SPIRV-Tools/source/opt/def_use_manager.h
Greg Fischer faa8d6a653
Revert "Optimize DefUseManager allocations (#4709)" (#4846)
This reverts commit d18d0d92e5.

This is reverted because it causes a 7X slowdown when legalizing
SPIR-V with NonSemantic.Shader.DebugInfo.100 instructions.
This is due to the creation of very large UseLists for several
heavily used operands for this extension combined with the fact
that the original commit changed the performance of Uselists to O(n).
2022-07-12 13:14:47 -06:00

253 lines
9.7 KiB
C++

// Copyright (c) 2016 Google Inc.
//
// 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 SOURCE_OPT_DEF_USE_MANAGER_H_
#define SOURCE_OPT_DEF_USE_MANAGER_H_
#include <set>
#include <unordered_map>
#include <vector>
#include "source/opt/instruction.h"
#include "source/opt/module.h"
#include "spirv-tools/libspirv.hpp"
namespace spvtools {
namespace opt {
namespace analysis {
// Class for representing a use of id. Note that:
// * Result type id is a use.
// * Ids referenced in OpSectionMerge & OpLoopMerge are considered as use.
// * Ids referenced in OpPhi's in operands are considered as use.
struct Use {
Instruction* inst; // Instruction using the id.
uint32_t operand_index; // logical operand index of the id use. This can be
// the index of result type id.
};
inline bool operator==(const Use& lhs, const Use& rhs) {
return lhs.inst == rhs.inst && lhs.operand_index == rhs.operand_index;
}
inline bool operator!=(const Use& lhs, const Use& rhs) { return !(lhs == rhs); }
inline bool operator<(const Use& lhs, const Use& rhs) {
if (lhs.inst < rhs.inst) return true;
if (lhs.inst > rhs.inst) return false;
return lhs.operand_index < rhs.operand_index;
}
// Definition should never be null. User can be null, however, such an entry
// should be used only for searching (e.g. all users of a particular definition)
// and never stored in a container.
struct UserEntry {
Instruction* def;
Instruction* user;
};
inline bool operator==(const UserEntry& lhs, const UserEntry& rhs) {
return lhs.def == rhs.def && lhs.user == rhs.user;
}
// Orders UserEntry for use in associative containers (i.e. less than ordering).
//
// The definition of an UserEntry is treated as the major key and the users as
// the minor key so that all the users of a particular definition are
// consecutive in a container.
//
// A null user always compares less than a real user. This is done to provide
// easy values to search for the beginning of the users of a particular
// definition (i.e. using {def, nullptr}).
struct UserEntryLess {
bool operator()(const UserEntry& lhs, const UserEntry& rhs) const {
// If lhs.def and rhs.def are both null, fall through to checking the
// second entries.
if (!lhs.def && rhs.def) return true;
if (lhs.def && !rhs.def) return false;
// If neither definition is null, then compare unique ids.
if (lhs.def && rhs.def) {
if (lhs.def->unique_id() < rhs.def->unique_id()) return true;
if (rhs.def->unique_id() < lhs.def->unique_id()) return false;
}
// Return false on equality.
if (!lhs.user && !rhs.user) return false;
if (!lhs.user) return true;
if (!rhs.user) return false;
// If neither user is null then compare unique ids.
return lhs.user->unique_id() < rhs.user->unique_id();
}
};
// A class for analyzing and managing defs and uses in an Module.
class DefUseManager {
public:
using IdToDefMap = std::unordered_map<uint32_t, Instruction*>;
// Constructs a def-use manager from the given |module|. All internal messages
// will be communicated to the outside via the given message |consumer|. This
// instance only keeps a reference to the |consumer|, so the |consumer| should
// outlive this instance.
DefUseManager(Module* module) { AnalyzeDefUse(module); }
DefUseManager(const DefUseManager&) = delete;
DefUseManager(DefUseManager&&) = delete;
DefUseManager& operator=(const DefUseManager&) = delete;
DefUseManager& operator=(DefUseManager&&) = delete;
// Analyzes the defs in the given |inst|.
void AnalyzeInstDef(Instruction* inst);
// Analyzes the uses in the given |inst|.
//
// All operands of |inst| must be analyzed as defs.
void AnalyzeInstUse(Instruction* inst);
// Analyzes the defs and uses in the given |inst|.
void AnalyzeInstDefUse(Instruction* inst);
// Returns the def instruction for the given |id|. If there is no instruction
// defining |id|, returns nullptr.
Instruction* GetDef(uint32_t id);
const Instruction* GetDef(uint32_t id) const;
// Runs the given function |f| on each unique user instruction of |def| (or
// |id|).
//
// If one instruction uses |def| in multiple operands, that instruction will
// only be visited once.
//
// |def| (or |id|) must be registered as a definition.
void ForEachUser(const Instruction* def,
const std::function<void(Instruction*)>& f) const;
void ForEachUser(uint32_t id,
const std::function<void(Instruction*)>& f) const;
// Runs the given function |f| on each unique user instruction of |def| (or
// |id|). If |f| returns false, iteration is terminated and this function
// returns false.
//
// If one instruction uses |def| in multiple operands, that instruction will
// be only be visited once.
//
// |def| (or |id|) must be registered as a definition.
bool WhileEachUser(const Instruction* def,
const std::function<bool(Instruction*)>& f) const;
bool WhileEachUser(uint32_t id,
const std::function<bool(Instruction*)>& f) const;
// Runs the given function |f| on each unique use of |def| (or
// |id|).
//
// If one instruction uses |def| in multiple operands, each operand will be
// visited separately.
//
// |def| (or |id|) must be registered as a definition.
void ForEachUse(
const Instruction* def,
const std::function<void(Instruction*, uint32_t operand_index)>& f) const;
void ForEachUse(
uint32_t id,
const std::function<void(Instruction*, uint32_t operand_index)>& f) const;
// Runs the given function |f| on each unique use of |def| (or
// |id|). If |f| returns false, iteration is terminated and this function
// returns false.
//
// If one instruction uses |def| in multiple operands, each operand will be
// visited separately.
//
// |def| (or |id|) must be registered as a definition.
bool WhileEachUse(
const Instruction* def,
const std::function<bool(Instruction*, uint32_t operand_index)>& f) const;
bool WhileEachUse(
uint32_t id,
const std::function<bool(Instruction*, uint32_t operand_index)>& f) const;
// Returns the number of users of |def| (or |id|).
uint32_t NumUsers(const Instruction* def) const;
uint32_t NumUsers(uint32_t id) const;
// Returns the number of uses of |def| (or |id|).
uint32_t NumUses(const Instruction* def) const;
uint32_t NumUses(uint32_t id) const;
// Returns the annotation instrunctions which are a direct use of the given
// |id|. This means when the decorations are applied through decoration
// group(s), this function will just return the OpGroupDecorate
// instruction(s) which refer to the given id as an operand. The OpDecorate
// instructions which decorate the decoration group will not be returned.
std::vector<Instruction*> GetAnnotations(uint32_t id) const;
// Returns the map from ids to their def instructions.
const IdToDefMap& id_to_defs() const { return id_to_def_; }
// Clear the internal def-use record of the given instruction |inst|. This
// method will update the use information of the operand ids of |inst|. The
// record: |inst| uses an |id|, will be removed from the use records of |id|.
// If |inst| defines an result id, the use record of this result id will also
// be removed. Does nothing if |inst| was not analyzed before.
void ClearInst(Instruction* inst);
// Erases the records that a given instruction uses its operand ids.
void EraseUseRecordsOfOperandIds(const Instruction* inst);
friend bool CompareAndPrintDifferences(const DefUseManager&,
const DefUseManager&);
// If |inst| has not already been analysed, then analyses its definition and
// uses.
void UpdateDefUse(Instruction* inst);
private:
using IdToUsersMap = std::set<UserEntry, UserEntryLess>;
using InstToUsedIdsMap =
std::unordered_map<const Instruction*, std::vector<uint32_t>>;
// Returns the first location that {|def|, nullptr} could be inserted into the
// users map without violating ordering.
IdToUsersMap::const_iterator UsersBegin(const Instruction* def) const;
// Returns true if |iter| has not reached the end of |def|'s users.
//
// In the first version |iter| is compared against the end of the map for
// validity before other checks. In the second version, |iter| is compared
// against |cached_end| for validity before other checks. This allows caching
// the map's end which is a performance improvement on some platforms.
bool UsersNotEnd(const IdToUsersMap::const_iterator& iter,
const Instruction* def) const;
bool UsersNotEnd(const IdToUsersMap::const_iterator& iter,
const IdToUsersMap::const_iterator& cached_end,
const Instruction* def) const;
// Analyzes the defs and uses in the given |module| and populates data
// structures in this class. Does nothing if |module| is nullptr.
void AnalyzeDefUse(Module* module);
IdToDefMap id_to_def_; // Mapping from ids to their definitions
IdToUsersMap id_to_users_; // Mapping from ids to their users
// Mapping from instructions to the ids used in the instruction.
InstToUsedIdsMap inst_to_used_ids_;
};
} // namespace analysis
} // namespace opt
} // namespace spvtools
#endif // SOURCE_OPT_DEF_USE_MANAGER_H_