1 //===-- PPCFrameLowering.cpp - PPC Frame Information ----------------------===//
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
7 //===----------------------------------------------------------------------===//
9 // This file contains the PPC implementation of TargetFrameLowering class.
11 //===----------------------------------------------------------------------===//
13 #include "PPCFrameLowering.h"
14 #include "PPCInstrBuilder.h"
15 #include "PPCInstrInfo.h"
16 #include "PPCMachineFunctionInfo.h"
17 #include "PPCSubtarget.h"
18 #include "PPCTargetMachine.h"
19 #include "llvm/ADT/Statistic.h"
20 #include "llvm/CodeGen/MachineFrameInfo.h"
21 #include "llvm/CodeGen/MachineFunction.h"
22 #include "llvm/CodeGen/MachineInstrBuilder.h"
23 #include "llvm/CodeGen/MachineModuleInfo.h"
24 #include "llvm/CodeGen/MachineRegisterInfo.h"
25 #include "llvm/CodeGen/RegisterScavenging.h"
26 #include "llvm/IR/Function.h"
27 #include "llvm/Target/TargetOptions.h"
31 #define DEBUG_TYPE "framelowering"
32 STATISTIC(NumPESpillVSR
, "Number of spills to vector in prologue");
33 STATISTIC(NumPEReloadVSR
, "Number of reloads from vector in epilogue");
36 EnablePEVectorSpills("ppc-enable-pe-vector-spills",
37 cl::desc("Enable spills in prologue to vector registers."),
38 cl::init(false), cl::Hidden
);
40 /// VRRegNo - Map from a numbered VR register to its enum value.
42 static const MCPhysReg VRRegNo
[] = {
43 PPC::V0
, PPC::V1
, PPC::V2
, PPC::V3
, PPC::V4
, PPC::V5
, PPC::V6
, PPC::V7
,
44 PPC::V8
, PPC::V9
, PPC::V10
, PPC::V11
, PPC::V12
, PPC::V13
, PPC::V14
, PPC::V15
,
45 PPC::V16
, PPC::V17
, PPC::V18
, PPC::V19
, PPC::V20
, PPC::V21
, PPC::V22
, PPC::V23
,
46 PPC::V24
, PPC::V25
, PPC::V26
, PPC::V27
, PPC::V28
, PPC::V29
, PPC::V30
, PPC::V31
49 static unsigned computeReturnSaveOffset(const PPCSubtarget
&STI
) {
50 if (STI
.isDarwinABI() || STI
.isAIXABI())
51 return STI
.isPPC64() ? 16 : 8;
53 return STI
.isPPC64() ? 16 : 4;
56 static unsigned computeTOCSaveOffset(const PPCSubtarget
&STI
) {
58 return STI
.isPPC64() ? 40 : 20;
59 return STI
.isELFv2ABI() ? 24 : 40;
62 static unsigned computeFramePointerSaveOffset(const PPCSubtarget
&STI
) {
63 // For the Darwin ABI:
64 // We cannot use the TOC save slot (offset +20) in the PowerPC linkage area
65 // for saving the frame pointer (if needed.) While the published ABI has
66 // not used this slot since at least MacOSX 10.2, there is older code
67 // around that does use it, and that needs to continue to work.
68 if (STI
.isDarwinABI())
69 return STI
.isPPC64() ? -8U : -4U;
71 // SVR4 ABI: First slot in the general register save area.
72 return STI
.isPPC64() ? -8U : -4U;
75 static unsigned computeLinkageSize(const PPCSubtarget
&STI
) {
76 if ((STI
.isDarwinABI() || STI
.isAIXABI()) || STI
.isPPC64())
77 return (STI
.isELFv2ABI() ? 4 : 6) * (STI
.isPPC64() ? 8 : 4);
83 static unsigned computeBasePointerSaveOffset(const PPCSubtarget
&STI
) {
84 if (STI
.isDarwinABI())
85 return STI
.isPPC64() ? -16U : -8U;
87 // SVR4 ABI: First slot in the general register save area.
90 : STI
.getTargetMachine().isPositionIndependent() ? -12U : -8U;
93 static unsigned computeCRSaveOffset() {
94 // The condition register save offset needs to be updated for AIX PPC32.
98 PPCFrameLowering::PPCFrameLowering(const PPCSubtarget
&STI
)
99 : TargetFrameLowering(TargetFrameLowering::StackGrowsDown
,
100 STI
.getPlatformStackAlignment(), 0),
101 Subtarget(STI
), ReturnSaveOffset(computeReturnSaveOffset(Subtarget
)),
102 TOCSaveOffset(computeTOCSaveOffset(Subtarget
)),
103 FramePointerSaveOffset(computeFramePointerSaveOffset(Subtarget
)),
104 LinkageSize(computeLinkageSize(Subtarget
)),
105 BasePointerSaveOffset(computeBasePointerSaveOffset(Subtarget
)),
106 CRSaveOffset(computeCRSaveOffset()) {}
108 // With the SVR4 ABI, callee-saved registers have fixed offsets on the stack.
109 const PPCFrameLowering::SpillSlot
*PPCFrameLowering::getCalleeSavedSpillSlots(
110 unsigned &NumEntries
) const {
111 if (Subtarget
.isDarwinABI()) {
113 if (Subtarget
.isPPC64()) {
114 static const SpillSlot darwin64Offsets
= {PPC::X31
, -8};
115 return &darwin64Offsets
;
117 static const SpillSlot darwinOffsets
= {PPC::R31
, -4};
118 return &darwinOffsets
;
122 // Early exit if not using the SVR4 ABI.
123 if (!Subtarget
.isSVR4ABI()) {
128 // Note that the offsets here overlap, but this is fixed up in
129 // processFunctionBeforeFrameFinalized.
131 static const SpillSlot Offsets
[] = {
132 // Floating-point register save area offsets.
152 // General register save area offsets.
172 // CR save area offset. We map each of the nonvolatile CR fields
173 // to the slot for CR2, which is the first of the nonvolatile CR
174 // fields to be assigned, so that we only allocate one save slot.
175 // See PPCRegisterInfo::hasReservedSpillSlot() for more information.
178 // VRSAVE save area offset.
181 // Vector register save area
195 // SPE register save area (overlaps Vector save area).
215 static const SpillSlot Offsets64
[] = {
216 // Floating-point register save area offsets.
236 // General register save area offsets.
256 // VRSAVE save area offset.
259 // Vector register save area
273 if (Subtarget
.isPPC64()) {
274 NumEntries
= array_lengthof(Offsets64
);
278 NumEntries
= array_lengthof(Offsets
);
284 /// RemoveVRSaveCode - We have found that this function does not need any code
285 /// to manipulate the VRSAVE register, even though it uses vector registers.
286 /// This can happen when the only registers used are known to be live in or out
287 /// of the function. Remove all of the VRSAVE related code from the function.
288 /// FIXME: The removal of the code results in a compile failure at -O0 when the
289 /// function contains a function call, as the GPR containing original VRSAVE
290 /// contents is spilled and reloaded around the call. Without the prolog code,
291 /// the spill instruction refers to an undefined register. This code needs
292 /// to account for all uses of that GPR.
293 static void RemoveVRSaveCode(MachineInstr
&MI
) {
294 MachineBasicBlock
*Entry
= MI
.getParent();
295 MachineFunction
*MF
= Entry
->getParent();
297 // We know that the MTVRSAVE instruction immediately follows MI. Remove it.
298 MachineBasicBlock::iterator MBBI
= MI
;
300 assert(MBBI
!= Entry
->end() && MBBI
->getOpcode() == PPC::MTVRSAVE
);
301 MBBI
->eraseFromParent();
303 bool RemovedAllMTVRSAVEs
= true;
304 // See if we can find and remove the MTVRSAVE instruction from all of the
306 for (MachineFunction::iterator I
= MF
->begin(), E
= MF
->end(); I
!= E
; ++I
) {
307 // If last instruction is a return instruction, add an epilogue
308 if (I
->isReturnBlock()) {
309 bool FoundIt
= false;
310 for (MBBI
= I
->end(); MBBI
!= I
->begin(); ) {
312 if (MBBI
->getOpcode() == PPC::MTVRSAVE
) {
313 MBBI
->eraseFromParent(); // remove it.
318 RemovedAllMTVRSAVEs
&= FoundIt
;
322 // If we found and removed all MTVRSAVE instructions, remove the read of
324 if (RemovedAllMTVRSAVEs
) {
326 assert(MBBI
!= Entry
->begin() && "UPDATE_VRSAVE is first instr in block?");
328 assert(MBBI
->getOpcode() == PPC::MFVRSAVE
&& "VRSAVE instrs wandered?");
329 MBBI
->eraseFromParent();
332 // Finally, nuke the UPDATE_VRSAVE.
333 MI
.eraseFromParent();
336 // HandleVRSaveUpdate - MI is the UPDATE_VRSAVE instruction introduced by the
337 // instruction selector. Based on the vector registers that have been used,
338 // transform this into the appropriate ORI instruction.
339 static void HandleVRSaveUpdate(MachineInstr
&MI
, const TargetInstrInfo
&TII
) {
340 MachineFunction
*MF
= MI
.getParent()->getParent();
341 const TargetRegisterInfo
*TRI
= MF
->getSubtarget().getRegisterInfo();
342 DebugLoc dl
= MI
.getDebugLoc();
344 const MachineRegisterInfo
&MRI
= MF
->getRegInfo();
345 unsigned UsedRegMask
= 0;
346 for (unsigned i
= 0; i
!= 32; ++i
)
347 if (MRI
.isPhysRegModified(VRRegNo
[i
]))
348 UsedRegMask
|= 1 << (31-i
);
350 // Live in and live out values already must be in the mask, so don't bother
352 for (std::pair
<unsigned, unsigned> LI
: MF
->getRegInfo().liveins()) {
353 unsigned RegNo
= TRI
->getEncodingValue(LI
.first
);
354 if (VRRegNo
[RegNo
] == LI
.first
) // If this really is a vector reg.
355 UsedRegMask
&= ~(1 << (31-RegNo
)); // Doesn't need to be marked.
358 // Live out registers appear as use operands on return instructions.
359 for (MachineFunction::const_iterator BI
= MF
->begin(), BE
= MF
->end();
360 UsedRegMask
!= 0 && BI
!= BE
; ++BI
) {
361 const MachineBasicBlock
&MBB
= *BI
;
362 if (!MBB
.isReturnBlock())
364 const MachineInstr
&Ret
= MBB
.back();
365 for (unsigned I
= 0, E
= Ret
.getNumOperands(); I
!= E
; ++I
) {
366 const MachineOperand
&MO
= Ret
.getOperand(I
);
367 if (!MO
.isReg() || !PPC::VRRCRegClass
.contains(MO
.getReg()))
369 unsigned RegNo
= TRI
->getEncodingValue(MO
.getReg());
370 UsedRegMask
&= ~(1 << (31-RegNo
));
374 // If no registers are used, turn this into a copy.
375 if (UsedRegMask
== 0) {
376 // Remove all VRSAVE code.
377 RemoveVRSaveCode(MI
);
381 Register SrcReg
= MI
.getOperand(1).getReg();
382 Register DstReg
= MI
.getOperand(0).getReg();
384 if ((UsedRegMask
& 0xFFFF) == UsedRegMask
) {
385 if (DstReg
!= SrcReg
)
386 BuildMI(*MI
.getParent(), MI
, dl
, TII
.get(PPC::ORI
), DstReg
)
388 .addImm(UsedRegMask
);
390 BuildMI(*MI
.getParent(), MI
, dl
, TII
.get(PPC::ORI
), DstReg
)
391 .addReg(SrcReg
, RegState::Kill
)
392 .addImm(UsedRegMask
);
393 } else if ((UsedRegMask
& 0xFFFF0000) == UsedRegMask
) {
394 if (DstReg
!= SrcReg
)
395 BuildMI(*MI
.getParent(), MI
, dl
, TII
.get(PPC::ORIS
), DstReg
)
397 .addImm(UsedRegMask
>> 16);
399 BuildMI(*MI
.getParent(), MI
, dl
, TII
.get(PPC::ORIS
), DstReg
)
400 .addReg(SrcReg
, RegState::Kill
)
401 .addImm(UsedRegMask
>> 16);
403 if (DstReg
!= SrcReg
)
404 BuildMI(*MI
.getParent(), MI
, dl
, TII
.get(PPC::ORIS
), DstReg
)
406 .addImm(UsedRegMask
>> 16);
408 BuildMI(*MI
.getParent(), MI
, dl
, TII
.get(PPC::ORIS
), DstReg
)
409 .addReg(SrcReg
, RegState::Kill
)
410 .addImm(UsedRegMask
>> 16);
412 BuildMI(*MI
.getParent(), MI
, dl
, TII
.get(PPC::ORI
), DstReg
)
413 .addReg(DstReg
, RegState::Kill
)
414 .addImm(UsedRegMask
& 0xFFFF);
417 // Remove the old UPDATE_VRSAVE instruction.
418 MI
.eraseFromParent();
421 static bool spillsCR(const MachineFunction
&MF
) {
422 const PPCFunctionInfo
*FuncInfo
= MF
.getInfo
<PPCFunctionInfo
>();
423 return FuncInfo
->isCRSpilled();
426 static bool spillsVRSAVE(const MachineFunction
&MF
) {
427 const PPCFunctionInfo
*FuncInfo
= MF
.getInfo
<PPCFunctionInfo
>();
428 return FuncInfo
->isVRSAVESpilled();
431 static bool hasSpills(const MachineFunction
&MF
) {
432 const PPCFunctionInfo
*FuncInfo
= MF
.getInfo
<PPCFunctionInfo
>();
433 return FuncInfo
->hasSpills();
436 static bool hasNonRISpills(const MachineFunction
&MF
) {
437 const PPCFunctionInfo
*FuncInfo
= MF
.getInfo
<PPCFunctionInfo
>();
438 return FuncInfo
->hasNonRISpills();
441 /// MustSaveLR - Return true if this function requires that we save the LR
442 /// register onto the stack in the prolog and restore it in the epilog of the
444 static bool MustSaveLR(const MachineFunction
&MF
, unsigned LR
) {
445 const PPCFunctionInfo
*MFI
= MF
.getInfo
<PPCFunctionInfo
>();
447 // We need a save/restore of LR if there is any def of LR (which is
448 // defined by calls, including the PIC setup sequence), or if there is
449 // some use of the LR stack slot (e.g. for builtin_return_address).
450 // (LR comes in 32 and 64 bit versions.)
451 MachineRegisterInfo::def_iterator RI
= MF
.getRegInfo().def_begin(LR
);
452 return RI
!=MF
.getRegInfo().def_end() || MFI
->isLRStoreRequired();
455 /// determineFrameLayoutAndUpdate - Determine the size of the frame and maximum
456 /// call frame size. Update the MachineFunction object with the stack size.
458 PPCFrameLowering::determineFrameLayoutAndUpdate(MachineFunction
&MF
,
459 bool UseEstimate
) const {
460 unsigned NewMaxCallFrameSize
= 0;
461 unsigned FrameSize
= determineFrameLayout(MF
, UseEstimate
,
462 &NewMaxCallFrameSize
);
463 MF
.getFrameInfo().setStackSize(FrameSize
);
464 MF
.getFrameInfo().setMaxCallFrameSize(NewMaxCallFrameSize
);
468 /// determineFrameLayout - Determine the size of the frame and maximum call
471 PPCFrameLowering::determineFrameLayout(const MachineFunction
&MF
,
473 unsigned *NewMaxCallFrameSize
) const {
474 const MachineFrameInfo
&MFI
= MF
.getFrameInfo();
475 const PPCFunctionInfo
*FI
= MF
.getInfo
<PPCFunctionInfo
>();
477 // Get the number of bytes to allocate from the FrameInfo
479 UseEstimate
? MFI
.estimateStackSize(MF
) : MFI
.getStackSize();
481 // Get stack alignments. The frame must be aligned to the greatest of these:
482 unsigned TargetAlign
= getStackAlignment(); // alignment required per the ABI
483 unsigned MaxAlign
= MFI
.getMaxAlignment(); // algmt required by data in frame
484 unsigned AlignMask
= std::max(MaxAlign
, TargetAlign
) - 1;
486 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
488 unsigned LR
= RegInfo
->getRARegister();
489 bool DisableRedZone
= MF
.getFunction().hasFnAttribute(Attribute::NoRedZone
);
490 bool CanUseRedZone
= !MFI
.hasVarSizedObjects() && // No dynamic alloca.
491 !MFI
.adjustsStack() && // No calls.
492 !MustSaveLR(MF
, LR
) && // No need to save LR.
493 !FI
->mustSaveTOC() && // No need to save TOC.
494 !RegInfo
->hasBasePointer(MF
); // No special alignment.
496 // Note: for PPC32 SVR4ABI (Non-DarwinABI), we can still generate stackless
497 // code if all local vars are reg-allocated.
498 bool FitsInRedZone
= FrameSize
<= Subtarget
.getRedZoneSize();
500 // Check whether we can skip adjusting the stack pointer (by using red zone)
501 if (!DisableRedZone
&& CanUseRedZone
&& FitsInRedZone
) {
506 // Get the maximum call frame size of all the calls.
507 unsigned maxCallFrameSize
= MFI
.getMaxCallFrameSize();
509 // Maximum call frame needs to be at least big enough for linkage area.
510 unsigned minCallFrameSize
= getLinkageSize();
511 maxCallFrameSize
= std::max(maxCallFrameSize
, minCallFrameSize
);
513 // If we have dynamic alloca then maxCallFrameSize needs to be aligned so
514 // that allocations will be aligned.
515 if (MFI
.hasVarSizedObjects())
516 maxCallFrameSize
= (maxCallFrameSize
+ AlignMask
) & ~AlignMask
;
518 // Update the new max call frame size if the caller passes in a valid pointer.
519 if (NewMaxCallFrameSize
)
520 *NewMaxCallFrameSize
= maxCallFrameSize
;
522 // Include call frame size in total.
523 FrameSize
+= maxCallFrameSize
;
525 // Make sure the frame is aligned.
526 FrameSize
= (FrameSize
+ AlignMask
) & ~AlignMask
;
531 // hasFP - Return true if the specified function actually has a dedicated frame
533 bool PPCFrameLowering::hasFP(const MachineFunction
&MF
) const {
534 const MachineFrameInfo
&MFI
= MF
.getFrameInfo();
535 // FIXME: This is pretty much broken by design: hasFP() might be called really
536 // early, before the stack layout was calculated and thus hasFP() might return
537 // true or false here depending on the time of call.
538 return (MFI
.getStackSize()) && needsFP(MF
);
541 // needsFP - Return true if the specified function should have a dedicated frame
542 // pointer register. This is true if the function has variable sized allocas or
543 // if frame pointer elimination is disabled.
544 bool PPCFrameLowering::needsFP(const MachineFunction
&MF
) const {
545 const MachineFrameInfo
&MFI
= MF
.getFrameInfo();
547 // Naked functions have no stack frame pushed, so we don't have a frame
549 if (MF
.getFunction().hasFnAttribute(Attribute::Naked
))
552 return MF
.getTarget().Options
.DisableFramePointerElim(MF
) ||
553 MFI
.hasVarSizedObjects() || MFI
.hasStackMap() || MFI
.hasPatchPoint() ||
554 (MF
.getTarget().Options
.GuaranteedTailCallOpt
&&
555 MF
.getInfo
<PPCFunctionInfo
>()->hasFastCall());
558 void PPCFrameLowering::replaceFPWithRealFP(MachineFunction
&MF
) const {
559 bool is31
= needsFP(MF
);
560 unsigned FPReg
= is31
? PPC::R31
: PPC::R1
;
561 unsigned FP8Reg
= is31
? PPC::X31
: PPC::X1
;
563 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
564 bool HasBP
= RegInfo
->hasBasePointer(MF
);
565 unsigned BPReg
= HasBP
? (unsigned) RegInfo
->getBaseRegister(MF
) : FPReg
;
566 unsigned BP8Reg
= HasBP
? (unsigned) PPC::X30
: FP8Reg
;
568 for (MachineFunction::iterator BI
= MF
.begin(), BE
= MF
.end();
570 for (MachineBasicBlock::iterator MBBI
= BI
->end(); MBBI
!= BI
->begin(); ) {
572 for (unsigned I
= 0, E
= MBBI
->getNumOperands(); I
!= E
; ++I
) {
573 MachineOperand
&MO
= MBBI
->getOperand(I
);
577 switch (MO
.getReg()) {
596 /* This function will do the following:
597 - If MBB is an entry or exit block, set SR1 and SR2 to R0 and R12
598 respectively (defaults recommended by the ABI) and return true
599 - If MBB is not an entry block, initialize the register scavenger and look
600 for available registers.
601 - If the defaults (R0/R12) are available, return true
602 - If TwoUniqueRegsRequired is set to true, it looks for two unique
603 registers. Otherwise, look for a single available register.
604 - If the required registers are found, set SR1 and SR2 and return true.
605 - If the required registers are not found, set SR2 or both SR1 and SR2 to
606 PPC::NoRegister and return false.
608 Note that if both SR1 and SR2 are valid parameters and TwoUniqueRegsRequired
609 is not set, this function will attempt to find two different registers, but
610 still return true if only one register is available (and set SR1 == SR2).
613 PPCFrameLowering::findScratchRegister(MachineBasicBlock
*MBB
,
615 bool TwoUniqueRegsRequired
,
617 unsigned *SR2
) const {
619 unsigned R0
= Subtarget
.isPPC64() ? PPC::X0
: PPC::R0
;
620 unsigned R12
= Subtarget
.isPPC64() ? PPC::X12
: PPC::R12
;
622 // Set the defaults for the two scratch registers.
627 assert (SR1
&& "Asking for the second scratch register but not the first?");
631 // If MBB is an entry or exit block, use R0 and R12 as the scratch registers.
632 if ((UseAtEnd
&& MBB
->isReturnBlock()) ||
633 (!UseAtEnd
&& (&MBB
->getParent()->front() == MBB
)))
636 RS
.enterBasicBlock(*MBB
);
638 if (UseAtEnd
&& !MBB
->empty()) {
639 // The scratch register will be used at the end of the block, so must
640 // consider all registers used within the block
642 MachineBasicBlock::iterator MBBI
= MBB
->getFirstTerminator();
643 // If no terminator, back iterator up to previous instruction.
644 if (MBBI
== MBB
->end())
645 MBBI
= std::prev(MBBI
);
647 if (MBBI
!= MBB
->begin())
651 // If the two registers are available, we're all good.
652 // Note that we only return here if both R0 and R12 are available because
653 // although the function may not require two unique registers, it may benefit
654 // from having two so we should try to provide them.
655 if (!RS
.isRegUsed(R0
) && !RS
.isRegUsed(R12
))
658 // Get the list of callee-saved registers for the target.
659 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
660 const MCPhysReg
*CSRegs
= RegInfo
->getCalleeSavedRegs(MBB
->getParent());
662 // Get all the available registers in the block.
663 BitVector BV
= RS
.getRegsAvailable(Subtarget
.isPPC64() ? &PPC::G8RCRegClass
:
666 // We shouldn't use callee-saved registers as scratch registers as they may be
667 // available when looking for a candidate block for shrink wrapping but not
668 // available when the actual prologue/epilogue is being emitted because they
669 // were added as live-in to the prologue block by PrologueEpilogueInserter.
670 for (int i
= 0; CSRegs
[i
]; ++i
)
673 // Set the first scratch register to the first available one.
675 int FirstScratchReg
= BV
.find_first();
676 *SR1
= FirstScratchReg
== -1 ? (unsigned)PPC::NoRegister
: FirstScratchReg
;
679 // If there is another one available, set the second scratch register to that.
680 // Otherwise, set it to either PPC::NoRegister if this function requires two
681 // or to whatever SR1 is set to if this function doesn't require two.
683 int SecondScratchReg
= BV
.find_next(*SR1
);
684 if (SecondScratchReg
!= -1)
685 *SR2
= SecondScratchReg
;
687 *SR2
= TwoUniqueRegsRequired
? (unsigned)PPC::NoRegister
: *SR1
;
690 // Now that we've done our best to provide both registers, double check
691 // whether we were unable to provide enough.
692 if (BV
.count() < (TwoUniqueRegsRequired
? 2U : 1U))
698 // We need a scratch register for spilling LR and for spilling CR. By default,
699 // we use two scratch registers to hide latency. However, if only one scratch
700 // register is available, we can adjust for that by not overlapping the spill
701 // code. However, if we need to realign the stack (i.e. have a base pointer)
702 // and the stack frame is large, we need two scratch registers.
704 PPCFrameLowering::twoUniqueScratchRegsRequired(MachineBasicBlock
*MBB
) const {
705 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
706 MachineFunction
&MF
= *(MBB
->getParent());
707 bool HasBP
= RegInfo
->hasBasePointer(MF
);
708 unsigned FrameSize
= determineFrameLayout(MF
);
709 int NegFrameSize
= -FrameSize
;
710 bool IsLargeFrame
= !isInt
<16>(NegFrameSize
);
711 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
712 unsigned MaxAlign
= MFI
.getMaxAlignment();
713 bool HasRedZone
= Subtarget
.isPPC64() || !Subtarget
.isSVR4ABI();
715 return (IsLargeFrame
|| !HasRedZone
) && HasBP
&& MaxAlign
> 1;
718 bool PPCFrameLowering::canUseAsPrologue(const MachineBasicBlock
&MBB
) const {
719 MachineBasicBlock
*TmpMBB
= const_cast<MachineBasicBlock
*>(&MBB
);
721 return findScratchRegister(TmpMBB
, false,
722 twoUniqueScratchRegsRequired(TmpMBB
));
725 bool PPCFrameLowering::canUseAsEpilogue(const MachineBasicBlock
&MBB
) const {
726 MachineBasicBlock
*TmpMBB
= const_cast<MachineBasicBlock
*>(&MBB
);
728 return findScratchRegister(TmpMBB
, true);
731 bool PPCFrameLowering::stackUpdateCanBeMoved(MachineFunction
&MF
) const {
732 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
733 PPCFunctionInfo
*FI
= MF
.getInfo
<PPCFunctionInfo
>();
735 // Abort if there is no register info or function info.
739 // Only move the stack update on ELFv2 ABI and PPC64.
740 if (!Subtarget
.isELFv2ABI() || !Subtarget
.isPPC64())
743 // Check the frame size first and return false if it does not fit the
745 // We need a non-zero frame size as well as a frame that will fit in the red
746 // zone. This is because by moving the stack pointer update we are now storing
747 // to the red zone until the stack pointer is updated. If we get an interrupt
748 // inside the prologue but before the stack update we now have a number of
749 // stores to the red zone and those stores must all fit.
750 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
751 unsigned FrameSize
= MFI
.getStackSize();
752 if (!FrameSize
|| FrameSize
> Subtarget
.getRedZoneSize())
755 // Frame pointers and base pointers complicate matters so don't do anything
756 // if we have them. For example having a frame pointer will sometimes require
757 // a copy of r1 into r31 and that makes keeping track of updates to r1 more
759 if (hasFP(MF
) || RegInfo
->hasBasePointer(MF
))
762 // Calls to fast_cc functions use different rules for passing parameters on
763 // the stack from the ABI and using PIC base in the function imposes
764 // similar restrictions to using the base pointer. It is not generally safe
765 // to move the stack pointer update in these situations.
766 if (FI
->hasFastCall() || FI
->usesPICBase())
769 // Finally we can move the stack update if we do not require register
770 // scavenging. Register scavenging can introduce more spills and so
771 // may make the frame size larger than we have computed.
772 return !RegInfo
->requiresFrameIndexScavenging(MF
);
775 void PPCFrameLowering::emitPrologue(MachineFunction
&MF
,
776 MachineBasicBlock
&MBB
) const {
777 MachineBasicBlock::iterator MBBI
= MBB
.begin();
778 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
779 const PPCInstrInfo
&TII
= *Subtarget
.getInstrInfo();
780 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
782 MachineModuleInfo
&MMI
= MF
.getMMI();
783 const MCRegisterInfo
*MRI
= MMI
.getContext().getRegisterInfo();
785 bool needsCFI
= MMI
.hasDebugInfo() ||
786 MF
.getFunction().needsUnwindTableEntry();
788 // Get processor type.
789 bool isPPC64
= Subtarget
.isPPC64();
791 bool isSVR4ABI
= Subtarget
.isSVR4ABI();
792 bool isAIXABI
= Subtarget
.isAIXABI();
793 bool isELFv2ABI
= Subtarget
.isELFv2ABI();
794 assert((Subtarget
.isDarwinABI() || isSVR4ABI
|| isAIXABI
) &&
795 "Unsupported PPC ABI.");
797 // Scan the prolog, looking for an UPDATE_VRSAVE instruction. If we find it,
800 for (unsigned i
= 0; MBBI
!= MBB
.end(); ++i
, ++MBBI
) {
801 if (MBBI
->getOpcode() == PPC::UPDATE_VRSAVE
) {
803 report_fatal_error("UPDATE_VRSAVE is unexpected on AIX.");
804 HandleVRSaveUpdate(*MBBI
, TII
);
809 // Move MBBI back to the beginning of the prologue block.
812 // Work out frame sizes.
813 unsigned FrameSize
= determineFrameLayoutAndUpdate(MF
);
814 int NegFrameSize
= -FrameSize
;
815 if (!isInt
<32>(NegFrameSize
))
816 llvm_unreachable("Unhandled stack size!");
818 if (MFI
.isFrameAddressTaken())
819 replaceFPWithRealFP(MF
);
821 // Check if the link register (LR) must be saved.
822 PPCFunctionInfo
*FI
= MF
.getInfo
<PPCFunctionInfo
>();
823 bool MustSaveLR
= FI
->mustSaveLR();
824 bool MustSaveTOC
= FI
->mustSaveTOC();
825 const SmallVectorImpl
<unsigned> &MustSaveCRs
= FI
->getMustSaveCRs();
826 bool MustSaveCR
= !MustSaveCRs
.empty();
827 // Do we have a frame pointer and/or base pointer for this function?
828 bool HasFP
= hasFP(MF
);
829 bool HasBP
= RegInfo
->hasBasePointer(MF
);
830 bool HasRedZone
= isPPC64
|| !isSVR4ABI
;
832 unsigned SPReg
= isPPC64
? PPC::X1
: PPC::R1
;
833 Register BPReg
= RegInfo
->getBaseRegister(MF
);
834 unsigned FPReg
= isPPC64
? PPC::X31
: PPC::R31
;
835 unsigned LRReg
= isPPC64
? PPC::LR8
: PPC::LR
;
836 unsigned TOCReg
= isPPC64
? PPC::X2
: PPC::R2
;
837 unsigned ScratchReg
= 0;
838 unsigned TempReg
= isPPC64
? PPC::X12
: PPC::R12
; // another scratch reg
839 // ...(R12/X12 is volatile in both Darwin & SVR4, & can't be a function arg.)
840 const MCInstrDesc
& MFLRInst
= TII
.get(isPPC64
? PPC::MFLR8
842 const MCInstrDesc
& StoreInst
= TII
.get(isPPC64
? PPC::STD
844 const MCInstrDesc
& StoreUpdtInst
= TII
.get(isPPC64
? PPC::STDU
846 const MCInstrDesc
& StoreUpdtIdxInst
= TII
.get(isPPC64
? PPC::STDUX
848 const MCInstrDesc
& LoadImmShiftedInst
= TII
.get(isPPC64
? PPC::LIS8
850 const MCInstrDesc
& OrImmInst
= TII
.get(isPPC64
? PPC::ORI8
852 const MCInstrDesc
& OrInst
= TII
.get(isPPC64
? PPC::OR8
854 const MCInstrDesc
& SubtractCarryingInst
= TII
.get(isPPC64
? PPC::SUBFC8
856 const MCInstrDesc
& SubtractImmCarryingInst
= TII
.get(isPPC64
? PPC::SUBFIC8
859 // Regarding this assert: Even though LR is saved in the caller's frame (i.e.,
860 // LROffset is positive), that slot is callee-owned. Because PPC32 SVR4 has no
861 // Red Zone, an asynchronous event (a form of "callee") could claim a frame &
862 // overwrite it, so PPC32 SVR4 must claim at least a minimal frame to save LR.
863 assert((isPPC64
|| !isSVR4ABI
|| !(!FrameSize
&& (MustSaveLR
|| HasFP
))) &&
864 "FrameSize must be >0 to save/restore the FP or LR for 32-bit SVR4.");
866 // Using the same bool variable as below to suppress compiler warnings.
867 bool SingleScratchReg
=
868 findScratchRegister(&MBB
, false, twoUniqueScratchRegsRequired(&MBB
),
869 &ScratchReg
, &TempReg
);
870 assert(SingleScratchReg
&&
871 "Required number of registers not available in this block");
873 SingleScratchReg
= ScratchReg
== TempReg
;
875 int LROffset
= getReturnSaveOffset();
880 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
881 int FPIndex
= FI
->getFramePointerSaveIndex();
882 assert(FPIndex
&& "No Frame Pointer Save Slot!");
883 FPOffset
= MFI
.getObjectOffset(FPIndex
);
885 FPOffset
= getFramePointerSaveOffset();
892 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
893 int BPIndex
= FI
->getBasePointerSaveIndex();
894 assert(BPIndex
&& "No Base Pointer Save Slot!");
895 BPOffset
= MFI
.getObjectOffset(BPIndex
);
897 BPOffset
= getBasePointerSaveOffset();
902 if (FI
->usesPICBase()) {
903 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
904 int PBPIndex
= FI
->getPICBasePointerSaveIndex();
905 assert(PBPIndex
&& "No PIC Base Pointer Save Slot!");
906 PBPOffset
= MFI
.getObjectOffset(PBPIndex
);
909 // Get stack alignments.
910 unsigned MaxAlign
= MFI
.getMaxAlignment();
911 if (HasBP
&& MaxAlign
> 1)
912 assert(isPowerOf2_32(MaxAlign
) && isInt
<16>(MaxAlign
) &&
913 "Invalid alignment!");
915 // Frames of 32KB & larger require special handling because they cannot be
916 // indexed into with a simple STDU/STWU/STD/STW immediate offset operand.
917 bool isLargeFrame
= !isInt
<16>(NegFrameSize
);
919 assert((isPPC64
|| !MustSaveCR
) &&
920 "Prologue CR saving supported only in 64-bit mode");
922 if (MustSaveCR
&& isAIXABI
)
923 report_fatal_error("Prologue CR saving is unimplemented on AIX.");
925 // Check if we can move the stack update instruction (stdu) down the prologue
926 // past the callee saves. Hopefully this will avoid the situation where the
927 // saves are waiting for the update on the store with update to complete.
928 MachineBasicBlock::iterator StackUpdateLoc
= MBBI
;
929 bool MovingStackUpdateDown
= false;
931 // Check if we can move the stack update.
932 if (stackUpdateCanBeMoved(MF
)) {
933 const std::vector
<CalleeSavedInfo
> &Info
= MFI
.getCalleeSavedInfo();
934 for (CalleeSavedInfo CSI
: Info
) {
935 int FrIdx
= CSI
.getFrameIdx();
936 // If the frame index is not negative the callee saved info belongs to a
937 // stack object that is not a fixed stack object. We ignore non-fixed
938 // stack objects because we won't move the stack update pointer past them.
942 if (MFI
.isFixedObjectIndex(FrIdx
) && MFI
.getObjectOffset(FrIdx
) < 0) {
944 MovingStackUpdateDown
= true;
946 // We need all of the Frame Indices to meet these conditions.
947 // If they do not, abort the whole operation.
948 StackUpdateLoc
= MBBI
;
949 MovingStackUpdateDown
= false;
954 // If the operation was not aborted then update the object offset.
955 if (MovingStackUpdateDown
) {
956 for (CalleeSavedInfo CSI
: Info
) {
957 int FrIdx
= CSI
.getFrameIdx();
959 MFI
.setObjectOffset(FrIdx
, MFI
.getObjectOffset(FrIdx
) + NegFrameSize
);
964 // If we need to spill the CR and the LR but we don't have two separate
965 // registers available, we must spill them one at a time
966 if (MustSaveCR
&& SingleScratchReg
&& MustSaveLR
) {
967 // In the ELFv2 ABI, we are not required to save all CR fields.
968 // If only one or two CR fields are clobbered, it is more efficient to use
969 // mfocrf to selectively save just those fields, because mfocrf has short
970 // latency compares to mfcr.
971 unsigned MfcrOpcode
= PPC::MFCR8
;
972 unsigned CrState
= RegState::ImplicitKill
;
973 if (isELFv2ABI
&& MustSaveCRs
.size() == 1) {
974 MfcrOpcode
= PPC::MFOCRF8
;
975 CrState
= RegState::Kill
;
977 MachineInstrBuilder MIB
=
978 BuildMI(MBB
, MBBI
, dl
, TII
.get(MfcrOpcode
), TempReg
);
979 for (unsigned i
= 0, e
= MustSaveCRs
.size(); i
!= e
; ++i
)
980 MIB
.addReg(MustSaveCRs
[i
], CrState
);
981 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::STW8
))
982 .addReg(TempReg
, getKillRegState(true))
983 .addImm(getCRSaveOffset())
988 BuildMI(MBB
, MBBI
, dl
, MFLRInst
, ScratchReg
);
991 !(SingleScratchReg
&& MustSaveLR
)) { // will only occur for PPC64
992 // In the ELFv2 ABI, we are not required to save all CR fields.
993 // If only one or two CR fields are clobbered, it is more efficient to use
994 // mfocrf to selectively save just those fields, because mfocrf has short
995 // latency compares to mfcr.
996 unsigned MfcrOpcode
= PPC::MFCR8
;
997 unsigned CrState
= RegState::ImplicitKill
;
998 if (isELFv2ABI
&& MustSaveCRs
.size() == 1) {
999 MfcrOpcode
= PPC::MFOCRF8
;
1000 CrState
= RegState::Kill
;
1002 MachineInstrBuilder MIB
=
1003 BuildMI(MBB
, MBBI
, dl
, TII
.get(MfcrOpcode
), TempReg
);
1004 for (unsigned i
= 0, e
= MustSaveCRs
.size(); i
!= e
; ++i
)
1005 MIB
.addReg(MustSaveCRs
[i
], CrState
);
1010 BuildMI(MBB
, MBBI
, dl
, StoreInst
)
1014 if (FI
->usesPICBase())
1015 BuildMI(MBB
, MBBI
, dl
, StoreInst
)
1020 BuildMI(MBB
, MBBI
, dl
, StoreInst
)
1027 BuildMI(MBB
, StackUpdateLoc
, dl
, StoreInst
)
1028 .addReg(ScratchReg
, getKillRegState(true))
1033 !(SingleScratchReg
&& MustSaveLR
)) { // will only occur for PPC64
1034 assert(HasRedZone
&& "A red zone is always available on PPC64");
1035 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::STW8
))
1036 .addReg(TempReg
, getKillRegState(true))
1037 .addImm(getCRSaveOffset())
1041 // Skip the rest if this is a leaf function & all spills fit in the Red Zone.
1045 // Adjust stack pointer: r1 += NegFrameSize.
1046 // If there is a preferred stack alignment, align R1 now
1048 if (HasBP
&& HasRedZone
) {
1049 // Save a copy of r1 as the base pointer.
1050 BuildMI(MBB
, MBBI
, dl
, OrInst
, BPReg
)
1055 // Have we generated a STUX instruction to claim stack frame? If so,
1056 // the negated frame size will be placed in ScratchReg.
1057 bool HasSTUX
= false;
1059 // This condition must be kept in sync with canUseAsPrologue.
1060 if (HasBP
&& MaxAlign
> 1) {
1062 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::RLDICL
), ScratchReg
)
1065 .addImm(64 - Log2_32(MaxAlign
));
1067 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::RLWINM
), ScratchReg
)
1070 .addImm(32 - Log2_32(MaxAlign
))
1072 if (!isLargeFrame
) {
1073 BuildMI(MBB
, MBBI
, dl
, SubtractImmCarryingInst
, ScratchReg
)
1074 .addReg(ScratchReg
, RegState::Kill
)
1075 .addImm(NegFrameSize
);
1077 assert(!SingleScratchReg
&& "Only a single scratch reg available");
1078 BuildMI(MBB
, MBBI
, dl
, LoadImmShiftedInst
, TempReg
)
1079 .addImm(NegFrameSize
>> 16);
1080 BuildMI(MBB
, MBBI
, dl
, OrImmInst
, TempReg
)
1081 .addReg(TempReg
, RegState::Kill
)
1082 .addImm(NegFrameSize
& 0xFFFF);
1083 BuildMI(MBB
, MBBI
, dl
, SubtractCarryingInst
, ScratchReg
)
1084 .addReg(ScratchReg
, RegState::Kill
)
1085 .addReg(TempReg
, RegState::Kill
);
1088 BuildMI(MBB
, MBBI
, dl
, StoreUpdtIdxInst
, SPReg
)
1089 .addReg(SPReg
, RegState::Kill
)
1091 .addReg(ScratchReg
);
1094 } else if (!isLargeFrame
) {
1095 BuildMI(MBB
, StackUpdateLoc
, dl
, StoreUpdtInst
, SPReg
)
1097 .addImm(NegFrameSize
)
1101 BuildMI(MBB
, MBBI
, dl
, LoadImmShiftedInst
, ScratchReg
)
1102 .addImm(NegFrameSize
>> 16);
1103 BuildMI(MBB
, MBBI
, dl
, OrImmInst
, ScratchReg
)
1104 .addReg(ScratchReg
, RegState::Kill
)
1105 .addImm(NegFrameSize
& 0xFFFF);
1106 BuildMI(MBB
, MBBI
, dl
, StoreUpdtIdxInst
, SPReg
)
1107 .addReg(SPReg
, RegState::Kill
)
1109 .addReg(ScratchReg
);
1113 // Save the TOC register after the stack pointer update if a prologue TOC
1114 // save is required for the function.
1116 assert(isELFv2ABI
&& "TOC saves in the prologue only supported on ELFv2");
1117 BuildMI(MBB
, StackUpdateLoc
, dl
, TII
.get(PPC::STD
))
1118 .addReg(TOCReg
, getKillRegState(true))
1119 .addImm(TOCSaveOffset
)
1124 assert(!isPPC64
&& "A red zone is always available on PPC64");
1126 // The negated frame size is in ScratchReg, and the SPReg has been
1127 // decremented by the frame size: SPReg = old SPReg + ScratchReg.
1128 // Since FPOffset, PBPOffset, etc. are relative to the beginning of
1129 // the stack frame (i.e. the old SP), ideally, we would put the old
1130 // SP into a register and use it as the base for the stores. The
1131 // problem is that the only available register may be ScratchReg,
1132 // which could be R0, and R0 cannot be used as a base address.
1134 // First, set ScratchReg to the old SP. This may need to be modified
1136 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::SUBF
), ScratchReg
)
1137 .addReg(ScratchReg
, RegState::Kill
)
1140 if (ScratchReg
== PPC::R0
) {
1141 // R0 cannot be used as a base register, but it can be used as an
1142 // index in a store-indexed.
1145 // R0 += (FPOffset-LastOffset).
1146 // Need addic, since addi treats R0 as 0.
1147 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::ADDIC
), ScratchReg
)
1149 .addImm(FPOffset
-LastOffset
);
1150 LastOffset
= FPOffset
;
1151 // Store FP into *R0.
1152 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::STWX
))
1153 .addReg(FPReg
, RegState::Kill
) // Save FP.
1155 .addReg(ScratchReg
); // This will be the index (R0 is ok here).
1157 if (FI
->usesPICBase()) {
1158 // R0 += (PBPOffset-LastOffset).
1159 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::ADDIC
), ScratchReg
)
1161 .addImm(PBPOffset
-LastOffset
);
1162 LastOffset
= PBPOffset
;
1163 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::STWX
))
1164 .addReg(PPC::R30
, RegState::Kill
) // Save PIC base pointer.
1166 .addReg(ScratchReg
); // This will be the index (R0 is ok here).
1169 // R0 += (BPOffset-LastOffset).
1170 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::ADDIC
), ScratchReg
)
1172 .addImm(BPOffset
-LastOffset
);
1173 LastOffset
= BPOffset
;
1174 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::STWX
))
1175 .addReg(BPReg
, RegState::Kill
) // Save BP.
1177 .addReg(ScratchReg
); // This will be the index (R0 is ok here).
1178 // BP = R0-LastOffset
1179 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::ADDIC
), BPReg
)
1180 .addReg(ScratchReg
, RegState::Kill
)
1181 .addImm(-LastOffset
);
1184 // ScratchReg is not R0, so use it as the base register. It is
1185 // already set to the old SP, so we can use the offsets directly.
1187 // Now that the stack frame has been allocated, save all the necessary
1188 // registers using ScratchReg as the base address.
1190 BuildMI(MBB
, MBBI
, dl
, StoreInst
)
1193 .addReg(ScratchReg
);
1194 if (FI
->usesPICBase())
1195 BuildMI(MBB
, MBBI
, dl
, StoreInst
)
1198 .addReg(ScratchReg
);
1200 BuildMI(MBB
, MBBI
, dl
, StoreInst
)
1203 .addReg(ScratchReg
);
1204 BuildMI(MBB
, MBBI
, dl
, OrInst
, BPReg
)
1205 .addReg(ScratchReg
, RegState::Kill
)
1206 .addReg(ScratchReg
);
1210 // The frame size is a known 16-bit constant (fitting in the immediate
1211 // field of STWU). To be here we have to be compiling for PPC32.
1212 // Since the SPReg has been decreased by FrameSize, add it back to each
1215 BuildMI(MBB
, MBBI
, dl
, StoreInst
)
1217 .addImm(FrameSize
+ FPOffset
)
1219 if (FI
->usesPICBase())
1220 BuildMI(MBB
, MBBI
, dl
, StoreInst
)
1222 .addImm(FrameSize
+ PBPOffset
)
1225 BuildMI(MBB
, MBBI
, dl
, StoreInst
)
1227 .addImm(FrameSize
+ BPOffset
)
1229 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::ADDI
), BPReg
)
1236 // Add Call Frame Information for the instructions we generated above.
1241 // Define CFA in terms of BP. Do this in preference to using FP/SP,
1242 // because if the stack needed aligning then CFA won't be at a fixed
1243 // offset from FP/SP.
1244 unsigned Reg
= MRI
->getDwarfRegNum(BPReg
, true);
1245 CFIIndex
= MF
.addFrameInst(
1246 MCCFIInstruction::createDefCfaRegister(nullptr, Reg
));
1248 // Adjust the definition of CFA to account for the change in SP.
1249 assert(NegFrameSize
);
1250 CFIIndex
= MF
.addFrameInst(
1251 MCCFIInstruction::createDefCfaOffset(nullptr, NegFrameSize
));
1253 BuildMI(MBB
, MBBI
, dl
, TII
.get(TargetOpcode::CFI_INSTRUCTION
))
1254 .addCFIIndex(CFIIndex
);
1257 // Describe where FP was saved, at a fixed offset from CFA.
1258 unsigned Reg
= MRI
->getDwarfRegNum(FPReg
, true);
1259 CFIIndex
= MF
.addFrameInst(
1260 MCCFIInstruction::createOffset(nullptr, Reg
, FPOffset
));
1261 BuildMI(MBB
, MBBI
, dl
, TII
.get(TargetOpcode::CFI_INSTRUCTION
))
1262 .addCFIIndex(CFIIndex
);
1265 if (FI
->usesPICBase()) {
1266 // Describe where FP was saved, at a fixed offset from CFA.
1267 unsigned Reg
= MRI
->getDwarfRegNum(PPC::R30
, true);
1268 CFIIndex
= MF
.addFrameInst(
1269 MCCFIInstruction::createOffset(nullptr, Reg
, PBPOffset
));
1270 BuildMI(MBB
, MBBI
, dl
, TII
.get(TargetOpcode::CFI_INSTRUCTION
))
1271 .addCFIIndex(CFIIndex
);
1275 // Describe where BP was saved, at a fixed offset from CFA.
1276 unsigned Reg
= MRI
->getDwarfRegNum(BPReg
, true);
1277 CFIIndex
= MF
.addFrameInst(
1278 MCCFIInstruction::createOffset(nullptr, Reg
, BPOffset
));
1279 BuildMI(MBB
, MBBI
, dl
, TII
.get(TargetOpcode::CFI_INSTRUCTION
))
1280 .addCFIIndex(CFIIndex
);
1284 // Describe where LR was saved, at a fixed offset from CFA.
1285 unsigned Reg
= MRI
->getDwarfRegNum(LRReg
, true);
1286 CFIIndex
= MF
.addFrameInst(
1287 MCCFIInstruction::createOffset(nullptr, Reg
, LROffset
));
1288 BuildMI(MBB
, MBBI
, dl
, TII
.get(TargetOpcode::CFI_INSTRUCTION
))
1289 .addCFIIndex(CFIIndex
);
1293 // If there is a frame pointer, copy R1 into R31
1295 BuildMI(MBB
, MBBI
, dl
, OrInst
, FPReg
)
1299 if (!HasBP
&& needsCFI
) {
1300 // Change the definition of CFA from SP+offset to FP+offset, because SP
1301 // will change at every alloca.
1302 unsigned Reg
= MRI
->getDwarfRegNum(FPReg
, true);
1303 unsigned CFIIndex
= MF
.addFrameInst(
1304 MCCFIInstruction::createDefCfaRegister(nullptr, Reg
));
1306 BuildMI(MBB
, MBBI
, dl
, TII
.get(TargetOpcode::CFI_INSTRUCTION
))
1307 .addCFIIndex(CFIIndex
);
1312 // Describe where callee saved registers were saved, at fixed offsets from
1314 const std::vector
<CalleeSavedInfo
> &CSI
= MFI
.getCalleeSavedInfo();
1315 for (unsigned I
= 0, E
= CSI
.size(); I
!= E
; ++I
) {
1316 unsigned Reg
= CSI
[I
].getReg();
1317 if (Reg
== PPC::LR
|| Reg
== PPC::LR8
|| Reg
== PPC::RM
) continue;
1319 // This is a bit of a hack: CR2LT, CR2GT, CR2EQ and CR2UN are just
1320 // subregisters of CR2. We just need to emit a move of CR2.
1321 if (PPC::CRBITRCRegClass
.contains(Reg
))
1324 if ((Reg
== PPC::X2
|| Reg
== PPC::R2
) && MustSaveTOC
)
1327 // For SVR4, don't emit a move for the CR spill slot if we haven't
1329 if (isSVR4ABI
&& (PPC::CR2
<= Reg
&& Reg
<= PPC::CR4
)
1333 // For 64-bit SVR4 when we have spilled CRs, the spill location
1334 // is SP+8, not a frame-relative slot.
1335 if (isSVR4ABI
&& isPPC64
&& (PPC::CR2
<= Reg
&& Reg
<= PPC::CR4
)) {
1336 // In the ELFv1 ABI, only CR2 is noted in CFI and stands in for
1337 // the whole CR word. In the ELFv2 ABI, every CR that was
1338 // actually saved gets its own CFI record.
1339 unsigned CRReg
= isELFv2ABI
? Reg
: (unsigned) PPC::CR2
;
1340 unsigned CFIIndex
= MF
.addFrameInst(MCCFIInstruction::createOffset(
1341 nullptr, MRI
->getDwarfRegNum(CRReg
, true), getCRSaveOffset()));
1342 BuildMI(MBB
, MBBI
, dl
, TII
.get(TargetOpcode::CFI_INSTRUCTION
))
1343 .addCFIIndex(CFIIndex
);
1347 if (CSI
[I
].isSpilledToReg()) {
1348 unsigned SpilledReg
= CSI
[I
].getDstReg();
1349 unsigned CFIRegister
= MF
.addFrameInst(MCCFIInstruction::createRegister(
1350 nullptr, MRI
->getDwarfRegNum(Reg
, true),
1351 MRI
->getDwarfRegNum(SpilledReg
, true)));
1352 BuildMI(MBB
, MBBI
, dl
, TII
.get(TargetOpcode::CFI_INSTRUCTION
))
1353 .addCFIIndex(CFIRegister
);
1355 int Offset
= MFI
.getObjectOffset(CSI
[I
].getFrameIdx());
1356 // We have changed the object offset above but we do not want to change
1357 // the actual offsets in the CFI instruction so we have to undo the
1358 // offset change here.
1359 if (MovingStackUpdateDown
)
1360 Offset
-= NegFrameSize
;
1362 unsigned CFIIndex
= MF
.addFrameInst(MCCFIInstruction::createOffset(
1363 nullptr, MRI
->getDwarfRegNum(Reg
, true), Offset
));
1364 BuildMI(MBB
, MBBI
, dl
, TII
.get(TargetOpcode::CFI_INSTRUCTION
))
1365 .addCFIIndex(CFIIndex
);
1371 void PPCFrameLowering::emitEpilogue(MachineFunction
&MF
,
1372 MachineBasicBlock
&MBB
) const {
1373 MachineBasicBlock::iterator MBBI
= MBB
.getFirstTerminator();
1376 if (MBBI
!= MBB
.end())
1377 dl
= MBBI
->getDebugLoc();
1379 const PPCInstrInfo
&TII
= *Subtarget
.getInstrInfo();
1380 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
1382 // Get alignment info so we know how to restore the SP.
1383 const MachineFrameInfo
&MFI
= MF
.getFrameInfo();
1385 // Get the number of bytes allocated from the FrameInfo.
1386 int FrameSize
= MFI
.getStackSize();
1388 // Get processor type.
1389 bool isPPC64
= Subtarget
.isPPC64();
1391 bool isSVR4ABI
= Subtarget
.isSVR4ABI();
1393 // Check if the link register (LR) has been saved.
1394 PPCFunctionInfo
*FI
= MF
.getInfo
<PPCFunctionInfo
>();
1395 bool MustSaveLR
= FI
->mustSaveLR();
1396 const SmallVectorImpl
<unsigned> &MustSaveCRs
= FI
->getMustSaveCRs();
1397 bool MustSaveCR
= !MustSaveCRs
.empty();
1398 // Do we have a frame pointer and/or base pointer for this function?
1399 bool HasFP
= hasFP(MF
);
1400 bool HasBP
= RegInfo
->hasBasePointer(MF
);
1401 bool HasRedZone
= Subtarget
.isPPC64() || !Subtarget
.isSVR4ABI();
1403 unsigned SPReg
= isPPC64
? PPC::X1
: PPC::R1
;
1404 Register BPReg
= RegInfo
->getBaseRegister(MF
);
1405 unsigned FPReg
= isPPC64
? PPC::X31
: PPC::R31
;
1406 unsigned ScratchReg
= 0;
1407 unsigned TempReg
= isPPC64
? PPC::X12
: PPC::R12
; // another scratch reg
1408 const MCInstrDesc
& MTLRInst
= TII
.get( isPPC64
? PPC::MTLR8
1410 const MCInstrDesc
& LoadInst
= TII
.get( isPPC64
? PPC::LD
1412 const MCInstrDesc
& LoadImmShiftedInst
= TII
.get( isPPC64
? PPC::LIS8
1414 const MCInstrDesc
& OrInst
= TII
.get(isPPC64
? PPC::OR8
1416 const MCInstrDesc
& OrImmInst
= TII
.get( isPPC64
? PPC::ORI8
1418 const MCInstrDesc
& AddImmInst
= TII
.get( isPPC64
? PPC::ADDI8
1420 const MCInstrDesc
& AddInst
= TII
.get( isPPC64
? PPC::ADD8
1423 int LROffset
= getReturnSaveOffset();
1427 // Using the same bool variable as below to suppress compiler warnings.
1428 bool SingleScratchReg
= findScratchRegister(&MBB
, true, false, &ScratchReg
,
1430 assert(SingleScratchReg
&&
1431 "Could not find an available scratch register");
1433 SingleScratchReg
= ScratchReg
== TempReg
;
1437 int FPIndex
= FI
->getFramePointerSaveIndex();
1438 assert(FPIndex
&& "No Frame Pointer Save Slot!");
1439 FPOffset
= MFI
.getObjectOffset(FPIndex
);
1441 FPOffset
= getFramePointerSaveOffset();
1448 int BPIndex
= FI
->getBasePointerSaveIndex();
1449 assert(BPIndex
&& "No Base Pointer Save Slot!");
1450 BPOffset
= MFI
.getObjectOffset(BPIndex
);
1452 BPOffset
= getBasePointerSaveOffset();
1457 if (FI
->usesPICBase()) {
1458 int PBPIndex
= FI
->getPICBasePointerSaveIndex();
1459 assert(PBPIndex
&& "No PIC Base Pointer Save Slot!");
1460 PBPOffset
= MFI
.getObjectOffset(PBPIndex
);
1463 bool IsReturnBlock
= (MBBI
!= MBB
.end() && MBBI
->isReturn());
1465 if (IsReturnBlock
) {
1466 unsigned RetOpcode
= MBBI
->getOpcode();
1467 bool UsesTCRet
= RetOpcode
== PPC::TCRETURNri
||
1468 RetOpcode
== PPC::TCRETURNdi
||
1469 RetOpcode
== PPC::TCRETURNai
||
1470 RetOpcode
== PPC::TCRETURNri8
||
1471 RetOpcode
== PPC::TCRETURNdi8
||
1472 RetOpcode
== PPC::TCRETURNai8
;
1475 int MaxTCRetDelta
= FI
->getTailCallSPDelta();
1476 MachineOperand
&StackAdjust
= MBBI
->getOperand(1);
1477 assert(StackAdjust
.isImm() && "Expecting immediate value.");
1478 // Adjust stack pointer.
1479 int StackAdj
= StackAdjust
.getImm();
1480 int Delta
= StackAdj
- MaxTCRetDelta
;
1481 assert((Delta
>= 0) && "Delta must be positive");
1482 if (MaxTCRetDelta
>0)
1483 FrameSize
+= (StackAdj
+Delta
);
1485 FrameSize
+= StackAdj
;
1489 // Frames of 32KB & larger require special handling because they cannot be
1490 // indexed into with a simple LD/LWZ immediate offset operand.
1491 bool isLargeFrame
= !isInt
<16>(FrameSize
);
1493 // On targets without red zone, the SP needs to be restored last, so that
1494 // all live contents of the stack frame are upwards of the SP. This means
1495 // that we cannot restore SP just now, since there may be more registers
1496 // to restore from the stack frame (e.g. R31). If the frame size is not
1497 // a simple immediate value, we will need a spare register to hold the
1498 // restored SP. If the frame size is known and small, we can simply adjust
1499 // the offsets of the registers to be restored, and still use SP to restore
1500 // them. In such case, the final update of SP will be to add the frame
1502 // To simplify the code, set RBReg to the base register used to restore
1503 // values from the stack, and set SPAdd to the value that needs to be added
1504 // to the SP at the end. The default values are as if red zone was present.
1505 unsigned RBReg
= SPReg
;
1508 // Check if we can move the stack update instruction up the epilogue
1509 // past the callee saves. This will allow the move to LR instruction
1510 // to be executed before the restores of the callee saves which means
1511 // that the callee saves can hide the latency from the MTLR instrcution.
1512 MachineBasicBlock::iterator StackUpdateLoc
= MBBI
;
1513 if (stackUpdateCanBeMoved(MF
)) {
1514 const std::vector
<CalleeSavedInfo
> & Info
= MFI
.getCalleeSavedInfo();
1515 for (CalleeSavedInfo CSI
: Info
) {
1516 int FrIdx
= CSI
.getFrameIdx();
1517 // If the frame index is not negative the callee saved info belongs to a
1518 // stack object that is not a fixed stack object. We ignore non-fixed
1519 // stack objects because we won't move the update of the stack pointer
1524 if (MFI
.isFixedObjectIndex(FrIdx
) && MFI
.getObjectOffset(FrIdx
) < 0)
1527 // Abort the operation as we can't update all CSR restores.
1528 StackUpdateLoc
= MBBI
;
1535 // In the prologue, the loaded (or persistent) stack pointer value is
1536 // offset by the STDU/STDUX/STWU/STWUX instruction. For targets with red
1537 // zone add this offset back now.
1539 // If this function contained a fastcc call and GuaranteedTailCallOpt is
1540 // enabled (=> hasFastCall()==true) the fastcc call might contain a tail
1541 // call which invalidates the stack pointer value in SP(0). So we use the
1542 // value of R31 in this case.
1543 if (FI
->hasFastCall()) {
1544 assert(HasFP
&& "Expecting a valid frame pointer.");
1547 if (!isLargeFrame
) {
1548 BuildMI(MBB
, MBBI
, dl
, AddImmInst
, RBReg
)
1549 .addReg(FPReg
).addImm(FrameSize
);
1551 BuildMI(MBB
, MBBI
, dl
, LoadImmShiftedInst
, ScratchReg
)
1552 .addImm(FrameSize
>> 16);
1553 BuildMI(MBB
, MBBI
, dl
, OrImmInst
, ScratchReg
)
1554 .addReg(ScratchReg
, RegState::Kill
)
1555 .addImm(FrameSize
& 0xFFFF);
1556 BuildMI(MBB
, MBBI
, dl
, AddInst
)
1559 .addReg(ScratchReg
);
1561 } else if (!isLargeFrame
&& !HasBP
&& !MFI
.hasVarSizedObjects()) {
1563 BuildMI(MBB
, StackUpdateLoc
, dl
, AddImmInst
, SPReg
)
1567 // Make sure that adding FrameSize will not overflow the max offset
1569 assert(FPOffset
<= 0 && BPOffset
<= 0 && PBPOffset
<= 0 &&
1570 "Local offsets should be negative");
1572 FPOffset
+= FrameSize
;
1573 BPOffset
+= FrameSize
;
1574 PBPOffset
+= FrameSize
;
1577 // We don't want to use ScratchReg as a base register, because it
1578 // could happen to be R0. Use FP instead, but make sure to preserve it.
1580 // If FP is not saved, copy it to ScratchReg.
1582 BuildMI(MBB
, MBBI
, dl
, OrInst
, ScratchReg
)
1587 BuildMI(MBB
, StackUpdateLoc
, dl
, LoadInst
, RBReg
)
1592 assert(RBReg
!= ScratchReg
&& "Should have avoided ScratchReg");
1593 // If there is no red zone, ScratchReg may be needed for holding a useful
1594 // value (although not the base register). Make sure it is not overwritten
1597 assert((isPPC64
|| !MustSaveCR
) &&
1598 "Epilogue CR restoring supported only in 64-bit mode");
1600 // If we need to restore both the LR and the CR and we only have one
1601 // available scratch register, we must do them one at a time.
1602 if (MustSaveCR
&& SingleScratchReg
&& MustSaveLR
) {
1603 // Here TempReg == ScratchReg, and in the absence of red zone ScratchReg
1605 assert(HasRedZone
&& "Expecting red zone");
1606 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::LWZ8
), TempReg
)
1607 .addImm(getCRSaveOffset())
1609 for (unsigned i
= 0, e
= MustSaveCRs
.size(); i
!= e
; ++i
)
1610 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::MTOCRF8
), MustSaveCRs
[i
])
1611 .addReg(TempReg
, getKillRegState(i
== e
-1));
1614 // Delay restoring of the LR if ScratchReg is needed. This is ok, since
1615 // LR is stored in the caller's stack frame. ScratchReg will be needed
1616 // if RBReg is anything other than SP. We shouldn't use ScratchReg as
1617 // a base register anyway, because it may happen to be R0.
1618 bool LoadedLR
= false;
1619 if (MustSaveLR
&& RBReg
== SPReg
&& isInt
<16>(LROffset
+SPAdd
)) {
1620 BuildMI(MBB
, StackUpdateLoc
, dl
, LoadInst
, ScratchReg
)
1621 .addImm(LROffset
+SPAdd
)
1626 if (MustSaveCR
&& !(SingleScratchReg
&& MustSaveLR
)) {
1627 // This will only occur for PPC64.
1628 assert(isPPC64
&& "Expecting 64-bit mode");
1629 assert(RBReg
== SPReg
&& "Should be using SP as a base register");
1630 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::LWZ8
), TempReg
)
1631 .addImm(getCRSaveOffset())
1636 // If there is red zone, restore FP directly, since SP has already been
1637 // restored. Otherwise, restore the value of FP into ScratchReg.
1638 if (HasRedZone
|| RBReg
== SPReg
)
1639 BuildMI(MBB
, MBBI
, dl
, LoadInst
, FPReg
)
1643 BuildMI(MBB
, MBBI
, dl
, LoadInst
, ScratchReg
)
1648 if (FI
->usesPICBase())
1649 BuildMI(MBB
, MBBI
, dl
, LoadInst
, PPC::R30
)
1654 BuildMI(MBB
, MBBI
, dl
, LoadInst
, BPReg
)
1658 // There is nothing more to be loaded from the stack, so now we can
1659 // restore SP: SP = RBReg + SPAdd.
1660 if (RBReg
!= SPReg
|| SPAdd
!= 0) {
1661 assert(!HasRedZone
&& "This should not happen with red zone");
1662 // If SPAdd is 0, generate a copy.
1664 BuildMI(MBB
, MBBI
, dl
, OrInst
, SPReg
)
1668 BuildMI(MBB
, MBBI
, dl
, AddImmInst
, SPReg
)
1672 assert(RBReg
!= ScratchReg
&& "Should be using FP or SP as base register");
1674 BuildMI(MBB
, MBBI
, dl
, OrInst
, FPReg
)
1676 .addReg(ScratchReg
);
1678 // Now load the LR from the caller's stack frame.
1679 if (MustSaveLR
&& !LoadedLR
)
1680 BuildMI(MBB
, MBBI
, dl
, LoadInst
, ScratchReg
)
1686 !(SingleScratchReg
&& MustSaveLR
)) // will only occur for PPC64
1687 for (unsigned i
= 0, e
= MustSaveCRs
.size(); i
!= e
; ++i
)
1688 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::MTOCRF8
), MustSaveCRs
[i
])
1689 .addReg(TempReg
, getKillRegState(i
== e
-1));
1692 BuildMI(MBB
, StackUpdateLoc
, dl
, MTLRInst
).addReg(ScratchReg
);
1694 // Callee pop calling convention. Pop parameter/linkage area. Used for tail
1695 // call optimization
1696 if (IsReturnBlock
) {
1697 unsigned RetOpcode
= MBBI
->getOpcode();
1698 if (MF
.getTarget().Options
.GuaranteedTailCallOpt
&&
1699 (RetOpcode
== PPC::BLR
|| RetOpcode
== PPC::BLR8
) &&
1700 MF
.getFunction().getCallingConv() == CallingConv::Fast
) {
1701 PPCFunctionInfo
*FI
= MF
.getInfo
<PPCFunctionInfo
>();
1702 unsigned CallerAllocatedAmt
= FI
->getMinReservedArea();
1704 if (CallerAllocatedAmt
&& isInt
<16>(CallerAllocatedAmt
)) {
1705 BuildMI(MBB
, MBBI
, dl
, AddImmInst
, SPReg
)
1706 .addReg(SPReg
).addImm(CallerAllocatedAmt
);
1708 BuildMI(MBB
, MBBI
, dl
, LoadImmShiftedInst
, ScratchReg
)
1709 .addImm(CallerAllocatedAmt
>> 16);
1710 BuildMI(MBB
, MBBI
, dl
, OrImmInst
, ScratchReg
)
1711 .addReg(ScratchReg
, RegState::Kill
)
1712 .addImm(CallerAllocatedAmt
& 0xFFFF);
1713 BuildMI(MBB
, MBBI
, dl
, AddInst
)
1716 .addReg(ScratchReg
);
1719 createTailCallBranchInstr(MBB
);
1724 void PPCFrameLowering::createTailCallBranchInstr(MachineBasicBlock
&MBB
) const {
1725 MachineBasicBlock::iterator MBBI
= MBB
.getFirstTerminator();
1727 // If we got this far a first terminator should exist.
1728 assert(MBBI
!= MBB
.end() && "Failed to find the first terminator.");
1730 DebugLoc dl
= MBBI
->getDebugLoc();
1731 const PPCInstrInfo
&TII
= *Subtarget
.getInstrInfo();
1733 // Create branch instruction for pseudo tail call return instruction
1734 unsigned RetOpcode
= MBBI
->getOpcode();
1735 if (RetOpcode
== PPC::TCRETURNdi
) {
1736 MBBI
= MBB
.getLastNonDebugInstr();
1737 MachineOperand
&JumpTarget
= MBBI
->getOperand(0);
1738 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::TAILB
)).
1739 addGlobalAddress(JumpTarget
.getGlobal(), JumpTarget
.getOffset());
1740 } else if (RetOpcode
== PPC::TCRETURNri
) {
1741 MBBI
= MBB
.getLastNonDebugInstr();
1742 assert(MBBI
->getOperand(0).isReg() && "Expecting register operand.");
1743 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::TAILBCTR
));
1744 } else if (RetOpcode
== PPC::TCRETURNai
) {
1745 MBBI
= MBB
.getLastNonDebugInstr();
1746 MachineOperand
&JumpTarget
= MBBI
->getOperand(0);
1747 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::TAILBA
)).addImm(JumpTarget
.getImm());
1748 } else if (RetOpcode
== PPC::TCRETURNdi8
) {
1749 MBBI
= MBB
.getLastNonDebugInstr();
1750 MachineOperand
&JumpTarget
= MBBI
->getOperand(0);
1751 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::TAILB8
)).
1752 addGlobalAddress(JumpTarget
.getGlobal(), JumpTarget
.getOffset());
1753 } else if (RetOpcode
== PPC::TCRETURNri8
) {
1754 MBBI
= MBB
.getLastNonDebugInstr();
1755 assert(MBBI
->getOperand(0).isReg() && "Expecting register operand.");
1756 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::TAILBCTR8
));
1757 } else if (RetOpcode
== PPC::TCRETURNai8
) {
1758 MBBI
= MBB
.getLastNonDebugInstr();
1759 MachineOperand
&JumpTarget
= MBBI
->getOperand(0);
1760 BuildMI(MBB
, MBBI
, dl
, TII
.get(PPC::TAILBA8
)).addImm(JumpTarget
.getImm());
1764 void PPCFrameLowering::determineCalleeSaves(MachineFunction
&MF
,
1765 BitVector
&SavedRegs
,
1766 RegScavenger
*RS
) const {
1767 TargetFrameLowering::determineCalleeSaves(MF
, SavedRegs
, RS
);
1769 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
1771 // Save and clear the LR state.
1772 PPCFunctionInfo
*FI
= MF
.getInfo
<PPCFunctionInfo
>();
1773 unsigned LR
= RegInfo
->getRARegister();
1774 FI
->setMustSaveLR(MustSaveLR(MF
, LR
));
1775 SavedRegs
.reset(LR
);
1777 // Save R31 if necessary
1778 int FPSI
= FI
->getFramePointerSaveIndex();
1779 bool isPPC64
= Subtarget
.isPPC64();
1780 bool isDarwinABI
= Subtarget
.isDarwinABI();
1781 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
1783 // If the frame pointer save index hasn't been defined yet.
1784 if (!FPSI
&& needsFP(MF
)) {
1785 // Find out what the fix offset of the frame pointer save area.
1786 int FPOffset
= getFramePointerSaveOffset();
1787 // Allocate the frame index for frame pointer save area.
1788 FPSI
= MFI
.CreateFixedObject(isPPC64
? 8 : 4, FPOffset
, true);
1790 FI
->setFramePointerSaveIndex(FPSI
);
1793 int BPSI
= FI
->getBasePointerSaveIndex();
1794 if (!BPSI
&& RegInfo
->hasBasePointer(MF
)) {
1795 int BPOffset
= getBasePointerSaveOffset();
1796 // Allocate the frame index for the base pointer save area.
1797 BPSI
= MFI
.CreateFixedObject(isPPC64
? 8 : 4, BPOffset
, true);
1799 FI
->setBasePointerSaveIndex(BPSI
);
1802 // Reserve stack space for the PIC Base register (R30).
1803 // Only used in SVR4 32-bit.
1804 if (FI
->usesPICBase()) {
1805 int PBPSI
= MFI
.CreateFixedObject(4, -8, true);
1806 FI
->setPICBasePointerSaveIndex(PBPSI
);
1809 // Make sure we don't explicitly spill r31, because, for example, we have
1810 // some inline asm which explicitly clobbers it, when we otherwise have a
1811 // frame pointer and are using r31's spill slot for the prologue/epilogue
1812 // code. Same goes for the base pointer and the PIC base register.
1814 SavedRegs
.reset(isPPC64
? PPC::X31
: PPC::R31
);
1815 if (RegInfo
->hasBasePointer(MF
))
1816 SavedRegs
.reset(RegInfo
->getBaseRegister(MF
));
1817 if (FI
->usesPICBase())
1818 SavedRegs
.reset(PPC::R30
);
1820 // Reserve stack space to move the linkage area to in case of a tail call.
1822 if (MF
.getTarget().Options
.GuaranteedTailCallOpt
&&
1823 (TCSPDelta
= FI
->getTailCallSPDelta()) < 0) {
1824 MFI
.CreateFixedObject(-1 * TCSPDelta
, TCSPDelta
, true);
1827 // For 32-bit SVR4, allocate the nonvolatile CR spill slot iff the
1828 // function uses CR 2, 3, or 4.
1829 if (!isPPC64
&& !isDarwinABI
&&
1830 (SavedRegs
.test(PPC::CR2
) ||
1831 SavedRegs
.test(PPC::CR3
) ||
1832 SavedRegs
.test(PPC::CR4
))) {
1833 int FrameIdx
= MFI
.CreateFixedObject((uint64_t)4, (int64_t)-4, true);
1834 FI
->setCRSpillFrameIndex(FrameIdx
);
1838 void PPCFrameLowering::processFunctionBeforeFrameFinalized(MachineFunction
&MF
,
1839 RegScavenger
*RS
) const {
1840 // Early exit if not using the SVR4 ABI.
1841 if (!Subtarget
.isSVR4ABI()) {
1842 addScavengingSpillSlot(MF
, RS
);
1846 // Get callee saved register information.
1847 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
1848 const std::vector
<CalleeSavedInfo
> &CSI
= MFI
.getCalleeSavedInfo();
1850 // If the function is shrink-wrapped, and if the function has a tail call, the
1851 // tail call might not be in the new RestoreBlock, so real branch instruction
1852 // won't be generated by emitEpilogue(), because shrink-wrap has chosen new
1853 // RestoreBlock. So we handle this case here.
1854 if (MFI
.getSavePoint() && MFI
.hasTailCall()) {
1855 MachineBasicBlock
*RestoreBlock
= MFI
.getRestorePoint();
1856 for (MachineBasicBlock
&MBB
: MF
) {
1857 if (MBB
.isReturnBlock() && (&MBB
) != RestoreBlock
)
1858 createTailCallBranchInstr(MBB
);
1862 // Early exit if no callee saved registers are modified!
1863 if (CSI
.empty() && !needsFP(MF
)) {
1864 addScavengingSpillSlot(MF
, RS
);
1868 unsigned MinGPR
= PPC::R31
;
1869 unsigned MinG8R
= PPC::X31
;
1870 unsigned MinFPR
= PPC::F31
;
1871 unsigned MinVR
= Subtarget
.hasSPE() ? PPC::S31
: PPC::V31
;
1873 bool HasGPSaveArea
= false;
1874 bool HasG8SaveArea
= false;
1875 bool HasFPSaveArea
= false;
1876 bool HasVRSAVESaveArea
= false;
1877 bool HasVRSaveArea
= false;
1879 SmallVector
<CalleeSavedInfo
, 18> GPRegs
;
1880 SmallVector
<CalleeSavedInfo
, 18> G8Regs
;
1881 SmallVector
<CalleeSavedInfo
, 18> FPRegs
;
1882 SmallVector
<CalleeSavedInfo
, 18> VRegs
;
1884 for (unsigned i
= 0, e
= CSI
.size(); i
!= e
; ++i
) {
1885 unsigned Reg
= CSI
[i
].getReg();
1886 assert((!MF
.getInfo
<PPCFunctionInfo
>()->mustSaveTOC() ||
1887 (Reg
!= PPC::X2
&& Reg
!= PPC::R2
)) &&
1888 "Not expecting to try to spill R2 in a function that must save TOC");
1889 if (PPC::GPRCRegClass
.contains(Reg
)) {
1890 HasGPSaveArea
= true;
1892 GPRegs
.push_back(CSI
[i
]);
1897 } else if (PPC::G8RCRegClass
.contains(Reg
)) {
1898 HasG8SaveArea
= true;
1900 G8Regs
.push_back(CSI
[i
]);
1905 } else if (PPC::F8RCRegClass
.contains(Reg
)) {
1906 HasFPSaveArea
= true;
1908 FPRegs
.push_back(CSI
[i
]);
1913 } else if (PPC::CRBITRCRegClass
.contains(Reg
) ||
1914 PPC::CRRCRegClass
.contains(Reg
)) {
1915 ; // do nothing, as we already know whether CRs are spilled
1916 } else if (PPC::VRSAVERCRegClass
.contains(Reg
)) {
1917 HasVRSAVESaveArea
= true;
1918 } else if (PPC::VRRCRegClass
.contains(Reg
) ||
1919 PPC::SPERCRegClass
.contains(Reg
)) {
1920 // Altivec and SPE are mutually exclusive, but have the same stack
1921 // alignment requirements, so overload the save area for both cases.
1922 HasVRSaveArea
= true;
1924 VRegs
.push_back(CSI
[i
]);
1930 llvm_unreachable("Unknown RegisterClass!");
1934 PPCFunctionInfo
*PFI
= MF
.getInfo
<PPCFunctionInfo
>();
1935 const TargetRegisterInfo
*TRI
= Subtarget
.getRegisterInfo();
1937 int64_t LowerBound
= 0;
1939 // Take into account stack space reserved for tail calls.
1941 if (MF
.getTarget().Options
.GuaranteedTailCallOpt
&&
1942 (TCSPDelta
= PFI
->getTailCallSPDelta()) < 0) {
1943 LowerBound
= TCSPDelta
;
1946 // The Floating-point register save area is right below the back chain word
1947 // of the previous stack frame.
1948 if (HasFPSaveArea
) {
1949 for (unsigned i
= 0, e
= FPRegs
.size(); i
!= e
; ++i
) {
1950 int FI
= FPRegs
[i
].getFrameIdx();
1952 MFI
.setObjectOffset(FI
, LowerBound
+ MFI
.getObjectOffset(FI
));
1955 LowerBound
-= (31 - TRI
->getEncodingValue(MinFPR
) + 1) * 8;
1958 // Check whether the frame pointer register is allocated. If so, make sure it
1959 // is spilled to the correct offset.
1961 int FI
= PFI
->getFramePointerSaveIndex();
1962 assert(FI
&& "No Frame Pointer Save Slot!");
1963 MFI
.setObjectOffset(FI
, LowerBound
+ MFI
.getObjectOffset(FI
));
1964 // FP is R31/X31, so no need to update MinGPR/MinG8R.
1965 HasGPSaveArea
= true;
1968 if (PFI
->usesPICBase()) {
1969 int FI
= PFI
->getPICBasePointerSaveIndex();
1970 assert(FI
&& "No PIC Base Pointer Save Slot!");
1971 MFI
.setObjectOffset(FI
, LowerBound
+ MFI
.getObjectOffset(FI
));
1973 MinGPR
= std::min
<unsigned>(MinGPR
, PPC::R30
);
1974 HasGPSaveArea
= true;
1977 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
1978 if (RegInfo
->hasBasePointer(MF
)) {
1979 int FI
= PFI
->getBasePointerSaveIndex();
1980 assert(FI
&& "No Base Pointer Save Slot!");
1981 MFI
.setObjectOffset(FI
, LowerBound
+ MFI
.getObjectOffset(FI
));
1983 Register BP
= RegInfo
->getBaseRegister(MF
);
1984 if (PPC::G8RCRegClass
.contains(BP
)) {
1985 MinG8R
= std::min
<unsigned>(MinG8R
, BP
);
1986 HasG8SaveArea
= true;
1987 } else if (PPC::GPRCRegClass
.contains(BP
)) {
1988 MinGPR
= std::min
<unsigned>(MinGPR
, BP
);
1989 HasGPSaveArea
= true;
1993 // General register save area starts right below the Floating-point
1994 // register save area.
1995 if (HasGPSaveArea
|| HasG8SaveArea
) {
1996 // Move general register save area spill slots down, taking into account
1997 // the size of the Floating-point register save area.
1998 for (unsigned i
= 0, e
= GPRegs
.size(); i
!= e
; ++i
) {
1999 if (!GPRegs
[i
].isSpilledToReg()) {
2000 int FI
= GPRegs
[i
].getFrameIdx();
2001 MFI
.setObjectOffset(FI
, LowerBound
+ MFI
.getObjectOffset(FI
));
2005 // Move general register save area spill slots down, taking into account
2006 // the size of the Floating-point register save area.
2007 for (unsigned i
= 0, e
= G8Regs
.size(); i
!= e
; ++i
) {
2008 if (!G8Regs
[i
].isSpilledToReg()) {
2009 int FI
= G8Regs
[i
].getFrameIdx();
2010 MFI
.setObjectOffset(FI
, LowerBound
+ MFI
.getObjectOffset(FI
));
2015 std::min
<unsigned>(TRI
->getEncodingValue(MinGPR
),
2016 TRI
->getEncodingValue(MinG8R
));
2018 if (Subtarget
.isPPC64()) {
2019 LowerBound
-= (31 - MinReg
+ 1) * 8;
2021 LowerBound
-= (31 - MinReg
+ 1) * 4;
2025 // For 32-bit only, the CR save area is below the general register
2026 // save area. For 64-bit SVR4, the CR save area is addressed relative
2027 // to the stack pointer and hence does not need an adjustment here.
2028 // Only CR2 (the first nonvolatile spilled) has an associated frame
2029 // index so that we have a single uniform save area.
2030 if (spillsCR(MF
) && !(Subtarget
.isPPC64() && Subtarget
.isSVR4ABI())) {
2031 // Adjust the frame index of the CR spill slot.
2032 for (unsigned i
= 0, e
= CSI
.size(); i
!= e
; ++i
) {
2033 unsigned Reg
= CSI
[i
].getReg();
2035 if ((Subtarget
.isSVR4ABI() && Reg
== PPC::CR2
)
2036 // Leave Darwin logic as-is.
2037 || (!Subtarget
.isSVR4ABI() &&
2038 (PPC::CRBITRCRegClass
.contains(Reg
) ||
2039 PPC::CRRCRegClass
.contains(Reg
)))) {
2040 int FI
= CSI
[i
].getFrameIdx();
2042 MFI
.setObjectOffset(FI
, LowerBound
+ MFI
.getObjectOffset(FI
));
2046 LowerBound
-= 4; // The CR save area is always 4 bytes long.
2049 if (HasVRSAVESaveArea
) {
2050 // FIXME SVR4: Is it actually possible to have multiple elements in CSI
2051 // which have the VRSAVE register class?
2052 // Adjust the frame index of the VRSAVE spill slot.
2053 for (unsigned i
= 0, e
= CSI
.size(); i
!= e
; ++i
) {
2054 unsigned Reg
= CSI
[i
].getReg();
2056 if (PPC::VRSAVERCRegClass
.contains(Reg
)) {
2057 int FI
= CSI
[i
].getFrameIdx();
2059 MFI
.setObjectOffset(FI
, LowerBound
+ MFI
.getObjectOffset(FI
));
2063 LowerBound
-= 4; // The VRSAVE save area is always 4 bytes long.
2066 // Both Altivec and SPE have the same alignment and padding requirements
2067 // within the stack frame.
2068 if (HasVRSaveArea
) {
2069 // Insert alignment padding, we need 16-byte alignment. Note: for positive
2070 // number the alignment formula is : y = (x + (n-1)) & (~(n-1)). But since
2071 // we are using negative number here (the stack grows downward). We should
2072 // use formula : y = x & (~(n-1)). Where x is the size before aligning, n
2073 // is the alignment size ( n = 16 here) and y is the size after aligning.
2074 assert(LowerBound
<= 0 && "Expect LowerBound have a non-positive value!");
2075 LowerBound
&= ~(15);
2077 for (unsigned i
= 0, e
= VRegs
.size(); i
!= e
; ++i
) {
2078 int FI
= VRegs
[i
].getFrameIdx();
2080 MFI
.setObjectOffset(FI
, LowerBound
+ MFI
.getObjectOffset(FI
));
2084 addScavengingSpillSlot(MF
, RS
);
2088 PPCFrameLowering::addScavengingSpillSlot(MachineFunction
&MF
,
2089 RegScavenger
*RS
) const {
2090 // Reserve a slot closest to SP or frame pointer if we have a dynalloc or
2091 // a large stack, which will require scavenging a register to materialize a
2094 // We need to have a scavenger spill slot for spills if the frame size is
2095 // large. In case there is no free register for large-offset addressing,
2096 // this slot is used for the necessary emergency spill. Also, we need the
2097 // slot for dynamic stack allocations.
2099 // The scavenger might be invoked if the frame offset does not fit into
2100 // the 16-bit immediate. We don't know the complete frame size here
2101 // because we've not yet computed callee-saved register spills or the
2102 // needed alignment padding.
2103 unsigned StackSize
= determineFrameLayout(MF
, true);
2104 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
2105 if (MFI
.hasVarSizedObjects() || spillsCR(MF
) || spillsVRSAVE(MF
) ||
2106 hasNonRISpills(MF
) || (hasSpills(MF
) && !isInt
<16>(StackSize
))) {
2107 const TargetRegisterClass
&GPRC
= PPC::GPRCRegClass
;
2108 const TargetRegisterClass
&G8RC
= PPC::G8RCRegClass
;
2109 const TargetRegisterClass
&RC
= Subtarget
.isPPC64() ? G8RC
: GPRC
;
2110 const TargetRegisterInfo
&TRI
= *Subtarget
.getRegisterInfo();
2111 unsigned Size
= TRI
.getSpillSize(RC
);
2112 unsigned Align
= TRI
.getSpillAlignment(RC
);
2113 RS
->addScavengingFrameIndex(MFI
.CreateStackObject(Size
, Align
, false));
2115 // Might we have over-aligned allocas?
2116 bool HasAlVars
= MFI
.hasVarSizedObjects() &&
2117 MFI
.getMaxAlignment() > getStackAlignment();
2119 // These kinds of spills might need two registers.
2120 if (spillsCR(MF
) || spillsVRSAVE(MF
) || HasAlVars
)
2121 RS
->addScavengingFrameIndex(MFI
.CreateStackObject(Size
, Align
, false));
2126 // This function checks if a callee saved gpr can be spilled to a volatile
2127 // vector register. This occurs for leaf functions when the option
2128 // ppc-enable-pe-vector-spills is enabled. If there are any remaining registers
2129 // which were not spilled to vectors, return false so the target independent
2130 // code can handle them by assigning a FrameIdx to a stack slot.
2131 bool PPCFrameLowering::assignCalleeSavedSpillSlots(
2132 MachineFunction
&MF
, const TargetRegisterInfo
*TRI
,
2133 std::vector
<CalleeSavedInfo
> &CSI
) const {
2136 return true; // Early exit if no callee saved registers are modified!
2138 // Early exit if cannot spill gprs to volatile vector registers.
2139 MachineFrameInfo
&MFI
= MF
.getFrameInfo();
2140 if (!EnablePEVectorSpills
|| MFI
.hasCalls() || !Subtarget
.hasP9Vector())
2143 // Build a BitVector of VSRs that can be used for spilling GPRs.
2144 BitVector BVAllocatable
= TRI
->getAllocatableSet(MF
);
2145 BitVector
BVCalleeSaved(TRI
->getNumRegs());
2146 const PPCRegisterInfo
*RegInfo
= Subtarget
.getRegisterInfo();
2147 const MCPhysReg
*CSRegs
= RegInfo
->getCalleeSavedRegs(&MF
);
2148 for (unsigned i
= 0; CSRegs
[i
]; ++i
)
2149 BVCalleeSaved
.set(CSRegs
[i
]);
2151 for (unsigned Reg
: BVAllocatable
.set_bits()) {
2152 // Set to 0 if the register is not a volatile VF/F8 register, or if it is
2153 // used in the function.
2154 if (BVCalleeSaved
[Reg
] ||
2155 (!PPC::F8RCRegClass
.contains(Reg
) &&
2156 !PPC::VFRCRegClass
.contains(Reg
)) ||
2157 (MF
.getRegInfo().isPhysRegUsed(Reg
)))
2158 BVAllocatable
.reset(Reg
);
2161 bool AllSpilledToReg
= true;
2162 for (auto &CS
: CSI
) {
2163 if (BVAllocatable
.none())
2166 unsigned Reg
= CS
.getReg();
2167 if (!PPC::G8RCRegClass
.contains(Reg
) && !PPC::GPRCRegClass
.contains(Reg
)) {
2168 AllSpilledToReg
= false;
2172 unsigned VolatileVFReg
= BVAllocatable
.find_first();
2173 if (VolatileVFReg
< BVAllocatable
.size()) {
2174 CS
.setDstReg(VolatileVFReg
);
2175 BVAllocatable
.reset(VolatileVFReg
);
2177 AllSpilledToReg
= false;
2180 return AllSpilledToReg
;
2185 PPCFrameLowering::spillCalleeSavedRegisters(MachineBasicBlock
&MBB
,
2186 MachineBasicBlock::iterator MI
,
2187 const std::vector
<CalleeSavedInfo
> &CSI
,
2188 const TargetRegisterInfo
*TRI
) const {
2190 // Currently, this function only handles SVR4 32- and 64-bit ABIs.
2191 // Return false otherwise to maintain pre-existing behavior.
2192 if (!Subtarget
.isSVR4ABI())
2195 MachineFunction
*MF
= MBB
.getParent();
2196 const PPCInstrInfo
&TII
= *Subtarget
.getInstrInfo();
2197 PPCFunctionInfo
*FI
= MF
->getInfo
<PPCFunctionInfo
>();
2198 bool MustSaveTOC
= FI
->mustSaveTOC();
2200 bool CRSpilled
= false;
2201 MachineInstrBuilder CRMIB
;
2203 for (unsigned i
= 0, e
= CSI
.size(); i
!= e
; ++i
) {
2204 unsigned Reg
= CSI
[i
].getReg();
2205 // Only Darwin actually uses the VRSAVE register, but it can still appear
2206 // here if, for example, @llvm.eh.unwind.init() is used. If we're not on
2207 // Darwin, ignore it.
2208 if (Reg
== PPC::VRSAVE
&& !Subtarget
.isDarwinABI())
2211 // CR2 through CR4 are the nonvolatile CR fields.
2212 bool IsCRField
= PPC::CR2
<= Reg
&& Reg
<= PPC::CR4
;
2214 // Add the callee-saved register as live-in; it's killed at the spill.
2215 // Do not do this for callee-saved registers that are live-in to the
2216 // function because they will already be marked live-in and this will be
2217 // adding it for a second time. It is an error to add the same register
2218 // to the set more than once.
2219 const MachineRegisterInfo
&MRI
= MF
->getRegInfo();
2220 bool IsLiveIn
= MRI
.isLiveIn(Reg
);
2224 if (CRSpilled
&& IsCRField
) {
2225 CRMIB
.addReg(Reg
, RegState::ImplicitKill
);
2229 // The actual spill will happen in the prologue.
2230 if ((Reg
== PPC::X2
|| Reg
== PPC::R2
) && MustSaveTOC
)
2233 // Insert the spill to the stack frame.
2235 PPCFunctionInfo
*FuncInfo
= MF
->getInfo
<PPCFunctionInfo
>();
2236 if (Subtarget
.isPPC64()) {
2237 // The actual spill will happen at the start of the prologue.
2238 FuncInfo
->addMustSaveCR(Reg
);
2241 FuncInfo
->setSpillsCR();
2243 // 32-bit: FP-relative. Note that we made sure CR2-CR4 all have
2244 // the same frame index in PPCRegisterInfo::hasReservedSpillSlot.
2245 CRMIB
= BuildMI(*MF
, DL
, TII
.get(PPC::MFCR
), PPC::R12
)
2246 .addReg(Reg
, RegState::ImplicitKill
);
2248 MBB
.insert(MI
, CRMIB
);
2249 MBB
.insert(MI
, addFrameReference(BuildMI(*MF
, DL
, TII
.get(PPC::STW
))
2251 getKillRegState(true)),
2252 CSI
[i
].getFrameIdx()));
2255 if (CSI
[i
].isSpilledToReg()) {
2257 BuildMI(MBB
, MI
, DL
, TII
.get(PPC::MTVSRD
), CSI
[i
].getDstReg())
2258 .addReg(Reg
, getKillRegState(true));
2260 const TargetRegisterClass
*RC
= TRI
->getMinimalPhysRegClass(Reg
);
2261 // Use !IsLiveIn for the kill flag.
2262 // We do not want to kill registers that are live in this function
2263 // before their use because they will become undefined registers.
2264 TII
.storeRegToStackSlot(MBB
, MI
, Reg
, !IsLiveIn
,
2265 CSI
[i
].getFrameIdx(), RC
, TRI
);
2273 restoreCRs(bool isPPC64
, bool is31
,
2274 bool CR2Spilled
, bool CR3Spilled
, bool CR4Spilled
,
2275 MachineBasicBlock
&MBB
, MachineBasicBlock::iterator MI
,
2276 const std::vector
<CalleeSavedInfo
> &CSI
, unsigned CSIIndex
) {
2278 MachineFunction
*MF
= MBB
.getParent();
2279 const PPCInstrInfo
&TII
= *MF
->getSubtarget
<PPCSubtarget
>().getInstrInfo();
2281 unsigned RestoreOp
, MoveReg
;
2284 // This is handled during epilogue generation.
2287 // 32-bit: FP-relative
2288 MBB
.insert(MI
, addFrameReference(BuildMI(*MF
, DL
, TII
.get(PPC::LWZ
),
2290 CSI
[CSIIndex
].getFrameIdx()));
2291 RestoreOp
= PPC::MTOCRF
;
2296 MBB
.insert(MI
, BuildMI(*MF
, DL
, TII
.get(RestoreOp
), PPC::CR2
)
2297 .addReg(MoveReg
, getKillRegState(!CR3Spilled
&& !CR4Spilled
)));
2300 MBB
.insert(MI
, BuildMI(*MF
, DL
, TII
.get(RestoreOp
), PPC::CR3
)
2301 .addReg(MoveReg
, getKillRegState(!CR4Spilled
)));
2304 MBB
.insert(MI
, BuildMI(*MF
, DL
, TII
.get(RestoreOp
), PPC::CR4
)
2305 .addReg(MoveReg
, getKillRegState(true)));
2308 MachineBasicBlock::iterator
PPCFrameLowering::
2309 eliminateCallFramePseudoInstr(MachineFunction
&MF
, MachineBasicBlock
&MBB
,
2310 MachineBasicBlock::iterator I
) const {
2311 const TargetInstrInfo
&TII
= *Subtarget
.getInstrInfo();
2312 if (MF
.getTarget().Options
.GuaranteedTailCallOpt
&&
2313 I
->getOpcode() == PPC::ADJCALLSTACKUP
) {
2314 // Add (actually subtract) back the amount the callee popped on return.
2315 if (int CalleeAmt
= I
->getOperand(1).getImm()) {
2316 bool is64Bit
= Subtarget
.isPPC64();
2318 unsigned StackReg
= is64Bit
? PPC::X1
: PPC::R1
;
2319 unsigned TmpReg
= is64Bit
? PPC::X0
: PPC::R0
;
2320 unsigned ADDIInstr
= is64Bit
? PPC::ADDI8
: PPC::ADDI
;
2321 unsigned ADDInstr
= is64Bit
? PPC::ADD8
: PPC::ADD4
;
2322 unsigned LISInstr
= is64Bit
? PPC::LIS8
: PPC::LIS
;
2323 unsigned ORIInstr
= is64Bit
? PPC::ORI8
: PPC::ORI
;
2324 const DebugLoc
&dl
= I
->getDebugLoc();
2326 if (isInt
<16>(CalleeAmt
)) {
2327 BuildMI(MBB
, I
, dl
, TII
.get(ADDIInstr
), StackReg
)
2328 .addReg(StackReg
, RegState::Kill
)
2331 MachineBasicBlock::iterator MBBI
= I
;
2332 BuildMI(MBB
, MBBI
, dl
, TII
.get(LISInstr
), TmpReg
)
2333 .addImm(CalleeAmt
>> 16);
2334 BuildMI(MBB
, MBBI
, dl
, TII
.get(ORIInstr
), TmpReg
)
2335 .addReg(TmpReg
, RegState::Kill
)
2336 .addImm(CalleeAmt
& 0xFFFF);
2337 BuildMI(MBB
, MBBI
, dl
, TII
.get(ADDInstr
), StackReg
)
2338 .addReg(StackReg
, RegState::Kill
)
2343 // Simply discard ADJCALLSTACKDOWN, ADJCALLSTACKUP instructions.
2344 return MBB
.erase(I
);
2348 PPCFrameLowering::restoreCalleeSavedRegisters(MachineBasicBlock
&MBB
,
2349 MachineBasicBlock::iterator MI
,
2350 std::vector
<CalleeSavedInfo
> &CSI
,
2351 const TargetRegisterInfo
*TRI
) const {
2353 // Currently, this function only handles SVR4 32- and 64-bit ABIs.
2354 // Return false otherwise to maintain pre-existing behavior.
2355 if (!Subtarget
.isSVR4ABI())
2358 MachineFunction
*MF
= MBB
.getParent();
2359 const PPCInstrInfo
&TII
= *Subtarget
.getInstrInfo();
2360 PPCFunctionInfo
*FI
= MF
->getInfo
<PPCFunctionInfo
>();
2361 bool MustSaveTOC
= FI
->mustSaveTOC();
2362 bool CR2Spilled
= false;
2363 bool CR3Spilled
= false;
2364 bool CR4Spilled
= false;
2365 unsigned CSIIndex
= 0;
2367 // Initialize insertion-point logic; we will be restoring in reverse
2369 MachineBasicBlock::iterator I
= MI
, BeforeI
= I
;
2370 bool AtStart
= I
== MBB
.begin();
2375 for (unsigned i
= 0, e
= CSI
.size(); i
!= e
; ++i
) {
2376 unsigned Reg
= CSI
[i
].getReg();
2378 // Only Darwin actually uses the VRSAVE register, but it can still appear
2379 // here if, for example, @llvm.eh.unwind.init() is used. If we're not on
2380 // Darwin, ignore it.
2381 if (Reg
== PPC::VRSAVE
&& !Subtarget
.isDarwinABI())
2384 if ((Reg
== PPC::X2
|| Reg
== PPC::R2
) && MustSaveTOC
)
2387 if (Reg
== PPC::CR2
) {
2389 // The spill slot is associated only with CR2, which is the
2390 // first nonvolatile spilled. Save it here.
2393 } else if (Reg
== PPC::CR3
) {
2396 } else if (Reg
== PPC::CR4
) {
2400 // When we first encounter a non-CR register after seeing at
2401 // least one CR register, restore all spilled CRs together.
2402 if ((CR2Spilled
|| CR3Spilled
|| CR4Spilled
)
2403 && !(PPC::CR2
<= Reg
&& Reg
<= PPC::CR4
)) {
2404 bool is31
= needsFP(*MF
);
2405 restoreCRs(Subtarget
.isPPC64(), is31
,
2406 CR2Spilled
, CR3Spilled
, CR4Spilled
,
2407 MBB
, I
, CSI
, CSIIndex
);
2408 CR2Spilled
= CR3Spilled
= CR4Spilled
= false;
2411 if (CSI
[i
].isSpilledToReg()) {
2414 BuildMI(MBB
, I
, DL
, TII
.get(PPC::MFVSRD
), Reg
)
2415 .addReg(CSI
[i
].getDstReg(), getKillRegState(true));
2417 // Default behavior for non-CR saves.
2418 const TargetRegisterClass
*RC
= TRI
->getMinimalPhysRegClass(Reg
);
2419 TII
.loadRegFromStackSlot(MBB
, I
, Reg
, CSI
[i
].getFrameIdx(), RC
, TRI
);
2420 assert(I
!= MBB
.begin() &&
2421 "loadRegFromStackSlot didn't insert any code!");
2425 // Insert in reverse order.
2434 // If we haven't yet spilled the CRs, do so now.
2435 if (CR2Spilled
|| CR3Spilled
|| CR4Spilled
) {
2436 bool is31
= needsFP(*MF
);
2437 restoreCRs(Subtarget
.isPPC64(), is31
, CR2Spilled
, CR3Spilled
, CR4Spilled
,
2438 MBB
, I
, CSI
, CSIIndex
);
2444 unsigned PPCFrameLowering::getTOCSaveOffset() const {
2445 if (Subtarget
.isAIXABI())
2446 // TOC save/restore is normally handled by the linker.
2447 // Indirect calls should hit this limitation.
2448 report_fatal_error("TOC save is not implemented on AIX yet.");
2449 return TOCSaveOffset
;
2452 unsigned PPCFrameLowering::getFramePointerSaveOffset() const {
2453 if (Subtarget
.isAIXABI())
2454 report_fatal_error("FramePointer is not implemented on AIX yet.");
2455 return FramePointerSaveOffset
;
2458 unsigned PPCFrameLowering::getBasePointerSaveOffset() const {
2459 if (Subtarget
.isAIXABI())
2460 report_fatal_error("BasePointer is not implemented on AIX yet.");
2461 return BasePointerSaveOffset
;
2464 bool PPCFrameLowering::enableShrinkWrapping(const MachineFunction
&MF
) const {
2465 if (MF
.getInfo
<PPCFunctionInfo
>()->shrinkWrapDisabled())
2467 return (MF
.getSubtarget
<PPCSubtarget
>().isSVR4ABI() &&
2468 MF
.getSubtarget
<PPCSubtarget
>().isPPC64());