foundationdb/fdbclient/CommitTransaction.h

221 lines
8.4 KiB
C++

/*
* CommitTransaction.h
*
* This source file is part of the FoundationDB open source project
*
* Copyright 2013-2018 Apple Inc. and the FoundationDB project authors
*
* Licensed 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 FLOW_FDBCLIENT_COMMITTRANSACTION_H
#define FLOW_FDBCLIENT_COMMITTRANSACTION_H
#pragma once
#include "fdbclient/FDBTypes.h"
#include "fdbserver/Knobs.h"
// The versioned message has wire format : -1, version, messages
static const int32_t VERSION_HEADER = -1;
static const char* typeString[] = { "SetValue",
"ClearRange",
"AddValue",
"DebugKeyRange",
"DebugKey",
"NoOp",
"And",
"Or",
"Xor",
"AppendIfFits",
"AvailableForReuse",
"Reserved_For_LogProtocolMessage",
"Max",
"Min",
"SetVersionstampedKey",
"SetVersionstampedValue",
"ByteMin",
"ByteMax",
"MinV2",
"AndV2",
"CompareAndClear",
"Reserved_For_SpanContextMessage",
"MAX_ATOMIC_OP" };
struct MutationRef {
static const int OVERHEAD_BYTES = 12; // 12 is the size of Header in MutationList entries
enum Type : uint8_t {
SetValue = 0,
ClearRange,
AddValue,
DebugKeyRange,
DebugKey,
NoOp,
And,
Or,
Xor,
AppendIfFits,
AvailableForReuse,
Reserved_For_LogProtocolMessage /* See fdbserver/LogProtocolMessage.h */,
Max,
Min,
SetVersionstampedKey,
SetVersionstampedValue,
ByteMin,
ByteMax,
MinV2,
AndV2,
CompareAndClear,
Reserved_For_SpanContextMessage /* See fdbserver/SpanContextMessage.h */,
MAX_ATOMIC_OP
};
// This is stored this way for serialization purposes.
uint8_t type;
StringRef param1, param2;
MutationRef() {}
MutationRef(Type t, StringRef a, StringRef b) : type(t), param1(a), param2(b) {}
MutationRef(Arena& to, Type t, StringRef a, StringRef b) : type(t), param1(to, a), param2(to, b) {}
MutationRef(Arena& to, const MutationRef& from)
: type(from.type), param1(to, from.param1), param2(to, from.param2) {}
int totalSize() const { return OVERHEAD_BYTES + param1.size() + param2.size(); }
int expectedSize() const { return param1.size() + param2.size(); }
int weightedTotalSize() const {
// AtomicOp can cause more workload to FDB cluster than the same-size set mutation;
// Amplify atomicOp size to consider such extra workload.
// A good value for FASTRESTORE_ATOMICOP_WEIGHT needs experimental evaluations.
if (isAtomicOp()) {
return totalSize() * SERVER_KNOBS->FASTRESTORE_ATOMICOP_WEIGHT;
} else {
return totalSize();
}
}
std::string toString() const {
return format("code: %s param1: %s param2: %s",
type < MutationRef::MAX_ATOMIC_OP ? typeString[(int)type] : "Unset",
printable(param1).c_str(),
printable(param2).c_str());
}
bool isAtomicOp() const { return (ATOMIC_MASK & (1 << type)) != 0; }
template <class Ar>
void serialize(Ar& ar) {
if (ar.isSerializing && type == ClearRange && equalsKeyAfter(param1, param2)) {
StringRef empty;
serializer(ar, type, param2, empty);
} else {
serializer(ar, type, param1, param2);
}
if (ar.isDeserializing && type == ClearRange && param2 == StringRef() && param1 != StringRef()) {
ASSERT(param1[param1.size() - 1] == '\x00');
param2 = param1;
param1 = param2.substr(0, param2.size() - 1);
}
}
// These masks define which mutation types have particular properties (they are used to implement
// isSingleKeyMutation() etc)
enum {
ATOMIC_MASK = (1 << AddValue) | (1 << And) | (1 << Or) | (1 << Xor) | (1 << AppendIfFits) | (1 << Max) |
(1 << Min) | (1 << SetVersionstampedKey) | (1 << SetVersionstampedValue) | (1 << ByteMin) |
(1 << ByteMax) | (1 << MinV2) | (1 << AndV2) | (1 << CompareAndClear),
SINGLE_KEY_MASK = ATOMIC_MASK | (1 << SetValue),
NON_ASSOCIATIVE_MASK = (1 << AddValue) | (1 << Or) | (1 << Xor) | (1 << Max) | (1 << Min) |
(1 << SetVersionstampedKey) | (1 << SetVersionstampedValue) | (1 << MinV2) |
(1 << CompareAndClear)
};
};
template <>
struct Traceable<MutationRef> : std::true_type {
static std::string toString(MutationRef const& value) { return value.toString(); }
};
static inline std::string getTypeString(MutationRef::Type type) {
return type < MutationRef::MAX_ATOMIC_OP ? typeString[(int)type] : "Unset";
}
static inline std::string getTypeString(uint8_t type) {
return type < MutationRef::MAX_ATOMIC_OP ? typeString[type] : "Unset";
}
// A 'single key mutation' is one which affects exactly the value of the key specified by its param1
static inline bool isSingleKeyMutation(MutationRef::Type type) {
return (MutationRef::SINGLE_KEY_MASK & (1 << type)) != 0;
}
// Returns true if the given type can be safely cast to MutationRef::Type and used as a parameter to
// isSingleKeyMutation, isAtomicOp, etc. It does NOT mean that the type is a valid type of a MutationRef in any
// particular context.
static inline bool isValidMutationType(uint32_t type) {
return (type < MutationRef::MAX_ATOMIC_OP);
}
// An 'atomic operation' is a single key mutation which sets the key specified by its param1 to a
// nontrivial function of the previous value of the key and param2, and thus requires a
// read/modify/write to implement. (Basically a single key mutation other than a set)
static inline bool isAtomicOp(MutationRef::Type mutationType) {
return (MutationRef::ATOMIC_MASK & (1 << mutationType)) != 0;
}
// Returns true for operations which do not obey the associative law (i.e. a*(b*c) == (a*b)*c) in all cases
// unless a, b, and c have equal lengths, in which case even these operations are associative.
static inline bool isNonAssociativeOp(MutationRef::Type mutationType) {
return (MutationRef::NON_ASSOCIATIVE_MASK & (1 << mutationType)) != 0;
}
struct CommitTransactionRef {
CommitTransactionRef() : read_snapshot(0), report_conflicting_keys(false) {}
CommitTransactionRef(Arena& a, const CommitTransactionRef& from)
: read_conflict_ranges(a, from.read_conflict_ranges), write_conflict_ranges(a, from.write_conflict_ranges),
mutations(a, from.mutations), read_snapshot(from.read_snapshot),
report_conflicting_keys(from.report_conflicting_keys) {}
VectorRef<KeyRangeRef> read_conflict_ranges;
VectorRef<KeyRangeRef> write_conflict_ranges;
VectorRef<MutationRef> mutations;
Version read_snapshot;
bool report_conflicting_keys;
template <class Ar>
force_inline void serialize(Ar& ar) {
if constexpr (is_fb_function<Ar>) {
serializer(
ar, read_conflict_ranges, write_conflict_ranges, mutations, read_snapshot, report_conflicting_keys);
} else {
serializer(ar, read_conflict_ranges, write_conflict_ranges, mutations, read_snapshot);
if (ar.protocolVersion().hasReportConflictingKeys()) {
serializer(ar, report_conflicting_keys);
}
}
}
// Convenience for internal code required to manipulate these without the Native API
void set(Arena& arena, KeyRef const& key, ValueRef const& value) {
mutations.push_back_deep(arena, MutationRef(MutationRef::SetValue, key, value));
write_conflict_ranges.push_back(arena, singleKeyRange(key, arena));
}
void clear(Arena& arena, KeyRangeRef const& keys) {
mutations.push_back_deep(arena, MutationRef(MutationRef::ClearRange, keys.begin, keys.end));
write_conflict_ranges.push_back_deep(arena, keys);
}
size_t expectedSize() const {
return read_conflict_ranges.expectedSize() + write_conflict_ranges.expectedSize() + mutations.expectedSize();
}
};
#endif