blob: 70b9cde93427de607445aa52d7899ad896774b73 [file]
/*
* 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_DECODER_H
#define ENCODING_DECODER_H
#include "common/allocator/byte_stream.h"
#include "common/db_common.h"
namespace storage {
class Decoder {
public:
Decoder() {}
virtual ~Decoder() {}
virtual void reset() = 0;
virtual bool has_remaining(const common::ByteStream& buffer) = 0;
virtual int read_boolean(bool& ret_value, common::ByteStream& in) = 0;
virtual int read_int32(int32_t& ret_value, common::ByteStream& in) = 0;
virtual int read_int64(int64_t& ret_value, common::ByteStream& in) = 0;
virtual int read_float(float& ret_value, common::ByteStream& in) = 0;
virtual int read_double(double& ret_value, common::ByteStream& in) = 0;
virtual int read_String(common::String& ret_value, common::PageArena& pa,
common::ByteStream& in) = 0;
virtual int read_batch_int32(int32_t* out, int capacity, int& actual,
common::ByteStream& in) {
actual = 0;
int ret = common::E_OK;
int32_t val;
while (actual < capacity && has_remaining(in)) {
ret = read_int32(val, in);
if (ret != common::E_OK) {
return ret;
}
out[actual++] = val;
}
return common::E_OK;
}
virtual int read_batch_int64(int64_t* out, int capacity, int& actual,
common::ByteStream& in) {
actual = 0;
int ret = common::E_OK;
int64_t val;
while (actual < capacity && has_remaining(in)) {
ret = read_int64(val, in);
if (ret != common::E_OK) {
return ret;
}
out[actual++] = val;
}
return common::E_OK;
}
virtual int read_batch_float(float* out, int capacity, int& actual,
common::ByteStream& in) {
actual = 0;
int ret = common::E_OK;
float val;
while (actual < capacity && has_remaining(in)) {
ret = read_float(val, in);
if (ret != common::E_OK) {
return ret;
}
out[actual++] = val;
}
return common::E_OK;
}
virtual int read_batch_double(double* out, int capacity, int& actual,
common::ByteStream& in) {
actual = 0;
int ret = common::E_OK;
double val;
while (actual < capacity && has_remaining(in)) {
ret = read_double(val, in);
if (ret != common::E_OK) {
return ret;
}
out[actual++] = val;
}
return common::E_OK;
}
virtual int skip_int32(int count, int& skipped, common::ByteStream& in) {
skipped = 0;
int ret = common::E_OK;
int32_t dummy;
while (skipped < count && has_remaining(in)) {
ret = read_int32(dummy, in);
if (ret != common::E_OK) {
return ret;
}
++skipped;
}
return common::E_OK;
}
virtual int skip_int64(int count, int& skipped, common::ByteStream& in) {
skipped = 0;
int ret = common::E_OK;
int64_t dummy;
while (skipped < count && has_remaining(in)) {
ret = read_int64(dummy, in);
if (ret != common::E_OK) {
return ret;
}
++skipped;
}
return common::E_OK;
}
virtual int skip_float(int count, int& skipped, common::ByteStream& in) {
skipped = 0;
int ret = common::E_OK;
float dummy;
while (skipped < count && has_remaining(in)) {
ret = read_float(dummy, in);
if (ret != common::E_OK) {
return ret;
}
++skipped;
}
return common::E_OK;
}
virtual int skip_double(int count, int& skipped, common::ByteStream& in) {
skipped = 0;
int ret = common::E_OK;
double dummy;
while (skipped < count && has_remaining(in)) {
ret = read_double(dummy, in);
if (ret != common::E_OK) {
return ret;
}
++skipped;
}
return common::E_OK;
}
// Block-level filter pushdown for TS_2DIFF-encoded INT64 columns.
//
// TS_2DIFF stores values in self-contained "blocks": a header (value
// count + per-delta bit width), then a min-delta and a first value,
// then `count` bit-packed delta-of-deltas. A page may hold several
// sequential blocks; the boundary is set by the encoder's batch size.
// This call peeks the next block's header (without consuming the packed
// payload) and reports the block's value range [block_min, block_max]
// and `block_count` — the number of values the block covers (first value
// plus the packed deltas). The caller then either:
// - Call skip_peeked_block_int64() to skip the whole block when a
// filter excludes [block_min, block_max], or
// - Call read_batch_int64(), which reuses the peeked header.
//
// Implemented only for INT64 because it targets the time column, which is
// always INT64 and monotonically increasing. Monotonicity is what makes
// the range recoverable from the header alone (min = first value, max =
// the block's last timestamp, obtained by looking ahead to the next
// block's first value). Non-monotonic columns (INT32 / value columns)
// can't derive a range cheaply, so they fall back to this default and
// decode normally.
// Returns true if a block was peeked; false if not supported or no data.
virtual bool peek_next_block_range_int64(common::ByteStream& in,
int64_t& block_min,
int64_t& block_max,
int& block_count) {
return false;
}
// Skip the block whose header was already consumed by peek.
virtual int skip_peeked_block_int64(common::ByteStream& in, int& skipped) {
return common::E_NOT_SUPPORT;
}
};
} // end namespace storage
#endif // ENCODING_DECODER_H