forked from OSchip/llvm-project
1688 lines
61 KiB
C++
1688 lines
61 KiB
C++
//===-- X86FloatingPoint.cpp - Floating point Reg -> Stack converter ------===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines the pass which converts floating point instructions from
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// pseudo registers into register stack instructions. This pass uses live
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// variable information to indicate where the FPn registers are used and their
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// lifetimes.
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//
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// The x87 hardware tracks liveness of the stack registers, so it is necessary
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// to implement exact liveness tracking between basic blocks. The CFG edges are
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// partitioned into bundles where the same FP registers must be live in
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// identical stack positions. Instructions are inserted at the end of each basic
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// block to rearrange the live registers to match the outgoing bundle.
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//
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// This approach avoids splitting critical edges at the potential cost of more
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// live register shuffling instructions when critical edges are present.
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//
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//===----------------------------------------------------------------------===//
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#include "X86.h"
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#include "X86InstrInfo.h"
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#include "llvm/ADT/DepthFirstIterator.h"
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#include "llvm/ADT/STLExtras.h"
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#include "llvm/ADT/SmallPtrSet.h"
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#include "llvm/ADT/SmallSet.h"
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#include "llvm/ADT/SmallVector.h"
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#include "llvm/ADT/Statistic.h"
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#include "llvm/CodeGen/EdgeBundles.h"
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#include "llvm/CodeGen/MachineFunctionPass.h"
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#include "llvm/CodeGen/MachineInstrBuilder.h"
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#include "llvm/CodeGen/MachineRegisterInfo.h"
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#include "llvm/CodeGen/LivePhysRegs.h"
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#include "llvm/CodeGen/Passes.h"
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#include "llvm/IR/InlineAsm.h"
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#include "llvm/Support/Debug.h"
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#include "llvm/Support/ErrorHandling.h"
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#include "llvm/Support/raw_ostream.h"
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#include "llvm/Target/TargetInstrInfo.h"
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#include "llvm/Target/TargetMachine.h"
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#include "llvm/Target/TargetSubtargetInfo.h"
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#include <algorithm>
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#include <bitset>
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using namespace llvm;
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#define DEBUG_TYPE "x86-codegen"
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STATISTIC(NumFXCH, "Number of fxch instructions inserted");
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STATISTIC(NumFP , "Number of floating point instructions");
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namespace {
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const unsigned ScratchFPReg = 7;
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struct FPS : public MachineFunctionPass {
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static char ID;
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FPS() : MachineFunctionPass(ID) {
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initializeEdgeBundlesPass(*PassRegistry::getPassRegistry());
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// This is really only to keep valgrind quiet.
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// The logic in isLive() is too much for it.
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memset(Stack, 0, sizeof(Stack));
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memset(RegMap, 0, sizeof(RegMap));
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}
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void getAnalysisUsage(AnalysisUsage &AU) const override {
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AU.setPreservesCFG();
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AU.addRequired<EdgeBundles>();
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AU.addPreservedID(MachineLoopInfoID);
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AU.addPreservedID(MachineDominatorsID);
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MachineFunctionPass::getAnalysisUsage(AU);
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}
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bool runOnMachineFunction(MachineFunction &MF) override;
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const char *getPassName() const override { return "X86 FP Stackifier"; }
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private:
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const TargetInstrInfo *TII; // Machine instruction info.
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// Two CFG edges are related if they leave the same block, or enter the same
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// block. The transitive closure of an edge under this relation is a
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// LiveBundle. It represents a set of CFG edges where the live FP stack
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// registers must be allocated identically in the x87 stack.
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//
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// A LiveBundle is usually all the edges leaving a block, or all the edges
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// entering a block, but it can contain more edges if critical edges are
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// present.
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//
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// The set of live FP registers in a LiveBundle is calculated by bundleCFG,
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// but the exact mapping of FP registers to stack slots is fixed later.
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struct LiveBundle {
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// Bit mask of live FP registers. Bit 0 = FP0, bit 1 = FP1, &c.
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unsigned Mask;
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// Number of pre-assigned live registers in FixStack. This is 0 when the
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// stack order has not yet been fixed.
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unsigned FixCount;
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// Assigned stack order for live-in registers.
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// FixStack[i] == getStackEntry(i) for all i < FixCount.
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unsigned char FixStack[8];
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LiveBundle() : Mask(0), FixCount(0) {}
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// Have the live registers been assigned a stack order yet?
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bool isFixed() const { return !Mask || FixCount; }
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};
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// Numbered LiveBundle structs. LiveBundles[0] is used for all CFG edges
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// with no live FP registers.
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SmallVector<LiveBundle, 8> LiveBundles;
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// The edge bundle analysis provides indices into the LiveBundles vector.
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EdgeBundles *Bundles;
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// Return a bitmask of FP registers in block's live-in list.
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static unsigned calcLiveInMask(MachineBasicBlock *MBB) {
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unsigned Mask = 0;
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for (MachineBasicBlock::livein_iterator I = MBB->livein_begin(),
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E = MBB->livein_end(); I != E; ++I) {
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unsigned Reg = *I;
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if (Reg < X86::FP0 || Reg > X86::FP6)
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continue;
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Mask |= 1 << (Reg - X86::FP0);
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}
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return Mask;
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}
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// Partition all the CFG edges into LiveBundles.
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void bundleCFG(MachineFunction &MF);
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MachineBasicBlock *MBB; // Current basic block
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// The hardware keeps track of how many FP registers are live, so we have
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// to model that exactly. Usually, each live register corresponds to an
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// FP<n> register, but when dealing with calls, returns, and inline
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// assembly, it is sometimes necessary to have live scratch registers.
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unsigned Stack[8]; // FP<n> Registers in each stack slot...
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unsigned StackTop; // The current top of the FP stack.
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enum {
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NumFPRegs = 8 // Including scratch pseudo-registers.
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};
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// For each live FP<n> register, point to its Stack[] entry.
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// The first entries correspond to FP0-FP6, the rest are scratch registers
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// used when we need slightly different live registers than what the
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// register allocator thinks.
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unsigned RegMap[NumFPRegs];
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// Set up our stack model to match the incoming registers to MBB.
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void setupBlockStack();
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// Shuffle live registers to match the expectations of successor blocks.
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void finishBlockStack();
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#if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP)
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void dumpStack() const {
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dbgs() << "Stack contents:";
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for (unsigned i = 0; i != StackTop; ++i) {
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dbgs() << " FP" << Stack[i];
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assert(RegMap[Stack[i]] == i && "Stack[] doesn't match RegMap[]!");
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}
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}
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#endif
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/// getSlot - Return the stack slot number a particular register number is
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/// in.
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unsigned getSlot(unsigned RegNo) const {
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assert(RegNo < NumFPRegs && "Regno out of range!");
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return RegMap[RegNo];
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}
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/// isLive - Is RegNo currently live in the stack?
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bool isLive(unsigned RegNo) const {
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unsigned Slot = getSlot(RegNo);
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return Slot < StackTop && Stack[Slot] == RegNo;
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}
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/// getStackEntry - Return the X86::FP<n> register in register ST(i).
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unsigned getStackEntry(unsigned STi) const {
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if (STi >= StackTop)
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report_fatal_error("Access past stack top!");
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return Stack[StackTop-1-STi];
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}
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/// getSTReg - Return the X86::ST(i) register which contains the specified
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/// FP<RegNo> register.
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unsigned getSTReg(unsigned RegNo) const {
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return StackTop - 1 - getSlot(RegNo) + X86::ST0;
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}
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// pushReg - Push the specified FP<n> register onto the stack.
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void pushReg(unsigned Reg) {
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assert(Reg < NumFPRegs && "Register number out of range!");
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if (StackTop >= 8)
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report_fatal_error("Stack overflow!");
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Stack[StackTop] = Reg;
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RegMap[Reg] = StackTop++;
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}
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bool isAtTop(unsigned RegNo) const { return getSlot(RegNo) == StackTop-1; }
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void moveToTop(unsigned RegNo, MachineBasicBlock::iterator I) {
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DebugLoc dl = I == MBB->end() ? DebugLoc() : I->getDebugLoc();
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if (isAtTop(RegNo)) return;
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unsigned STReg = getSTReg(RegNo);
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unsigned RegOnTop = getStackEntry(0);
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// Swap the slots the regs are in.
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std::swap(RegMap[RegNo], RegMap[RegOnTop]);
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// Swap stack slot contents.
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if (RegMap[RegOnTop] >= StackTop)
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report_fatal_error("Access past stack top!");
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std::swap(Stack[RegMap[RegOnTop]], Stack[StackTop-1]);
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// Emit an fxch to update the runtime processors version of the state.
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BuildMI(*MBB, I, dl, TII->get(X86::XCH_F)).addReg(STReg);
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++NumFXCH;
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}
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void duplicateToTop(unsigned RegNo, unsigned AsReg, MachineInstr *I) {
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DebugLoc dl = I == MBB->end() ? DebugLoc() : I->getDebugLoc();
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unsigned STReg = getSTReg(RegNo);
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pushReg(AsReg); // New register on top of stack
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BuildMI(*MBB, I, dl, TII->get(X86::LD_Frr)).addReg(STReg);
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}
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/// popStackAfter - Pop the current value off of the top of the FP stack
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/// after the specified instruction.
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void popStackAfter(MachineBasicBlock::iterator &I);
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/// freeStackSlotAfter - Free the specified register from the register
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/// stack, so that it is no longer in a register. If the register is
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/// currently at the top of the stack, we just pop the current instruction,
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/// otherwise we store the current top-of-stack into the specified slot,
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/// then pop the top of stack.
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void freeStackSlotAfter(MachineBasicBlock::iterator &I, unsigned Reg);
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/// freeStackSlotBefore - Just the pop, no folding. Return the inserted
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/// instruction.
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MachineBasicBlock::iterator
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freeStackSlotBefore(MachineBasicBlock::iterator I, unsigned FPRegNo);
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/// Adjust the live registers to be the set in Mask.
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void adjustLiveRegs(unsigned Mask, MachineBasicBlock::iterator I);
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/// Shuffle the top FixCount stack entries such that FP reg FixStack[0] is
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/// st(0), FP reg FixStack[1] is st(1) etc.
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void shuffleStackTop(const unsigned char *FixStack, unsigned FixCount,
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MachineBasicBlock::iterator I);
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bool processBasicBlock(MachineFunction &MF, MachineBasicBlock &MBB);
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void handleCall(MachineBasicBlock::iterator &I);
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void handleZeroArgFP(MachineBasicBlock::iterator &I);
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void handleOneArgFP(MachineBasicBlock::iterator &I);
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void handleOneArgFPRW(MachineBasicBlock::iterator &I);
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void handleTwoArgFP(MachineBasicBlock::iterator &I);
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void handleCompareFP(MachineBasicBlock::iterator &I);
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void handleCondMovFP(MachineBasicBlock::iterator &I);
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void handleSpecialFP(MachineBasicBlock::iterator &I);
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// Check if a COPY instruction is using FP registers.
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static bool isFPCopy(MachineInstr *MI) {
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unsigned DstReg = MI->getOperand(0).getReg();
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unsigned SrcReg = MI->getOperand(1).getReg();
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return X86::RFP80RegClass.contains(DstReg) ||
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X86::RFP80RegClass.contains(SrcReg);
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}
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void setKillFlags(MachineBasicBlock &MBB) const;
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};
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char FPS::ID = 0;
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}
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FunctionPass *llvm::createX86FloatingPointStackifierPass() { return new FPS(); }
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/// getFPReg - Return the X86::FPx register number for the specified operand.
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/// For example, this returns 3 for X86::FP3.
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static unsigned getFPReg(const MachineOperand &MO) {
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assert(MO.isReg() && "Expected an FP register!");
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unsigned Reg = MO.getReg();
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assert(Reg >= X86::FP0 && Reg <= X86::FP6 && "Expected FP register!");
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return Reg - X86::FP0;
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}
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/// runOnMachineFunction - Loop over all of the basic blocks, transforming FP
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/// register references into FP stack references.
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///
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bool FPS::runOnMachineFunction(MachineFunction &MF) {
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// We only need to run this pass if there are any FP registers used in this
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// function. If it is all integer, there is nothing for us to do!
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bool FPIsUsed = false;
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assert(X86::FP6 == X86::FP0+6 && "Register enums aren't sorted right!");
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for (unsigned i = 0; i <= 6; ++i)
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if (MF.getRegInfo().isPhysRegUsed(X86::FP0+i)) {
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FPIsUsed = true;
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break;
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}
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// Early exit.
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if (!FPIsUsed) return false;
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Bundles = &getAnalysis<EdgeBundles>();
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TII = MF.getSubtarget().getInstrInfo();
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// Prepare cross-MBB liveness.
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bundleCFG(MF);
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StackTop = 0;
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// Process the function in depth first order so that we process at least one
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// of the predecessors for every reachable block in the function.
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SmallPtrSet<MachineBasicBlock*, 8> Processed;
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MachineBasicBlock *Entry = MF.begin();
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bool Changed = false;
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for (MachineBasicBlock *BB : depth_first_ext(Entry, Processed))
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Changed |= processBasicBlock(MF, *BB);
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// Process any unreachable blocks in arbitrary order now.
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if (MF.size() != Processed.size())
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for (MachineFunction::iterator BB = MF.begin(), E = MF.end(); BB != E; ++BB)
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if (Processed.insert(BB).second)
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Changed |= processBasicBlock(MF, *BB);
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LiveBundles.clear();
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return Changed;
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}
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/// bundleCFG - Scan all the basic blocks to determine consistent live-in and
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/// live-out sets for the FP registers. Consistent means that the set of
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/// registers live-out from a block is identical to the live-in set of all
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/// successors. This is not enforced by the normal live-in lists since
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/// registers may be implicitly defined, or not used by all successors.
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void FPS::bundleCFG(MachineFunction &MF) {
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assert(LiveBundles.empty() && "Stale data in LiveBundles");
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LiveBundles.resize(Bundles->getNumBundles());
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// Gather the actual live-in masks for all MBBs.
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for (MachineFunction::iterator I = MF.begin(), E = MF.end(); I != E; ++I) {
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MachineBasicBlock *MBB = I;
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const unsigned Mask = calcLiveInMask(MBB);
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if (!Mask)
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continue;
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// Update MBB ingoing bundle mask.
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LiveBundles[Bundles->getBundle(MBB->getNumber(), false)].Mask |= Mask;
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}
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}
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/// processBasicBlock - Loop over all of the instructions in the basic block,
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/// transforming FP instructions into their stack form.
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///
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bool FPS::processBasicBlock(MachineFunction &MF, MachineBasicBlock &BB) {
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bool Changed = false;
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MBB = &BB;
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setKillFlags(BB);
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setupBlockStack();
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for (MachineBasicBlock::iterator I = BB.begin(); I != BB.end(); ++I) {
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MachineInstr *MI = I;
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uint64_t Flags = MI->getDesc().TSFlags;
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unsigned FPInstClass = Flags & X86II::FPTypeMask;
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if (MI->isInlineAsm())
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FPInstClass = X86II::SpecialFP;
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if (MI->isCopy() && isFPCopy(MI))
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FPInstClass = X86II::SpecialFP;
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if (MI->isImplicitDef() &&
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X86::RFP80RegClass.contains(MI->getOperand(0).getReg()))
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FPInstClass = X86II::SpecialFP;
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if (MI->isCall())
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FPInstClass = X86II::SpecialFP;
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if (FPInstClass == X86II::NotFP)
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continue; // Efficiently ignore non-fp insts!
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MachineInstr *PrevMI = nullptr;
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if (I != BB.begin())
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PrevMI = std::prev(I);
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++NumFP; // Keep track of # of pseudo instrs
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DEBUG(dbgs() << "\nFPInst:\t" << *MI);
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// Get dead variables list now because the MI pointer may be deleted as part
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// of processing!
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SmallVector<unsigned, 8> DeadRegs;
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for (unsigned i = 0, e = MI->getNumOperands(); i != e; ++i) {
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const MachineOperand &MO = MI->getOperand(i);
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if (MO.isReg() && MO.isDead())
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DeadRegs.push_back(MO.getReg());
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}
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switch (FPInstClass) {
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case X86II::ZeroArgFP: handleZeroArgFP(I); break;
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case X86II::OneArgFP: handleOneArgFP(I); break; // fstp ST(0)
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case X86II::OneArgFPRW: handleOneArgFPRW(I); break; // ST(0) = fsqrt(ST(0))
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case X86II::TwoArgFP: handleTwoArgFP(I); break;
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case X86II::CompareFP: handleCompareFP(I); break;
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case X86II::CondMovFP: handleCondMovFP(I); break;
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case X86II::SpecialFP: handleSpecialFP(I); break;
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default: llvm_unreachable("Unknown FP Type!");
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}
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// Check to see if any of the values defined by this instruction are dead
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// after definition. If so, pop them.
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for (unsigned i = 0, e = DeadRegs.size(); i != e; ++i) {
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unsigned Reg = DeadRegs[i];
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// Check if Reg is live on the stack. An inline-asm register operand that
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// is in the clobber list and marked dead might not be live on the stack.
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if (Reg >= X86::FP0 && Reg <= X86::FP6 && isLive(Reg-X86::FP0)) {
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DEBUG(dbgs() << "Register FP#" << Reg-X86::FP0 << " is dead!\n");
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freeStackSlotAfter(I, Reg-X86::FP0);
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}
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}
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// Print out all of the instructions expanded to if -debug
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DEBUG(
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MachineBasicBlock::iterator PrevI(PrevMI);
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if (I == PrevI) {
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dbgs() << "Just deleted pseudo instruction\n";
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} else {
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MachineBasicBlock::iterator Start = I;
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// Rewind to first instruction newly inserted.
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while (Start != BB.begin() && std::prev(Start) != PrevI) --Start;
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dbgs() << "Inserted instructions:\n\t";
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Start->print(dbgs(), &MF.getTarget());
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while (++Start != std::next(I)) {}
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}
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dumpStack();
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);
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(void)PrevMI;
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Changed = true;
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}
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finishBlockStack();
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return Changed;
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}
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/// setupBlockStack - Use the live bundles to set up our model of the stack
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/// to match predecessors' live out stack.
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void FPS::setupBlockStack() {
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DEBUG(dbgs() << "\nSetting up live-ins for BB#" << MBB->getNumber()
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<< " derived from " << MBB->getName() << ".\n");
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StackTop = 0;
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// Get the live-in bundle for MBB.
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const LiveBundle &Bundle =
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LiveBundles[Bundles->getBundle(MBB->getNumber(), false)];
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if (!Bundle.Mask) {
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DEBUG(dbgs() << "Block has no FP live-ins.\n");
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return;
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}
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// Depth-first iteration should ensure that we always have an assigned stack.
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assert(Bundle.isFixed() && "Reached block before any predecessors");
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// Push the fixed live-in registers.
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for (unsigned i = Bundle.FixCount; i > 0; --i) {
|
|
MBB->addLiveIn(X86::ST0+i-1);
|
|
DEBUG(dbgs() << "Live-in st(" << (i-1) << "): %FP"
|
|
<< unsigned(Bundle.FixStack[i-1]) << '\n');
|
|
pushReg(Bundle.FixStack[i-1]);
|
|
}
|
|
|
|
// Kill off unwanted live-ins. This can happen with a critical edge.
|
|
// FIXME: We could keep these live registers around as zombies. They may need
|
|
// to be revived at the end of a short block. It might save a few instrs.
|
|
adjustLiveRegs(calcLiveInMask(MBB), MBB->begin());
|
|
DEBUG(MBB->dump());
|
|
}
|
|
|
|
/// finishBlockStack - Revive live-outs that are implicitly defined out of
|
|
/// MBB. Shuffle live registers to match the expected fixed stack of any
|
|
/// predecessors, and ensure that all predecessors are expecting the same
|
|
/// stack.
|
|
void FPS::finishBlockStack() {
|
|
// The RET handling below takes care of return blocks for us.
|
|
if (MBB->succ_empty())
|
|
return;
|
|
|
|
DEBUG(dbgs() << "Setting up live-outs for BB#" << MBB->getNumber()
|
|
<< " derived from " << MBB->getName() << ".\n");
|
|
|
|
// Get MBB's live-out bundle.
|
|
unsigned BundleIdx = Bundles->getBundle(MBB->getNumber(), true);
|
|
LiveBundle &Bundle = LiveBundles[BundleIdx];
|
|
|
|
// We may need to kill and define some registers to match successors.
|
|
// FIXME: This can probably be combined with the shuffle below.
|
|
MachineBasicBlock::iterator Term = MBB->getFirstTerminator();
|
|
adjustLiveRegs(Bundle.Mask, Term);
|
|
|
|
if (!Bundle.Mask) {
|
|
DEBUG(dbgs() << "No live-outs.\n");
|
|
return;
|
|
}
|
|
|
|
// Has the stack order been fixed yet?
|
|
DEBUG(dbgs() << "LB#" << BundleIdx << ": ");
|
|
if (Bundle.isFixed()) {
|
|
DEBUG(dbgs() << "Shuffling stack to match.\n");
|
|
shuffleStackTop(Bundle.FixStack, Bundle.FixCount, Term);
|
|
} else {
|
|
// Not fixed yet, we get to choose.
|
|
DEBUG(dbgs() << "Fixing stack order now.\n");
|
|
Bundle.FixCount = StackTop;
|
|
for (unsigned i = 0; i < StackTop; ++i)
|
|
Bundle.FixStack[i] = getStackEntry(i);
|
|
}
|
|
}
|
|
|
|
|
|
//===----------------------------------------------------------------------===//
|
|
// Efficient Lookup Table Support
|
|
//===----------------------------------------------------------------------===//
|
|
|
|
namespace {
|
|
struct TableEntry {
|
|
uint16_t from;
|
|
uint16_t to;
|
|
bool operator<(const TableEntry &TE) const { return from < TE.from; }
|
|
friend bool operator<(const TableEntry &TE, unsigned V) {
|
|
return TE.from < V;
|
|
}
|
|
friend bool LLVM_ATTRIBUTE_UNUSED operator<(unsigned V,
|
|
const TableEntry &TE) {
|
|
return V < TE.from;
|
|
}
|
|
};
|
|
}
|
|
|
|
#ifndef NDEBUG
|
|
static bool TableIsSorted(const TableEntry *Table, unsigned NumEntries) {
|
|
for (unsigned i = 0; i != NumEntries-1; ++i)
|
|
if (!(Table[i] < Table[i+1])) return false;
|
|
return true;
|
|
}
|
|
#endif
|
|
|
|
static int Lookup(const TableEntry *Table, unsigned N, unsigned Opcode) {
|
|
const TableEntry *I = std::lower_bound(Table, Table+N, Opcode);
|
|
if (I != Table+N && I->from == Opcode)
|
|
return I->to;
|
|
return -1;
|
|
}
|
|
|
|
#ifdef NDEBUG
|
|
#define ASSERT_SORTED(TABLE)
|
|
#else
|
|
#define ASSERT_SORTED(TABLE) \
|
|
{ static bool TABLE##Checked = false; \
|
|
if (!TABLE##Checked) { \
|
|
assert(TableIsSorted(TABLE, array_lengthof(TABLE)) && \
|
|
"All lookup tables must be sorted for efficient access!"); \
|
|
TABLE##Checked = true; \
|
|
} \
|
|
}
|
|
#endif
|
|
|
|
//===----------------------------------------------------------------------===//
|
|
// Register File -> Register Stack Mapping Methods
|
|
//===----------------------------------------------------------------------===//
|
|
|
|
// OpcodeTable - Sorted map of register instructions to their stack version.
|
|
// The first element is an register file pseudo instruction, the second is the
|
|
// concrete X86 instruction which uses the register stack.
|
|
//
|
|
static const TableEntry OpcodeTable[] = {
|
|
{ X86::ABS_Fp32 , X86::ABS_F },
|
|
{ X86::ABS_Fp64 , X86::ABS_F },
|
|
{ X86::ABS_Fp80 , X86::ABS_F },
|
|
{ X86::ADD_Fp32m , X86::ADD_F32m },
|
|
{ X86::ADD_Fp64m , X86::ADD_F64m },
|
|
{ X86::ADD_Fp64m32 , X86::ADD_F32m },
|
|
{ X86::ADD_Fp80m32 , X86::ADD_F32m },
|
|
{ X86::ADD_Fp80m64 , X86::ADD_F64m },
|
|
{ X86::ADD_FpI16m32 , X86::ADD_FI16m },
|
|
{ X86::ADD_FpI16m64 , X86::ADD_FI16m },
|
|
{ X86::ADD_FpI16m80 , X86::ADD_FI16m },
|
|
{ X86::ADD_FpI32m32 , X86::ADD_FI32m },
|
|
{ X86::ADD_FpI32m64 , X86::ADD_FI32m },
|
|
{ X86::ADD_FpI32m80 , X86::ADD_FI32m },
|
|
{ X86::CHS_Fp32 , X86::CHS_F },
|
|
{ X86::CHS_Fp64 , X86::CHS_F },
|
|
{ X86::CHS_Fp80 , X86::CHS_F },
|
|
{ X86::CMOVBE_Fp32 , X86::CMOVBE_F },
|
|
{ X86::CMOVBE_Fp64 , X86::CMOVBE_F },
|
|
{ X86::CMOVBE_Fp80 , X86::CMOVBE_F },
|
|
{ X86::CMOVB_Fp32 , X86::CMOVB_F },
|
|
{ X86::CMOVB_Fp64 , X86::CMOVB_F },
|
|
{ X86::CMOVB_Fp80 , X86::CMOVB_F },
|
|
{ X86::CMOVE_Fp32 , X86::CMOVE_F },
|
|
{ X86::CMOVE_Fp64 , X86::CMOVE_F },
|
|
{ X86::CMOVE_Fp80 , X86::CMOVE_F },
|
|
{ X86::CMOVNBE_Fp32 , X86::CMOVNBE_F },
|
|
{ X86::CMOVNBE_Fp64 , X86::CMOVNBE_F },
|
|
{ X86::CMOVNBE_Fp80 , X86::CMOVNBE_F },
|
|
{ X86::CMOVNB_Fp32 , X86::CMOVNB_F },
|
|
{ X86::CMOVNB_Fp64 , X86::CMOVNB_F },
|
|
{ X86::CMOVNB_Fp80 , X86::CMOVNB_F },
|
|
{ X86::CMOVNE_Fp32 , X86::CMOVNE_F },
|
|
{ X86::CMOVNE_Fp64 , X86::CMOVNE_F },
|
|
{ X86::CMOVNE_Fp80 , X86::CMOVNE_F },
|
|
{ X86::CMOVNP_Fp32 , X86::CMOVNP_F },
|
|
{ X86::CMOVNP_Fp64 , X86::CMOVNP_F },
|
|
{ X86::CMOVNP_Fp80 , X86::CMOVNP_F },
|
|
{ X86::CMOVP_Fp32 , X86::CMOVP_F },
|
|
{ X86::CMOVP_Fp64 , X86::CMOVP_F },
|
|
{ X86::CMOVP_Fp80 , X86::CMOVP_F },
|
|
{ X86::COS_Fp32 , X86::COS_F },
|
|
{ X86::COS_Fp64 , X86::COS_F },
|
|
{ X86::COS_Fp80 , X86::COS_F },
|
|
{ X86::DIVR_Fp32m , X86::DIVR_F32m },
|
|
{ X86::DIVR_Fp64m , X86::DIVR_F64m },
|
|
{ X86::DIVR_Fp64m32 , X86::DIVR_F32m },
|
|
{ X86::DIVR_Fp80m32 , X86::DIVR_F32m },
|
|
{ X86::DIVR_Fp80m64 , X86::DIVR_F64m },
|
|
{ X86::DIVR_FpI16m32, X86::DIVR_FI16m},
|
|
{ X86::DIVR_FpI16m64, X86::DIVR_FI16m},
|
|
{ X86::DIVR_FpI16m80, X86::DIVR_FI16m},
|
|
{ X86::DIVR_FpI32m32, X86::DIVR_FI32m},
|
|
{ X86::DIVR_FpI32m64, X86::DIVR_FI32m},
|
|
{ X86::DIVR_FpI32m80, X86::DIVR_FI32m},
|
|
{ X86::DIV_Fp32m , X86::DIV_F32m },
|
|
{ X86::DIV_Fp64m , X86::DIV_F64m },
|
|
{ X86::DIV_Fp64m32 , X86::DIV_F32m },
|
|
{ X86::DIV_Fp80m32 , X86::DIV_F32m },
|
|
{ X86::DIV_Fp80m64 , X86::DIV_F64m },
|
|
{ X86::DIV_FpI16m32 , X86::DIV_FI16m },
|
|
{ X86::DIV_FpI16m64 , X86::DIV_FI16m },
|
|
{ X86::DIV_FpI16m80 , X86::DIV_FI16m },
|
|
{ X86::DIV_FpI32m32 , X86::DIV_FI32m },
|
|
{ X86::DIV_FpI32m64 , X86::DIV_FI32m },
|
|
{ X86::DIV_FpI32m80 , X86::DIV_FI32m },
|
|
{ X86::ILD_Fp16m32 , X86::ILD_F16m },
|
|
{ X86::ILD_Fp16m64 , X86::ILD_F16m },
|
|
{ X86::ILD_Fp16m80 , X86::ILD_F16m },
|
|
{ X86::ILD_Fp32m32 , X86::ILD_F32m },
|
|
{ X86::ILD_Fp32m64 , X86::ILD_F32m },
|
|
{ X86::ILD_Fp32m80 , X86::ILD_F32m },
|
|
{ X86::ILD_Fp64m32 , X86::ILD_F64m },
|
|
{ X86::ILD_Fp64m64 , X86::ILD_F64m },
|
|
{ X86::ILD_Fp64m80 , X86::ILD_F64m },
|
|
{ X86::ISTT_Fp16m32 , X86::ISTT_FP16m},
|
|
{ X86::ISTT_Fp16m64 , X86::ISTT_FP16m},
|
|
{ X86::ISTT_Fp16m80 , X86::ISTT_FP16m},
|
|
{ X86::ISTT_Fp32m32 , X86::ISTT_FP32m},
|
|
{ X86::ISTT_Fp32m64 , X86::ISTT_FP32m},
|
|
{ X86::ISTT_Fp32m80 , X86::ISTT_FP32m},
|
|
{ X86::ISTT_Fp64m32 , X86::ISTT_FP64m},
|
|
{ X86::ISTT_Fp64m64 , X86::ISTT_FP64m},
|
|
{ X86::ISTT_Fp64m80 , X86::ISTT_FP64m},
|
|
{ X86::IST_Fp16m32 , X86::IST_F16m },
|
|
{ X86::IST_Fp16m64 , X86::IST_F16m },
|
|
{ X86::IST_Fp16m80 , X86::IST_F16m },
|
|
{ X86::IST_Fp32m32 , X86::IST_F32m },
|
|
{ X86::IST_Fp32m64 , X86::IST_F32m },
|
|
{ X86::IST_Fp32m80 , X86::IST_F32m },
|
|
{ X86::IST_Fp64m32 , X86::IST_FP64m },
|
|
{ X86::IST_Fp64m64 , X86::IST_FP64m },
|
|
{ X86::IST_Fp64m80 , X86::IST_FP64m },
|
|
{ X86::LD_Fp032 , X86::LD_F0 },
|
|
{ X86::LD_Fp064 , X86::LD_F0 },
|
|
{ X86::LD_Fp080 , X86::LD_F0 },
|
|
{ X86::LD_Fp132 , X86::LD_F1 },
|
|
{ X86::LD_Fp164 , X86::LD_F1 },
|
|
{ X86::LD_Fp180 , X86::LD_F1 },
|
|
{ X86::LD_Fp32m , X86::LD_F32m },
|
|
{ X86::LD_Fp32m64 , X86::LD_F32m },
|
|
{ X86::LD_Fp32m80 , X86::LD_F32m },
|
|
{ X86::LD_Fp64m , X86::LD_F64m },
|
|
{ X86::LD_Fp64m80 , X86::LD_F64m },
|
|
{ X86::LD_Fp80m , X86::LD_F80m },
|
|
{ X86::MUL_Fp32m , X86::MUL_F32m },
|
|
{ X86::MUL_Fp64m , X86::MUL_F64m },
|
|
{ X86::MUL_Fp64m32 , X86::MUL_F32m },
|
|
{ X86::MUL_Fp80m32 , X86::MUL_F32m },
|
|
{ X86::MUL_Fp80m64 , X86::MUL_F64m },
|
|
{ X86::MUL_FpI16m32 , X86::MUL_FI16m },
|
|
{ X86::MUL_FpI16m64 , X86::MUL_FI16m },
|
|
{ X86::MUL_FpI16m80 , X86::MUL_FI16m },
|
|
{ X86::MUL_FpI32m32 , X86::MUL_FI32m },
|
|
{ X86::MUL_FpI32m64 , X86::MUL_FI32m },
|
|
{ X86::MUL_FpI32m80 , X86::MUL_FI32m },
|
|
{ X86::SIN_Fp32 , X86::SIN_F },
|
|
{ X86::SIN_Fp64 , X86::SIN_F },
|
|
{ X86::SIN_Fp80 , X86::SIN_F },
|
|
{ X86::SQRT_Fp32 , X86::SQRT_F },
|
|
{ X86::SQRT_Fp64 , X86::SQRT_F },
|
|
{ X86::SQRT_Fp80 , X86::SQRT_F },
|
|
{ X86::ST_Fp32m , X86::ST_F32m },
|
|
{ X86::ST_Fp64m , X86::ST_F64m },
|
|
{ X86::ST_Fp64m32 , X86::ST_F32m },
|
|
{ X86::ST_Fp80m32 , X86::ST_F32m },
|
|
{ X86::ST_Fp80m64 , X86::ST_F64m },
|
|
{ X86::ST_FpP80m , X86::ST_FP80m },
|
|
{ X86::SUBR_Fp32m , X86::SUBR_F32m },
|
|
{ X86::SUBR_Fp64m , X86::SUBR_F64m },
|
|
{ X86::SUBR_Fp64m32 , X86::SUBR_F32m },
|
|
{ X86::SUBR_Fp80m32 , X86::SUBR_F32m },
|
|
{ X86::SUBR_Fp80m64 , X86::SUBR_F64m },
|
|
{ X86::SUBR_FpI16m32, X86::SUBR_FI16m},
|
|
{ X86::SUBR_FpI16m64, X86::SUBR_FI16m},
|
|
{ X86::SUBR_FpI16m80, X86::SUBR_FI16m},
|
|
{ X86::SUBR_FpI32m32, X86::SUBR_FI32m},
|
|
{ X86::SUBR_FpI32m64, X86::SUBR_FI32m},
|
|
{ X86::SUBR_FpI32m80, X86::SUBR_FI32m},
|
|
{ X86::SUB_Fp32m , X86::SUB_F32m },
|
|
{ X86::SUB_Fp64m , X86::SUB_F64m },
|
|
{ X86::SUB_Fp64m32 , X86::SUB_F32m },
|
|
{ X86::SUB_Fp80m32 , X86::SUB_F32m },
|
|
{ X86::SUB_Fp80m64 , X86::SUB_F64m },
|
|
{ X86::SUB_FpI16m32 , X86::SUB_FI16m },
|
|
{ X86::SUB_FpI16m64 , X86::SUB_FI16m },
|
|
{ X86::SUB_FpI16m80 , X86::SUB_FI16m },
|
|
{ X86::SUB_FpI32m32 , X86::SUB_FI32m },
|
|
{ X86::SUB_FpI32m64 , X86::SUB_FI32m },
|
|
{ X86::SUB_FpI32m80 , X86::SUB_FI32m },
|
|
{ X86::TST_Fp32 , X86::TST_F },
|
|
{ X86::TST_Fp64 , X86::TST_F },
|
|
{ X86::TST_Fp80 , X86::TST_F },
|
|
{ X86::UCOM_FpIr32 , X86::UCOM_FIr },
|
|
{ X86::UCOM_FpIr64 , X86::UCOM_FIr },
|
|
{ X86::UCOM_FpIr80 , X86::UCOM_FIr },
|
|
{ X86::UCOM_Fpr32 , X86::UCOM_Fr },
|
|
{ X86::UCOM_Fpr64 , X86::UCOM_Fr },
|
|
{ X86::UCOM_Fpr80 , X86::UCOM_Fr },
|
|
};
|
|
|
|
static unsigned getConcreteOpcode(unsigned Opcode) {
|
|
ASSERT_SORTED(OpcodeTable);
|
|
int Opc = Lookup(OpcodeTable, array_lengthof(OpcodeTable), Opcode);
|
|
assert(Opc != -1 && "FP Stack instruction not in OpcodeTable!");
|
|
return Opc;
|
|
}
|
|
|
|
//===----------------------------------------------------------------------===//
|
|
// Helper Methods
|
|
//===----------------------------------------------------------------------===//
|
|
|
|
// PopTable - Sorted map of instructions to their popping version. The first
|
|
// element is an instruction, the second is the version which pops.
|
|
//
|
|
static const TableEntry PopTable[] = {
|
|
{ X86::ADD_FrST0 , X86::ADD_FPrST0 },
|
|
|
|
{ X86::DIVR_FrST0, X86::DIVR_FPrST0 },
|
|
{ X86::DIV_FrST0 , X86::DIV_FPrST0 },
|
|
|
|
{ X86::IST_F16m , X86::IST_FP16m },
|
|
{ X86::IST_F32m , X86::IST_FP32m },
|
|
|
|
{ X86::MUL_FrST0 , X86::MUL_FPrST0 },
|
|
|
|
{ X86::ST_F32m , X86::ST_FP32m },
|
|
{ X86::ST_F64m , X86::ST_FP64m },
|
|
{ X86::ST_Frr , X86::ST_FPrr },
|
|
|
|
{ X86::SUBR_FrST0, X86::SUBR_FPrST0 },
|
|
{ X86::SUB_FrST0 , X86::SUB_FPrST0 },
|
|
|
|
{ X86::UCOM_FIr , X86::UCOM_FIPr },
|
|
|
|
{ X86::UCOM_FPr , X86::UCOM_FPPr },
|
|
{ X86::UCOM_Fr , X86::UCOM_FPr },
|
|
};
|
|
|
|
/// popStackAfter - Pop the current value off of the top of the FP stack after
|
|
/// the specified instruction. This attempts to be sneaky and combine the pop
|
|
/// into the instruction itself if possible. The iterator is left pointing to
|
|
/// the last instruction, be it a new pop instruction inserted, or the old
|
|
/// instruction if it was modified in place.
|
|
///
|
|
void FPS::popStackAfter(MachineBasicBlock::iterator &I) {
|
|
MachineInstr* MI = I;
|
|
DebugLoc dl = MI->getDebugLoc();
|
|
ASSERT_SORTED(PopTable);
|
|
if (StackTop == 0)
|
|
report_fatal_error("Cannot pop empty stack!");
|
|
RegMap[Stack[--StackTop]] = ~0; // Update state
|
|
|
|
// Check to see if there is a popping version of this instruction...
|
|
int Opcode = Lookup(PopTable, array_lengthof(PopTable), I->getOpcode());
|
|
if (Opcode != -1) {
|
|
I->setDesc(TII->get(Opcode));
|
|
if (Opcode == X86::UCOM_FPPr)
|
|
I->RemoveOperand(0);
|
|
} else { // Insert an explicit pop
|
|
I = BuildMI(*MBB, ++I, dl, TII->get(X86::ST_FPrr)).addReg(X86::ST0);
|
|
}
|
|
}
|
|
|
|
/// freeStackSlotAfter - Free the specified register from the register stack, so
|
|
/// that it is no longer in a register. If the register is currently at the top
|
|
/// of the stack, we just pop the current instruction, otherwise we store the
|
|
/// current top-of-stack into the specified slot, then pop the top of stack.
|
|
void FPS::freeStackSlotAfter(MachineBasicBlock::iterator &I, unsigned FPRegNo) {
|
|
if (getStackEntry(0) == FPRegNo) { // already at the top of stack? easy.
|
|
popStackAfter(I);
|
|
return;
|
|
}
|
|
|
|
// Otherwise, store the top of stack into the dead slot, killing the operand
|
|
// without having to add in an explicit xchg then pop.
|
|
//
|
|
I = freeStackSlotBefore(++I, FPRegNo);
|
|
}
|
|
|
|
/// freeStackSlotBefore - Free the specified register without trying any
|
|
/// folding.
|
|
MachineBasicBlock::iterator
|
|
FPS::freeStackSlotBefore(MachineBasicBlock::iterator I, unsigned FPRegNo) {
|
|
unsigned STReg = getSTReg(FPRegNo);
|
|
unsigned OldSlot = getSlot(FPRegNo);
|
|
unsigned TopReg = Stack[StackTop-1];
|
|
Stack[OldSlot] = TopReg;
|
|
RegMap[TopReg] = OldSlot;
|
|
RegMap[FPRegNo] = ~0;
|
|
Stack[--StackTop] = ~0;
|
|
return BuildMI(*MBB, I, DebugLoc(), TII->get(X86::ST_FPrr))
|
|
.addReg(STReg)
|
|
.getInstr();
|
|
}
|
|
|
|
/// adjustLiveRegs - Kill and revive registers such that exactly the FP
|
|
/// registers with a bit in Mask are live.
|
|
void FPS::adjustLiveRegs(unsigned Mask, MachineBasicBlock::iterator I) {
|
|
unsigned Defs = Mask;
|
|
unsigned Kills = 0;
|
|
for (unsigned i = 0; i < StackTop; ++i) {
|
|
unsigned RegNo = Stack[i];
|
|
if (!(Defs & (1 << RegNo)))
|
|
// This register is live, but we don't want it.
|
|
Kills |= (1 << RegNo);
|
|
else
|
|
// We don't need to imp-def this live register.
|
|
Defs &= ~(1 << RegNo);
|
|
}
|
|
assert((Kills & Defs) == 0 && "Register needs killing and def'ing?");
|
|
|
|
// Produce implicit-defs for free by using killed registers.
|
|
while (Kills && Defs) {
|
|
unsigned KReg = countTrailingZeros(Kills);
|
|
unsigned DReg = countTrailingZeros(Defs);
|
|
DEBUG(dbgs() << "Renaming %FP" << KReg << " as imp %FP" << DReg << "\n");
|
|
std::swap(Stack[getSlot(KReg)], Stack[getSlot(DReg)]);
|
|
std::swap(RegMap[KReg], RegMap[DReg]);
|
|
Kills &= ~(1 << KReg);
|
|
Defs &= ~(1 << DReg);
|
|
}
|
|
|
|
// Kill registers by popping.
|
|
if (Kills && I != MBB->begin()) {
|
|
MachineBasicBlock::iterator I2 = std::prev(I);
|
|
while (StackTop) {
|
|
unsigned KReg = getStackEntry(0);
|
|
if (!(Kills & (1 << KReg)))
|
|
break;
|
|
DEBUG(dbgs() << "Popping %FP" << KReg << "\n");
|
|
popStackAfter(I2);
|
|
Kills &= ~(1 << KReg);
|
|
}
|
|
}
|
|
|
|
// Manually kill the rest.
|
|
while (Kills) {
|
|
unsigned KReg = countTrailingZeros(Kills);
|
|
DEBUG(dbgs() << "Killing %FP" << KReg << "\n");
|
|
freeStackSlotBefore(I, KReg);
|
|
Kills &= ~(1 << KReg);
|
|
}
|
|
|
|
// Load zeros for all the imp-defs.
|
|
while(Defs) {
|
|
unsigned DReg = countTrailingZeros(Defs);
|
|
DEBUG(dbgs() << "Defining %FP" << DReg << " as 0\n");
|
|
BuildMI(*MBB, I, DebugLoc(), TII->get(X86::LD_F0));
|
|
pushReg(DReg);
|
|
Defs &= ~(1 << DReg);
|
|
}
|
|
|
|
// Now we should have the correct registers live.
|
|
DEBUG(dumpStack());
|
|
assert(StackTop == CountPopulation_32(Mask) && "Live count mismatch");
|
|
}
|
|
|
|
/// shuffleStackTop - emit fxch instructions before I to shuffle the top
|
|
/// FixCount entries into the order given by FixStack.
|
|
/// FIXME: Is there a better algorithm than insertion sort?
|
|
void FPS::shuffleStackTop(const unsigned char *FixStack,
|
|
unsigned FixCount,
|
|
MachineBasicBlock::iterator I) {
|
|
// Move items into place, starting from the desired stack bottom.
|
|
while (FixCount--) {
|
|
// Old register at position FixCount.
|
|
unsigned OldReg = getStackEntry(FixCount);
|
|
// Desired register at position FixCount.
|
|
unsigned Reg = FixStack[FixCount];
|
|
if (Reg == OldReg)
|
|
continue;
|
|
// (Reg st0) (OldReg st0) = (Reg OldReg st0)
|
|
moveToTop(Reg, I);
|
|
if (FixCount > 0)
|
|
moveToTop(OldReg, I);
|
|
}
|
|
DEBUG(dumpStack());
|
|
}
|
|
|
|
|
|
//===----------------------------------------------------------------------===//
|
|
// Instruction transformation implementation
|
|
//===----------------------------------------------------------------------===//
|
|
|
|
void FPS::handleCall(MachineBasicBlock::iterator &I) {
|
|
unsigned STReturns = 0;
|
|
|
|
for (const auto &MO : I->operands()) {
|
|
if (!MO.isReg())
|
|
continue;
|
|
|
|
unsigned R = MO.getReg() - X86::FP0;
|
|
|
|
if (R < 8) {
|
|
assert(MO.isDef() && MO.isImplicit());
|
|
STReturns |= 1 << R;
|
|
}
|
|
}
|
|
|
|
unsigned N = CountTrailingOnes_32(STReturns);
|
|
|
|
// FP registers used for function return must be consecutive starting at
|
|
// FP0.
|
|
assert(STReturns == 0 || (isMask_32(STReturns) && N <= 2));
|
|
|
|
for (unsigned I = 0; I < N; ++I)
|
|
pushReg(N - I - 1);
|
|
}
|
|
|
|
/// handleZeroArgFP - ST(0) = fld0 ST(0) = flds <mem>
|
|
///
|
|
void FPS::handleZeroArgFP(MachineBasicBlock::iterator &I) {
|
|
MachineInstr *MI = I;
|
|
unsigned DestReg = getFPReg(MI->getOperand(0));
|
|
|
|
// Change from the pseudo instruction to the concrete instruction.
|
|
MI->RemoveOperand(0); // Remove the explicit ST(0) operand
|
|
MI->setDesc(TII->get(getConcreteOpcode(MI->getOpcode())));
|
|
|
|
// Result gets pushed on the stack.
|
|
pushReg(DestReg);
|
|
}
|
|
|
|
/// handleOneArgFP - fst <mem>, ST(0)
|
|
///
|
|
void FPS::handleOneArgFP(MachineBasicBlock::iterator &I) {
|
|
MachineInstr *MI = I;
|
|
unsigned NumOps = MI->getDesc().getNumOperands();
|
|
assert((NumOps == X86::AddrNumOperands + 1 || NumOps == 1) &&
|
|
"Can only handle fst* & ftst instructions!");
|
|
|
|
// Is this the last use of the source register?
|
|
unsigned Reg = getFPReg(MI->getOperand(NumOps-1));
|
|
bool KillsSrc = MI->killsRegister(X86::FP0+Reg);
|
|
|
|
// FISTP64m is strange because there isn't a non-popping versions.
|
|
// If we have one _and_ we don't want to pop the operand, duplicate the value
|
|
// on the stack instead of moving it. This ensure that popping the value is
|
|
// always ok.
|
|
// Ditto FISTTP16m, FISTTP32m, FISTTP64m, ST_FpP80m.
|
|
//
|
|
if (!KillsSrc &&
|
|
(MI->getOpcode() == X86::IST_Fp64m32 ||
|
|
MI->getOpcode() == X86::ISTT_Fp16m32 ||
|
|
MI->getOpcode() == X86::ISTT_Fp32m32 ||
|
|
MI->getOpcode() == X86::ISTT_Fp64m32 ||
|
|
MI->getOpcode() == X86::IST_Fp64m64 ||
|
|
MI->getOpcode() == X86::ISTT_Fp16m64 ||
|
|
MI->getOpcode() == X86::ISTT_Fp32m64 ||
|
|
MI->getOpcode() == X86::ISTT_Fp64m64 ||
|
|
MI->getOpcode() == X86::IST_Fp64m80 ||
|
|
MI->getOpcode() == X86::ISTT_Fp16m80 ||
|
|
MI->getOpcode() == X86::ISTT_Fp32m80 ||
|
|
MI->getOpcode() == X86::ISTT_Fp64m80 ||
|
|
MI->getOpcode() == X86::ST_FpP80m)) {
|
|
duplicateToTop(Reg, ScratchFPReg, I);
|
|
} else {
|
|
moveToTop(Reg, I); // Move to the top of the stack...
|
|
}
|
|
|
|
// Convert from the pseudo instruction to the concrete instruction.
|
|
MI->RemoveOperand(NumOps-1); // Remove explicit ST(0) operand
|
|
MI->setDesc(TII->get(getConcreteOpcode(MI->getOpcode())));
|
|
|
|
if (MI->getOpcode() == X86::IST_FP64m ||
|
|
MI->getOpcode() == X86::ISTT_FP16m ||
|
|
MI->getOpcode() == X86::ISTT_FP32m ||
|
|
MI->getOpcode() == X86::ISTT_FP64m ||
|
|
MI->getOpcode() == X86::ST_FP80m) {
|
|
if (StackTop == 0)
|
|
report_fatal_error("Stack empty??");
|
|
--StackTop;
|
|
} else if (KillsSrc) { // Last use of operand?
|
|
popStackAfter(I);
|
|
}
|
|
}
|
|
|
|
|
|
/// handleOneArgFPRW: Handle instructions that read from the top of stack and
|
|
/// replace the value with a newly computed value. These instructions may have
|
|
/// non-fp operands after their FP operands.
|
|
///
|
|
/// Examples:
|
|
/// R1 = fchs R2
|
|
/// R1 = fadd R2, [mem]
|
|
///
|
|
void FPS::handleOneArgFPRW(MachineBasicBlock::iterator &I) {
|
|
MachineInstr *MI = I;
|
|
#ifndef NDEBUG
|
|
unsigned NumOps = MI->getDesc().getNumOperands();
|
|
assert(NumOps >= 2 && "FPRW instructions must have 2 ops!!");
|
|
#endif
|
|
|
|
// Is this the last use of the source register?
|
|
unsigned Reg = getFPReg(MI->getOperand(1));
|
|
bool KillsSrc = MI->killsRegister(X86::FP0+Reg);
|
|
|
|
if (KillsSrc) {
|
|
// If this is the last use of the source register, just make sure it's on
|
|
// the top of the stack.
|
|
moveToTop(Reg, I);
|
|
if (StackTop == 0)
|
|
report_fatal_error("Stack cannot be empty!");
|
|
--StackTop;
|
|
pushReg(getFPReg(MI->getOperand(0)));
|
|
} else {
|
|
// If this is not the last use of the source register, _copy_ it to the top
|
|
// of the stack.
|
|
duplicateToTop(Reg, getFPReg(MI->getOperand(0)), I);
|
|
}
|
|
|
|
// Change from the pseudo instruction to the concrete instruction.
|
|
MI->RemoveOperand(1); // Drop the source operand.
|
|
MI->RemoveOperand(0); // Drop the destination operand.
|
|
MI->setDesc(TII->get(getConcreteOpcode(MI->getOpcode())));
|
|
}
|
|
|
|
|
|
//===----------------------------------------------------------------------===//
|
|
// Define tables of various ways to map pseudo instructions
|
|
//
|
|
|
|
// ForwardST0Table - Map: A = B op C into: ST(0) = ST(0) op ST(i)
|
|
static const TableEntry ForwardST0Table[] = {
|
|
{ X86::ADD_Fp32 , X86::ADD_FST0r },
|
|
{ X86::ADD_Fp64 , X86::ADD_FST0r },
|
|
{ X86::ADD_Fp80 , X86::ADD_FST0r },
|
|
{ X86::DIV_Fp32 , X86::DIV_FST0r },
|
|
{ X86::DIV_Fp64 , X86::DIV_FST0r },
|
|
{ X86::DIV_Fp80 , X86::DIV_FST0r },
|
|
{ X86::MUL_Fp32 , X86::MUL_FST0r },
|
|
{ X86::MUL_Fp64 , X86::MUL_FST0r },
|
|
{ X86::MUL_Fp80 , X86::MUL_FST0r },
|
|
{ X86::SUB_Fp32 , X86::SUB_FST0r },
|
|
{ X86::SUB_Fp64 , X86::SUB_FST0r },
|
|
{ X86::SUB_Fp80 , X86::SUB_FST0r },
|
|
};
|
|
|
|
// ReverseST0Table - Map: A = B op C into: ST(0) = ST(i) op ST(0)
|
|
static const TableEntry ReverseST0Table[] = {
|
|
{ X86::ADD_Fp32 , X86::ADD_FST0r }, // commutative
|
|
{ X86::ADD_Fp64 , X86::ADD_FST0r }, // commutative
|
|
{ X86::ADD_Fp80 , X86::ADD_FST0r }, // commutative
|
|
{ X86::DIV_Fp32 , X86::DIVR_FST0r },
|
|
{ X86::DIV_Fp64 , X86::DIVR_FST0r },
|
|
{ X86::DIV_Fp80 , X86::DIVR_FST0r },
|
|
{ X86::MUL_Fp32 , X86::MUL_FST0r }, // commutative
|
|
{ X86::MUL_Fp64 , X86::MUL_FST0r }, // commutative
|
|
{ X86::MUL_Fp80 , X86::MUL_FST0r }, // commutative
|
|
{ X86::SUB_Fp32 , X86::SUBR_FST0r },
|
|
{ X86::SUB_Fp64 , X86::SUBR_FST0r },
|
|
{ X86::SUB_Fp80 , X86::SUBR_FST0r },
|
|
};
|
|
|
|
// ForwardSTiTable - Map: A = B op C into: ST(i) = ST(0) op ST(i)
|
|
static const TableEntry ForwardSTiTable[] = {
|
|
{ X86::ADD_Fp32 , X86::ADD_FrST0 }, // commutative
|
|
{ X86::ADD_Fp64 , X86::ADD_FrST0 }, // commutative
|
|
{ X86::ADD_Fp80 , X86::ADD_FrST0 }, // commutative
|
|
{ X86::DIV_Fp32 , X86::DIVR_FrST0 },
|
|
{ X86::DIV_Fp64 , X86::DIVR_FrST0 },
|
|
{ X86::DIV_Fp80 , X86::DIVR_FrST0 },
|
|
{ X86::MUL_Fp32 , X86::MUL_FrST0 }, // commutative
|
|
{ X86::MUL_Fp64 , X86::MUL_FrST0 }, // commutative
|
|
{ X86::MUL_Fp80 , X86::MUL_FrST0 }, // commutative
|
|
{ X86::SUB_Fp32 , X86::SUBR_FrST0 },
|
|
{ X86::SUB_Fp64 , X86::SUBR_FrST0 },
|
|
{ X86::SUB_Fp80 , X86::SUBR_FrST0 },
|
|
};
|
|
|
|
// ReverseSTiTable - Map: A = B op C into: ST(i) = ST(i) op ST(0)
|
|
static const TableEntry ReverseSTiTable[] = {
|
|
{ X86::ADD_Fp32 , X86::ADD_FrST0 },
|
|
{ X86::ADD_Fp64 , X86::ADD_FrST0 },
|
|
{ X86::ADD_Fp80 , X86::ADD_FrST0 },
|
|
{ X86::DIV_Fp32 , X86::DIV_FrST0 },
|
|
{ X86::DIV_Fp64 , X86::DIV_FrST0 },
|
|
{ X86::DIV_Fp80 , X86::DIV_FrST0 },
|
|
{ X86::MUL_Fp32 , X86::MUL_FrST0 },
|
|
{ X86::MUL_Fp64 , X86::MUL_FrST0 },
|
|
{ X86::MUL_Fp80 , X86::MUL_FrST0 },
|
|
{ X86::SUB_Fp32 , X86::SUB_FrST0 },
|
|
{ X86::SUB_Fp64 , X86::SUB_FrST0 },
|
|
{ X86::SUB_Fp80 , X86::SUB_FrST0 },
|
|
};
|
|
|
|
|
|
/// handleTwoArgFP - Handle instructions like FADD and friends which are virtual
|
|
/// instructions which need to be simplified and possibly transformed.
|
|
///
|
|
/// Result: ST(0) = fsub ST(0), ST(i)
|
|
/// ST(i) = fsub ST(0), ST(i)
|
|
/// ST(0) = fsubr ST(0), ST(i)
|
|
/// ST(i) = fsubr ST(0), ST(i)
|
|
///
|
|
void FPS::handleTwoArgFP(MachineBasicBlock::iterator &I) {
|
|
ASSERT_SORTED(ForwardST0Table); ASSERT_SORTED(ReverseST0Table);
|
|
ASSERT_SORTED(ForwardSTiTable); ASSERT_SORTED(ReverseSTiTable);
|
|
MachineInstr *MI = I;
|
|
|
|
unsigned NumOperands = MI->getDesc().getNumOperands();
|
|
assert(NumOperands == 3 && "Illegal TwoArgFP instruction!");
|
|
unsigned Dest = getFPReg(MI->getOperand(0));
|
|
unsigned Op0 = getFPReg(MI->getOperand(NumOperands-2));
|
|
unsigned Op1 = getFPReg(MI->getOperand(NumOperands-1));
|
|
bool KillsOp0 = MI->killsRegister(X86::FP0+Op0);
|
|
bool KillsOp1 = MI->killsRegister(X86::FP0+Op1);
|
|
DebugLoc dl = MI->getDebugLoc();
|
|
|
|
unsigned TOS = getStackEntry(0);
|
|
|
|
// One of our operands must be on the top of the stack. If neither is yet, we
|
|
// need to move one.
|
|
if (Op0 != TOS && Op1 != TOS) { // No operand at TOS?
|
|
// We can choose to move either operand to the top of the stack. If one of
|
|
// the operands is killed by this instruction, we want that one so that we
|
|
// can update right on top of the old version.
|
|
if (KillsOp0) {
|
|
moveToTop(Op0, I); // Move dead operand to TOS.
|
|
TOS = Op0;
|
|
} else if (KillsOp1) {
|
|
moveToTop(Op1, I);
|
|
TOS = Op1;
|
|
} else {
|
|
// All of the operands are live after this instruction executes, so we
|
|
// cannot update on top of any operand. Because of this, we must
|
|
// duplicate one of the stack elements to the top. It doesn't matter
|
|
// which one we pick.
|
|
//
|
|
duplicateToTop(Op0, Dest, I);
|
|
Op0 = TOS = Dest;
|
|
KillsOp0 = true;
|
|
}
|
|
} else if (!KillsOp0 && !KillsOp1) {
|
|
// If we DO have one of our operands at the top of the stack, but we don't
|
|
// have a dead operand, we must duplicate one of the operands to a new slot
|
|
// on the stack.
|
|
duplicateToTop(Op0, Dest, I);
|
|
Op0 = TOS = Dest;
|
|
KillsOp0 = true;
|
|
}
|
|
|
|
// Now we know that one of our operands is on the top of the stack, and at
|
|
// least one of our operands is killed by this instruction.
|
|
assert((TOS == Op0 || TOS == Op1) && (KillsOp0 || KillsOp1) &&
|
|
"Stack conditions not set up right!");
|
|
|
|
// We decide which form to use based on what is on the top of the stack, and
|
|
// which operand is killed by this instruction.
|
|
const TableEntry *InstTable;
|
|
bool isForward = TOS == Op0;
|
|
bool updateST0 = (TOS == Op0 && !KillsOp1) || (TOS == Op1 && !KillsOp0);
|
|
if (updateST0) {
|
|
if (isForward)
|
|
InstTable = ForwardST0Table;
|
|
else
|
|
InstTable = ReverseST0Table;
|
|
} else {
|
|
if (isForward)
|
|
InstTable = ForwardSTiTable;
|
|
else
|
|
InstTable = ReverseSTiTable;
|
|
}
|
|
|
|
int Opcode = Lookup(InstTable, array_lengthof(ForwardST0Table),
|
|
MI->getOpcode());
|
|
assert(Opcode != -1 && "Unknown TwoArgFP pseudo instruction!");
|
|
|
|
// NotTOS - The register which is not on the top of stack...
|
|
unsigned NotTOS = (TOS == Op0) ? Op1 : Op0;
|
|
|
|
// Replace the old instruction with a new instruction
|
|
MBB->remove(I++);
|
|
I = BuildMI(*MBB, I, dl, TII->get(Opcode)).addReg(getSTReg(NotTOS));
|
|
|
|
// If both operands are killed, pop one off of the stack in addition to
|
|
// overwriting the other one.
|
|
if (KillsOp0 && KillsOp1 && Op0 != Op1) {
|
|
assert(!updateST0 && "Should have updated other operand!");
|
|
popStackAfter(I); // Pop the top of stack
|
|
}
|
|
|
|
// Update stack information so that we know the destination register is now on
|
|
// the stack.
|
|
unsigned UpdatedSlot = getSlot(updateST0 ? TOS : NotTOS);
|
|
assert(UpdatedSlot < StackTop && Dest < 7);
|
|
Stack[UpdatedSlot] = Dest;
|
|
RegMap[Dest] = UpdatedSlot;
|
|
MBB->getParent()->DeleteMachineInstr(MI); // Remove the old instruction
|
|
}
|
|
|
|
/// handleCompareFP - Handle FUCOM and FUCOMI instructions, which have two FP
|
|
/// register arguments and no explicit destinations.
|
|
///
|
|
void FPS::handleCompareFP(MachineBasicBlock::iterator &I) {
|
|
ASSERT_SORTED(ForwardST0Table); ASSERT_SORTED(ReverseST0Table);
|
|
ASSERT_SORTED(ForwardSTiTable); ASSERT_SORTED(ReverseSTiTable);
|
|
MachineInstr *MI = I;
|
|
|
|
unsigned NumOperands = MI->getDesc().getNumOperands();
|
|
assert(NumOperands == 2 && "Illegal FUCOM* instruction!");
|
|
unsigned Op0 = getFPReg(MI->getOperand(NumOperands-2));
|
|
unsigned Op1 = getFPReg(MI->getOperand(NumOperands-1));
|
|
bool KillsOp0 = MI->killsRegister(X86::FP0+Op0);
|
|
bool KillsOp1 = MI->killsRegister(X86::FP0+Op1);
|
|
|
|
// Make sure the first operand is on the top of stack, the other one can be
|
|
// anywhere.
|
|
moveToTop(Op0, I);
|
|
|
|
// Change from the pseudo instruction to the concrete instruction.
|
|
MI->getOperand(0).setReg(getSTReg(Op1));
|
|
MI->RemoveOperand(1);
|
|
MI->setDesc(TII->get(getConcreteOpcode(MI->getOpcode())));
|
|
|
|
// If any of the operands are killed by this instruction, free them.
|
|
if (KillsOp0) freeStackSlotAfter(I, Op0);
|
|
if (KillsOp1 && Op0 != Op1) freeStackSlotAfter(I, Op1);
|
|
}
|
|
|
|
/// handleCondMovFP - Handle two address conditional move instructions. These
|
|
/// instructions move a st(i) register to st(0) iff a condition is true. These
|
|
/// instructions require that the first operand is at the top of the stack, but
|
|
/// otherwise don't modify the stack at all.
|
|
void FPS::handleCondMovFP(MachineBasicBlock::iterator &I) {
|
|
MachineInstr *MI = I;
|
|
|
|
unsigned Op0 = getFPReg(MI->getOperand(0));
|
|
unsigned Op1 = getFPReg(MI->getOperand(2));
|
|
bool KillsOp1 = MI->killsRegister(X86::FP0+Op1);
|
|
|
|
// The first operand *must* be on the top of the stack.
|
|
moveToTop(Op0, I);
|
|
|
|
// Change the second operand to the stack register that the operand is in.
|
|
// Change from the pseudo instruction to the concrete instruction.
|
|
MI->RemoveOperand(0);
|
|
MI->RemoveOperand(1);
|
|
MI->getOperand(0).setReg(getSTReg(Op1));
|
|
MI->setDesc(TII->get(getConcreteOpcode(MI->getOpcode())));
|
|
|
|
// If we kill the second operand, make sure to pop it from the stack.
|
|
if (Op0 != Op1 && KillsOp1) {
|
|
// Get this value off of the register stack.
|
|
freeStackSlotAfter(I, Op1);
|
|
}
|
|
}
|
|
|
|
|
|
/// handleSpecialFP - Handle special instructions which behave unlike other
|
|
/// floating point instructions. This is primarily intended for use by pseudo
|
|
/// instructions.
|
|
///
|
|
void FPS::handleSpecialFP(MachineBasicBlock::iterator &Inst) {
|
|
MachineInstr *MI = Inst;
|
|
|
|
if (MI->isCall()) {
|
|
handleCall(Inst);
|
|
return;
|
|
}
|
|
|
|
switch (MI->getOpcode()) {
|
|
default: llvm_unreachable("Unknown SpecialFP instruction!");
|
|
case TargetOpcode::COPY: {
|
|
// We handle three kinds of copies: FP <- FP, FP <- ST, and ST <- FP.
|
|
const MachineOperand &MO1 = MI->getOperand(1);
|
|
const MachineOperand &MO0 = MI->getOperand(0);
|
|
bool KillsSrc = MI->killsRegister(MO1.getReg());
|
|
|
|
// FP <- FP copy.
|
|
unsigned DstFP = getFPReg(MO0);
|
|
unsigned SrcFP = getFPReg(MO1);
|
|
assert(isLive(SrcFP) && "Cannot copy dead register");
|
|
if (KillsSrc) {
|
|
// If the input operand is killed, we can just change the owner of the
|
|
// incoming stack slot into the result.
|
|
unsigned Slot = getSlot(SrcFP);
|
|
Stack[Slot] = DstFP;
|
|
RegMap[DstFP] = Slot;
|
|
} else {
|
|
// For COPY we just duplicate the specified value to a new stack slot.
|
|
// This could be made better, but would require substantial changes.
|
|
duplicateToTop(SrcFP, DstFP, Inst);
|
|
}
|
|
break;
|
|
}
|
|
|
|
case TargetOpcode::IMPLICIT_DEF: {
|
|
// All FP registers must be explicitly defined, so load a 0 instead.
|
|
unsigned Reg = MI->getOperand(0).getReg() - X86::FP0;
|
|
DEBUG(dbgs() << "Emitting LD_F0 for implicit FP" << Reg << '\n');
|
|
BuildMI(*MBB, Inst, MI->getDebugLoc(), TII->get(X86::LD_F0));
|
|
pushReg(Reg);
|
|
break;
|
|
}
|
|
|
|
case TargetOpcode::INLINEASM: {
|
|
// The inline asm MachineInstr currently only *uses* FP registers for the
|
|
// 'f' constraint. These should be turned into the current ST(x) register
|
|
// in the machine instr.
|
|
//
|
|
// There are special rules for x87 inline assembly. The compiler must know
|
|
// exactly how many registers are popped and pushed implicitly by the asm.
|
|
// Otherwise it is not possible to restore the stack state after the inline
|
|
// asm.
|
|
//
|
|
// There are 3 kinds of input operands:
|
|
//
|
|
// 1. Popped inputs. These must appear at the stack top in ST0-STn. A
|
|
// popped input operand must be in a fixed stack slot, and it is either
|
|
// tied to an output operand, or in the clobber list. The MI has ST use
|
|
// and def operands for these inputs.
|
|
//
|
|
// 2. Fixed inputs. These inputs appear in fixed stack slots, but are
|
|
// preserved by the inline asm. The fixed stack slots must be STn-STm
|
|
// following the popped inputs. A fixed input operand cannot be tied to
|
|
// an output or appear in the clobber list. The MI has ST use operands
|
|
// and no defs for these inputs.
|
|
//
|
|
// 3. Preserved inputs. These inputs use the "f" constraint which is
|
|
// represented as an FP register. The inline asm won't change these
|
|
// stack slots.
|
|
//
|
|
// Outputs must be in ST registers, FP outputs are not allowed. Clobbered
|
|
// registers do not count as output operands. The inline asm changes the
|
|
// stack as if it popped all the popped inputs and then pushed all the
|
|
// output operands.
|
|
|
|
// Scan the assembly for ST registers used, defined and clobbered. We can
|
|
// only tell clobbers from defs by looking at the asm descriptor.
|
|
unsigned STUses = 0, STDefs = 0, STClobbers = 0, STDeadDefs = 0;
|
|
unsigned NumOps = 0;
|
|
SmallSet<unsigned, 1> FRegIdx;
|
|
unsigned RCID;
|
|
|
|
for (unsigned i = InlineAsm::MIOp_FirstOperand, e = MI->getNumOperands();
|
|
i != e && MI->getOperand(i).isImm(); i += 1 + NumOps) {
|
|
unsigned Flags = MI->getOperand(i).getImm();
|
|
|
|
NumOps = InlineAsm::getNumOperandRegisters(Flags);
|
|
if (NumOps != 1)
|
|
continue;
|
|
const MachineOperand &MO = MI->getOperand(i + 1);
|
|
if (!MO.isReg())
|
|
continue;
|
|
unsigned STReg = MO.getReg() - X86::FP0;
|
|
if (STReg >= 8)
|
|
continue;
|
|
|
|
// If the flag has a register class constraint, this must be an operand
|
|
// with constraint "f". Record its index and continue.
|
|
if (InlineAsm::hasRegClassConstraint(Flags, RCID)) {
|
|
FRegIdx.insert(i + 1);
|
|
continue;
|
|
}
|
|
|
|
switch (InlineAsm::getKind(Flags)) {
|
|
case InlineAsm::Kind_RegUse:
|
|
STUses |= (1u << STReg);
|
|
break;
|
|
case InlineAsm::Kind_RegDef:
|
|
case InlineAsm::Kind_RegDefEarlyClobber:
|
|
STDefs |= (1u << STReg);
|
|
if (MO.isDead())
|
|
STDeadDefs |= (1u << STReg);
|
|
break;
|
|
case InlineAsm::Kind_Clobber:
|
|
STClobbers |= (1u << STReg);
|
|
break;
|
|
default:
|
|
break;
|
|
}
|
|
}
|
|
|
|
if (STUses && !isMask_32(STUses))
|
|
MI->emitError("fixed input regs must be last on the x87 stack");
|
|
unsigned NumSTUses = CountTrailingOnes_32(STUses);
|
|
|
|
// Defs must be contiguous from the stack top. ST0-STn.
|
|
if (STDefs && !isMask_32(STDefs)) {
|
|
MI->emitError("output regs must be last on the x87 stack");
|
|
STDefs = NextPowerOf2(STDefs) - 1;
|
|
}
|
|
unsigned NumSTDefs = CountTrailingOnes_32(STDefs);
|
|
|
|
// So must the clobbered stack slots. ST0-STm, m >= n.
|
|
if (STClobbers && !isMask_32(STDefs | STClobbers))
|
|
MI->emitError("clobbers must be last on the x87 stack");
|
|
|
|
// Popped inputs are the ones that are also clobbered or defined.
|
|
unsigned STPopped = STUses & (STDefs | STClobbers);
|
|
if (STPopped && !isMask_32(STPopped))
|
|
MI->emitError("implicitly popped regs must be last on the x87 stack");
|
|
unsigned NumSTPopped = CountTrailingOnes_32(STPopped);
|
|
|
|
DEBUG(dbgs() << "Asm uses " << NumSTUses << " fixed regs, pops "
|
|
<< NumSTPopped << ", and defines " << NumSTDefs << " regs.\n");
|
|
|
|
#ifndef NDEBUG
|
|
// If any input operand uses constraint "f", all output register
|
|
// constraints must be early-clobber defs.
|
|
for (unsigned I = 0, E = MI->getNumOperands(); I < E; ++I)
|
|
if (FRegIdx.count(I)) {
|
|
assert((1 << getFPReg(MI->getOperand(I)) & STDefs) == 0 &&
|
|
"Operands with constraint \"f\" cannot overlap with defs");
|
|
}
|
|
#endif
|
|
|
|
// Collect all FP registers (register operands with constraints "t", "u",
|
|
// and "f") to kill afer the instruction.
|
|
unsigned FPKills = ((1u << NumFPRegs) - 1) & ~0xff;
|
|
for (unsigned i = 0, e = MI->getNumOperands(); i != e; ++i) {
|
|
MachineOperand &Op = MI->getOperand(i);
|
|
if (!Op.isReg() || Op.getReg() < X86::FP0 || Op.getReg() > X86::FP6)
|
|
continue;
|
|
unsigned FPReg = getFPReg(Op);
|
|
|
|
// If we kill this operand, make sure to pop it from the stack after the
|
|
// asm. We just remember it for now, and pop them all off at the end in
|
|
// a batch.
|
|
if (Op.isUse() && Op.isKill())
|
|
FPKills |= 1U << FPReg;
|
|
}
|
|
|
|
// Do not include registers that are implicitly popped by defs/clobbers.
|
|
FPKills &= ~(STDefs | STClobbers);
|
|
|
|
// Now we can rearrange the live registers to match what was requested.
|
|
unsigned char STUsesArray[8];
|
|
|
|
for (unsigned I = 0; I < NumSTUses; ++I)
|
|
STUsesArray[I] = I;
|
|
|
|
shuffleStackTop(STUsesArray, NumSTUses, Inst);
|
|
DEBUG({dbgs() << "Before asm: "; dumpStack();});
|
|
|
|
// With the stack layout fixed, rewrite the FP registers.
|
|
for (unsigned i = 0, e = MI->getNumOperands(); i != e; ++i) {
|
|
MachineOperand &Op = MI->getOperand(i);
|
|
if (!Op.isReg() || Op.getReg() < X86::FP0 || Op.getReg() > X86::FP6)
|
|
continue;
|
|
|
|
unsigned FPReg = getFPReg(Op);
|
|
|
|
if (FRegIdx.count(i))
|
|
// Operand with constraint "f".
|
|
Op.setReg(getSTReg(FPReg));
|
|
else
|
|
// Operand with a single register class constraint ("t" or "u").
|
|
Op.setReg(X86::ST0 + FPReg);
|
|
}
|
|
|
|
// Simulate the inline asm popping its inputs and pushing its outputs.
|
|
StackTop -= NumSTPopped;
|
|
|
|
for (unsigned i = 0; i < NumSTDefs; ++i)
|
|
pushReg(NumSTDefs - i - 1);
|
|
|
|
// If this asm kills any FP registers (is the last use of them) we must
|
|
// explicitly emit pop instructions for them. Do this now after the asm has
|
|
// executed so that the ST(x) numbers are not off (which would happen if we
|
|
// did this inline with operand rewriting).
|
|
//
|
|
// Note: this might be a non-optimal pop sequence. We might be able to do
|
|
// better by trying to pop in stack order or something.
|
|
while (FPKills) {
|
|
unsigned FPReg = countTrailingZeros(FPKills);
|
|
if (isLive(FPReg))
|
|
freeStackSlotAfter(Inst, FPReg);
|
|
FPKills &= ~(1U << FPReg);
|
|
}
|
|
|
|
// Don't delete the inline asm!
|
|
return;
|
|
}
|
|
|
|
case X86::WIN_FTOL_32:
|
|
case X86::WIN_FTOL_64: {
|
|
// Push the operand into ST0.
|
|
MachineOperand &Op = MI->getOperand(0);
|
|
assert(Op.isUse() && Op.isReg() &&
|
|
Op.getReg() >= X86::FP0 && Op.getReg() <= X86::FP6);
|
|
unsigned FPReg = getFPReg(Op);
|
|
if (Op.isKill())
|
|
moveToTop(FPReg, Inst);
|
|
else
|
|
duplicateToTop(FPReg, FPReg, Inst);
|
|
|
|
// Emit the call. This will pop the operand.
|
|
BuildMI(*MBB, Inst, MI->getDebugLoc(), TII->get(X86::CALLpcrel32))
|
|
.addExternalSymbol("_ftol2")
|
|
.addReg(X86::ST0, RegState::ImplicitKill)
|
|
.addReg(X86::ECX, RegState::ImplicitDefine)
|
|
.addReg(X86::EAX, RegState::Define | RegState::Implicit)
|
|
.addReg(X86::EDX, RegState::Define | RegState::Implicit)
|
|
.addReg(X86::EFLAGS, RegState::Define | RegState::Implicit);
|
|
--StackTop;
|
|
|
|
break;
|
|
}
|
|
|
|
case X86::RETQ:
|
|
case X86::RETL:
|
|
case X86::RETIL:
|
|
case X86::RETIQ:
|
|
// If RET has an FP register use operand, pass the first one in ST(0) and
|
|
// the second one in ST(1).
|
|
|
|
// Find the register operands.
|
|
unsigned FirstFPRegOp = ~0U, SecondFPRegOp = ~0U;
|
|
unsigned LiveMask = 0;
|
|
|
|
for (unsigned i = 0, e = MI->getNumOperands(); i != e; ++i) {
|
|
MachineOperand &Op = MI->getOperand(i);
|
|
if (!Op.isReg() || Op.getReg() < X86::FP0 || Op.getReg() > X86::FP6)
|
|
continue;
|
|
// FP Register uses must be kills unless there are two uses of the same
|
|
// register, in which case only one will be a kill.
|
|
assert(Op.isUse() &&
|
|
(Op.isKill() || // Marked kill.
|
|
getFPReg(Op) == FirstFPRegOp || // Second instance.
|
|
MI->killsRegister(Op.getReg())) && // Later use is marked kill.
|
|
"Ret only defs operands, and values aren't live beyond it");
|
|
|
|
if (FirstFPRegOp == ~0U)
|
|
FirstFPRegOp = getFPReg(Op);
|
|
else {
|
|
assert(SecondFPRegOp == ~0U && "More than two fp operands!");
|
|
SecondFPRegOp = getFPReg(Op);
|
|
}
|
|
LiveMask |= (1 << getFPReg(Op));
|
|
|
|
// Remove the operand so that later passes don't see it.
|
|
MI->RemoveOperand(i);
|
|
--i, --e;
|
|
}
|
|
|
|
// We may have been carrying spurious live-ins, so make sure only the returned
|
|
// registers are left live.
|
|
adjustLiveRegs(LiveMask, MI);
|
|
if (!LiveMask) return; // Quick check to see if any are possible.
|
|
|
|
// There are only four possibilities here:
|
|
// 1) we are returning a single FP value. In this case, it has to be in
|
|
// ST(0) already, so just declare success by removing the value from the
|
|
// FP Stack.
|
|
if (SecondFPRegOp == ~0U) {
|
|
// Assert that the top of stack contains the right FP register.
|
|
assert(StackTop == 1 && FirstFPRegOp == getStackEntry(0) &&
|
|
"Top of stack not the right register for RET!");
|
|
|
|
// Ok, everything is good, mark the value as not being on the stack
|
|
// anymore so that our assertion about the stack being empty at end of
|
|
// block doesn't fire.
|
|
StackTop = 0;
|
|
return;
|
|
}
|
|
|
|
// Otherwise, we are returning two values:
|
|
// 2) If returning the same value for both, we only have one thing in the FP
|
|
// stack. Consider: RET FP1, FP1
|
|
if (StackTop == 1) {
|
|
assert(FirstFPRegOp == SecondFPRegOp && FirstFPRegOp == getStackEntry(0)&&
|
|
"Stack misconfiguration for RET!");
|
|
|
|
// Duplicate the TOS so that we return it twice. Just pick some other FPx
|
|
// register to hold it.
|
|
unsigned NewReg = ScratchFPReg;
|
|
duplicateToTop(FirstFPRegOp, NewReg, MI);
|
|
FirstFPRegOp = NewReg;
|
|
}
|
|
|
|
/// Okay we know we have two different FPx operands now:
|
|
assert(StackTop == 2 && "Must have two values live!");
|
|
|
|
/// 3) If SecondFPRegOp is currently in ST(0) and FirstFPRegOp is currently
|
|
/// in ST(1). In this case, emit an fxch.
|
|
if (getStackEntry(0) == SecondFPRegOp) {
|
|
assert(getStackEntry(1) == FirstFPRegOp && "Unknown regs live");
|
|
moveToTop(FirstFPRegOp, MI);
|
|
}
|
|
|
|
/// 4) Finally, FirstFPRegOp must be in ST(0) and SecondFPRegOp must be in
|
|
/// ST(1). Just remove both from our understanding of the stack and return.
|
|
assert(getStackEntry(0) == FirstFPRegOp && "Unknown regs live");
|
|
assert(getStackEntry(1) == SecondFPRegOp && "Unknown regs live");
|
|
StackTop = 0;
|
|
return;
|
|
}
|
|
|
|
Inst = MBB->erase(Inst); // Remove the pseudo instruction
|
|
|
|
// We want to leave I pointing to the previous instruction, but what if we
|
|
// just erased the first instruction?
|
|
if (Inst == MBB->begin()) {
|
|
DEBUG(dbgs() << "Inserting dummy KILL\n");
|
|
Inst = BuildMI(*MBB, Inst, DebugLoc(), TII->get(TargetOpcode::KILL));
|
|
} else
|
|
--Inst;
|
|
}
|
|
|
|
void FPS::setKillFlags(MachineBasicBlock &MBB) const {
|
|
const TargetRegisterInfo *TRI =
|
|
MBB.getParent()->getSubtarget().getRegisterInfo();
|
|
LivePhysRegs LPR(TRI);
|
|
|
|
LPR.addLiveOuts(&MBB);
|
|
|
|
for (MachineBasicBlock::reverse_iterator I = MBB.rbegin(), E = MBB.rend();
|
|
I != E; ++I) {
|
|
if (I->isDebugValue())
|
|
continue;
|
|
|
|
std::bitset<8> Defs;
|
|
SmallVector<MachineOperand *, 2> Uses;
|
|
MachineInstr &MI = *I;
|
|
|
|
for (auto &MO : I->operands()) {
|
|
if (!MO.isReg())
|
|
continue;
|
|
|
|
unsigned Reg = MO.getReg() - X86::FP0;
|
|
|
|
if (Reg >= 8)
|
|
continue;
|
|
|
|
if (MO.isDef()) {
|
|
Defs.set(Reg);
|
|
if (!LPR.contains(MO.getReg()))
|
|
MO.setIsDead();
|
|
} else
|
|
Uses.push_back(&MO);
|
|
}
|
|
|
|
for (auto *MO : Uses)
|
|
if (Defs.test(getFPReg(*MO)) || !LPR.contains(MO->getReg()))
|
|
MO->setIsKill();
|
|
|
|
LPR.stepBackward(MI);
|
|
}
|
|
}
|