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https://github.com/facebook/rocksdb.git
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ab13d43e1d
Summary: Calculate ```IOOptions::timeout``` using ```ReadOptions::deadline``` and pass it to ```FileSystem::Read/FileSystem::MultiRead```. This allows us to impose a tighter bound on the time taken by Get/MultiGet on FileSystem/Envs that support IO timeouts. Even on those that don't support, check in ```RandomAccessFileReader::Read``` and ```MultiRead``` and return ```Status::TimedOut()``` if the deadline is exceeded. For now, TableReader creation, which might do file opens and reads, are not covered. It will be implemented in another PR. Tests: Update existing unit tests to verify the correct timeout value is being passed Pull Request resolved: https://github.com/facebook/rocksdb/pull/6751 Reviewed By: riversand963 Differential Revision: D21285631 Pulled By: anand1976 fbshipit-source-id: d89af843e5a91ece866e87aa29438b52a65a8567
503 lines
18 KiB
C++
503 lines
18 KiB
C++
// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
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// This source code is licensed under both the GPLv2 (found in the
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// COPYING file in the root directory) and Apache 2.0 License
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// (found in the LICENSE.Apache file in the root directory).
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#ifndef ROCKSDB_LITE
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#include "table/plain/plain_table_key_coding.h"
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#include <algorithm>
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#include <string>
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#include "db/dbformat.h"
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#include "file/writable_file_writer.h"
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#include "table/plain/plain_table_factory.h"
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#include "table/plain/plain_table_reader.h"
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namespace ROCKSDB_NAMESPACE {
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enum PlainTableEntryType : unsigned char {
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kFullKey = 0,
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kPrefixFromPreviousKey = 1,
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kKeySuffix = 2,
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};
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namespace {
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// Control byte:
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// First two bits indicate type of entry
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// Other bytes are inlined sizes. If all bits are 1 (0x03F), overflow bytes
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// are used. key_size-0x3F will be encoded as a variint32 after this bytes.
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const unsigned char kSizeInlineLimit = 0x3F;
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// Return 0 for error
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size_t EncodeSize(PlainTableEntryType type, uint32_t key_size,
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char* out_buffer) {
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out_buffer[0] = type << 6;
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if (key_size < static_cast<uint32_t>(kSizeInlineLimit)) {
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// size inlined
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out_buffer[0] |= static_cast<char>(key_size);
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return 1;
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} else {
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out_buffer[0] |= kSizeInlineLimit;
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char* ptr = EncodeVarint32(out_buffer + 1, key_size - kSizeInlineLimit);
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return ptr - out_buffer;
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}
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}
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} // namespace
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// Fill bytes_read with number of bytes read.
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inline Status PlainTableKeyDecoder::DecodeSize(uint32_t start_offset,
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PlainTableEntryType* entry_type,
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uint32_t* key_size,
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uint32_t* bytes_read) {
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Slice next_byte_slice;
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bool success = file_reader_.Read(start_offset, 1, &next_byte_slice);
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if (!success) {
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return file_reader_.status();
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}
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*entry_type = static_cast<PlainTableEntryType>(
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(static_cast<unsigned char>(next_byte_slice[0]) & ~kSizeInlineLimit) >>
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6);
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char inline_key_size = next_byte_slice[0] & kSizeInlineLimit;
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if (inline_key_size < kSizeInlineLimit) {
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*key_size = inline_key_size;
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*bytes_read = 1;
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return Status::OK();
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} else {
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uint32_t extra_size;
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uint32_t tmp_bytes_read;
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success = file_reader_.ReadVarint32(start_offset + 1, &extra_size,
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&tmp_bytes_read);
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if (!success) {
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return file_reader_.status();
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}
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assert(tmp_bytes_read > 0);
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*key_size = kSizeInlineLimit + extra_size;
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*bytes_read = tmp_bytes_read + 1;
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return Status::OK();
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}
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}
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IOStatus PlainTableKeyEncoder::AppendKey(const Slice& key,
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WritableFileWriter* file,
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uint64_t* offset, char* meta_bytes_buf,
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size_t* meta_bytes_buf_size) {
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ParsedInternalKey parsed_key;
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if (!ParseInternalKey(key, &parsed_key)) {
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return IOStatus::Corruption(Slice());
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}
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Slice key_to_write = key; // Portion of internal key to write out.
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uint32_t user_key_size = static_cast<uint32_t>(key.size() - 8);
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if (encoding_type_ == kPlain) {
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if (fixed_user_key_len_ == kPlainTableVariableLength) {
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// Write key length
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char key_size_buf[5]; // tmp buffer for key size as varint32
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char* ptr = EncodeVarint32(key_size_buf, user_key_size);
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assert(ptr <= key_size_buf + sizeof(key_size_buf));
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auto len = ptr - key_size_buf;
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IOStatus io_s = file->Append(Slice(key_size_buf, len));
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if (!io_s.ok()) {
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return io_s;
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}
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*offset += len;
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}
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} else {
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assert(encoding_type_ == kPrefix);
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char size_bytes[12];
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size_t size_bytes_pos = 0;
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Slice prefix =
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prefix_extractor_->Transform(Slice(key.data(), user_key_size));
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if (key_count_for_prefix_ == 0 || prefix != pre_prefix_.GetUserKey() ||
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key_count_for_prefix_ % index_sparseness_ == 0) {
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key_count_for_prefix_ = 1;
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pre_prefix_.SetUserKey(prefix);
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size_bytes_pos += EncodeSize(kFullKey, user_key_size, size_bytes);
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IOStatus io_s = file->Append(Slice(size_bytes, size_bytes_pos));
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if (!io_s.ok()) {
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return io_s;
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}
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*offset += size_bytes_pos;
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} else {
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key_count_for_prefix_++;
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if (key_count_for_prefix_ == 2) {
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// For second key within a prefix, need to encode prefix length
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size_bytes_pos +=
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EncodeSize(kPrefixFromPreviousKey,
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static_cast<uint32_t>(pre_prefix_.GetUserKey().size()),
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size_bytes + size_bytes_pos);
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}
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uint32_t prefix_len =
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static_cast<uint32_t>(pre_prefix_.GetUserKey().size());
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size_bytes_pos += EncodeSize(kKeySuffix, user_key_size - prefix_len,
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size_bytes + size_bytes_pos);
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IOStatus io_s = file->Append(Slice(size_bytes, size_bytes_pos));
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if (!io_s.ok()) {
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return io_s;
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}
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*offset += size_bytes_pos;
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key_to_write = Slice(key.data() + prefix_len, key.size() - prefix_len);
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}
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}
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// Encode full key
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// For value size as varint32 (up to 5 bytes).
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// If the row is of value type with seqId 0, flush the special flag together
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// in this buffer to safe one file append call, which takes 1 byte.
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if (parsed_key.sequence == 0 && parsed_key.type == kTypeValue) {
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IOStatus io_s =
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file->Append(Slice(key_to_write.data(), key_to_write.size() - 8));
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if (!io_s.ok()) {
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return io_s;
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}
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*offset += key_to_write.size() - 8;
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meta_bytes_buf[*meta_bytes_buf_size] = PlainTableFactory::kValueTypeSeqId0;
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*meta_bytes_buf_size += 1;
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} else {
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IOStatus io_s = file->Append(key_to_write);
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if (!io_s.ok()) {
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return io_s;
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}
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*offset += key_to_write.size();
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}
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return IOStatus::OK();
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}
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Slice PlainTableFileReader::GetFromBuffer(Buffer* buffer, uint32_t file_offset,
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uint32_t len) {
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assert(file_offset + len <= file_info_->data_end_offset);
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return Slice(buffer->buf.get() + (file_offset - buffer->buf_start_offset),
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len);
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}
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bool PlainTableFileReader::ReadNonMmap(uint32_t file_offset, uint32_t len,
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Slice* out) {
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const uint32_t kPrefetchSize = 256u;
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// Try to read from buffers.
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for (uint32_t i = 0; i < num_buf_; i++) {
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Buffer* buffer = buffers_[num_buf_ - 1 - i].get();
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if (file_offset >= buffer->buf_start_offset &&
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file_offset + len <= buffer->buf_start_offset + buffer->buf_len) {
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*out = GetFromBuffer(buffer, file_offset, len);
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return true;
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}
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}
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Buffer* new_buffer;
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// Data needed is not in any of the buffer. Allocate a new buffer.
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if (num_buf_ < buffers_.size()) {
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// Add a new buffer
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new_buffer = new Buffer();
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buffers_[num_buf_++].reset(new_buffer);
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} else {
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// Now simply replace the last buffer. Can improve the placement policy
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// if needed.
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new_buffer = buffers_[num_buf_ - 1].get();
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}
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assert(file_offset + len <= file_info_->data_end_offset);
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uint32_t size_to_read = std::min(file_info_->data_end_offset - file_offset,
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std::max(kPrefetchSize, len));
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if (size_to_read > new_buffer->buf_capacity) {
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new_buffer->buf.reset(new char[size_to_read]);
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new_buffer->buf_capacity = size_to_read;
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new_buffer->buf_len = 0;
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}
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Slice read_result;
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Status s =
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file_info_->file->Read(IOOptions(), file_offset, size_to_read,
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&read_result, new_buffer->buf.get(), nullptr);
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if (!s.ok()) {
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status_ = s;
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return false;
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}
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new_buffer->buf_start_offset = file_offset;
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new_buffer->buf_len = size_to_read;
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*out = GetFromBuffer(new_buffer, file_offset, len);
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return true;
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}
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inline bool PlainTableFileReader::ReadVarint32(uint32_t offset, uint32_t* out,
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uint32_t* bytes_read) {
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if (file_info_->is_mmap_mode) {
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const char* start = file_info_->file_data.data() + offset;
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const char* limit =
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file_info_->file_data.data() + file_info_->data_end_offset;
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const char* key_ptr = GetVarint32Ptr(start, limit, out);
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assert(key_ptr != nullptr);
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*bytes_read = static_cast<uint32_t>(key_ptr - start);
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return true;
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} else {
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return ReadVarint32NonMmap(offset, out, bytes_read);
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}
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}
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bool PlainTableFileReader::ReadVarint32NonMmap(uint32_t offset, uint32_t* out,
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uint32_t* bytes_read) {
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const char* start;
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const char* limit;
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const uint32_t kMaxVarInt32Size = 6u;
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uint32_t bytes_to_read =
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std::min(file_info_->data_end_offset - offset, kMaxVarInt32Size);
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Slice bytes;
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if (!Read(offset, bytes_to_read, &bytes)) {
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return false;
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}
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start = bytes.data();
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limit = bytes.data() + bytes.size();
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const char* key_ptr = GetVarint32Ptr(start, limit, out);
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*bytes_read =
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(key_ptr != nullptr) ? static_cast<uint32_t>(key_ptr - start) : 0;
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return true;
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}
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Status PlainTableKeyDecoder::ReadInternalKey(
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uint32_t file_offset, uint32_t user_key_size, ParsedInternalKey* parsed_key,
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uint32_t* bytes_read, bool* internal_key_valid, Slice* internal_key) {
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Slice tmp_slice;
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bool success = file_reader_.Read(file_offset, user_key_size + 1, &tmp_slice);
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if (!success) {
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return file_reader_.status();
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}
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if (tmp_slice[user_key_size] == PlainTableFactory::kValueTypeSeqId0) {
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// Special encoding for the row with seqID=0
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parsed_key->user_key = Slice(tmp_slice.data(), user_key_size);
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parsed_key->sequence = 0;
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parsed_key->type = kTypeValue;
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*bytes_read += user_key_size + 1;
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*internal_key_valid = false;
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} else {
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success = file_reader_.Read(file_offset, user_key_size + 8, internal_key);
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if (!success) {
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return file_reader_.status();
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}
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*internal_key_valid = true;
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if (!ParseInternalKey(*internal_key, parsed_key)) {
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return Status::Corruption(
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Slice("Incorrect value type found when reading the next key"));
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}
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*bytes_read += user_key_size + 8;
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}
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return Status::OK();
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}
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Status PlainTableKeyDecoder::NextPlainEncodingKey(uint32_t start_offset,
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ParsedInternalKey* parsed_key,
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Slice* internal_key,
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uint32_t* bytes_read,
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bool* /*seekable*/) {
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uint32_t user_key_size = 0;
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Status s;
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if (fixed_user_key_len_ != kPlainTableVariableLength) {
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user_key_size = fixed_user_key_len_;
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} else {
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uint32_t tmp_size = 0;
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uint32_t tmp_read;
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bool success =
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file_reader_.ReadVarint32(start_offset, &tmp_size, &tmp_read);
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if (!success) {
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return file_reader_.status();
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}
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assert(tmp_read > 0);
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user_key_size = tmp_size;
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*bytes_read = tmp_read;
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}
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// dummy initial value to avoid compiler complain
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bool decoded_internal_key_valid = true;
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Slice decoded_internal_key;
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s = ReadInternalKey(start_offset + *bytes_read, user_key_size, parsed_key,
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bytes_read, &decoded_internal_key_valid,
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&decoded_internal_key);
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if (!s.ok()) {
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return s;
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}
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if (!file_reader_.file_info()->is_mmap_mode) {
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cur_key_.SetInternalKey(*parsed_key);
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parsed_key->user_key =
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Slice(cur_key_.GetInternalKey().data(), user_key_size);
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if (internal_key != nullptr) {
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*internal_key = cur_key_.GetInternalKey();
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}
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} else if (internal_key != nullptr) {
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if (decoded_internal_key_valid) {
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*internal_key = decoded_internal_key;
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} else {
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// Need to copy out the internal key
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cur_key_.SetInternalKey(*parsed_key);
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*internal_key = cur_key_.GetInternalKey();
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}
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}
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return Status::OK();
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}
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Status PlainTableKeyDecoder::NextPrefixEncodingKey(
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uint32_t start_offset, ParsedInternalKey* parsed_key, Slice* internal_key,
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uint32_t* bytes_read, bool* seekable) {
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PlainTableEntryType entry_type;
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bool expect_suffix = false;
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Status s;
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do {
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uint32_t size = 0;
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// dummy initial value to avoid compiler complain
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bool decoded_internal_key_valid = true;
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uint32_t my_bytes_read = 0;
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s = DecodeSize(start_offset + *bytes_read, &entry_type, &size,
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&my_bytes_read);
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if (!s.ok()) {
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return s;
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}
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if (my_bytes_read == 0) {
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return Status::Corruption("Unexpected EOF when reading size of the key");
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}
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*bytes_read += my_bytes_read;
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switch (entry_type) {
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case kFullKey: {
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expect_suffix = false;
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Slice decoded_internal_key;
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s = ReadInternalKey(start_offset + *bytes_read, size, parsed_key,
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bytes_read, &decoded_internal_key_valid,
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&decoded_internal_key);
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if (!s.ok()) {
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return s;
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}
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if (!file_reader_.file_info()->is_mmap_mode ||
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(internal_key != nullptr && !decoded_internal_key_valid)) {
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// In non-mmap mode, always need to make a copy of keys returned to
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// users, because after reading value for the key, the key might
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// be invalid.
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cur_key_.SetInternalKey(*parsed_key);
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saved_user_key_ = cur_key_.GetUserKey();
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if (!file_reader_.file_info()->is_mmap_mode) {
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parsed_key->user_key =
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Slice(cur_key_.GetInternalKey().data(), size);
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}
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if (internal_key != nullptr) {
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*internal_key = cur_key_.GetInternalKey();
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}
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} else {
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if (internal_key != nullptr) {
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*internal_key = decoded_internal_key;
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}
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saved_user_key_ = parsed_key->user_key;
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}
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break;
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}
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case kPrefixFromPreviousKey: {
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if (seekable != nullptr) {
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*seekable = false;
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}
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prefix_len_ = size;
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assert(prefix_extractor_ == nullptr ||
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prefix_extractor_->Transform(saved_user_key_).size() ==
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prefix_len_);
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// Need read another size flag for suffix
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expect_suffix = true;
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break;
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}
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case kKeySuffix: {
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expect_suffix = false;
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if (seekable != nullptr) {
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*seekable = false;
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}
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Slice tmp_slice;
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s = ReadInternalKey(start_offset + *bytes_read, size, parsed_key,
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bytes_read, &decoded_internal_key_valid,
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&tmp_slice);
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if (!s.ok()) {
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return s;
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}
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if (!file_reader_.file_info()->is_mmap_mode) {
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// In non-mmap mode, we need to make a copy of keys returned to
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// users, because after reading value for the key, the key might
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// be invalid.
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// saved_user_key_ points to cur_key_. We are making a copy of
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// the prefix part to another string, and construct the current
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// key from the prefix part and the suffix part back to cur_key_.
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std::string tmp =
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Slice(saved_user_key_.data(), prefix_len_).ToString();
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cur_key_.Reserve(prefix_len_ + size);
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cur_key_.SetInternalKey(tmp, *parsed_key);
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parsed_key->user_key =
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Slice(cur_key_.GetInternalKey().data(), prefix_len_ + size);
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saved_user_key_ = cur_key_.GetUserKey();
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} else {
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cur_key_.Reserve(prefix_len_ + size);
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cur_key_.SetInternalKey(Slice(saved_user_key_.data(), prefix_len_),
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*parsed_key);
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}
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parsed_key->user_key = cur_key_.GetUserKey();
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if (internal_key != nullptr) {
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*internal_key = cur_key_.GetInternalKey();
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}
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break;
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}
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default:
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return Status::Corruption("Un-identified size flag.");
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}
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} while (expect_suffix); // Another round if suffix is expected.
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return Status::OK();
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}
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Status PlainTableKeyDecoder::NextKey(uint32_t start_offset,
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ParsedInternalKey* parsed_key,
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Slice* internal_key, Slice* value,
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uint32_t* bytes_read, bool* seekable) {
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assert(value != nullptr);
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Status s = NextKeyNoValue(start_offset, parsed_key, internal_key, bytes_read,
|
|
seekable);
|
|
if (s.ok()) {
|
|
assert(bytes_read != nullptr);
|
|
uint32_t value_size;
|
|
uint32_t value_size_bytes;
|
|
bool success = file_reader_.ReadVarint32(start_offset + *bytes_read,
|
|
&value_size, &value_size_bytes);
|
|
if (!success) {
|
|
return file_reader_.status();
|
|
}
|
|
if (value_size_bytes == 0) {
|
|
return Status::Corruption(
|
|
"Unexpected EOF when reading the next value's size.");
|
|
}
|
|
*bytes_read += value_size_bytes;
|
|
success = file_reader_.Read(start_offset + *bytes_read, value_size, value);
|
|
if (!success) {
|
|
return file_reader_.status();
|
|
}
|
|
*bytes_read += value_size;
|
|
}
|
|
return s;
|
|
}
|
|
|
|
Status PlainTableKeyDecoder::NextKeyNoValue(uint32_t start_offset,
|
|
ParsedInternalKey* parsed_key,
|
|
Slice* internal_key,
|
|
uint32_t* bytes_read,
|
|
bool* seekable) {
|
|
*bytes_read = 0;
|
|
if (seekable != nullptr) {
|
|
*seekable = true;
|
|
}
|
|
Status s;
|
|
if (encoding_type_ == kPlain) {
|
|
return NextPlainEncodingKey(start_offset, parsed_key, internal_key,
|
|
bytes_read, seekable);
|
|
} else {
|
|
assert(encoding_type_ == kPrefix);
|
|
return NextPrefixEncodingKey(start_offset, parsed_key, internal_key,
|
|
bytes_read, seekable);
|
|
}
|
|
}
|
|
|
|
} // namespace ROCKSDB_NAMESPACE
|
|
#endif // ROCKSDB_LIT
|