next.
void reset() override {
TS2DIFFEncoder<int64_t>::reset();
underflow_flags_.clear();
}
int flush(common::ByteStream& out_stream) override;
int encode(bool value, common::ByteStream& out_stream);
int encode(int32_t value, common::ByteStream& out_stream);
int encode(int64_t value, common::ByteStream& out_stream);
int encode(float value, common::ByteStream& out_stream);
int encode(double value, common::ByteStream& out_stream);
private:
int64_t convert_double_to_long(double value) {
const double scaled = value * max_point_value_;
if (scaled > static_cast<double>(std::numeric_limits<int64_t>::max()) ||
scaled < static_cast<double>(std::numeric_limits<int64_t>::min())) {
if (std::isnan(value) ||
value >
static_cast<double>(std::numeric_limits<int64_t>::max()) ||
value <
static_cast<double>(std::numeric_limits<int64_t>::min())) {
underflow_flags_.push_back(-1);
return common::double_to_long(value);
}
underflow_flags_.push_back(0);
return static_cast<int64_t>(std::llround(value));
}
if (std::isnan(value)) {
underflow_flags_.push_back(-1);
return common::double_to_long(value);
}
underflow_flags_.push_back(1);
return static_cast<int64_t>(std::llround(scaled));
}
bool has_overflow() const {
for (int8_t f : underflow_flags_) {
if (f != 1) {
return true;
}
}
return false;
}
private:
int max_point_number_;
double max_point_value_;
std::vector<int8_t> underflow_flags_;
};
typedef TS2DIFFEncoder<int32_t> IntTS2DIFFEncoder;
typedef TS2DIFFEncoder<int64_t> LongTS2DIFFEncoder;
// wrap as Encoder
template <>
FORCE_INLINE int IntTS2DIFFEncoder::encode(bool value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
template <>
FORCE_INLINE int IntTS2DIFFEncoder::encode(int32_t value,
common::ByteStream& out) {
return do_encode(value, out);
}
template <>
FORCE_INLINE int IntTS2DIFFEncoder::encode(int64_t value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
template <>
FORCE_INLINE int IntTS2DIFFEncoder::encode(float value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
template <>
FORCE_INLINE int IntTS2DIFFEncoder::encode(double value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
template <>
FORCE_INLINE int IntTS2DIFFEncoder::encode(common::String value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
template <>
FORCE_INLINE int LongTS2DIFFEncoder::encode(bool value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
template <>
FORCE_INLINE int LongTS2DIFFEncoder::encode(int32_t value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
template <>
FORCE_INLINE int LongTS2DIFFEncoder::encode(int64_t value,
common::ByteStream& out) {
return do_encode(value, out);
}
template <>
FORCE_INLINE int LongTS2DIFFEncoder::encode(float value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
template <>
FORCE_INLINE int LongTS2DIFFEncoder::encode(double value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
template <>
FORCE_INLINE int LongTS2DIFFEncoder::encode(common::String value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
FORCE_INLINE int FloatTS2DIFFEncoder::encode(bool value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
FORCE_INLINE int FloatTS2DIFFEncoder::encode(int32_t value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
FORCE_INLINE int FloatTS2DIFFEncoder::encode(int64_t value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
FORCE_INLINE int FloatTS2DIFFEncoder::encode(float value,
common::ByteStream& out) {
return do_encode(value, out);
}
FORCE_INLINE int FloatTS2DIFFEncoder::encode(double value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
FORCE_INLINE int DoubleTS2DIFFEncoder::encode(bool value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
FORCE_INLINE int DoubleTS2DIFFEncoder::encode(int32_t value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
FORCE_INLINE int DoubleTS2DIFFEncoder::encode(int64_t value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
FORCE_INLINE int DoubleTS2DIFFEncoder::encode(float value,
common::ByteStream& out) {
return common::E_TYPE_NOT_MATCH;
}
FORCE_INLINE int DoubleTS2DIFFEncoder::encode(double value,
common::ByteStream& out) {
return do_encode(value, out);
}
// Keep float/double TS_2DIFF page layout compatible with Java.
FORCE_INLINE int FloatTS2DIFFEncoder::flush(common::ByteStream& out_stream) {
int ret = common::E_OK;
if (write_index_ == -1) {
return common::E_OK;
}
const int num_values = write_index_ + 1;
common::ByteStream inner(1024, common::MOD_TS2DIFF_OBJ, false);
if (RET_FAIL(common::SerializationUtil::write_var_uint(
static_cast<uint32_t>(max_point_number_), inner))) {
return ret;
}
SIMDOps<int32_t>::rebase(delta_arr_, delta_arr_min_, write_index_);
int bit_width = cal_bit_width(delta_arr_max_ - delta_arr_min_);
if (RET_FAIL(common::SerializationUtil::write_ui32(
static_cast<uint32_t>(write_index_), inner))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_ui32(
static_cast<uint32_t>(bit_width), inner))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_ui32(
static_cast<uint32_t>(delta_arr_min_), inner))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_ui32(
static_cast<uint32_t>(first_value_), inner))) {
return ret;
}
for (int i = 0; i < write_index_; i++) {
write_bits(delta_arr_[i], bit_width, inner);
}
flush_remaining(inner);
const bool overflow = has_overflow();
if (overflow) {
std::vector<uint8_t> underflow_bitmap(
static_cast<size_t>(num_values / 8 + 1), 0);
std::vector<uint8_t> overflow_bitmap(
static_cast<size_t>(num_values / 8 + 1), 0);
bool has_original_value_overflow = false;
for (int i = 0; i < num_values; i++) {
int8_t f = underflow_flags_[static_cast<size_t>(i)];
if (f == 1) {
underflow_bitmap[static_cast<size_t>(i / 8)] |=
static_cast<uint8_t>(1u << (i % 8));
} else if (f == -1) {
has_original_value_overflow = true;
overflow_bitmap[static_cast<size_t>(i / 8)] |=
static_cast<uint8_t>(1u << (i % 8));
}
}
constexpr uint32_t FLAG_SCALED_VALUE_OVERFLOW =
2147483647u; // Integer.MAX_VALUE
constexpr uint32_t FLAG_ORIGINAL_VALUE_OVERFLOW =
2147483646u; // Integer.MAX_VALUE - 1
if (RET_FAIL(common::SerializationUtil::write_var_uint(
has_original_value_overflow ? FLAG_ORIGINAL_VALUE_OVERFLOW
: FLAG_SCALED_VALUE_OVERFLOW,
out_stream))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_var_uint(
static_cast<uint32_t>(num_values), out_stream))) {
return ret;
}
const uint32_t bm_len = static_cast<uint32_t>(num_values / 8 + 1);
if (RET_FAIL(out_stream.write_buf(underflow_bitmap.data(), bm_len))) {
return ret;
}
if (has_original_value_overflow &&
RET_FAIL(out_stream.write_buf(overflow_bitmap.data(), bm_len))) {
return ret;
}
}
if (RET_FAIL(merge_byte_stream(out_stream, inner, true))) {
return ret;
}
// Defer encoder-state wipe until after every write into out_stream has
// committed. An earlier reset() let a mid-flush failure leave
// write_index_ at -1, so the next flush() short-circuited at the top
// and the data was silently lost.
underflow_flags_.clear();
TS2DIFFEncoder<int32_t>::reset();
return ret;
}
FORCE_INLINE int DoubleTS2DIFFEncoder::flush(common::ByteStream& out_stream) {
int ret = common::E_OK;
if (write_index_ == -1) {
return common::E_OK;
}
const int num_values = write_index_ + 1;
common::ByteStream inner(1024, common::MOD_TS2DIFF_OBJ, false);
if (RET_FAIL(common::SerializationUtil::write_var_uint(
static_cast<uint32_t>(max_point_number_), inner))) {
return ret;
}
SIMDOps<int64_t>::rebase(delta_arr_, delta_arr_min_, write_index_);
int bit_width = cal_bit_width(delta_arr_max_ - delta_arr_min_);
if (RET_FAIL(common::SerializationUtil::write_i32(write_index_, inner))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_i32(bit_width, inner))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_i64(delta_arr_min_, inner))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_i64(first_value_, inner))) {
return ret;
}
for (int i = 0; i < write_index_; i++) {
write_bits(delta_arr_[i], bit_width, inner);
}
flush_remaining(inner);
const bool overflow = has_overflow();
if (overflow) {
std::vector<uint8_t> underflow_bitmap(
static_cast<size_t>(num_values / 8 + 1), 0);
std::vector<uint8_t> overflow_bitmap(
static_cast<size_t>(num_values / 8 + 1), 0);
bool has_original_value_overflow = false;
for (int i = 0; i < num_values; i++) {
int8_t f = underflow_flags_[static_cast<size_t>(i)];
if (f == 1) {
underflow_bitmap[static_cast<size_t>(i / 8)] |=
static_cast<uint8_t>(1u << (i % 8));
} else if (f == -1) {
has_original_value_overflow = true;
overflow_bitmap[static_cast<size_t>(i / 8)] |=
static_cast<uint8_t>(1u << (i % 8));
}
}
constexpr uint32_t FLAG_SCALED_VALUE_OVERFLOW =
2147483647u; // Integer.MAX_VALUE
constexpr uint32_t FLAG_ORIGINAL_VALUE_OVERFLOW =
2147483646u; // Integer.MAX_VALUE - 1
if (RET_FAIL(common::SerializationUtil::write_var_uint(
has_original_value_overflow ? FLAG_ORIGINAL_VALUE_OVERFLOW
: FLAG_SCALED_VALUE_OVERFLOW,
out_stream))) {
return ret;
}
if (RET_FAIL(common::SerializationUtil::write_var_uint(
static_cast<uint32_t>(num_values), out_stream))) {
return ret;
}
const uint32_t bm_len = static_cast<uint32_t>(num_values / 8 + 1);
if (RET_FAIL(out_stream.write_buf(underflow_bitmap.data(), bm_len))) {
return ret;
}
if (has_original_value_overflow &&
RET_FAIL(out_stream.write_buf(overflow_bitmap.data(), bm_len))) {
return ret;
}
}
if (RET_FAIL(merge_byte_stream(out_stream, inner, true))) {
return ret;
}
// Same deferred-reset rationale as FloatTS2DIFFEncoder::flush — keeping
// write_index_ live until every committed write succeeds avoids the
// "next flush returns E_OK on lost data" pattern.
underflow_flags_.clear();
TS2DIFFEncoder<int64_t>::reset();
return ret;
}
} // end namespace storage
#endif // ENCODING_TS2DIFF_ENCODER_H