third_party/llvm-16.0/llvm/lib/Target/SPIRV/SPIRVModuleAnalysis.h - SwiftShader - Git at Google

 //===- SPIRVModuleAnalysis.h - analysis of global instrs & regs -*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // The analysis collects instructions that should be output at the module level
 // and performs the global register numbering.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_LIB_TARGET_SPIRV_SPIRVMODULEANALYSIS_H
 #define LLVM_LIB_TARGET_SPIRV_SPIRVMODULEANALYSIS_H

 #include "MCTargetDesc/SPIRVBaseInfo.h"
 #include "SPIRVGlobalRegistry.h"
 #include "SPIRVUtils.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/SmallSet.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/StringMap.h"

 namespace llvm {
 class SPIRVSubtarget;
 class MachineFunction;
 class MachineModuleInfo;

 namespace SPIRV {
 // The enum contains logical module sections for the instruction collection.
 enum ModuleSectionType {
   //  MB_Capabilities, MB_Extensions, MB_ExtInstImports, MB_MemoryModel,
   MB_EntryPoints, // All OpEntryPoint instructions (if any).
   //  MB_ExecutionModes, MB_DebugSourceAndStrings,
   MB_DebugNames,           // All OpName and OpMemberName intrs.
   MB_DebugModuleProcessed, // All OpModuleProcessed instructions.
   MB_Annotations,          // OpDecorate, OpMemberDecorate etc.
   MB_TypeConstVars,        // OpTypeXXX, OpConstantXXX, and global OpVariables.
   MB_ExtFuncDecls,         // OpFunction etc. to declare for external funcs.
   NUM_MODULE_SECTIONS      // Total number of sections requiring basic blocks.
 };

 struct Requirements {
   const bool IsSatisfiable;
   const std::optional<Capability::Capability> Cap;
   const ExtensionList Exts;
   const unsigned MinVer; // 0 if no min version is required.
   const unsigned MaxVer; // 0 if no max version is required.

   Requirements(bool IsSatisfiable = false,
                std::optional<Capability::Capability> Cap = {},
                ExtensionList Exts = {}, unsigned MinVer = 0,
                unsigned MaxVer = 0)
       : IsSatisfiable(IsSatisfiable), Cap(Cap), Exts(Exts), MinVer(MinVer),
         MaxVer(MaxVer) {}
   Requirements(Capability::Capability Cap) : Requirements(true, {Cap}) {}
 };

 struct RequirementHandler {
 private:
   CapabilityList MinimalCaps;
   SmallSet<Capability::Capability, 8> AllCaps;
   SmallSet<Extension::Extension, 4> AllExtensions;
   unsigned MinVersion; // 0 if no min version is defined.
   unsigned MaxVersion; // 0 if no max version is defined.
   DenseSet<unsigned> AvailableCaps;
   // Remove a list of capabilities from dedupedCaps and add them to AllCaps,
   // recursing through their implicitly declared capabilities too.
   void pruneCapabilities(const CapabilityList &ToPrune);

 public:
   RequirementHandler() : MinVersion(0), MaxVersion(0) {}
   void clear() {
     MinimalCaps.clear();
     AllCaps.clear();
     AvailableCaps.clear();
     AllExtensions.clear();
     MinVersion = 0;
     MaxVersion = 0;
   }
   unsigned getMinVersion() const { return MinVersion; }
   unsigned getMaxVersion() const { return MaxVersion; }
   const CapabilityList &getMinimalCapabilities() const { return MinimalCaps; }
   const SmallSet<Extension::Extension, 4> &getExtensions() const {
     return AllExtensions;
   }
   // Add a list of capabilities, ensuring AllCaps captures all the implicitly
   // declared capabilities, and MinimalCaps has the minimal set of required
   // capabilities (so all implicitly declared ones are removed).
   void addCapabilities(const CapabilityList &ToAdd);
   void addCapability(Capability::Capability ToAdd) { addCapabilities({ToAdd}); }
   void addExtensions(const ExtensionList &ToAdd) {
     AllExtensions.insert(ToAdd.begin(), ToAdd.end());
   }
   void addExtension(Extension::Extension ToAdd) { AllExtensions.insert(ToAdd); }
   // Add the given requirements to the lists. If constraints conflict, or these
   // requirements cannot be satisfied, then abort the compilation.
   void addRequirements(const Requirements &Req);
   // Get requirement and add it to the list.
   void getAndAddRequirements(SPIRV::OperandCategory::OperandCategory Category,
                              uint32_t i, const SPIRVSubtarget &ST);
   // Check if all the requirements can be satisfied for the given subtarget, and
   // if not abort compilation.
   void checkSatisfiable(const SPIRVSubtarget &ST) const;
   void initAvailableCapabilities(const SPIRVSubtarget &ST);
   // Add the given capabilities to available and all their implicitly defined
   // capabilities too.
   void addAvailableCaps(const CapabilityList &ToAdd);
   bool isCapabilityAvailable(Capability::Capability Cap) const {
     return AvailableCaps.contains(Cap);
   }
 };

 using InstrList = SmallVector<MachineInstr *>;
 // Maps a local register to the corresponding global alias.
 using LocalToGlobalRegTable = std::map<Register, Register>;
 using RegisterAliasMapTy =
     std::map<const MachineFunction *, LocalToGlobalRegTable>;

 // The struct contains results of the module analysis and methods
 // to access them.
 struct ModuleAnalysisInfo {
   RequirementHandler Reqs;
   MemoryModel::MemoryModel Mem;
   AddressingModel::AddressingModel Addr;
   SourceLanguage::SourceLanguage SrcLang;
   unsigned SrcLangVersion;
   StringSet<> SrcExt;
   // Maps ExtInstSet to corresponding ID register.
   DenseMap<unsigned, Register> ExtInstSetMap;
   // Contains the list of all global OpVariables in the module.
   SmallVector<MachineInstr *, 4> GlobalVarList;
   // Maps functions to corresponding function ID registers.
   DenseMap<const Function *, Register> FuncMap;
   // The set contains machine instructions which are necessary
   // for correct MIR but will not be emitted in function bodies.
   DenseSet<MachineInstr *> InstrsToDelete;
   // The set contains machine basic blocks which are necessary
   // for correct MIR but will not be emitted.
   DenseSet<MachineBasicBlock *> MBBsToSkip;
   // The table contains global aliases of local registers for each machine
   // function. The aliases are used to substitute local registers during
   // code emission.
   RegisterAliasMapTy RegisterAliasTable;
   // The counter holds the maximum ID we have in the module.
   unsigned MaxID;
   // The array contains lists of MIs for each module section.
   InstrList MS[NUM_MODULE_SECTIONS];
   // The table maps MBB number to SPIR-V unique ID register.
   DenseMap<int, Register> BBNumToRegMap;

   Register getFuncReg(const Function *F) {
     assert(F && "Function is null");
     auto FuncPtrRegPair = FuncMap.find(F);
     assert(FuncPtrRegPair != FuncMap.end() && "Cannot find function ID");
     return FuncPtrRegPair->second;
   }
   Register getExtInstSetReg(unsigned SetNum) { return ExtInstSetMap[SetNum]; }
   InstrList &getMSInstrs(unsigned MSType) { return MS[MSType]; }
   void setSkipEmission(MachineInstr *MI) { InstrsToDelete.insert(MI); }
   bool getSkipEmission(const MachineInstr *MI) {
     return InstrsToDelete.contains(MI);
   }
   void setRegisterAlias(const MachineFunction *MF, Register Reg,
                         Register AliasReg) {
     RegisterAliasTable[MF][Reg] = AliasReg;
   }
   Register getRegisterAlias(const MachineFunction *MF, Register Reg) {
     auto RI = RegisterAliasTable[MF].find(Reg);
     if (RI == RegisterAliasTable[MF].end()) {
       return Register(0);
     }
     return RegisterAliasTable[MF][Reg];
   }
   bool hasRegisterAlias(const MachineFunction *MF, Register Reg) {
     return RegisterAliasTable.find(MF) != RegisterAliasTable.end() &&
            RegisterAliasTable[MF].find(Reg) != RegisterAliasTable[MF].end();
   }
   unsigned getNextID() { return MaxID++; }
   bool hasMBBRegister(const MachineBasicBlock &MBB) {
     return BBNumToRegMap.find(MBB.getNumber()) != BBNumToRegMap.end();
   }
   // Convert MBB's number to corresponding ID register.
   Register getOrCreateMBBRegister(const MachineBasicBlock &MBB) {
     auto f = BBNumToRegMap.find(MBB.getNumber());
     if (f != BBNumToRegMap.end())
       return f->second;
     Register NewReg = Register::index2VirtReg(getNextID());
     BBNumToRegMap[MBB.getNumber()] = NewReg;
     return NewReg;
   }
 };
 } // namespace SPIRV

 struct SPIRVModuleAnalysis : public ModulePass {
   static char ID;

 public:
   SPIRVModuleAnalysis() : ModulePass(ID) {}

   bool runOnModule(Module &M) override;
   void getAnalysisUsage(AnalysisUsage &AU) const override;
   static struct SPIRV::ModuleAnalysisInfo MAI;

 private:
   void setBaseInfo(const Module &M);
   void collectGlobalEntities(
       const std::vector<SPIRV::DTSortableEntry *> &DepsGraph,
       SPIRV::ModuleSectionType MSType,
       std::function<bool(const SPIRV::DTSortableEntry *)> Pred,
       bool UsePreOrder);
   void processDefInstrs(const Module &M);
   void collectFuncNames(MachineInstr &MI, const Function *F);
   void processOtherInstrs(const Module &M);
   void numberRegistersGlobally(const Module &M);

   const SPIRVSubtarget *ST;
   SPIRVGlobalRegistry *GR;
   const SPIRVInstrInfo *TII;
   MachineModuleInfo *MMI;
 };
 } // namespace llvm
 #endif // LLVM_LIB_TARGET_SPIRV_SPIRVMODULEANALYSIS_H
	//===- SPIRVModuleAnalysis.h - analysis of global instrs & regs -- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// The analysis collects instructions that should be output at the module level
	// and performs the global register numbering.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_LIB_TARGET_SPIRV_SPIRVMODULEANALYSIS_H
	#define LLVM_LIB_TARGET_SPIRV_SPIRVMODULEANALYSIS_H

	#include "MCTargetDesc/SPIRVBaseInfo.h"
	#include "SPIRVGlobalRegistry.h"
	#include "SPIRVUtils.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/SmallSet.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/StringMap.h"

	namespace llvm {
	class SPIRVSubtarget;
	class MachineFunction;
	class MachineModuleInfo;

	namespace SPIRV {
	// The enum contains logical module sections for the instruction collection.
	enum ModuleSectionType {
	// MB_Capabilities, MB_Extensions, MB_ExtInstImports, MB_MemoryModel,
	MB_EntryPoints, // All OpEntryPoint instructions (if any).
	// MB_ExecutionModes, MB_DebugSourceAndStrings,
	MB_DebugNames, // All OpName and OpMemberName intrs.
	MB_DebugModuleProcessed, // All OpModuleProcessed instructions.
	MB_Annotations, // OpDecorate, OpMemberDecorate etc.
	MB_TypeConstVars, // OpTypeXXX, OpConstantXXX, and global OpVariables.
	MB_ExtFuncDecls, // OpFunction etc. to declare for external funcs.
	NUM_MODULE_SECTIONS // Total number of sections requiring basic blocks.
	};

	struct Requirements {
	const bool IsSatisfiable;
	const std::optional<Capability::Capability> Cap;
	const ExtensionList Exts;
	const unsigned MinVer; // 0 if no min version is required.
	const unsigned MaxVer; // 0 if no max version is required.

	Requirements(bool IsSatisfiable = false,
	std::optional<Capability::Capability> Cap = {},
	ExtensionList Exts = {}, unsigned MinVer = 0,
	unsigned MaxVer = 0)
	: IsSatisfiable(IsSatisfiable), Cap(Cap), Exts(Exts), MinVer(MinVer),
	MaxVer(MaxVer) {}
	Requirements(Capability::Capability Cap) : Requirements(true, {Cap}) {}
	};

	struct RequirementHandler {
	private:
	CapabilityList MinimalCaps;
	SmallSet<Capability::Capability, 8> AllCaps;
	SmallSet<Extension::Extension, 4> AllExtensions;
	unsigned MinVersion; // 0 if no min version is defined.
	unsigned MaxVersion; // 0 if no max version is defined.
	DenseSet<unsigned> AvailableCaps;
	// Remove a list of capabilities from dedupedCaps and add them to AllCaps,
	// recursing through their implicitly declared capabilities too.
	void pruneCapabilities(const CapabilityList &ToPrune);

	public:
	RequirementHandler() : MinVersion(0), MaxVersion(0) {}
	void clear() {
	MinimalCaps.clear();
	AllCaps.clear();
	AvailableCaps.clear();
	AllExtensions.clear();
	MinVersion = 0;
	MaxVersion = 0;
	}
	unsigned getMinVersion() const { return MinVersion; }
	unsigned getMaxVersion() const { return MaxVersion; }
	const CapabilityList &getMinimalCapabilities() const { return MinimalCaps; }
	const SmallSet<Extension::Extension, 4> &getExtensions() const {
	return AllExtensions;
	}
	// Add a list of capabilities, ensuring AllCaps captures all the implicitly
	// declared capabilities, and MinimalCaps has the minimal set of required
	// capabilities (so all implicitly declared ones are removed).
	void addCapabilities(const CapabilityList &ToAdd);
	void addCapability(Capability::Capability ToAdd) { addCapabilities({ToAdd}); }
	void addExtensions(const ExtensionList &ToAdd) {
	AllExtensions.insert(ToAdd.begin(), ToAdd.end());
	}
	void addExtension(Extension::Extension ToAdd) { AllExtensions.insert(ToAdd); }
	// Add the given requirements to the lists. If constraints conflict, or these
	// requirements cannot be satisfied, then abort the compilation.
	void addRequirements(const Requirements &Req);
	// Get requirement and add it to the list.
	void getAndAddRequirements(SPIRV::OperandCategory::OperandCategory Category,
	uint32_t i, const SPIRVSubtarget &ST);
	// Check if all the requirements can be satisfied for the given subtarget, and
	// if not abort compilation.
	void checkSatisfiable(const SPIRVSubtarget &ST) const;
	void initAvailableCapabilities(const SPIRVSubtarget &ST);
	// Add the given capabilities to available and all their implicitly defined
	// capabilities too.
	void addAvailableCaps(const CapabilityList &ToAdd);
	bool isCapabilityAvailable(Capability::Capability Cap) const {
	return AvailableCaps.contains(Cap);
	}
	};

	using InstrList = SmallVector<MachineInstr *>;
	// Maps a local register to the corresponding global alias.
	using LocalToGlobalRegTable = std::map<Register, Register>;
	using RegisterAliasMapTy =
	std::map<const MachineFunction *, LocalToGlobalRegTable>;

	// The struct contains results of the module analysis and methods
	// to access them.
	struct ModuleAnalysisInfo {
	RequirementHandler Reqs;
	MemoryModel::MemoryModel Mem;
	AddressingModel::AddressingModel Addr;
	SourceLanguage::SourceLanguage SrcLang;
	unsigned SrcLangVersion;
	StringSet<> SrcExt;
	// Maps ExtInstSet to corresponding ID register.
	DenseMap<unsigned, Register> ExtInstSetMap;
	// Contains the list of all global OpVariables in the module.
	SmallVector<MachineInstr *, 4> GlobalVarList;
	// Maps functions to corresponding function ID registers.
	DenseMap<const Function *, Register> FuncMap;
	// The set contains machine instructions which are necessary
	// for correct MIR but will not be emitted in function bodies.
	DenseSet<MachineInstr *> InstrsToDelete;
	// The set contains machine basic blocks which are necessary
	// for correct MIR but will not be emitted.
	DenseSet<MachineBasicBlock *> MBBsToSkip;
	// The table contains global aliases of local registers for each machine
	// function. The aliases are used to substitute local registers during
	// code emission.
	RegisterAliasMapTy RegisterAliasTable;
	// The counter holds the maximum ID we have in the module.
	unsigned MaxID;
	// The array contains lists of MIs for each module section.
	InstrList MS[NUM_MODULE_SECTIONS];
	// The table maps MBB number to SPIR-V unique ID register.
	DenseMap<int, Register> BBNumToRegMap;

	Register getFuncReg(const Function *F) {
	assert(F && "Function is null");
	auto FuncPtrRegPair = FuncMap.find(F);
	assert(FuncPtrRegPair != FuncMap.end() && "Cannot find function ID");
	return FuncPtrRegPair->second;
	}
	Register getExtInstSetReg(unsigned SetNum) { return ExtInstSetMap[SetNum]; }
	InstrList &getMSInstrs(unsigned MSType) { return MS[MSType]; }
	void setSkipEmission(MachineInstr *MI) { InstrsToDelete.insert(MI); }
	bool getSkipEmission(const MachineInstr *MI) {
	return InstrsToDelete.contains(MI);
	}
	void setRegisterAlias(const MachineFunction *MF, Register Reg,
	Register AliasReg) {
	RegisterAliasTable[MF][Reg] = AliasReg;
	}
	Register getRegisterAlias(const MachineFunction *MF, Register Reg) {
	auto RI = RegisterAliasTable[MF].find(Reg);
	if (RI == RegisterAliasTable[MF].end()) {
	return Register(0);
	}
	return RegisterAliasTable[MF][Reg];
	}
	bool hasRegisterAlias(const MachineFunction *MF, Register Reg) {
	return RegisterAliasTable.find(MF) != RegisterAliasTable.end() &&
	RegisterAliasTable[MF].find(Reg) != RegisterAliasTable[MF].end();
	}
	unsigned getNextID() { return MaxID++; }
	bool hasMBBRegister(const MachineBasicBlock &MBB) {
	return BBNumToRegMap.find(MBB.getNumber()) != BBNumToRegMap.end();
	}
	// Convert MBB's number to corresponding ID register.
	Register getOrCreateMBBRegister(const MachineBasicBlock &MBB) {
	auto f = BBNumToRegMap.find(MBB.getNumber());
	if (f != BBNumToRegMap.end())
	return f->second;
	Register NewReg = Register::index2VirtReg(getNextID());
	BBNumToRegMap[MBB.getNumber()] = NewReg;
	return NewReg;
	}
	};
	} // namespace SPIRV

	struct SPIRVModuleAnalysis : public ModulePass {
	static char ID;

	public:
	SPIRVModuleAnalysis() : ModulePass(ID) {}

	bool runOnModule(Module &M) override;
	void getAnalysisUsage(AnalysisUsage &AU) const override;
	static struct SPIRV::ModuleAnalysisInfo MAI;

	private:
	void setBaseInfo(const Module &M);
	void collectGlobalEntities(
	const std::vector<SPIRV::DTSortableEntry *> &DepsGraph,
	SPIRV::ModuleSectionType MSType,
	std::function<bool(const SPIRV::DTSortableEntry *)> Pred,
	bool UsePreOrder);
	void processDefInstrs(const Module &M);
	void collectFuncNames(MachineInstr &MI, const Function *F);
	void processOtherInstrs(const Module &M);
	void numberRegistersGlobally(const Module &M);

	const SPIRVSubtarget *ST;
	SPIRVGlobalRegistry *GR;
	const SPIRVInstrInfo *TII;
	MachineModuleInfo *MMI;
	};
	} // namespace llvm
	#endif // LLVM_LIB_TARGET_SPIRV_SPIRVMODULEANALYSIS_H