1//===-- X86MachineFunctionInfo.h - X86 machine function info ----*- C++ -*-===//
2//
3// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4// See https://llvm.org/LICENSE.txt for license information.
5// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6//
7//===----------------------------------------------------------------------===//
8//
9// This file declares X86-specific per-machine-function information.
10//
11//===----------------------------------------------------------------------===//
12
13#ifndef LLVM_LIB_TARGET_X86_X86MACHINEFUNCTIONINFO_H
14#define LLVM_LIB_TARGET_X86_X86MACHINEFUNCTIONINFO_H
15
16#include "llvm/ADT/ArrayRef.h"
17#include "llvm/ADT/SmallVector.h"
18#include "llvm/CodeGen/CallingConvLower.h"
19#include "llvm/CodeGen/MIRYamlMapping.h"
20#include "llvm/CodeGen/MachineFunction.h"
21#include "llvm/Support/YAMLTraits.h"
22#include <set>
23
24namespace llvm {
25
26enum AMXProgModelEnum { None = 0, DirectReg = 1, ManagedRA = 2 };
27
28class X86MachineFunctionInfo;
29
30namespace yaml {
31template <> struct ScalarEnumerationTraits<AMXProgModelEnum> {
32 static void enumeration(IO &YamlIO, AMXProgModelEnum &Value) {
33 YamlIO.enumCase(Val&: Value, Str: "None", ConstVal: AMXProgModelEnum::None);
34 YamlIO.enumCase(Val&: Value, Str: "DirectReg", ConstVal: AMXProgModelEnum::DirectReg);
35 YamlIO.enumCase(Val&: Value, Str: "ManagedRA", ConstVal: AMXProgModelEnum::ManagedRA);
36 }
37};
38
39struct X86MachineFunctionInfo final : public yaml::MachineFunctionInfo {
40 AMXProgModelEnum AMXProgModel;
41
42 X86MachineFunctionInfo() = default;
43 X86MachineFunctionInfo(const llvm::X86MachineFunctionInfo &MFI);
44
45 void mappingImpl(yaml::IO &YamlIO) override;
46 ~X86MachineFunctionInfo() override = default;
47};
48
49template <> struct MappingTraits<X86MachineFunctionInfo> {
50 static void mapping(IO &YamlIO, X86MachineFunctionInfo &MFI) {
51 YamlIO.mapOptional(Key: "amxProgModel", Val&: MFI.AMXProgModel);
52 }
53};
54} // end namespace yaml
55
56/// X86MachineFunctionInfo - This class is derived from MachineFunction and
57/// contains private X86 target-specific information for each MachineFunction.
58class X86MachineFunctionInfo : public MachineFunctionInfo {
59 virtual void anchor();
60
61 /// ForceFramePointer - True if the function is required to use of frame
62 /// pointer for reasons other than it containing dynamic allocation or
63 /// that FP eliminatation is turned off. For example, Cygwin main function
64 /// contains stack pointer re-alignment code which requires FP.
65 bool ForceFramePointer = false;
66
67 /// RestoreBasePointerOffset - Non-zero if the function has base pointer
68 /// and makes call to llvm.eh.sjlj.setjmp. When non-zero, the value is a
69 /// displacement from the frame pointer to a slot where the base pointer
70 /// is stashed.
71 signed char RestoreBasePointerOffset = 0;
72
73 /// WinEHXMMSlotInfo - Slot information of XMM registers in the stack frame
74 /// in bytes.
75 DenseMap<int, unsigned> WinEHXMMSlotInfo;
76
77 /// CalleeSavedFrameSize - Size of the callee-saved register portion of the
78 /// stack frame in bytes.
79 unsigned CalleeSavedFrameSize = 0;
80
81 /// BytesToPopOnReturn - Number of bytes function pops on return (in addition
82 /// to the space used by the return address).
83 /// Used on windows platform for stdcall & fastcall name decoration
84 unsigned BytesToPopOnReturn = 0;
85
86 /// ReturnAddrIndex - FrameIndex for return slot.
87 int ReturnAddrIndex = 0;
88
89 /// FrameIndex for return slot.
90 int FrameAddrIndex = 0;
91
92 /// TailCallReturnAddrDelta - The number of bytes by which return address
93 /// stack slot is moved as the result of tail call optimization.
94 int TailCallReturnAddrDelta = 0;
95
96 /// SRetReturnReg - Some subtargets require that sret lowering includes
97 /// returning the value of the returned struct in a register. This field
98 /// holds the virtual register into which the sret argument is passed.
99 Register SRetReturnReg;
100
101 /// GlobalBaseReg - keeps track of the virtual register initialized for
102 /// use as the global base register. This is used for PIC in some PIC
103 /// relocation models.
104 Register GlobalBaseReg;
105
106 /// VarArgsFrameIndex - FrameIndex for start of varargs area.
107 int VarArgsFrameIndex = 0;
108 /// RegSaveFrameIndex - X86-64 vararg func register save area.
109 int RegSaveFrameIndex = 0;
110 /// VarArgsGPOffset - X86-64 vararg func int reg offset.
111 unsigned VarArgsGPOffset = 0;
112 /// VarArgsFPOffset - X86-64 vararg func fp reg offset.
113 unsigned VarArgsFPOffset = 0;
114 /// ArgumentStackSize - The number of bytes on stack consumed by the arguments
115 /// being passed on the stack.
116 unsigned ArgumentStackSize = 0;
117 /// NumLocalDynamics - Number of local-dynamic TLS accesses.
118 unsigned NumLocalDynamics = 0;
119 /// HasPushSequences - Keeps track of whether this function uses sequences
120 /// of pushes to pass function parameters.
121 bool HasPushSequences = false;
122
123 /// True if the function recovers from an SEH exception, and therefore needs
124 /// to spill and restore the frame pointer.
125 bool HasSEHFramePtrSave = false;
126
127 /// The frame index of a stack object containing the original frame pointer
128 /// used to address arguments in a function using a base pointer.
129 int SEHFramePtrSaveIndex = 0;
130
131 /// The AMX programing model used in the function.
132 AMXProgModelEnum AMXProgModel = AMXProgModelEnum::None;
133
134 /// True if this function has a subset of CSRs that is handled explicitly via
135 /// copies.
136 bool IsSplitCSR = false;
137
138 /// True if this function uses the red zone.
139 bool UsesRedZone = false;
140
141 /// True if this function has DYN_ALLOCA instructions.
142 bool HasDynAlloca = false;
143
144 /// True if this function has any preallocated calls.
145 bool HasPreallocatedCall = false;
146
147 /// Whether this function has an extended frame record [Ctx, RBP, Return
148 /// addr]. If so, bit 60 of the in-memory frame pointer will be 1 to enable
149 /// other tools to detect the extended record.
150 bool HasSwiftAsyncContext = false;
151
152 /// Candidate registers for push2/pop2
153 std::set<Register> CandidatesForPush2Pop2;
154
155 /// True if this function has CFI directives that adjust the CFA.
156 /// This is used to determine if we should direct the debugger to use
157 /// the CFA instead of the stack pointer.
158 bool HasCFIAdjustCfa = false;
159
160 MachineInstr *StackPtrSaveMI = nullptr;
161
162 std::optional<int> SwiftAsyncContextFrameIdx;
163
164 // Preallocated fields are only used during isel.
165 // FIXME: Can we find somewhere else to store these?
166 DenseMap<const Value *, size_t> PreallocatedIds;
167 SmallVector<size_t, 0> PreallocatedStackSizes;
168 SmallVector<SmallVector<size_t, 4>, 0> PreallocatedArgOffsets;
169
170 // True if a function clobbers FP/BP according to its calling convention.
171 bool FPClobberedByCall = false;
172 bool BPClobberedByCall = false;
173 bool FPClobberedByInvoke = false;
174 bool BPClobberedByInvoke = false;
175
176private:
177 /// ForwardedMustTailRegParms - A list of virtual and physical registers
178 /// that must be forwarded to every musttail call.
179 SmallVector<ForwardedRegister, 1> ForwardedMustTailRegParms;
180
181public:
182 X86MachineFunctionInfo() = default;
183 X86MachineFunctionInfo(const Function &F, const TargetSubtargetInfo *STI) {}
184
185 X86MachineFunctionInfo(const X86MachineFunctionInfo &) = default;
186
187 MachineFunctionInfo *
188 clone(BumpPtrAllocator &Allocator, MachineFunction &DestMF,
189 const DenseMap<MachineBasicBlock *, MachineBasicBlock *> &Src2DstMBB)
190 const override;
191
192 void initializeBaseYamlFields(const yaml::X86MachineFunctionInfo &YamlMFI);
193
194 bool getForceFramePointer() const { return ForceFramePointer;}
195 void setForceFramePointer(bool forceFP) { ForceFramePointer = forceFP; }
196
197 bool getHasPushSequences() const { return HasPushSequences; }
198 void setHasPushSequences(bool HasPush) { HasPushSequences = HasPush; }
199
200 bool getRestoreBasePointer() const { return RestoreBasePointerOffset!=0; }
201 void setRestoreBasePointer(const MachineFunction *MF);
202 void setRestoreBasePointer(unsigned CalleeSavedFrameSize) {
203 RestoreBasePointerOffset = -CalleeSavedFrameSize;
204 }
205 int getRestoreBasePointerOffset() const {return RestoreBasePointerOffset; }
206
207 DenseMap<int, unsigned>& getWinEHXMMSlotInfo() { return WinEHXMMSlotInfo; }
208 const DenseMap<int, unsigned>& getWinEHXMMSlotInfo() const {
209 return WinEHXMMSlotInfo; }
210
211 unsigned getCalleeSavedFrameSize() const { return CalleeSavedFrameSize; }
212 void setCalleeSavedFrameSize(unsigned bytes) { CalleeSavedFrameSize = bytes; }
213
214 unsigned getBytesToPopOnReturn() const { return BytesToPopOnReturn; }
215 void setBytesToPopOnReturn (unsigned bytes) { BytesToPopOnReturn = bytes;}
216
217 int getRAIndex() const { return ReturnAddrIndex; }
218 void setRAIndex(int Index) { ReturnAddrIndex = Index; }
219
220 int getFAIndex() const { return FrameAddrIndex; }
221 void setFAIndex(int Index) { FrameAddrIndex = Index; }
222
223 int getTCReturnAddrDelta() const { return TailCallReturnAddrDelta; }
224 void setTCReturnAddrDelta(int delta) {TailCallReturnAddrDelta = delta;}
225
226 Register getSRetReturnReg() const { return SRetReturnReg; }
227 void setSRetReturnReg(Register Reg) { SRetReturnReg = Reg; }
228
229 Register getGlobalBaseReg() const { return GlobalBaseReg; }
230 void setGlobalBaseReg(Register Reg) { GlobalBaseReg = Reg; }
231
232 int getVarArgsFrameIndex() const { return VarArgsFrameIndex; }
233 void setVarArgsFrameIndex(int Idx) { VarArgsFrameIndex = Idx; }
234
235 int getRegSaveFrameIndex() const { return RegSaveFrameIndex; }
236 void setRegSaveFrameIndex(int Idx) { RegSaveFrameIndex = Idx; }
237
238 unsigned getVarArgsGPOffset() const { return VarArgsGPOffset; }
239 void setVarArgsGPOffset(unsigned Offset) { VarArgsGPOffset = Offset; }
240
241 unsigned getVarArgsFPOffset() const { return VarArgsFPOffset; }
242 void setVarArgsFPOffset(unsigned Offset) { VarArgsFPOffset = Offset; }
243
244 unsigned getArgumentStackSize() const { return ArgumentStackSize; }
245 void setArgumentStackSize(unsigned size) { ArgumentStackSize = size; }
246
247 unsigned getNumLocalDynamicTLSAccesses() const { return NumLocalDynamics; }
248 void incNumLocalDynamicTLSAccesses() { ++NumLocalDynamics; }
249
250 bool getHasSEHFramePtrSave() const { return HasSEHFramePtrSave; }
251 void setHasSEHFramePtrSave(bool V) { HasSEHFramePtrSave = V; }
252
253 int getSEHFramePtrSaveIndex() const { return SEHFramePtrSaveIndex; }
254 void setSEHFramePtrSaveIndex(int Index) { SEHFramePtrSaveIndex = Index; }
255
256 AMXProgModelEnum getAMXProgModel() const { return AMXProgModel; }
257 void setAMXProgModel(AMXProgModelEnum Model) {
258 assert((AMXProgModel == AMXProgModelEnum::None || AMXProgModel == Model) &&
259 "mixed model is not supported");
260 AMXProgModel = Model;
261 }
262
263 SmallVectorImpl<ForwardedRegister> &getForwardedMustTailRegParms() {
264 return ForwardedMustTailRegParms;
265 }
266
267 bool isSplitCSR() const { return IsSplitCSR; }
268 void setIsSplitCSR(bool s) { IsSplitCSR = s; }
269
270 bool getUsesRedZone() const { return UsesRedZone; }
271 void setUsesRedZone(bool V) { UsesRedZone = V; }
272
273 bool hasDynAlloca() const { return HasDynAlloca; }
274 void setHasDynAlloca(bool v) { HasDynAlloca = v; }
275
276 bool hasPreallocatedCall() const { return HasPreallocatedCall; }
277 void setHasPreallocatedCall(bool v) { HasPreallocatedCall = v; }
278
279 bool hasSwiftAsyncContext() const { return HasSwiftAsyncContext; }
280 void setHasSwiftAsyncContext(bool v) { HasSwiftAsyncContext = v; }
281
282 bool isCandidateForPush2Pop2(Register Reg) const {
283 return CandidatesForPush2Pop2.find(x: Reg) != CandidatesForPush2Pop2.end();
284 }
285 void addCandidateForPush2Pop2(Register Reg) {
286 CandidatesForPush2Pop2.insert(x: Reg);
287 }
288 size_t getNumCandidatesForPush2Pop2() const {
289 return CandidatesForPush2Pop2.size();
290 }
291
292 bool hasCFIAdjustCfa() const { return HasCFIAdjustCfa; }
293 void setHasCFIAdjustCfa(bool v) { HasCFIAdjustCfa = v; }
294
295 void setStackPtrSaveMI(MachineInstr *MI) { StackPtrSaveMI = MI; }
296 MachineInstr *getStackPtrSaveMI() const { return StackPtrSaveMI; }
297
298 std::optional<int> getSwiftAsyncContextFrameIdx() const {
299 return SwiftAsyncContextFrameIdx;
300 }
301 void setSwiftAsyncContextFrameIdx(int v) { SwiftAsyncContextFrameIdx = v; }
302
303 size_t getPreallocatedIdForCallSite(const Value *CS) {
304 auto Insert = PreallocatedIds.insert(KV: {CS, PreallocatedIds.size()});
305 if (Insert.second) {
306 PreallocatedStackSizes.push_back(Elt: 0);
307 PreallocatedArgOffsets.emplace_back();
308 }
309 return Insert.first->second;
310 }
311
312 void setPreallocatedStackSize(size_t Id, size_t StackSize) {
313 PreallocatedStackSizes[Id] = StackSize;
314 }
315
316 size_t getPreallocatedStackSize(const size_t Id) {
317 assert(PreallocatedStackSizes[Id] != 0 && "stack size not set");
318 return PreallocatedStackSizes[Id];
319 }
320
321 void setPreallocatedArgOffsets(size_t Id, ArrayRef<size_t> AO) {
322 PreallocatedArgOffsets[Id].assign(in_start: AO.begin(), in_end: AO.end());
323 }
324
325 ArrayRef<size_t> getPreallocatedArgOffsets(const size_t Id) {
326 assert(!PreallocatedArgOffsets[Id].empty() && "arg offsets not set");
327 return PreallocatedArgOffsets[Id];
328 }
329
330 bool getFPClobberedByCall() const { return FPClobberedByCall; }
331 void setFPClobberedByCall(bool C) { FPClobberedByCall = C; }
332
333 bool getBPClobberedByCall() const { return BPClobberedByCall; }
334 void setBPClobberedByCall(bool C) { BPClobberedByCall = C; }
335
336 bool getFPClobberedByInvoke() const { return FPClobberedByInvoke; }
337 void setFPClobberedByInvoke(bool C) { FPClobberedByInvoke = C; }
338
339 bool getBPClobberedByInvoke() const { return BPClobberedByInvoke; }
340 void setBPClobberedByInvoke(bool C) { BPClobberedByInvoke = C; }
341};
342
343} // End llvm namespace
344
345#endif
346