1*ae6f7882SJeremy Morse //===- InstrRefBasedImpl.cpp - Tracking Debug Value MIs -------------------===// 2*ae6f7882SJeremy Morse // 3*ae6f7882SJeremy Morse // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. 4*ae6f7882SJeremy Morse // See https://llvm.org/LICENSE.txt for license information. 5*ae6f7882SJeremy Morse // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception 6*ae6f7882SJeremy Morse // 7*ae6f7882SJeremy Morse //===----------------------------------------------------------------------===// 8*ae6f7882SJeremy Morse /// \file InstrRefBasedImpl.cpp 9*ae6f7882SJeremy Morse /// 10*ae6f7882SJeremy Morse /// This is a separate implementation of LiveDebugValues, see 11*ae6f7882SJeremy Morse /// LiveDebugValues.cpp and VarLocBasedImpl.cpp for more information. 12*ae6f7882SJeremy Morse /// 13*ae6f7882SJeremy Morse /// This pass propagates variable locations between basic blocks, resolving 14*ae6f7882SJeremy Morse /// control flow conflicts between them. The problem is much like SSA 15*ae6f7882SJeremy Morse /// construction, where each DBG_VALUE instruction assigns the *value* that 16*ae6f7882SJeremy Morse /// a variable has, and every instruction where the variable is in scope uses 17*ae6f7882SJeremy Morse /// that variable. The resulting map of instruction-to-value is then translated 18*ae6f7882SJeremy Morse /// into a register (or spill) location for each variable over each instruction. 19*ae6f7882SJeremy Morse /// 20*ae6f7882SJeremy Morse /// This pass determines which DBG_VALUE dominates which instructions, or if 21*ae6f7882SJeremy Morse /// none do, where values must be merged (like PHI nodes). The added 22*ae6f7882SJeremy Morse /// complication is that because codegen has already finished, a PHI node may 23*ae6f7882SJeremy Morse /// be needed for a variable location to be correct, but no register or spill 24*ae6f7882SJeremy Morse /// slot merges the necessary values. In these circumstances, the variable 25*ae6f7882SJeremy Morse /// location is dropped. 26*ae6f7882SJeremy Morse /// 27*ae6f7882SJeremy Morse /// What makes this analysis non-trivial is loops: we cannot tell in advance 28*ae6f7882SJeremy Morse /// whether a variable location is live throughout a loop, or whether its 29*ae6f7882SJeremy Morse /// location is clobbered (or redefined by another DBG_VALUE), without 30*ae6f7882SJeremy Morse /// exploring all the way through. 31*ae6f7882SJeremy Morse /// 32*ae6f7882SJeremy Morse /// To make this simpler we perform two kinds of analysis. First, we identify 33*ae6f7882SJeremy Morse /// every value defined by every instruction (ignoring those that only move 34*ae6f7882SJeremy Morse /// another value), then compute a map of which values are available for each 35*ae6f7882SJeremy Morse /// instruction. This is stronger than a reaching-def analysis, as we create 36*ae6f7882SJeremy Morse /// PHI values where other values merge. 37*ae6f7882SJeremy Morse /// 38*ae6f7882SJeremy Morse /// Secondly, for each variable, we effectively re-construct SSA using each 39*ae6f7882SJeremy Morse /// DBG_VALUE as a def. The DBG_VALUEs read a value-number computed by the 40*ae6f7882SJeremy Morse /// first analysis from the location they refer to. We can then compute the 41*ae6f7882SJeremy Morse /// dominance frontiers of where a variable has a value, and create PHI nodes 42*ae6f7882SJeremy Morse /// where they merge. 43*ae6f7882SJeremy Morse /// This isn't precisely SSA-construction though, because the function shape 44*ae6f7882SJeremy Morse /// is pre-defined. If a variable location requires a PHI node, but no 45*ae6f7882SJeremy Morse /// PHI for the relevant values is present in the function (as computed by the 46*ae6f7882SJeremy Morse /// first analysis), the location must be dropped. 47*ae6f7882SJeremy Morse /// 48*ae6f7882SJeremy Morse /// Once both are complete, we can pass back over all instructions knowing: 49*ae6f7882SJeremy Morse /// * What _value_ each variable should contain, either defined by an 50*ae6f7882SJeremy Morse /// instruction or where control flow merges 51*ae6f7882SJeremy Morse /// * What the location of that value is (if any). 52*ae6f7882SJeremy Morse /// Allowing us to create appropriate live-in DBG_VALUEs, and DBG_VALUEs when 53*ae6f7882SJeremy Morse /// a value moves location. After this pass runs, all variable locations within 54*ae6f7882SJeremy Morse /// a block should be specified by DBG_VALUEs within that block, allowing 55*ae6f7882SJeremy Morse /// DbgEntityHistoryCalculator to focus on individual blocks. 56*ae6f7882SJeremy Morse /// 57*ae6f7882SJeremy Morse /// This pass is able to go fast because the size of the first 58*ae6f7882SJeremy Morse /// reaching-definition analysis is proportional to the working-set size of 59*ae6f7882SJeremy Morse /// the function, which the compiler tries to keep small. (It's also 60*ae6f7882SJeremy Morse /// proportional to the number of blocks). Additionally, we repeatedly perform 61*ae6f7882SJeremy Morse /// the second reaching-definition analysis with only the variables and blocks 62*ae6f7882SJeremy Morse /// in a single lexical scope, exploiting their locality. 63*ae6f7882SJeremy Morse /// 64*ae6f7882SJeremy Morse /// Determining where PHIs happen is trickier with this approach, and it comes 65*ae6f7882SJeremy Morse /// to a head in the major problem for LiveDebugValues: is a value live-through 66*ae6f7882SJeremy Morse /// a loop, or not? Your garden-variety dataflow analysis aims to build a set of 67*ae6f7882SJeremy Morse /// facts about a function, however this analysis needs to generate new value 68*ae6f7882SJeremy Morse /// numbers at joins. 69*ae6f7882SJeremy Morse /// 70*ae6f7882SJeremy Morse /// To do this, consider a lattice of all definition values, from instructions 71*ae6f7882SJeremy Morse /// and from PHIs. Each PHI is characterised by the RPO number of the block it 72*ae6f7882SJeremy Morse /// occurs in. Each value pair A, B can be ordered by RPO(A) < RPO(B): 73*ae6f7882SJeremy Morse /// with non-PHI values at the top, and any PHI value in the last block (by RPO 74*ae6f7882SJeremy Morse /// order) at the bottom. 75*ae6f7882SJeremy Morse /// 76*ae6f7882SJeremy Morse /// (Awkwardly: lower-down-the _lattice_ means a greater RPO _number_. Below, 77*ae6f7882SJeremy Morse /// "rank" always refers to the former). 78*ae6f7882SJeremy Morse /// 79*ae6f7882SJeremy Morse /// At any join, for each register, we consider: 80*ae6f7882SJeremy Morse /// * All incoming values, and 81*ae6f7882SJeremy Morse /// * The PREVIOUS live-in value at this join. 82*ae6f7882SJeremy Morse /// If all incoming values agree: that's the live-in value. If they do not, the 83*ae6f7882SJeremy Morse /// incoming values are ranked according to the partial order, and the NEXT 84*ae6f7882SJeremy Morse /// LOWEST rank after the PREVIOUS live-in value is picked (multiple values of 85*ae6f7882SJeremy Morse /// the same rank are ignored as conflicting). If there are no candidate values, 86*ae6f7882SJeremy Morse /// or if the rank of the live-in would be lower than the rank of the current 87*ae6f7882SJeremy Morse /// blocks PHIs, create a new PHI value. 88*ae6f7882SJeremy Morse /// 89*ae6f7882SJeremy Morse /// Intuitively: if it's not immediately obvious what value a join should result 90*ae6f7882SJeremy Morse /// in, we iteratively descend from instruction-definitions down through PHI 91*ae6f7882SJeremy Morse /// values, getting closer to the current block each time. If the current block 92*ae6f7882SJeremy Morse /// is a loop head, this ordering is effectively searching outer levels of 93*ae6f7882SJeremy Morse /// loops, to find a value that's live-through the current loop. 94*ae6f7882SJeremy Morse /// 95*ae6f7882SJeremy Morse /// If there is no value that's live-through this loop, a PHI is created for 96*ae6f7882SJeremy Morse /// this location instead. We can't use a lower-ranked PHI because by definition 97*ae6f7882SJeremy Morse /// it doesn't dominate the current block. We can't create a PHI value any 98*ae6f7882SJeremy Morse /// earlier, because we risk creating a PHI value at a location where values do 99*ae6f7882SJeremy Morse /// not in fact merge, thus misrepresenting the truth, and not making the true 100*ae6f7882SJeremy Morse /// live-through value for variable locations. 101*ae6f7882SJeremy Morse /// 102*ae6f7882SJeremy Morse /// This algorithm applies to both calculating the availability of values in 103*ae6f7882SJeremy Morse /// the first analysis, and the location of variables in the second. However 104*ae6f7882SJeremy Morse /// for the second we add an extra dimension of pain: creating a variable 105*ae6f7882SJeremy Morse /// location PHI is only valid if, for each incoming edge, 106*ae6f7882SJeremy Morse /// * There is a value for the variable on the incoming edge, and 107*ae6f7882SJeremy Morse /// * All the edges have that value in the same register. 108*ae6f7882SJeremy Morse /// Or put another way: we can only create a variable-location PHI if there is 109*ae6f7882SJeremy Morse /// a matching machine-location PHI, each input to which is the variables value 110*ae6f7882SJeremy Morse /// in the predecessor block. 111*ae6f7882SJeremy Morse /// 112*ae6f7882SJeremy Morse /// To accomodate this difference, each point on the lattice is split in 113*ae6f7882SJeremy Morse /// two: a "proposed" PHI and "definite" PHI. Any PHI that can immediately 114*ae6f7882SJeremy Morse /// have a location determined are "definite" PHIs, and no further work is 115*ae6f7882SJeremy Morse /// needed. Otherwise, a location that all non-backedge predecessors agree 116*ae6f7882SJeremy Morse /// on is picked and propagated as a "proposed" PHI value. If that PHI value 117*ae6f7882SJeremy Morse /// is truly live-through, it'll appear on the loop backedges on the next 118*ae6f7882SJeremy Morse /// dataflow iteration, after which the block live-in moves to be a "definite" 119*ae6f7882SJeremy Morse /// PHI. If it's not truly live-through, the variable value will be downgraded 120*ae6f7882SJeremy Morse /// further as we explore the lattice, or remains "proposed" and is considered 121*ae6f7882SJeremy Morse /// invalid once dataflow completes. 122*ae6f7882SJeremy Morse /// 123*ae6f7882SJeremy Morse /// ### Terminology 124*ae6f7882SJeremy Morse /// 125*ae6f7882SJeremy Morse /// A machine location is a register or spill slot, a value is something that's 126*ae6f7882SJeremy Morse /// defined by an instruction or PHI node, while a variable value is the value 127*ae6f7882SJeremy Morse /// assigned to a variable. A variable location is a machine location, that must 128*ae6f7882SJeremy Morse /// contain the appropriate variable value. A value that is a PHI node is 129*ae6f7882SJeremy Morse /// occasionally called an mphi. 130*ae6f7882SJeremy Morse /// 131*ae6f7882SJeremy Morse /// The first dataflow problem is the "machine value location" problem, 132*ae6f7882SJeremy Morse /// because we're determining which machine locations contain which values. 133*ae6f7882SJeremy Morse /// The "locations" are constant: what's unknown is what value they contain. 134*ae6f7882SJeremy Morse /// 135*ae6f7882SJeremy Morse /// The second dataflow problem (the one for variables) is the "variable value 136*ae6f7882SJeremy Morse /// problem", because it's determining what values a variable has, rather than 137*ae6f7882SJeremy Morse /// what location those values are placed in. Unfortunately, it's not that 138*ae6f7882SJeremy Morse /// simple, because producing a PHI value always involves picking a location. 139*ae6f7882SJeremy Morse /// This is an imperfection that we just have to accept, at least for now. 140*ae6f7882SJeremy Morse /// 141*ae6f7882SJeremy Morse /// TODO: 142*ae6f7882SJeremy Morse /// Overlapping fragments 143*ae6f7882SJeremy Morse /// Entry values 144*ae6f7882SJeremy Morse /// Add back DEBUG statements for debugging this 145*ae6f7882SJeremy Morse /// Collect statistics 146*ae6f7882SJeremy Morse /// 147*ae6f7882SJeremy Morse //===----------------------------------------------------------------------===// 148*ae6f7882SJeremy Morse 149*ae6f7882SJeremy Morse #include "llvm/ADT/DenseMap.h" 150*ae6f7882SJeremy Morse #include "llvm/ADT/PostOrderIterator.h" 151*ae6f7882SJeremy Morse #include "llvm/ADT/SmallPtrSet.h" 152*ae6f7882SJeremy Morse #include "llvm/ADT/SmallSet.h" 153*ae6f7882SJeremy Morse #include "llvm/ADT/SmallVector.h" 154*ae6f7882SJeremy Morse #include "llvm/ADT/Statistic.h" 155*ae6f7882SJeremy Morse #include "llvm/ADT/UniqueVector.h" 156*ae6f7882SJeremy Morse #include "llvm/CodeGen/LexicalScopes.h" 157*ae6f7882SJeremy Morse #include "llvm/CodeGen/MachineBasicBlock.h" 158*ae6f7882SJeremy Morse #include "llvm/CodeGen/MachineFrameInfo.h" 159*ae6f7882SJeremy Morse #include "llvm/CodeGen/MachineFunction.h" 160*ae6f7882SJeremy Morse #include "llvm/CodeGen/MachineFunctionPass.h" 161*ae6f7882SJeremy Morse #include "llvm/CodeGen/MachineInstr.h" 162*ae6f7882SJeremy Morse #include "llvm/CodeGen/MachineInstrBuilder.h" 163*ae6f7882SJeremy Morse #include "llvm/CodeGen/MachineMemOperand.h" 164*ae6f7882SJeremy Morse #include "llvm/CodeGen/MachineOperand.h" 165*ae6f7882SJeremy Morse #include "llvm/CodeGen/PseudoSourceValue.h" 166*ae6f7882SJeremy Morse #include "llvm/CodeGen/RegisterScavenging.h" 167*ae6f7882SJeremy Morse #include "llvm/CodeGen/TargetFrameLowering.h" 168*ae6f7882SJeremy Morse #include "llvm/CodeGen/TargetInstrInfo.h" 169*ae6f7882SJeremy Morse #include "llvm/CodeGen/TargetLowering.h" 170*ae6f7882SJeremy Morse #include "llvm/CodeGen/TargetPassConfig.h" 171*ae6f7882SJeremy Morse #include "llvm/CodeGen/TargetRegisterInfo.h" 172*ae6f7882SJeremy Morse #include "llvm/CodeGen/TargetSubtargetInfo.h" 173*ae6f7882SJeremy Morse #include "llvm/Config/llvm-config.h" 174*ae6f7882SJeremy Morse #include "llvm/IR/DIBuilder.h" 175*ae6f7882SJeremy Morse #include "llvm/IR/DebugInfoMetadata.h" 176*ae6f7882SJeremy Morse #include "llvm/IR/DebugLoc.h" 177*ae6f7882SJeremy Morse #include "llvm/IR/Function.h" 178*ae6f7882SJeremy Morse #include "llvm/IR/Module.h" 179*ae6f7882SJeremy Morse #include "llvm/InitializePasses.h" 180*ae6f7882SJeremy Morse #include "llvm/MC/MCRegisterInfo.h" 181*ae6f7882SJeremy Morse #include "llvm/Pass.h" 182*ae6f7882SJeremy Morse #include "llvm/Support/Casting.h" 183*ae6f7882SJeremy Morse #include "llvm/Support/Compiler.h" 184*ae6f7882SJeremy Morse #include "llvm/Support/Debug.h" 185*ae6f7882SJeremy Morse #include "llvm/Support/raw_ostream.h" 186*ae6f7882SJeremy Morse #include <algorithm> 187*ae6f7882SJeremy Morse #include <cassert> 188*ae6f7882SJeremy Morse #include <cstdint> 189*ae6f7882SJeremy Morse #include <functional> 190*ae6f7882SJeremy Morse #include <queue> 191*ae6f7882SJeremy Morse #include <tuple> 192*ae6f7882SJeremy Morse #include <utility> 193*ae6f7882SJeremy Morse #include <vector> 194*ae6f7882SJeremy Morse #include <limits.h> 195*ae6f7882SJeremy Morse #include <limits> 196*ae6f7882SJeremy Morse 197*ae6f7882SJeremy Morse #include "LiveDebugValues.h" 198*ae6f7882SJeremy Morse 199*ae6f7882SJeremy Morse using namespace llvm; 200*ae6f7882SJeremy Morse 201*ae6f7882SJeremy Morse #define DEBUG_TYPE "livedebugvalues" 202*ae6f7882SJeremy Morse 203*ae6f7882SJeremy Morse STATISTIC(NumInserted, "Number of DBG_VALUE instructions inserted"); 204*ae6f7882SJeremy Morse STATISTIC(NumRemoved, "Number of DBG_VALUE instructions removed"); 205*ae6f7882SJeremy Morse 206*ae6f7882SJeremy Morse // Act more like the VarLoc implementation, by propagating some locations too 207*ae6f7882SJeremy Morse // far and ignoring some transfers. 208*ae6f7882SJeremy Morse static cl::opt<bool> EmulateOldLDV("emulate-old-livedebugvalues", cl::Hidden, 209*ae6f7882SJeremy Morse cl::desc("Act like old LiveDebugValues did"), 210*ae6f7882SJeremy Morse cl::init(false)); 211*ae6f7882SJeremy Morse 212*ae6f7882SJeremy Morse // Rely on isStoreToStackSlotPostFE and similar to observe all stack spills. 213*ae6f7882SJeremy Morse static cl::opt<bool> 214*ae6f7882SJeremy Morse ObserveAllStackops("observe-all-stack-ops", cl::Hidden, 215*ae6f7882SJeremy Morse cl::desc("Allow non-kill spill and restores"), 216*ae6f7882SJeremy Morse cl::init(false)); 217*ae6f7882SJeremy Morse 218*ae6f7882SJeremy Morse namespace { 219*ae6f7882SJeremy Morse 220*ae6f7882SJeremy Morse // The location at which a spilled value resides. It consists of a register and 221*ae6f7882SJeremy Morse // an offset. 222*ae6f7882SJeremy Morse struct SpillLoc { 223*ae6f7882SJeremy Morse unsigned SpillBase; 224*ae6f7882SJeremy Morse int SpillOffset; 225*ae6f7882SJeremy Morse bool operator==(const SpillLoc &Other) const { 226*ae6f7882SJeremy Morse return std::tie(SpillBase, SpillOffset) == 227*ae6f7882SJeremy Morse std::tie(Other.SpillBase, Other.SpillOffset); 228*ae6f7882SJeremy Morse } 229*ae6f7882SJeremy Morse bool operator<(const SpillLoc &Other) const { 230*ae6f7882SJeremy Morse return std::tie(SpillBase, SpillOffset) < 231*ae6f7882SJeremy Morse std::tie(Other.SpillBase, Other.SpillOffset); 232*ae6f7882SJeremy Morse } 233*ae6f7882SJeremy Morse }; 234*ae6f7882SJeremy Morse 235*ae6f7882SJeremy Morse class LocIdx { 236*ae6f7882SJeremy Morse unsigned Location; 237*ae6f7882SJeremy Morse 238*ae6f7882SJeremy Morse // Default constructor is private, initializing to an illegal location number. 239*ae6f7882SJeremy Morse // Use only for "not an entry" elements in IndexedMaps. 240*ae6f7882SJeremy Morse LocIdx() : Location(UINT_MAX) { } 241*ae6f7882SJeremy Morse 242*ae6f7882SJeremy Morse public: 243*ae6f7882SJeremy Morse #define NUM_LOC_BITS 24 244*ae6f7882SJeremy Morse LocIdx(unsigned L) : Location(L) { 245*ae6f7882SJeremy Morse assert(L < (1 << NUM_LOC_BITS) && "Machine locations must fit in 24 bits"); 246*ae6f7882SJeremy Morse } 247*ae6f7882SJeremy Morse 248*ae6f7882SJeremy Morse static LocIdx MakeIllegalLoc() { 249*ae6f7882SJeremy Morse return LocIdx(); 250*ae6f7882SJeremy Morse } 251*ae6f7882SJeremy Morse 252*ae6f7882SJeremy Morse bool isIllegal() const { 253*ae6f7882SJeremy Morse return Location == UINT_MAX; 254*ae6f7882SJeremy Morse } 255*ae6f7882SJeremy Morse 256*ae6f7882SJeremy Morse uint64_t asU64() const { 257*ae6f7882SJeremy Morse return Location; 258*ae6f7882SJeremy Morse } 259*ae6f7882SJeremy Morse 260*ae6f7882SJeremy Morse bool operator==(unsigned L) const { 261*ae6f7882SJeremy Morse return Location == L; 262*ae6f7882SJeremy Morse } 263*ae6f7882SJeremy Morse 264*ae6f7882SJeremy Morse bool operator==(const LocIdx &L) const { 265*ae6f7882SJeremy Morse return Location == L.Location; 266*ae6f7882SJeremy Morse } 267*ae6f7882SJeremy Morse 268*ae6f7882SJeremy Morse bool operator!=(unsigned L) const { 269*ae6f7882SJeremy Morse return !(*this == L); 270*ae6f7882SJeremy Morse } 271*ae6f7882SJeremy Morse 272*ae6f7882SJeremy Morse bool operator!=(const LocIdx &L) const { 273*ae6f7882SJeremy Morse return !(*this == L); 274*ae6f7882SJeremy Morse } 275*ae6f7882SJeremy Morse 276*ae6f7882SJeremy Morse bool operator<(const LocIdx &Other) const { 277*ae6f7882SJeremy Morse return Location < Other.Location; 278*ae6f7882SJeremy Morse } 279*ae6f7882SJeremy Morse }; 280*ae6f7882SJeremy Morse 281*ae6f7882SJeremy Morse class LocIdxToIndexFunctor { 282*ae6f7882SJeremy Morse public: 283*ae6f7882SJeremy Morse using argument_type = LocIdx; 284*ae6f7882SJeremy Morse unsigned operator()(const LocIdx &L) const { 285*ae6f7882SJeremy Morse return L.asU64(); 286*ae6f7882SJeremy Morse } 287*ae6f7882SJeremy Morse }; 288*ae6f7882SJeremy Morse 289*ae6f7882SJeremy Morse /// Unique identifier for a value defined by an instruction, as a value type. 290*ae6f7882SJeremy Morse /// Casts back and forth to a uint64_t. Probably replacable with something less 291*ae6f7882SJeremy Morse /// bit-constrained. Each value identifies the instruction and machine location 292*ae6f7882SJeremy Morse /// where the value is defined, although there may be no corresponding machine 293*ae6f7882SJeremy Morse /// operand for it (ex: regmasks clobbering values). The instructions are 294*ae6f7882SJeremy Morse /// one-based, and definitions that are PHIs have instruction number zero. 295*ae6f7882SJeremy Morse /// 296*ae6f7882SJeremy Morse /// The obvious limits of a 1M block function or 1M instruction blocks are 297*ae6f7882SJeremy Morse /// problematic; but by that point we should probably have bailed out of 298*ae6f7882SJeremy Morse /// trying to analyse the function. 299*ae6f7882SJeremy Morse class ValueIDNum { 300*ae6f7882SJeremy Morse uint64_t BlockNo : 20; /// The block where the def happens. 301*ae6f7882SJeremy Morse uint64_t InstNo : 20; /// The Instruction where the def happens. 302*ae6f7882SJeremy Morse /// One based, is distance from start of block. 303*ae6f7882SJeremy Morse uint64_t LocNo : NUM_LOC_BITS; /// The machine location where the def happens. 304*ae6f7882SJeremy Morse 305*ae6f7882SJeremy Morse public: 306*ae6f7882SJeremy Morse // XXX -- temporarily enabled while the live-in / live-out tables are moved 307*ae6f7882SJeremy Morse // to something more type-y 308*ae6f7882SJeremy Morse ValueIDNum() : BlockNo(0xFFFFF), 309*ae6f7882SJeremy Morse InstNo(0xFFFFF), 310*ae6f7882SJeremy Morse LocNo(0xFFFFFF) { } 311*ae6f7882SJeremy Morse 312*ae6f7882SJeremy Morse ValueIDNum(uint64_t Block, uint64_t Inst, uint64_t Loc) 313*ae6f7882SJeremy Morse : BlockNo(Block), InstNo(Inst), LocNo(Loc) { } 314*ae6f7882SJeremy Morse 315*ae6f7882SJeremy Morse ValueIDNum(uint64_t Block, uint64_t Inst, LocIdx Loc) 316*ae6f7882SJeremy Morse : BlockNo(Block), InstNo(Inst), LocNo(Loc.asU64()) { } 317*ae6f7882SJeremy Morse 318*ae6f7882SJeremy Morse uint64_t getBlock() const { return BlockNo; } 319*ae6f7882SJeremy Morse uint64_t getInst() const { return InstNo; } 320*ae6f7882SJeremy Morse uint64_t getLoc() const { return LocNo; } 321*ae6f7882SJeremy Morse bool isPHI() const { return InstNo == 0; } 322*ae6f7882SJeremy Morse 323*ae6f7882SJeremy Morse uint64_t asU64() const { 324*ae6f7882SJeremy Morse uint64_t TmpBlock = BlockNo; 325*ae6f7882SJeremy Morse uint64_t TmpInst = InstNo; 326*ae6f7882SJeremy Morse return TmpBlock << 44ull | TmpInst << NUM_LOC_BITS | LocNo; 327*ae6f7882SJeremy Morse } 328*ae6f7882SJeremy Morse 329*ae6f7882SJeremy Morse static ValueIDNum fromU64(uint64_t v) { 330*ae6f7882SJeremy Morse uint64_t L = (v & 0x3FFF); 331*ae6f7882SJeremy Morse return {v >> 44ull, ((v >> NUM_LOC_BITS) & 0xFFFFF), L}; 332*ae6f7882SJeremy Morse } 333*ae6f7882SJeremy Morse 334*ae6f7882SJeremy Morse bool operator<(const ValueIDNum &Other) const { 335*ae6f7882SJeremy Morse return asU64() < Other.asU64(); 336*ae6f7882SJeremy Morse } 337*ae6f7882SJeremy Morse 338*ae6f7882SJeremy Morse bool operator==(const ValueIDNum &Other) const { 339*ae6f7882SJeremy Morse return std::tie(BlockNo, InstNo, LocNo) == 340*ae6f7882SJeremy Morse std::tie(Other.BlockNo, Other.InstNo, Other.LocNo); 341*ae6f7882SJeremy Morse } 342*ae6f7882SJeremy Morse 343*ae6f7882SJeremy Morse bool operator!=(const ValueIDNum &Other) const { return !(*this == Other); } 344*ae6f7882SJeremy Morse 345*ae6f7882SJeremy Morse std::string asString(const std::string &mlocname) const { 346*ae6f7882SJeremy Morse return Twine("bb ") 347*ae6f7882SJeremy Morse .concat(Twine(BlockNo).concat(Twine(" inst ").concat( 348*ae6f7882SJeremy Morse Twine(InstNo).concat(Twine(" loc ").concat(Twine(mlocname)))))) 349*ae6f7882SJeremy Morse .str(); 350*ae6f7882SJeremy Morse } 351*ae6f7882SJeremy Morse 352*ae6f7882SJeremy Morse static ValueIDNum EmptyValue; 353*ae6f7882SJeremy Morse }; 354*ae6f7882SJeremy Morse 355*ae6f7882SJeremy Morse } // end anonymous namespace 356*ae6f7882SJeremy Morse 357*ae6f7882SJeremy Morse namespace { 358*ae6f7882SJeremy Morse 359*ae6f7882SJeremy Morse /// Meta qualifiers for a value. Pair of whatever expression is used to qualify 360*ae6f7882SJeremy Morse /// the the value, and Boolean of whether or not it's indirect. 361*ae6f7882SJeremy Morse class DbgValueProperties { 362*ae6f7882SJeremy Morse public: 363*ae6f7882SJeremy Morse DbgValueProperties(const DIExpression *DIExpr, bool Indirect) 364*ae6f7882SJeremy Morse : DIExpr(DIExpr), Indirect(Indirect) {} 365*ae6f7882SJeremy Morse 366*ae6f7882SJeremy Morse DbgValueProperties(const DbgValueProperties &Cpy) 367*ae6f7882SJeremy Morse : DIExpr(Cpy.DIExpr), Indirect(Cpy.Indirect) {} 368*ae6f7882SJeremy Morse 369*ae6f7882SJeremy Morse /// Extract properties from an existing DBG_VALUE instruction. 370*ae6f7882SJeremy Morse DbgValueProperties(const MachineInstr &MI) { 371*ae6f7882SJeremy Morse assert(MI.isDebugValue()); 372*ae6f7882SJeremy Morse DIExpr = MI.getDebugExpression(); 373*ae6f7882SJeremy Morse Indirect = MI.getOperand(1).isImm(); 374*ae6f7882SJeremy Morse } 375*ae6f7882SJeremy Morse 376*ae6f7882SJeremy Morse bool operator==(const DbgValueProperties &Other) const { 377*ae6f7882SJeremy Morse return std::tie(DIExpr, Indirect) == std::tie(Other.DIExpr, Other.Indirect); 378*ae6f7882SJeremy Morse } 379*ae6f7882SJeremy Morse 380*ae6f7882SJeremy Morse bool operator!=(const DbgValueProperties &Other) const { 381*ae6f7882SJeremy Morse return !(*this == Other); 382*ae6f7882SJeremy Morse } 383*ae6f7882SJeremy Morse 384*ae6f7882SJeremy Morse const DIExpression *DIExpr; 385*ae6f7882SJeremy Morse bool Indirect; 386*ae6f7882SJeremy Morse }; 387*ae6f7882SJeremy Morse 388*ae6f7882SJeremy Morse /// Tracker for what values are in machine locations. Listens to the Things 389*ae6f7882SJeremy Morse /// being Done by various instructions, and maintains a table of what machine 390*ae6f7882SJeremy Morse /// locations have what values (as defined by a ValueIDNum). 391*ae6f7882SJeremy Morse /// 392*ae6f7882SJeremy Morse /// There are potentially a much larger number of machine locations on the 393*ae6f7882SJeremy Morse /// target machine than the actual working-set size of the function. On x86 for 394*ae6f7882SJeremy Morse /// example, we're extremely unlikely to want to track values through control 395*ae6f7882SJeremy Morse /// or debug registers. To avoid doing so, MLocTracker has several layers of 396*ae6f7882SJeremy Morse /// indirection going on, with two kinds of ``location'': 397*ae6f7882SJeremy Morse /// * A LocID uniquely identifies a register or spill location, with a 398*ae6f7882SJeremy Morse /// predictable value. 399*ae6f7882SJeremy Morse /// * A LocIdx is a key (in the database sense) for a LocID and a ValueIDNum. 400*ae6f7882SJeremy Morse /// Whenever a location is def'd or used by a MachineInstr, we automagically 401*ae6f7882SJeremy Morse /// create a new LocIdx for a location, but not otherwise. This ensures we only 402*ae6f7882SJeremy Morse /// account for locations that are actually used or defined. The cost is another 403*ae6f7882SJeremy Morse /// vector lookup (of LocID -> LocIdx) over any other implementation. This is 404*ae6f7882SJeremy Morse /// fairly cheap, and the compiler tries to reduce the working-set at any one 405*ae6f7882SJeremy Morse /// time in the function anyway. 406*ae6f7882SJeremy Morse /// 407*ae6f7882SJeremy Morse /// Register mask operands completely blow this out of the water; I've just 408*ae6f7882SJeremy Morse /// piled hacks on top of hacks to get around that. 409*ae6f7882SJeremy Morse class MLocTracker { 410*ae6f7882SJeremy Morse public: 411*ae6f7882SJeremy Morse MachineFunction &MF; 412*ae6f7882SJeremy Morse const TargetInstrInfo &TII; 413*ae6f7882SJeremy Morse const TargetRegisterInfo &TRI; 414*ae6f7882SJeremy Morse const TargetLowering &TLI; 415*ae6f7882SJeremy Morse 416*ae6f7882SJeremy Morse /// IndexedMap type, mapping from LocIdx to ValueIDNum. 417*ae6f7882SJeremy Morse typedef IndexedMap<ValueIDNum, LocIdxToIndexFunctor> LocToValueType; 418*ae6f7882SJeremy Morse 419*ae6f7882SJeremy Morse /// Map of LocIdxes to the ValueIDNums that they store. This is tightly 420*ae6f7882SJeremy Morse /// packed, entries only exist for locations that are being tracked. 421*ae6f7882SJeremy Morse LocToValueType LocIdxToIDNum; 422*ae6f7882SJeremy Morse 423*ae6f7882SJeremy Morse /// "Map" of machine location IDs (i.e., raw register or spill number) to the 424*ae6f7882SJeremy Morse /// LocIdx key / number for that location. There are always at least as many 425*ae6f7882SJeremy Morse /// as the number of registers on the target -- if the value in the register 426*ae6f7882SJeremy Morse /// is not being tracked, then the LocIdx value will be zero. New entries are 427*ae6f7882SJeremy Morse /// appended if a new spill slot begins being tracked. 428*ae6f7882SJeremy Morse /// This, and the corresponding reverse map persist for the analysis of the 429*ae6f7882SJeremy Morse /// whole function, and is necessarying for decoding various vectors of 430*ae6f7882SJeremy Morse /// values. 431*ae6f7882SJeremy Morse std::vector<LocIdx> LocIDToLocIdx; 432*ae6f7882SJeremy Morse 433*ae6f7882SJeremy Morse /// Inverse map of LocIDToLocIdx. 434*ae6f7882SJeremy Morse IndexedMap<unsigned, LocIdxToIndexFunctor> LocIdxToLocID; 435*ae6f7882SJeremy Morse 436*ae6f7882SJeremy Morse /// Unique-ification of spill slots. Used to number them -- their LocID 437*ae6f7882SJeremy Morse /// number is the index in SpillLocs minus one plus NumRegs. 438*ae6f7882SJeremy Morse UniqueVector<SpillLoc> SpillLocs; 439*ae6f7882SJeremy Morse 440*ae6f7882SJeremy Morse // If we discover a new machine location, assign it an mphi with this 441*ae6f7882SJeremy Morse // block number. 442*ae6f7882SJeremy Morse unsigned CurBB; 443*ae6f7882SJeremy Morse 444*ae6f7882SJeremy Morse /// Cached local copy of the number of registers the target has. 445*ae6f7882SJeremy Morse unsigned NumRegs; 446*ae6f7882SJeremy Morse 447*ae6f7882SJeremy Morse /// Collection of register mask operands that have been observed. Second part 448*ae6f7882SJeremy Morse /// of pair indicates the instruction that they happened in. Used to 449*ae6f7882SJeremy Morse /// reconstruct where defs happened if we start tracking a location later 450*ae6f7882SJeremy Morse /// on. 451*ae6f7882SJeremy Morse SmallVector<std::pair<const MachineOperand *, unsigned>, 32> Masks; 452*ae6f7882SJeremy Morse 453*ae6f7882SJeremy Morse /// Iterator for locations and the values they contain. Dereferencing 454*ae6f7882SJeremy Morse /// produces a struct/pair containing the LocIdx key for this location, 455*ae6f7882SJeremy Morse /// and a reference to the value currently stored. Simplifies the process 456*ae6f7882SJeremy Morse /// of seeking a particular location. 457*ae6f7882SJeremy Morse class MLocIterator { 458*ae6f7882SJeremy Morse LocToValueType &ValueMap; 459*ae6f7882SJeremy Morse LocIdx Idx; 460*ae6f7882SJeremy Morse 461*ae6f7882SJeremy Morse public: 462*ae6f7882SJeremy Morse class value_type { 463*ae6f7882SJeremy Morse public: 464*ae6f7882SJeremy Morse value_type(LocIdx Idx, ValueIDNum &Value) : Idx(Idx), Value(Value) { } 465*ae6f7882SJeremy Morse const LocIdx Idx; /// Read-only index of this location. 466*ae6f7882SJeremy Morse ValueIDNum &Value; /// Reference to the stored value at this location. 467*ae6f7882SJeremy Morse }; 468*ae6f7882SJeremy Morse 469*ae6f7882SJeremy Morse MLocIterator(LocToValueType &ValueMap, LocIdx Idx) 470*ae6f7882SJeremy Morse : ValueMap(ValueMap), Idx(Idx) { } 471*ae6f7882SJeremy Morse 472*ae6f7882SJeremy Morse bool operator==(const MLocIterator &Other) const { 473*ae6f7882SJeremy Morse assert(&ValueMap == &Other.ValueMap); 474*ae6f7882SJeremy Morse return Idx == Other.Idx; 475*ae6f7882SJeremy Morse } 476*ae6f7882SJeremy Morse 477*ae6f7882SJeremy Morse bool operator!=(const MLocIterator &Other) const { 478*ae6f7882SJeremy Morse return !(*this == Other); 479*ae6f7882SJeremy Morse } 480*ae6f7882SJeremy Morse 481*ae6f7882SJeremy Morse void operator++() { 482*ae6f7882SJeremy Morse Idx = LocIdx(Idx.asU64() + 1); 483*ae6f7882SJeremy Morse } 484*ae6f7882SJeremy Morse 485*ae6f7882SJeremy Morse value_type operator*() { 486*ae6f7882SJeremy Morse return value_type(Idx, ValueMap[LocIdx(Idx)]); 487*ae6f7882SJeremy Morse } 488*ae6f7882SJeremy Morse }; 489*ae6f7882SJeremy Morse 490*ae6f7882SJeremy Morse MLocTracker(MachineFunction &MF, const TargetInstrInfo &TII, 491*ae6f7882SJeremy Morse const TargetRegisterInfo &TRI, const TargetLowering &TLI) 492*ae6f7882SJeremy Morse : MF(MF), TII(TII), TRI(TRI), TLI(TLI), 493*ae6f7882SJeremy Morse LocIdxToIDNum(ValueIDNum::EmptyValue), 494*ae6f7882SJeremy Morse LocIdxToLocID(0) { 495*ae6f7882SJeremy Morse NumRegs = TRI.getNumRegs(); 496*ae6f7882SJeremy Morse reset(); 497*ae6f7882SJeremy Morse LocIDToLocIdx.resize(NumRegs, LocIdx::MakeIllegalLoc()); 498*ae6f7882SJeremy Morse assert(NumRegs < (1u << NUM_LOC_BITS)); // Detect bit packing failure 499*ae6f7882SJeremy Morse 500*ae6f7882SJeremy Morse // Always track SP. This avoids the implicit clobbering caused by regmasks 501*ae6f7882SJeremy Morse // from affectings its values. (LiveDebugValues disbelieves calls and 502*ae6f7882SJeremy Morse // regmasks that claim to clobber SP). 503*ae6f7882SJeremy Morse unsigned SP = TLI.getStackPointerRegisterToSaveRestore(); 504*ae6f7882SJeremy Morse if (SP) { 505*ae6f7882SJeremy Morse unsigned ID = getLocID(SP, false); 506*ae6f7882SJeremy Morse (void)lookupOrTrackRegister(ID); 507*ae6f7882SJeremy Morse } 508*ae6f7882SJeremy Morse } 509*ae6f7882SJeremy Morse 510*ae6f7882SJeremy Morse /// Produce location ID number for indexing LocIDToLocIdx. Takes the register 511*ae6f7882SJeremy Morse /// or spill number, and flag for whether it's a spill or not. 512*ae6f7882SJeremy Morse unsigned getLocID(unsigned RegOrSpill, bool isSpill) { 513*ae6f7882SJeremy Morse return (isSpill) ? RegOrSpill + NumRegs - 1 : RegOrSpill; 514*ae6f7882SJeremy Morse } 515*ae6f7882SJeremy Morse 516*ae6f7882SJeremy Morse /// Accessor for reading the value at Idx. 517*ae6f7882SJeremy Morse ValueIDNum getNumAtPos(LocIdx Idx) const { 518*ae6f7882SJeremy Morse assert(Idx.asU64() < LocIdxToIDNum.size()); 519*ae6f7882SJeremy Morse return LocIdxToIDNum[Idx]; 520*ae6f7882SJeremy Morse } 521*ae6f7882SJeremy Morse 522*ae6f7882SJeremy Morse unsigned getNumLocs(void) const { return LocIdxToIDNum.size(); } 523*ae6f7882SJeremy Morse 524*ae6f7882SJeremy Morse /// Reset all locations to contain a PHI value at the designated block. Used 525*ae6f7882SJeremy Morse /// sometimes for actual PHI values, othertimes to indicate the block entry 526*ae6f7882SJeremy Morse /// value (before any more information is known). 527*ae6f7882SJeremy Morse void setMPhis(unsigned NewCurBB) { 528*ae6f7882SJeremy Morse CurBB = NewCurBB; 529*ae6f7882SJeremy Morse for (auto Location : locations()) 530*ae6f7882SJeremy Morse Location.Value = {CurBB, 0, Location.Idx}; 531*ae6f7882SJeremy Morse } 532*ae6f7882SJeremy Morse 533*ae6f7882SJeremy Morse /// Load values for each location from array of ValueIDNums. Take current 534*ae6f7882SJeremy Morse /// bbnum just in case we read a value from a hitherto untouched register. 535*ae6f7882SJeremy Morse void loadFromArray(ValueIDNum *Locs, unsigned NewCurBB) { 536*ae6f7882SJeremy Morse CurBB = NewCurBB; 537*ae6f7882SJeremy Morse // Iterate over all tracked locations, and load each locations live-in 538*ae6f7882SJeremy Morse // value into our local index. 539*ae6f7882SJeremy Morse for (auto Location : locations()) 540*ae6f7882SJeremy Morse Location.Value = Locs[Location.Idx.asU64()]; 541*ae6f7882SJeremy Morse } 542*ae6f7882SJeremy Morse 543*ae6f7882SJeremy Morse /// Wipe any un-necessary location records after traversing a block. 544*ae6f7882SJeremy Morse void reset(void) { 545*ae6f7882SJeremy Morse // We could reset all the location values too; however either loadFromArray 546*ae6f7882SJeremy Morse // or setMPhis should be called before this object is re-used. Just 547*ae6f7882SJeremy Morse // clear Masks, they're definitely not needed. 548*ae6f7882SJeremy Morse Masks.clear(); 549*ae6f7882SJeremy Morse } 550*ae6f7882SJeremy Morse 551*ae6f7882SJeremy Morse /// Clear all data. Destroys the LocID <=> LocIdx map, which makes most of 552*ae6f7882SJeremy Morse /// the information in this pass uninterpretable. 553*ae6f7882SJeremy Morse void clear(void) { 554*ae6f7882SJeremy Morse reset(); 555*ae6f7882SJeremy Morse LocIDToLocIdx.clear(); 556*ae6f7882SJeremy Morse LocIdxToLocID.clear(); 557*ae6f7882SJeremy Morse LocIdxToIDNum.clear(); 558*ae6f7882SJeremy Morse //SpillLocs.reset(); XXX UniqueVector::reset assumes a SpillLoc casts from 0 559*ae6f7882SJeremy Morse SpillLocs = decltype(SpillLocs)(); 560*ae6f7882SJeremy Morse 561*ae6f7882SJeremy Morse LocIDToLocIdx.resize(NumRegs, LocIdx::MakeIllegalLoc()); 562*ae6f7882SJeremy Morse } 563*ae6f7882SJeremy Morse 564*ae6f7882SJeremy Morse /// Set a locaiton to a certain value. 565*ae6f7882SJeremy Morse void setMLoc(LocIdx L, ValueIDNum Num) { 566*ae6f7882SJeremy Morse assert(L.asU64() < LocIdxToIDNum.size()); 567*ae6f7882SJeremy Morse LocIdxToIDNum[L] = Num; 568*ae6f7882SJeremy Morse } 569*ae6f7882SJeremy Morse 570*ae6f7882SJeremy Morse /// Create a LocIdx for an untracked register ID. Initialize it to either an 571*ae6f7882SJeremy Morse /// mphi value representing a live-in, or a recent register mask clobber. 572*ae6f7882SJeremy Morse LocIdx trackRegister(unsigned ID) { 573*ae6f7882SJeremy Morse assert(ID != 0); 574*ae6f7882SJeremy Morse LocIdx NewIdx = LocIdx(LocIdxToIDNum.size()); 575*ae6f7882SJeremy Morse LocIdxToIDNum.grow(NewIdx); 576*ae6f7882SJeremy Morse LocIdxToLocID.grow(NewIdx); 577*ae6f7882SJeremy Morse 578*ae6f7882SJeremy Morse // Default: it's an mphi. 579*ae6f7882SJeremy Morse ValueIDNum ValNum = {CurBB, 0, NewIdx}; 580*ae6f7882SJeremy Morse // Was this reg ever touched by a regmask? 581*ae6f7882SJeremy Morse for (const auto &MaskPair : reverse(Masks)) { 582*ae6f7882SJeremy Morse if (MaskPair.first->clobbersPhysReg(ID)) { 583*ae6f7882SJeremy Morse // There was an earlier def we skipped. 584*ae6f7882SJeremy Morse ValNum = {CurBB, MaskPair.second, NewIdx}; 585*ae6f7882SJeremy Morse break; 586*ae6f7882SJeremy Morse } 587*ae6f7882SJeremy Morse } 588*ae6f7882SJeremy Morse 589*ae6f7882SJeremy Morse LocIdxToIDNum[NewIdx] = ValNum; 590*ae6f7882SJeremy Morse LocIdxToLocID[NewIdx] = ID; 591*ae6f7882SJeremy Morse return NewIdx; 592*ae6f7882SJeremy Morse } 593*ae6f7882SJeremy Morse 594*ae6f7882SJeremy Morse LocIdx lookupOrTrackRegister(unsigned ID) { 595*ae6f7882SJeremy Morse LocIdx &Index = LocIDToLocIdx[ID]; 596*ae6f7882SJeremy Morse if (Index.isIllegal()) 597*ae6f7882SJeremy Morse Index = trackRegister(ID); 598*ae6f7882SJeremy Morse return Index; 599*ae6f7882SJeremy Morse } 600*ae6f7882SJeremy Morse 601*ae6f7882SJeremy Morse /// Record a definition of the specified register at the given block / inst. 602*ae6f7882SJeremy Morse /// This doesn't take a ValueIDNum, because the definition and its location 603*ae6f7882SJeremy Morse /// are synonymous. 604*ae6f7882SJeremy Morse void defReg(Register R, unsigned BB, unsigned Inst) { 605*ae6f7882SJeremy Morse unsigned ID = getLocID(R, false); 606*ae6f7882SJeremy Morse LocIdx Idx = lookupOrTrackRegister(ID); 607*ae6f7882SJeremy Morse ValueIDNum ValueID = {BB, Inst, Idx}; 608*ae6f7882SJeremy Morse LocIdxToIDNum[Idx] = ValueID; 609*ae6f7882SJeremy Morse } 610*ae6f7882SJeremy Morse 611*ae6f7882SJeremy Morse /// Set a register to a value number. To be used if the value number is 612*ae6f7882SJeremy Morse /// known in advance. 613*ae6f7882SJeremy Morse void setReg(Register R, ValueIDNum ValueID) { 614*ae6f7882SJeremy Morse unsigned ID = getLocID(R, false); 615*ae6f7882SJeremy Morse LocIdx Idx = lookupOrTrackRegister(ID); 616*ae6f7882SJeremy Morse LocIdxToIDNum[Idx] = ValueID; 617*ae6f7882SJeremy Morse } 618*ae6f7882SJeremy Morse 619*ae6f7882SJeremy Morse ValueIDNum readReg(Register R) { 620*ae6f7882SJeremy Morse unsigned ID = getLocID(R, false); 621*ae6f7882SJeremy Morse LocIdx Idx = lookupOrTrackRegister(ID); 622*ae6f7882SJeremy Morse return LocIdxToIDNum[Idx]; 623*ae6f7882SJeremy Morse } 624*ae6f7882SJeremy Morse 625*ae6f7882SJeremy Morse /// Reset a register value to zero / empty. Needed to replicate the 626*ae6f7882SJeremy Morse /// VarLoc implementation where a copy to/from a register effectively 627*ae6f7882SJeremy Morse /// clears the contents of the source register. (Values can only have one 628*ae6f7882SJeremy Morse /// machine location in VarLocBasedImpl). 629*ae6f7882SJeremy Morse void wipeRegister(Register R) { 630*ae6f7882SJeremy Morse unsigned ID = getLocID(R, false); 631*ae6f7882SJeremy Morse LocIdx Idx = LocIDToLocIdx[ID]; 632*ae6f7882SJeremy Morse LocIdxToIDNum[Idx] = ValueIDNum::EmptyValue; 633*ae6f7882SJeremy Morse } 634*ae6f7882SJeremy Morse 635*ae6f7882SJeremy Morse /// Determine the LocIdx of an existing register. 636*ae6f7882SJeremy Morse LocIdx getRegMLoc(Register R) { 637*ae6f7882SJeremy Morse unsigned ID = getLocID(R, false); 638*ae6f7882SJeremy Morse return LocIDToLocIdx[ID]; 639*ae6f7882SJeremy Morse } 640*ae6f7882SJeremy Morse 641*ae6f7882SJeremy Morse /// Record a RegMask operand being executed. Defs any register we currently 642*ae6f7882SJeremy Morse /// track, stores a pointer to the mask in case we have to account for it 643*ae6f7882SJeremy Morse /// later. 644*ae6f7882SJeremy Morse void writeRegMask(const MachineOperand *MO, unsigned CurBB, unsigned InstID) { 645*ae6f7882SJeremy Morse // Ensure SP exists, so that we don't override it later. 646*ae6f7882SJeremy Morse unsigned SP = TLI.getStackPointerRegisterToSaveRestore(); 647*ae6f7882SJeremy Morse 648*ae6f7882SJeremy Morse // Def any register we track have that isn't preserved. The regmask 649*ae6f7882SJeremy Morse // terminates the liveness of a register, meaning its value can't be 650*ae6f7882SJeremy Morse // relied upon -- we represent this by giving it a new value. 651*ae6f7882SJeremy Morse for (auto Location : locations()) { 652*ae6f7882SJeremy Morse unsigned ID = LocIdxToLocID[Location.Idx]; 653*ae6f7882SJeremy Morse // Don't clobber SP, even if the mask says it's clobbered. 654*ae6f7882SJeremy Morse if (ID < NumRegs && ID != SP && MO->clobbersPhysReg(ID)) 655*ae6f7882SJeremy Morse defReg(ID, CurBB, InstID); 656*ae6f7882SJeremy Morse } 657*ae6f7882SJeremy Morse Masks.push_back(std::make_pair(MO, InstID)); 658*ae6f7882SJeremy Morse } 659*ae6f7882SJeremy Morse 660*ae6f7882SJeremy Morse /// Find LocIdx for SpillLoc \p L, creating a new one if it's not tracked. 661*ae6f7882SJeremy Morse LocIdx getOrTrackSpillLoc(SpillLoc L) { 662*ae6f7882SJeremy Morse unsigned SpillID = SpillLocs.idFor(L); 663*ae6f7882SJeremy Morse if (SpillID == 0) { 664*ae6f7882SJeremy Morse SpillID = SpillLocs.insert(L); 665*ae6f7882SJeremy Morse unsigned L = getLocID(SpillID, true); 666*ae6f7882SJeremy Morse LocIdx Idx = LocIdx(LocIdxToIDNum.size()); // New idx 667*ae6f7882SJeremy Morse LocIdxToIDNum.grow(Idx); 668*ae6f7882SJeremy Morse LocIdxToLocID.grow(Idx); 669*ae6f7882SJeremy Morse LocIDToLocIdx.push_back(Idx); 670*ae6f7882SJeremy Morse LocIdxToLocID[Idx] = L; 671*ae6f7882SJeremy Morse return Idx; 672*ae6f7882SJeremy Morse } else { 673*ae6f7882SJeremy Morse unsigned L = getLocID(SpillID, true); 674*ae6f7882SJeremy Morse LocIdx Idx = LocIDToLocIdx[L]; 675*ae6f7882SJeremy Morse return Idx; 676*ae6f7882SJeremy Morse } 677*ae6f7882SJeremy Morse } 678*ae6f7882SJeremy Morse 679*ae6f7882SJeremy Morse /// Set the value stored in a spill slot. 680*ae6f7882SJeremy Morse void setSpill(SpillLoc L, ValueIDNum ValueID) { 681*ae6f7882SJeremy Morse LocIdx Idx = getOrTrackSpillLoc(L); 682*ae6f7882SJeremy Morse LocIdxToIDNum[Idx] = ValueID; 683*ae6f7882SJeremy Morse } 684*ae6f7882SJeremy Morse 685*ae6f7882SJeremy Morse /// Read whatever value is in a spill slot, or None if it isn't tracked. 686*ae6f7882SJeremy Morse Optional<ValueIDNum> readSpill(SpillLoc L) { 687*ae6f7882SJeremy Morse unsigned SpillID = SpillLocs.idFor(L); 688*ae6f7882SJeremy Morse if (SpillID == 0) 689*ae6f7882SJeremy Morse return None; 690*ae6f7882SJeremy Morse 691*ae6f7882SJeremy Morse unsigned LocID = getLocID(SpillID, true); 692*ae6f7882SJeremy Morse LocIdx Idx = LocIDToLocIdx[LocID]; 693*ae6f7882SJeremy Morse return LocIdxToIDNum[Idx]; 694*ae6f7882SJeremy Morse } 695*ae6f7882SJeremy Morse 696*ae6f7882SJeremy Morse /// Determine the LocIdx of a spill slot. Return None if it previously 697*ae6f7882SJeremy Morse /// hasn't had a value assigned. 698*ae6f7882SJeremy Morse Optional<LocIdx> getSpillMLoc(SpillLoc L) { 699*ae6f7882SJeremy Morse unsigned SpillID = SpillLocs.idFor(L); 700*ae6f7882SJeremy Morse if (SpillID == 0) 701*ae6f7882SJeremy Morse return None; 702*ae6f7882SJeremy Morse unsigned LocNo = getLocID(SpillID, true); 703*ae6f7882SJeremy Morse return LocIDToLocIdx[LocNo]; 704*ae6f7882SJeremy Morse } 705*ae6f7882SJeremy Morse 706*ae6f7882SJeremy Morse /// Return true if Idx is a spill machine location. 707*ae6f7882SJeremy Morse bool isSpill(LocIdx Idx) const { 708*ae6f7882SJeremy Morse return LocIdxToLocID[Idx] >= NumRegs; 709*ae6f7882SJeremy Morse } 710*ae6f7882SJeremy Morse 711*ae6f7882SJeremy Morse MLocIterator begin() { 712*ae6f7882SJeremy Morse return MLocIterator(LocIdxToIDNum, 0); 713*ae6f7882SJeremy Morse } 714*ae6f7882SJeremy Morse 715*ae6f7882SJeremy Morse MLocIterator end() { 716*ae6f7882SJeremy Morse return MLocIterator(LocIdxToIDNum, LocIdxToIDNum.size()); 717*ae6f7882SJeremy Morse } 718*ae6f7882SJeremy Morse 719*ae6f7882SJeremy Morse /// Return a range over all locations currently tracked. 720*ae6f7882SJeremy Morse iterator_range<MLocIterator> locations() { 721*ae6f7882SJeremy Morse return llvm::make_range(begin(), end()); 722*ae6f7882SJeremy Morse } 723*ae6f7882SJeremy Morse 724*ae6f7882SJeremy Morse std::string LocIdxToName(LocIdx Idx) const { 725*ae6f7882SJeremy Morse unsigned ID = LocIdxToLocID[Idx]; 726*ae6f7882SJeremy Morse if (ID >= NumRegs) 727*ae6f7882SJeremy Morse return Twine("slot ").concat(Twine(ID - NumRegs)).str(); 728*ae6f7882SJeremy Morse else 729*ae6f7882SJeremy Morse return TRI.getRegAsmName(ID).str(); 730*ae6f7882SJeremy Morse } 731*ae6f7882SJeremy Morse 732*ae6f7882SJeremy Morse std::string IDAsString(const ValueIDNum &Num) const { 733*ae6f7882SJeremy Morse std::string DefName = LocIdxToName(Num.getLoc()); 734*ae6f7882SJeremy Morse return Num.asString(DefName); 735*ae6f7882SJeremy Morse } 736*ae6f7882SJeremy Morse 737*ae6f7882SJeremy Morse LLVM_DUMP_METHOD 738*ae6f7882SJeremy Morse void dump() { 739*ae6f7882SJeremy Morse for (auto Location : locations()) { 740*ae6f7882SJeremy Morse std::string MLocName = LocIdxToName(Location.Value.getLoc()); 741*ae6f7882SJeremy Morse std::string DefName = Location.Value.asString(MLocName); 742*ae6f7882SJeremy Morse dbgs() << LocIdxToName(Location.Idx) << " --> " << DefName << "\n"; 743*ae6f7882SJeremy Morse } 744*ae6f7882SJeremy Morse } 745*ae6f7882SJeremy Morse 746*ae6f7882SJeremy Morse LLVM_DUMP_METHOD 747*ae6f7882SJeremy Morse void dump_mloc_map() { 748*ae6f7882SJeremy Morse for (auto Location : locations()) { 749*ae6f7882SJeremy Morse std::string foo = LocIdxToName(Location.Idx); 750*ae6f7882SJeremy Morse dbgs() << "Idx " << Location.Idx.asU64() << " " << foo << "\n"; 751*ae6f7882SJeremy Morse } 752*ae6f7882SJeremy Morse } 753*ae6f7882SJeremy Morse 754*ae6f7882SJeremy Morse /// Create a DBG_VALUE based on machine location \p MLoc. Qualify it with the 755*ae6f7882SJeremy Morse /// information in \pProperties, for variable Var. Don't insert it anywhere, 756*ae6f7882SJeremy Morse /// just return the builder for it. 757*ae6f7882SJeremy Morse MachineInstrBuilder emitLoc(Optional<LocIdx> MLoc, const DebugVariable &Var, 758*ae6f7882SJeremy Morse const DbgValueProperties &Properties) { 759*ae6f7882SJeremy Morse DebugLoc DL = 760*ae6f7882SJeremy Morse DebugLoc::get(0, 0, Var.getVariable()->getScope(), Var.getInlinedAt()); 761*ae6f7882SJeremy Morse auto MIB = BuildMI(MF, DL, TII.get(TargetOpcode::DBG_VALUE)); 762*ae6f7882SJeremy Morse 763*ae6f7882SJeremy Morse const DIExpression *Expr = Properties.DIExpr; 764*ae6f7882SJeremy Morse if (!MLoc) { 765*ae6f7882SJeremy Morse // No location -> DBG_VALUE $noreg 766*ae6f7882SJeremy Morse MIB.addReg(0, RegState::Debug); 767*ae6f7882SJeremy Morse MIB.addReg(0, RegState::Debug); 768*ae6f7882SJeremy Morse } else if (LocIdxToLocID[*MLoc] >= NumRegs) { 769*ae6f7882SJeremy Morse unsigned LocID = LocIdxToLocID[*MLoc]; 770*ae6f7882SJeremy Morse const SpillLoc &Spill = SpillLocs[LocID - NumRegs + 1]; 771*ae6f7882SJeremy Morse Expr = DIExpression::prepend(Expr, DIExpression::ApplyOffset, 772*ae6f7882SJeremy Morse Spill.SpillOffset); 773*ae6f7882SJeremy Morse unsigned Base = Spill.SpillBase; 774*ae6f7882SJeremy Morse MIB.addReg(Base, RegState::Debug); 775*ae6f7882SJeremy Morse MIB.addImm(0); 776*ae6f7882SJeremy Morse } else { 777*ae6f7882SJeremy Morse unsigned LocID = LocIdxToLocID[*MLoc]; 778*ae6f7882SJeremy Morse MIB.addReg(LocID, RegState::Debug); 779*ae6f7882SJeremy Morse if (Properties.Indirect) 780*ae6f7882SJeremy Morse MIB.addImm(0); 781*ae6f7882SJeremy Morse else 782*ae6f7882SJeremy Morse MIB.addReg(0, RegState::Debug); 783*ae6f7882SJeremy Morse } 784*ae6f7882SJeremy Morse 785*ae6f7882SJeremy Morse MIB.addMetadata(Var.getVariable()); 786*ae6f7882SJeremy Morse MIB.addMetadata(Expr); 787*ae6f7882SJeremy Morse return MIB; 788*ae6f7882SJeremy Morse } 789*ae6f7882SJeremy Morse }; 790*ae6f7882SJeremy Morse 791*ae6f7882SJeremy Morse /// Class recording the (high level) _value_ of a variable. Identifies either 792*ae6f7882SJeremy Morse /// the value of the variable as a ValueIDNum, or a constant MachineOperand. 793*ae6f7882SJeremy Morse /// This class also stores meta-information about how the value is qualified. 794*ae6f7882SJeremy Morse /// Used to reason about variable values when performing the second 795*ae6f7882SJeremy Morse /// (DebugVariable specific) dataflow analysis. 796*ae6f7882SJeremy Morse class DbgValue { 797*ae6f7882SJeremy Morse public: 798*ae6f7882SJeremy Morse union { 799*ae6f7882SJeremy Morse /// If Kind is Def, the value number that this value is based on. 800*ae6f7882SJeremy Morse ValueIDNum ID; 801*ae6f7882SJeremy Morse /// If Kind is Const, the MachineOperand defining this value. 802*ae6f7882SJeremy Morse MachineOperand MO; 803*ae6f7882SJeremy Morse /// For a NoVal DbgValue, which block it was generated in. 804*ae6f7882SJeremy Morse unsigned BlockNo; 805*ae6f7882SJeremy Morse }; 806*ae6f7882SJeremy Morse /// Qualifiers for the ValueIDNum above. 807*ae6f7882SJeremy Morse DbgValueProperties Properties; 808*ae6f7882SJeremy Morse 809*ae6f7882SJeremy Morse typedef enum { 810*ae6f7882SJeremy Morse Undef, // Represents a DBG_VALUE $noreg in the transfer function only. 811*ae6f7882SJeremy Morse Def, // This value is defined by an inst, or is a PHI value. 812*ae6f7882SJeremy Morse Const, // A constant value contained in the MachineOperand field. 813*ae6f7882SJeremy Morse Proposed, // This is a tentative PHI value, which may be confirmed or 814*ae6f7882SJeremy Morse // invalidated later. 815*ae6f7882SJeremy Morse NoVal // Empty DbgValue, generated during dataflow. BlockNo stores 816*ae6f7882SJeremy Morse // which block this was generated in. 817*ae6f7882SJeremy Morse } KindT; 818*ae6f7882SJeremy Morse /// Discriminator for whether this is a constant or an in-program value. 819*ae6f7882SJeremy Morse KindT Kind; 820*ae6f7882SJeremy Morse 821*ae6f7882SJeremy Morse DbgValue(const ValueIDNum &Val, const DbgValueProperties &Prop, KindT Kind) 822*ae6f7882SJeremy Morse : ID(Val), Properties(Prop), Kind(Kind) { 823*ae6f7882SJeremy Morse assert(Kind == Def || Kind == Proposed); 824*ae6f7882SJeremy Morse } 825*ae6f7882SJeremy Morse 826*ae6f7882SJeremy Morse DbgValue(unsigned BlockNo, const DbgValueProperties &Prop, KindT Kind) 827*ae6f7882SJeremy Morse : BlockNo(BlockNo), Properties(Prop), Kind(Kind) { 828*ae6f7882SJeremy Morse assert(Kind == NoVal); 829*ae6f7882SJeremy Morse } 830*ae6f7882SJeremy Morse 831*ae6f7882SJeremy Morse DbgValue(const MachineOperand &MO, const DbgValueProperties &Prop, KindT Kind) 832*ae6f7882SJeremy Morse : MO(MO), Properties(Prop), Kind(Kind) { 833*ae6f7882SJeremy Morse assert(Kind == Const); 834*ae6f7882SJeremy Morse } 835*ae6f7882SJeremy Morse 836*ae6f7882SJeremy Morse DbgValue(const DbgValueProperties &Prop, KindT Kind) 837*ae6f7882SJeremy Morse : Properties(Prop), Kind(Kind) { 838*ae6f7882SJeremy Morse assert(Kind == Undef && 839*ae6f7882SJeremy Morse "Empty DbgValue constructor must pass in Undef kind"); 840*ae6f7882SJeremy Morse } 841*ae6f7882SJeremy Morse 842*ae6f7882SJeremy Morse void dump(const MLocTracker *MTrack) const { 843*ae6f7882SJeremy Morse if (Kind == Const) { 844*ae6f7882SJeremy Morse MO.dump(); 845*ae6f7882SJeremy Morse } else if (Kind == NoVal) { 846*ae6f7882SJeremy Morse dbgs() << "NoVal(" << BlockNo << ")"; 847*ae6f7882SJeremy Morse } else if (Kind == Proposed) { 848*ae6f7882SJeremy Morse dbgs() << "VPHI(" << MTrack->IDAsString(ID) << ")"; 849*ae6f7882SJeremy Morse } else { 850*ae6f7882SJeremy Morse assert(Kind == Def); 851*ae6f7882SJeremy Morse dbgs() << MTrack->IDAsString(ID); 852*ae6f7882SJeremy Morse } 853*ae6f7882SJeremy Morse if (Properties.Indirect) 854*ae6f7882SJeremy Morse dbgs() << " indir"; 855*ae6f7882SJeremy Morse if (Properties.DIExpr) 856*ae6f7882SJeremy Morse dbgs() << " " << *Properties.DIExpr; 857*ae6f7882SJeremy Morse } 858*ae6f7882SJeremy Morse 859*ae6f7882SJeremy Morse bool operator==(const DbgValue &Other) const { 860*ae6f7882SJeremy Morse if (std::tie(Kind, Properties) != std::tie(Other.Kind, Other.Properties)) 861*ae6f7882SJeremy Morse return false; 862*ae6f7882SJeremy Morse else if (Kind == Proposed && ID != Other.ID) 863*ae6f7882SJeremy Morse return false; 864*ae6f7882SJeremy Morse else if (Kind == Def && ID != Other.ID) 865*ae6f7882SJeremy Morse return false; 866*ae6f7882SJeremy Morse else if (Kind == NoVal && BlockNo != Other.BlockNo) 867*ae6f7882SJeremy Morse return false; 868*ae6f7882SJeremy Morse else if (Kind == Const) 869*ae6f7882SJeremy Morse return MO.isIdenticalTo(Other.MO); 870*ae6f7882SJeremy Morse 871*ae6f7882SJeremy Morse return true; 872*ae6f7882SJeremy Morse } 873*ae6f7882SJeremy Morse 874*ae6f7882SJeremy Morse bool operator!=(const DbgValue &Other) const { return !(*this == Other); } 875*ae6f7882SJeremy Morse }; 876*ae6f7882SJeremy Morse 877*ae6f7882SJeremy Morse /// Types for recording sets of variable fragments that overlap. For a given 878*ae6f7882SJeremy Morse /// local variable, we record all other fragments of that variable that could 879*ae6f7882SJeremy Morse /// overlap it, to reduce search time. 880*ae6f7882SJeremy Morse using FragmentOfVar = 881*ae6f7882SJeremy Morse std::pair<const DILocalVariable *, DIExpression::FragmentInfo>; 882*ae6f7882SJeremy Morse using OverlapMap = 883*ae6f7882SJeremy Morse DenseMap<FragmentOfVar, SmallVector<DIExpression::FragmentInfo, 1>>; 884*ae6f7882SJeremy Morse 885*ae6f7882SJeremy Morse /// Collection of DBG_VALUEs observed when traversing a block. Records each 886*ae6f7882SJeremy Morse /// variable and the value the DBG_VALUE refers to. Requires the machine value 887*ae6f7882SJeremy Morse /// location dataflow algorithm to have run already, so that values can be 888*ae6f7882SJeremy Morse /// identified. 889*ae6f7882SJeremy Morse class VLocTracker { 890*ae6f7882SJeremy Morse public: 891*ae6f7882SJeremy Morse /// Map DebugVariable to the latest Value it's defined to have. 892*ae6f7882SJeremy Morse /// Needs to be a MapVector because we determine order-in-the-input-MIR from 893*ae6f7882SJeremy Morse /// the order in this container. 894*ae6f7882SJeremy Morse /// We only retain the last DbgValue in each block for each variable, to 895*ae6f7882SJeremy Morse /// determine the blocks live-out variable value. The Vars container forms the 896*ae6f7882SJeremy Morse /// transfer function for this block, as part of the dataflow analysis. The 897*ae6f7882SJeremy Morse /// movement of values between locations inside of a block is handled at a 898*ae6f7882SJeremy Morse /// much later stage, in the TransferTracker class. 899*ae6f7882SJeremy Morse MapVector<DebugVariable, DbgValue> Vars; 900*ae6f7882SJeremy Morse DenseMap<DebugVariable, const DILocation *> Scopes; 901*ae6f7882SJeremy Morse MachineBasicBlock *MBB; 902*ae6f7882SJeremy Morse 903*ae6f7882SJeremy Morse public: 904*ae6f7882SJeremy Morse VLocTracker() {} 905*ae6f7882SJeremy Morse 906*ae6f7882SJeremy Morse void defVar(const MachineInstr &MI, Optional<ValueIDNum> ID) { 907*ae6f7882SJeremy Morse // XXX skipping overlapping fragments for now. 908*ae6f7882SJeremy Morse assert(MI.isDebugValue()); 909*ae6f7882SJeremy Morse DebugVariable Var(MI.getDebugVariable(), MI.getDebugExpression(), 910*ae6f7882SJeremy Morse MI.getDebugLoc()->getInlinedAt()); 911*ae6f7882SJeremy Morse DbgValueProperties Properties(MI); 912*ae6f7882SJeremy Morse DbgValue Rec = (ID) ? DbgValue(*ID, Properties, DbgValue::Def) 913*ae6f7882SJeremy Morse : DbgValue(Properties, DbgValue::Undef); 914*ae6f7882SJeremy Morse 915*ae6f7882SJeremy Morse // Attempt insertion; overwrite if it's already mapped. 916*ae6f7882SJeremy Morse auto Result = Vars.insert(std::make_pair(Var, Rec)); 917*ae6f7882SJeremy Morse if (!Result.second) 918*ae6f7882SJeremy Morse Result.first->second = Rec; 919*ae6f7882SJeremy Morse Scopes[Var] = MI.getDebugLoc().get(); 920*ae6f7882SJeremy Morse } 921*ae6f7882SJeremy Morse 922*ae6f7882SJeremy Morse void defVar(const MachineInstr &MI, const MachineOperand &MO) { 923*ae6f7882SJeremy Morse // XXX skipping overlapping fragments for now. 924*ae6f7882SJeremy Morse assert(MI.isDebugValue()); 925*ae6f7882SJeremy Morse DebugVariable Var(MI.getDebugVariable(), MI.getDebugExpression(), 926*ae6f7882SJeremy Morse MI.getDebugLoc()->getInlinedAt()); 927*ae6f7882SJeremy Morse DbgValueProperties Properties(MI); 928*ae6f7882SJeremy Morse DbgValue Rec = DbgValue(MO, Properties, DbgValue::Const); 929*ae6f7882SJeremy Morse 930*ae6f7882SJeremy Morse // Attempt insertion; overwrite if it's already mapped. 931*ae6f7882SJeremy Morse auto Result = Vars.insert(std::make_pair(Var, Rec)); 932*ae6f7882SJeremy Morse if (!Result.second) 933*ae6f7882SJeremy Morse Result.first->second = Rec; 934*ae6f7882SJeremy Morse Scopes[Var] = MI.getDebugLoc().get(); 935*ae6f7882SJeremy Morse } 936*ae6f7882SJeremy Morse }; 937*ae6f7882SJeremy Morse 938*ae6f7882SJeremy Morse /// Tracker for converting machine value locations and variable values into 939*ae6f7882SJeremy Morse /// variable locations (the output of LiveDebugValues), recorded as DBG_VALUEs 940*ae6f7882SJeremy Morse /// specifying block live-in locations and transfers within blocks. 941*ae6f7882SJeremy Morse /// 942*ae6f7882SJeremy Morse /// Operating on a per-block basis, this class takes a (pre-loaded) MLocTracker 943*ae6f7882SJeremy Morse /// and must be initialized with the set of variable values that are live-in to 944*ae6f7882SJeremy Morse /// the block. The caller then repeatedly calls process(). TransferTracker picks 945*ae6f7882SJeremy Morse /// out variable locations for the live-in variable values (if there _is_ a 946*ae6f7882SJeremy Morse /// location) and creates the corresponding DBG_VALUEs. Then, as the block is 947*ae6f7882SJeremy Morse /// stepped through, transfers of values between machine locations are 948*ae6f7882SJeremy Morse /// identified and if profitable, a DBG_VALUE created. 949*ae6f7882SJeremy Morse /// 950*ae6f7882SJeremy Morse /// This is where debug use-before-defs would be resolved: a variable with an 951*ae6f7882SJeremy Morse /// unavailable value could materialize in the middle of a block, when the 952*ae6f7882SJeremy Morse /// value becomes available. Or, we could detect clobbers and re-specify the 953*ae6f7882SJeremy Morse /// variable in a backup location. (XXX these are unimplemented). 954*ae6f7882SJeremy Morse class TransferTracker { 955*ae6f7882SJeremy Morse public: 956*ae6f7882SJeremy Morse const TargetInstrInfo *TII; 957*ae6f7882SJeremy Morse /// This machine location tracker is assumed to always contain the up-to-date 958*ae6f7882SJeremy Morse /// value mapping for all machine locations. TransferTracker only reads 959*ae6f7882SJeremy Morse /// information from it. (XXX make it const?) 960*ae6f7882SJeremy Morse MLocTracker *MTracker; 961*ae6f7882SJeremy Morse MachineFunction &MF; 962*ae6f7882SJeremy Morse 963*ae6f7882SJeremy Morse /// Record of all changes in variable locations at a block position. Awkwardly 964*ae6f7882SJeremy Morse /// we allow inserting either before or after the point: MBB != nullptr 965*ae6f7882SJeremy Morse /// indicates it's before, otherwise after. 966*ae6f7882SJeremy Morse struct Transfer { 967*ae6f7882SJeremy Morse MachineBasicBlock::iterator Pos; /// Position to insert DBG_VALUes 968*ae6f7882SJeremy Morse MachineBasicBlock *MBB; /// non-null if we should insert after. 969*ae6f7882SJeremy Morse SmallVector<MachineInstr *, 4> Insts; /// Vector of DBG_VALUEs to insert. 970*ae6f7882SJeremy Morse }; 971*ae6f7882SJeremy Morse 972*ae6f7882SJeremy Morse typedef struct { 973*ae6f7882SJeremy Morse LocIdx Loc; 974*ae6f7882SJeremy Morse DbgValueProperties Properties; 975*ae6f7882SJeremy Morse } LocAndProperties; 976*ae6f7882SJeremy Morse 977*ae6f7882SJeremy Morse /// Collection of transfers (DBG_VALUEs) to be inserted. 978*ae6f7882SJeremy Morse SmallVector<Transfer, 32> Transfers; 979*ae6f7882SJeremy Morse 980*ae6f7882SJeremy Morse /// Local cache of what-value-is-in-what-LocIdx. Used to identify differences 981*ae6f7882SJeremy Morse /// between TransferTrackers view of variable locations and MLocTrackers. For 982*ae6f7882SJeremy Morse /// example, MLocTracker observes all clobbers, but TransferTracker lazily 983*ae6f7882SJeremy Morse /// does not. 984*ae6f7882SJeremy Morse std::vector<ValueIDNum> VarLocs; 985*ae6f7882SJeremy Morse 986*ae6f7882SJeremy Morse /// Map from LocIdxes to which DebugVariables are based that location. 987*ae6f7882SJeremy Morse /// Mantained while stepping through the block. Not accurate if 988*ae6f7882SJeremy Morse /// VarLocs[Idx] != MTracker->LocIdxToIDNum[Idx]. 989*ae6f7882SJeremy Morse std::map<LocIdx, SmallSet<DebugVariable, 4>> ActiveMLocs; 990*ae6f7882SJeremy Morse 991*ae6f7882SJeremy Morse /// Map from DebugVariable to it's current location and qualifying meta 992*ae6f7882SJeremy Morse /// information. To be used in conjunction with ActiveMLocs to construct 993*ae6f7882SJeremy Morse /// enough information for the DBG_VALUEs for a particular LocIdx. 994*ae6f7882SJeremy Morse DenseMap<DebugVariable, LocAndProperties> ActiveVLocs; 995*ae6f7882SJeremy Morse 996*ae6f7882SJeremy Morse /// Temporary cache of DBG_VALUEs to be entered into the Transfers collection. 997*ae6f7882SJeremy Morse SmallVector<MachineInstr *, 4> PendingDbgValues; 998*ae6f7882SJeremy Morse 999*ae6f7882SJeremy Morse const TargetRegisterInfo &TRI; 1000*ae6f7882SJeremy Morse const BitVector &CalleeSavedRegs; 1001*ae6f7882SJeremy Morse 1002*ae6f7882SJeremy Morse TransferTracker(const TargetInstrInfo *TII, MLocTracker *MTracker, 1003*ae6f7882SJeremy Morse MachineFunction &MF, const TargetRegisterInfo &TRI, 1004*ae6f7882SJeremy Morse const BitVector &CalleeSavedRegs) 1005*ae6f7882SJeremy Morse : TII(TII), MTracker(MTracker), MF(MF), TRI(TRI), 1006*ae6f7882SJeremy Morse CalleeSavedRegs(CalleeSavedRegs) {} 1007*ae6f7882SJeremy Morse 1008*ae6f7882SJeremy Morse /// Load object with live-in variable values. \p mlocs contains the live-in 1009*ae6f7882SJeremy Morse /// values in each machine location, while \p vlocs the live-in variable 1010*ae6f7882SJeremy Morse /// values. This method picks variable locations for the live-in variables, 1011*ae6f7882SJeremy Morse /// creates DBG_VALUEs and puts them in #Transfers, then prepares the other 1012*ae6f7882SJeremy Morse /// object fields to track variable locations as we step through the block. 1013*ae6f7882SJeremy Morse /// FIXME: could just examine mloctracker instead of passing in \p mlocs? 1014*ae6f7882SJeremy Morse void loadInlocs(MachineBasicBlock &MBB, ValueIDNum *MLocs, 1015*ae6f7882SJeremy Morse SmallVectorImpl<std::pair<DebugVariable, DbgValue>> &VLocs, 1016*ae6f7882SJeremy Morse unsigned NumLocs) { 1017*ae6f7882SJeremy Morse ActiveMLocs.clear(); 1018*ae6f7882SJeremy Morse ActiveVLocs.clear(); 1019*ae6f7882SJeremy Morse VarLocs.clear(); 1020*ae6f7882SJeremy Morse VarLocs.reserve(NumLocs); 1021*ae6f7882SJeremy Morse 1022*ae6f7882SJeremy Morse auto isCalleeSaved = [&](LocIdx L) { 1023*ae6f7882SJeremy Morse unsigned Reg = MTracker->LocIdxToLocID[L]; 1024*ae6f7882SJeremy Morse if (Reg >= MTracker->NumRegs) 1025*ae6f7882SJeremy Morse return false; 1026*ae6f7882SJeremy Morse for (MCRegAliasIterator RAI(Reg, &TRI, true); RAI.isValid(); ++RAI) 1027*ae6f7882SJeremy Morse if (CalleeSavedRegs.test(*RAI)) 1028*ae6f7882SJeremy Morse return true; 1029*ae6f7882SJeremy Morse return false; 1030*ae6f7882SJeremy Morse }; 1031*ae6f7882SJeremy Morse 1032*ae6f7882SJeremy Morse // Map of the preferred location for each value. 1033*ae6f7882SJeremy Morse std::map<ValueIDNum, LocIdx> ValueToLoc; 1034*ae6f7882SJeremy Morse 1035*ae6f7882SJeremy Morse // Produce a map of value numbers to the current machine locs they live 1036*ae6f7882SJeremy Morse // in. When emulating VarLocBasedImpl, there should only be one 1037*ae6f7882SJeremy Morse // location; when not, we get to pick. 1038*ae6f7882SJeremy Morse for (auto Location : MTracker->locations()) { 1039*ae6f7882SJeremy Morse LocIdx Idx = Location.Idx; 1040*ae6f7882SJeremy Morse ValueIDNum &VNum = MLocs[Idx.asU64()]; 1041*ae6f7882SJeremy Morse VarLocs.push_back(VNum); 1042*ae6f7882SJeremy Morse auto it = ValueToLoc.find(VNum); 1043*ae6f7882SJeremy Morse // In order of preference, pick: 1044*ae6f7882SJeremy Morse // * Callee saved registers, 1045*ae6f7882SJeremy Morse // * Other registers, 1046*ae6f7882SJeremy Morse // * Spill slots. 1047*ae6f7882SJeremy Morse if (it == ValueToLoc.end() || MTracker->isSpill(it->second) || 1048*ae6f7882SJeremy Morse (!isCalleeSaved(it->second) && isCalleeSaved(Idx.asU64()))) { 1049*ae6f7882SJeremy Morse // Insert, or overwrite if insertion failed. 1050*ae6f7882SJeremy Morse auto PrefLocRes = ValueToLoc.insert(std::make_pair(VNum, Idx)); 1051*ae6f7882SJeremy Morse if (!PrefLocRes.second) 1052*ae6f7882SJeremy Morse PrefLocRes.first->second = Idx; 1053*ae6f7882SJeremy Morse } 1054*ae6f7882SJeremy Morse } 1055*ae6f7882SJeremy Morse 1056*ae6f7882SJeremy Morse // Now map variables to their picked LocIdxes. 1057*ae6f7882SJeremy Morse for (auto Var : VLocs) { 1058*ae6f7882SJeremy Morse if (Var.second.Kind == DbgValue::Const) { 1059*ae6f7882SJeremy Morse PendingDbgValues.push_back( 1060*ae6f7882SJeremy Morse emitMOLoc(Var.second.MO, Var.first, Var.second.Properties)); 1061*ae6f7882SJeremy Morse continue; 1062*ae6f7882SJeremy Morse } 1063*ae6f7882SJeremy Morse 1064*ae6f7882SJeremy Morse // If the value has no location, we can't make a variable location. 1065*ae6f7882SJeremy Morse auto ValuesPreferredLoc = ValueToLoc.find(Var.second.ID); 1066*ae6f7882SJeremy Morse if (ValuesPreferredLoc == ValueToLoc.end()) 1067*ae6f7882SJeremy Morse continue; 1068*ae6f7882SJeremy Morse 1069*ae6f7882SJeremy Morse LocIdx M = ValuesPreferredLoc->second; 1070*ae6f7882SJeremy Morse auto NewValue = LocAndProperties{M, Var.second.Properties}; 1071*ae6f7882SJeremy Morse auto Result = ActiveVLocs.insert(std::make_pair(Var.first, NewValue)); 1072*ae6f7882SJeremy Morse if (!Result.second) 1073*ae6f7882SJeremy Morse Result.first->second = NewValue; 1074*ae6f7882SJeremy Morse ActiveMLocs[M].insert(Var.first); 1075*ae6f7882SJeremy Morse PendingDbgValues.push_back( 1076*ae6f7882SJeremy Morse MTracker->emitLoc(M, Var.first, Var.second.Properties)); 1077*ae6f7882SJeremy Morse } 1078*ae6f7882SJeremy Morse flushDbgValues(MBB.begin(), &MBB); 1079*ae6f7882SJeremy Morse } 1080*ae6f7882SJeremy Morse 1081*ae6f7882SJeremy Morse /// Helper to move created DBG_VALUEs into Transfers collection. 1082*ae6f7882SJeremy Morse void flushDbgValues(MachineBasicBlock::iterator Pos, MachineBasicBlock *MBB) { 1083*ae6f7882SJeremy Morse if (PendingDbgValues.size() > 0) { 1084*ae6f7882SJeremy Morse Transfers.push_back({Pos, MBB, PendingDbgValues}); 1085*ae6f7882SJeremy Morse PendingDbgValues.clear(); 1086*ae6f7882SJeremy Morse } 1087*ae6f7882SJeremy Morse } 1088*ae6f7882SJeremy Morse 1089*ae6f7882SJeremy Morse /// Handle a DBG_VALUE within a block. Terminate the variables current 1090*ae6f7882SJeremy Morse /// location, and record the value its DBG_VALUE refers to, so that we can 1091*ae6f7882SJeremy Morse /// detect location transfers later on. 1092*ae6f7882SJeremy Morse void redefVar(const MachineInstr &MI) { 1093*ae6f7882SJeremy Morse DebugVariable Var(MI.getDebugVariable(), MI.getDebugExpression(), 1094*ae6f7882SJeremy Morse MI.getDebugLoc()->getInlinedAt()); 1095*ae6f7882SJeremy Morse const MachineOperand &MO = MI.getOperand(0); 1096*ae6f7882SJeremy Morse 1097*ae6f7882SJeremy Morse // Erase any previous location, 1098*ae6f7882SJeremy Morse auto It = ActiveVLocs.find(Var); 1099*ae6f7882SJeremy Morse if (It != ActiveVLocs.end()) { 1100*ae6f7882SJeremy Morse ActiveMLocs[It->second.Loc].erase(Var); 1101*ae6f7882SJeremy Morse } 1102*ae6f7882SJeremy Morse 1103*ae6f7882SJeremy Morse // Insert a new variable location. Ignore non-register locations, we don't 1104*ae6f7882SJeremy Morse // transfer those, and can't currently describe spill locs independently of 1105*ae6f7882SJeremy Morse // regs. 1106*ae6f7882SJeremy Morse // (This is because a spill location is a DBG_VALUE of the stack pointer). 1107*ae6f7882SJeremy Morse if (!MO.isReg() || MO.getReg() == 0) { 1108*ae6f7882SJeremy Morse if (It != ActiveVLocs.end()) 1109*ae6f7882SJeremy Morse ActiveVLocs.erase(It); 1110*ae6f7882SJeremy Morse return; 1111*ae6f7882SJeremy Morse } 1112*ae6f7882SJeremy Morse 1113*ae6f7882SJeremy Morse Register Reg = MO.getReg(); 1114*ae6f7882SJeremy Morse LocIdx MLoc = MTracker->getRegMLoc(Reg); 1115*ae6f7882SJeremy Morse DbgValueProperties Properties(MI); 1116*ae6f7882SJeremy Morse 1117*ae6f7882SJeremy Morse // Check whether our local copy of values-by-location in #VarLocs is out of 1118*ae6f7882SJeremy Morse // date. Wipe old tracking data for the location if it's been clobbered in 1119*ae6f7882SJeremy Morse // the meantime. 1120*ae6f7882SJeremy Morse if (MTracker->getNumAtPos(MLoc) != VarLocs[MLoc.asU64()]) { 1121*ae6f7882SJeremy Morse for (auto &P : ActiveMLocs[MLoc.asU64()]) { 1122*ae6f7882SJeremy Morse ActiveVLocs.erase(P); 1123*ae6f7882SJeremy Morse } 1124*ae6f7882SJeremy Morse ActiveMLocs[MLoc].clear(); 1125*ae6f7882SJeremy Morse VarLocs[MLoc.asU64()] = MTracker->getNumAtPos(MLoc); 1126*ae6f7882SJeremy Morse } 1127*ae6f7882SJeremy Morse 1128*ae6f7882SJeremy Morse ActiveMLocs[MLoc].insert(Var); 1129*ae6f7882SJeremy Morse if (It == ActiveVLocs.end()) { 1130*ae6f7882SJeremy Morse ActiveVLocs.insert(std::make_pair(Var, LocAndProperties{MLoc, Properties})); 1131*ae6f7882SJeremy Morse } else { 1132*ae6f7882SJeremy Morse It->second.Loc = MLoc; 1133*ae6f7882SJeremy Morse It->second.Properties = Properties; 1134*ae6f7882SJeremy Morse } 1135*ae6f7882SJeremy Morse } 1136*ae6f7882SJeremy Morse 1137*ae6f7882SJeremy Morse /// Explicitly terminate variable locations based on \p mloc. Creates undef 1138*ae6f7882SJeremy Morse /// DBG_VALUEs for any variables that were located there, and clears 1139*ae6f7882SJeremy Morse /// #ActiveMLoc / #ActiveVLoc tracking information for that location. 1140*ae6f7882SJeremy Morse void clobberMloc(LocIdx MLoc, MachineBasicBlock::iterator Pos) { 1141*ae6f7882SJeremy Morse assert(MTracker->isSpill(MLoc)); 1142*ae6f7882SJeremy Morse auto ActiveMLocIt = ActiveMLocs.find(MLoc); 1143*ae6f7882SJeremy Morse if (ActiveMLocIt == ActiveMLocs.end()) 1144*ae6f7882SJeremy Morse return; 1145*ae6f7882SJeremy Morse 1146*ae6f7882SJeremy Morse VarLocs[MLoc.asU64()] = ValueIDNum::EmptyValue; 1147*ae6f7882SJeremy Morse 1148*ae6f7882SJeremy Morse for (auto &Var : ActiveMLocIt->second) { 1149*ae6f7882SJeremy Morse auto ActiveVLocIt = ActiveVLocs.find(Var); 1150*ae6f7882SJeremy Morse // Create an undef. We can't feed in a nullptr DIExpression alas, 1151*ae6f7882SJeremy Morse // so use the variables last expression. Pass None as the location. 1152*ae6f7882SJeremy Morse const DIExpression *Expr = ActiveVLocIt->second.Properties.DIExpr; 1153*ae6f7882SJeremy Morse DbgValueProperties Properties(Expr, false); 1154*ae6f7882SJeremy Morse PendingDbgValues.push_back(MTracker->emitLoc(None, Var, Properties)); 1155*ae6f7882SJeremy Morse ActiveVLocs.erase(ActiveVLocIt); 1156*ae6f7882SJeremy Morse } 1157*ae6f7882SJeremy Morse flushDbgValues(Pos, nullptr); 1158*ae6f7882SJeremy Morse 1159*ae6f7882SJeremy Morse ActiveMLocIt->second.clear(); 1160*ae6f7882SJeremy Morse } 1161*ae6f7882SJeremy Morse 1162*ae6f7882SJeremy Morse /// Transfer variables based on \p Src to be based on \p Dst. This handles 1163*ae6f7882SJeremy Morse /// both register copies as well as spills and restores. Creates DBG_VALUEs 1164*ae6f7882SJeremy Morse /// describing the movement. 1165*ae6f7882SJeremy Morse void transferMlocs(LocIdx Src, LocIdx Dst, MachineBasicBlock::iterator Pos) { 1166*ae6f7882SJeremy Morse // Does Src still contain the value num we expect? If not, it's been 1167*ae6f7882SJeremy Morse // clobbered in the meantime, and our variable locations are stale. 1168*ae6f7882SJeremy Morse if (VarLocs[Src.asU64()] != MTracker->getNumAtPos(Src)) 1169*ae6f7882SJeremy Morse return; 1170*ae6f7882SJeremy Morse 1171*ae6f7882SJeremy Morse // assert(ActiveMLocs[Dst].size() == 0); 1172*ae6f7882SJeremy Morse //^^^ Legitimate scenario on account of un-clobbered slot being assigned to? 1173*ae6f7882SJeremy Morse ActiveMLocs[Dst] = ActiveMLocs[Src]; 1174*ae6f7882SJeremy Morse VarLocs[Dst.asU64()] = VarLocs[Src.asU64()]; 1175*ae6f7882SJeremy Morse 1176*ae6f7882SJeremy Morse // For each variable based on Src; create a location at Dst. 1177*ae6f7882SJeremy Morse for (auto &Var : ActiveMLocs[Src]) { 1178*ae6f7882SJeremy Morse auto ActiveVLocIt = ActiveVLocs.find(Var); 1179*ae6f7882SJeremy Morse assert(ActiveVLocIt != ActiveVLocs.end()); 1180*ae6f7882SJeremy Morse ActiveVLocIt->second.Loc = Dst; 1181*ae6f7882SJeremy Morse 1182*ae6f7882SJeremy Morse assert(Dst != 0); 1183*ae6f7882SJeremy Morse MachineInstr *MI = 1184*ae6f7882SJeremy Morse MTracker->emitLoc(Dst, Var, ActiveVLocIt->second.Properties); 1185*ae6f7882SJeremy Morse PendingDbgValues.push_back(MI); 1186*ae6f7882SJeremy Morse } 1187*ae6f7882SJeremy Morse ActiveMLocs[Src].clear(); 1188*ae6f7882SJeremy Morse flushDbgValues(Pos, nullptr); 1189*ae6f7882SJeremy Morse 1190*ae6f7882SJeremy Morse // XXX XXX XXX "pretend to be old LDV" means dropping all tracking data 1191*ae6f7882SJeremy Morse // about the old location. 1192*ae6f7882SJeremy Morse if (EmulateOldLDV) 1193*ae6f7882SJeremy Morse VarLocs[Src.asU64()] = ValueIDNum::EmptyValue; 1194*ae6f7882SJeremy Morse } 1195*ae6f7882SJeremy Morse 1196*ae6f7882SJeremy Morse MachineInstrBuilder emitMOLoc(const MachineOperand &MO, 1197*ae6f7882SJeremy Morse const DebugVariable &Var, 1198*ae6f7882SJeremy Morse const DbgValueProperties &Properties) { 1199*ae6f7882SJeremy Morse DebugLoc DL = 1200*ae6f7882SJeremy Morse DebugLoc::get(0, 0, Var.getVariable()->getScope(), Var.getInlinedAt()); 1201*ae6f7882SJeremy Morse auto MIB = BuildMI(MF, DL, TII->get(TargetOpcode::DBG_VALUE)); 1202*ae6f7882SJeremy Morse MIB.add(MO); 1203*ae6f7882SJeremy Morse if (Properties.Indirect) 1204*ae6f7882SJeremy Morse MIB.addImm(0); 1205*ae6f7882SJeremy Morse else 1206*ae6f7882SJeremy Morse MIB.addReg(0); 1207*ae6f7882SJeremy Morse MIB.addMetadata(Var.getVariable()); 1208*ae6f7882SJeremy Morse MIB.addMetadata(Properties.DIExpr); 1209*ae6f7882SJeremy Morse return MIB; 1210*ae6f7882SJeremy Morse } 1211*ae6f7882SJeremy Morse }; 1212*ae6f7882SJeremy Morse 1213*ae6f7882SJeremy Morse class InstrRefBasedLDV : public LDVImpl { 1214*ae6f7882SJeremy Morse private: 1215*ae6f7882SJeremy Morse using FragmentInfo = DIExpression::FragmentInfo; 1216*ae6f7882SJeremy Morse using OptFragmentInfo = Optional<DIExpression::FragmentInfo>; 1217*ae6f7882SJeremy Morse 1218*ae6f7882SJeremy Morse // Helper while building OverlapMap, a map of all fragments seen for a given 1219*ae6f7882SJeremy Morse // DILocalVariable. 1220*ae6f7882SJeremy Morse using VarToFragments = 1221*ae6f7882SJeremy Morse DenseMap<const DILocalVariable *, SmallSet<FragmentInfo, 4>>; 1222*ae6f7882SJeremy Morse 1223*ae6f7882SJeremy Morse /// Machine location/value transfer function, a mapping of which locations 1224*ae6f7882SJeremy Morse // are assigned which new values. 1225*ae6f7882SJeremy Morse typedef std::map<LocIdx, ValueIDNum> MLocTransferMap; 1226*ae6f7882SJeremy Morse 1227*ae6f7882SJeremy Morse /// Live in/out structure for the variable values: a per-block map of 1228*ae6f7882SJeremy Morse /// variables to their values. XXX, better name? 1229*ae6f7882SJeremy Morse typedef DenseMap<const MachineBasicBlock *, 1230*ae6f7882SJeremy Morse DenseMap<DebugVariable, DbgValue> *> 1231*ae6f7882SJeremy Morse LiveIdxT; 1232*ae6f7882SJeremy Morse 1233*ae6f7882SJeremy Morse typedef std::pair<DebugVariable, DbgValue> VarAndLoc; 1234*ae6f7882SJeremy Morse 1235*ae6f7882SJeremy Morse /// Type for a live-in value: the predecessor block, and its value. 1236*ae6f7882SJeremy Morse typedef std::pair<MachineBasicBlock *, DbgValue *> InValueT; 1237*ae6f7882SJeremy Morse 1238*ae6f7882SJeremy Morse /// Vector (per block) of a collection (inner smallvector) of live-ins. 1239*ae6f7882SJeremy Morse /// Used as the result type for the variable value dataflow problem. 1240*ae6f7882SJeremy Morse typedef SmallVector<SmallVector<VarAndLoc, 8>, 8> LiveInsT; 1241*ae6f7882SJeremy Morse 1242*ae6f7882SJeremy Morse const TargetRegisterInfo *TRI; 1243*ae6f7882SJeremy Morse const TargetInstrInfo *TII; 1244*ae6f7882SJeremy Morse const TargetFrameLowering *TFI; 1245*ae6f7882SJeremy Morse BitVector CalleeSavedRegs; 1246*ae6f7882SJeremy Morse LexicalScopes LS; 1247*ae6f7882SJeremy Morse TargetPassConfig *TPC; 1248*ae6f7882SJeremy Morse 1249*ae6f7882SJeremy Morse /// Object to track machine locations as we step through a block. Could 1250*ae6f7882SJeremy Morse /// probably be a field rather than a pointer, as it's always used. 1251*ae6f7882SJeremy Morse MLocTracker *MTracker; 1252*ae6f7882SJeremy Morse 1253*ae6f7882SJeremy Morse /// Number of the current block LiveDebugValues is stepping through. 1254*ae6f7882SJeremy Morse unsigned CurBB; 1255*ae6f7882SJeremy Morse 1256*ae6f7882SJeremy Morse /// Number of the current instruction LiveDebugValues is evaluating. 1257*ae6f7882SJeremy Morse unsigned CurInst; 1258*ae6f7882SJeremy Morse 1259*ae6f7882SJeremy Morse /// Variable tracker -- listens to DBG_VALUEs occurring as InstrRefBasedImpl 1260*ae6f7882SJeremy Morse /// steps through a block. Reads the values at each location from the 1261*ae6f7882SJeremy Morse /// MLocTracker object. 1262*ae6f7882SJeremy Morse VLocTracker *VTracker; 1263*ae6f7882SJeremy Morse 1264*ae6f7882SJeremy Morse /// Tracker for transfers, listens to DBG_VALUEs and transfers of values 1265*ae6f7882SJeremy Morse /// between locations during stepping, creates new DBG_VALUEs when values move 1266*ae6f7882SJeremy Morse /// location. 1267*ae6f7882SJeremy Morse TransferTracker *TTracker; 1268*ae6f7882SJeremy Morse 1269*ae6f7882SJeremy Morse /// Blocks which are artificial, i.e. blocks which exclusively contain 1270*ae6f7882SJeremy Morse /// instructions without DebugLocs, or with line 0 locations. 1271*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 16> ArtificialBlocks; 1272*ae6f7882SJeremy Morse 1273*ae6f7882SJeremy Morse // Mapping of blocks to and from their RPOT order. 1274*ae6f7882SJeremy Morse DenseMap<unsigned int, MachineBasicBlock *> OrderToBB; 1275*ae6f7882SJeremy Morse DenseMap<MachineBasicBlock *, unsigned int> BBToOrder; 1276*ae6f7882SJeremy Morse DenseMap<unsigned, unsigned> BBNumToRPO; 1277*ae6f7882SJeremy Morse 1278*ae6f7882SJeremy Morse // Map of overlapping variable fragments. 1279*ae6f7882SJeremy Morse OverlapMap OverlapFragments; 1280*ae6f7882SJeremy Morse VarToFragments SeenFragments; 1281*ae6f7882SJeremy Morse 1282*ae6f7882SJeremy Morse /// Tests whether this instruction is a spill to a stack slot. 1283*ae6f7882SJeremy Morse bool isSpillInstruction(const MachineInstr &MI, MachineFunction *MF); 1284*ae6f7882SJeremy Morse 1285*ae6f7882SJeremy Morse /// Decide if @MI is a spill instruction and return true if it is. We use 2 1286*ae6f7882SJeremy Morse /// criteria to make this decision: 1287*ae6f7882SJeremy Morse /// - Is this instruction a store to a spill slot? 1288*ae6f7882SJeremy Morse /// - Is there a register operand that is both used and killed? 1289*ae6f7882SJeremy Morse /// TODO: Store optimization can fold spills into other stores (including 1290*ae6f7882SJeremy Morse /// other spills). We do not handle this yet (more than one memory operand). 1291*ae6f7882SJeremy Morse bool isLocationSpill(const MachineInstr &MI, MachineFunction *MF, 1292*ae6f7882SJeremy Morse unsigned &Reg); 1293*ae6f7882SJeremy Morse 1294*ae6f7882SJeremy Morse /// If a given instruction is identified as a spill, return the spill slot 1295*ae6f7882SJeremy Morse /// and set \p Reg to the spilled register. 1296*ae6f7882SJeremy Morse Optional<SpillLoc> isRestoreInstruction(const MachineInstr &MI, 1297*ae6f7882SJeremy Morse MachineFunction *MF, unsigned &Reg); 1298*ae6f7882SJeremy Morse 1299*ae6f7882SJeremy Morse /// Given a spill instruction, extract the register and offset used to 1300*ae6f7882SJeremy Morse /// address the spill slot in a target independent way. 1301*ae6f7882SJeremy Morse SpillLoc extractSpillBaseRegAndOffset(const MachineInstr &MI); 1302*ae6f7882SJeremy Morse 1303*ae6f7882SJeremy Morse /// Observe a single instruction while stepping through a block. 1304*ae6f7882SJeremy Morse void process(MachineInstr &MI); 1305*ae6f7882SJeremy Morse 1306*ae6f7882SJeremy Morse /// Examines whether \p MI is a DBG_VALUE and notifies trackers. 1307*ae6f7882SJeremy Morse /// \returns true if MI was recognized and processed. 1308*ae6f7882SJeremy Morse bool transferDebugValue(const MachineInstr &MI); 1309*ae6f7882SJeremy Morse 1310*ae6f7882SJeremy Morse /// Examines whether \p MI is copy instruction, and notifies trackers. 1311*ae6f7882SJeremy Morse /// \returns true if MI was recognized and processed. 1312*ae6f7882SJeremy Morse bool transferRegisterCopy(MachineInstr &MI); 1313*ae6f7882SJeremy Morse 1314*ae6f7882SJeremy Morse /// Examines whether \p MI is stack spill or restore instruction, and 1315*ae6f7882SJeremy Morse /// notifies trackers. \returns true if MI was recognized and processed. 1316*ae6f7882SJeremy Morse bool transferSpillOrRestoreInst(MachineInstr &MI); 1317*ae6f7882SJeremy Morse 1318*ae6f7882SJeremy Morse /// Examines \p MI for any registers that it defines, and notifies trackers. 1319*ae6f7882SJeremy Morse /// \returns true if MI was recognized and processed. 1320*ae6f7882SJeremy Morse void transferRegisterDef(MachineInstr &MI); 1321*ae6f7882SJeremy Morse 1322*ae6f7882SJeremy Morse /// Copy one location to the other, accounting for movement of subregisters 1323*ae6f7882SJeremy Morse /// too. 1324*ae6f7882SJeremy Morse void performCopy(Register Src, Register Dst); 1325*ae6f7882SJeremy Morse 1326*ae6f7882SJeremy Morse void accumulateFragmentMap(MachineInstr &MI); 1327*ae6f7882SJeremy Morse 1328*ae6f7882SJeremy Morse /// Step through the function, recording register definitions and movements 1329*ae6f7882SJeremy Morse /// in an MLocTracker. Convert the observations into a per-block transfer 1330*ae6f7882SJeremy Morse /// function in \p MLocTransfer, suitable for using with the machine value 1331*ae6f7882SJeremy Morse /// location dataflow problem. Do the same with VLoc trackers in \p VLocs, 1332*ae6f7882SJeremy Morse /// although the precise machine value numbers can't be known until after 1333*ae6f7882SJeremy Morse /// the machine value number problem is solved. 1334*ae6f7882SJeremy Morse void produceTransferFunctions(MachineFunction &MF, 1335*ae6f7882SJeremy Morse SmallVectorImpl<MLocTransferMap> &MLocTransfer, 1336*ae6f7882SJeremy Morse unsigned MaxNumBlocks, 1337*ae6f7882SJeremy Morse SmallVectorImpl<VLocTracker> &VLocs); 1338*ae6f7882SJeremy Morse 1339*ae6f7882SJeremy Morse /// Solve the machine value location dataflow problem. Takes as input the 1340*ae6f7882SJeremy Morse /// transfer functions in \p MLocTransfer. Writes the output live-in and 1341*ae6f7882SJeremy Morse /// live-out arrays to the (initialized to zero) multidimensional arrays in 1342*ae6f7882SJeremy Morse /// \p MInLocs and \p MOutLocs. The outer dimension is indexed by block 1343*ae6f7882SJeremy Morse /// number, the inner by LocIdx. 1344*ae6f7882SJeremy Morse void mlocDataflow(ValueIDNum **MInLocs, ValueIDNum **MOutLocs, 1345*ae6f7882SJeremy Morse SmallVectorImpl<MLocTransferMap> &MLocTransfer); 1346*ae6f7882SJeremy Morse 1347*ae6f7882SJeremy Morse /// Perform a control flow join (lattice value meet) of the values in machine 1348*ae6f7882SJeremy Morse /// locations at \p MBB. Follows the algorithm described in the file-comment, 1349*ae6f7882SJeremy Morse /// reading live-outs of predecessors from \p OutLocs, the current live ins 1350*ae6f7882SJeremy Morse /// from \p InLocs, and assigning the newly computed live ins back into 1351*ae6f7882SJeremy Morse /// \p InLocs. \returns two bools -- the first indicates whether a change 1352*ae6f7882SJeremy Morse /// was made, the second whether a lattice downgrade occurred. If the latter 1353*ae6f7882SJeremy Morse /// is true, revisiting this block is necessary. 1354*ae6f7882SJeremy Morse std::tuple<bool, bool> 1355*ae6f7882SJeremy Morse mlocJoin(MachineBasicBlock &MBB, 1356*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 16> &Visited, 1357*ae6f7882SJeremy Morse ValueIDNum **OutLocs, ValueIDNum *InLocs); 1358*ae6f7882SJeremy Morse 1359*ae6f7882SJeremy Morse /// Solve the variable value dataflow problem, for a single lexical scope. 1360*ae6f7882SJeremy Morse /// Uses the algorithm from the file comment to resolve control flow joins, 1361*ae6f7882SJeremy Morse /// although there are extra hacks, see vlocJoin. Reads the 1362*ae6f7882SJeremy Morse /// locations of values from the \p MInLocs and \p MOutLocs arrays (see 1363*ae6f7882SJeremy Morse /// mlocDataflow) and reads the variable values transfer function from 1364*ae6f7882SJeremy Morse /// \p AllTheVlocs. Live-in and Live-out variable values are stored locally, 1365*ae6f7882SJeremy Morse /// with the live-ins permanently stored to \p Output once the fixedpoint is 1366*ae6f7882SJeremy Morse /// reached. 1367*ae6f7882SJeremy Morse /// \p VarsWeCareAbout contains a collection of the variables in \p Scope 1368*ae6f7882SJeremy Morse /// that we should be tracking. 1369*ae6f7882SJeremy Morse /// \p AssignBlocks contains the set of blocks that aren't in \p Scope, but 1370*ae6f7882SJeremy Morse /// which do contain DBG_VALUEs, which VarLocBasedImpl tracks locations 1371*ae6f7882SJeremy Morse /// through. 1372*ae6f7882SJeremy Morse void vlocDataflow(const LexicalScope *Scope, const DILocation *DILoc, 1373*ae6f7882SJeremy Morse const SmallSet<DebugVariable, 4> &VarsWeCareAbout, 1374*ae6f7882SJeremy Morse SmallPtrSetImpl<MachineBasicBlock *> &AssignBlocks, 1375*ae6f7882SJeremy Morse LiveInsT &Output, ValueIDNum **MOutLocs, 1376*ae6f7882SJeremy Morse ValueIDNum **MInLocs, 1377*ae6f7882SJeremy Morse SmallVectorImpl<VLocTracker> &AllTheVLocs); 1378*ae6f7882SJeremy Morse 1379*ae6f7882SJeremy Morse /// Compute the live-ins to a block, considering control flow merges according 1380*ae6f7882SJeremy Morse /// to the method in the file comment. Live out and live in variable values 1381*ae6f7882SJeremy Morse /// are stored in \p VLOCOutLocs and \p VLOCInLocs. The live-ins for \p MBB 1382*ae6f7882SJeremy Morse /// are computed and stored into \p VLOCInLocs. \returns true if the live-ins 1383*ae6f7882SJeremy Morse /// are modified. 1384*ae6f7882SJeremy Morse /// \p InLocsT Output argument, storage for calculated live-ins. 1385*ae6f7882SJeremy Morse /// \returns two bools -- the first indicates whether a change 1386*ae6f7882SJeremy Morse /// was made, the second whether a lattice downgrade occurred. If the latter 1387*ae6f7882SJeremy Morse /// is true, revisiting this block is necessary. 1388*ae6f7882SJeremy Morse std::tuple<bool, bool> 1389*ae6f7882SJeremy Morse vlocJoin(MachineBasicBlock &MBB, LiveIdxT &VLOCOutLocs, LiveIdxT &VLOCInLocs, 1390*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 16> *VLOCVisited, 1391*ae6f7882SJeremy Morse unsigned BBNum, const SmallSet<DebugVariable, 4> &AllVars, 1392*ae6f7882SJeremy Morse ValueIDNum **MOutLocs, ValueIDNum **MInLocs, 1393*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 8> &InScopeBlocks, 1394*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 8> &BlocksToExplore, 1395*ae6f7882SJeremy Morse DenseMap<DebugVariable, DbgValue> &InLocsT); 1396*ae6f7882SJeremy Morse 1397*ae6f7882SJeremy Morse /// Continue exploration of the variable-value lattice, as explained in the 1398*ae6f7882SJeremy Morse /// file-level comment. \p OldLiveInLocation contains the current 1399*ae6f7882SJeremy Morse /// exploration position, from which we need to descend further. \p Values 1400*ae6f7882SJeremy Morse /// contains the set of live-in values, \p CurBlockRPONum the RPO number of 1401*ae6f7882SJeremy Morse /// the current block, and \p CandidateLocations a set of locations that 1402*ae6f7882SJeremy Morse /// should be considered as PHI locations, if we reach the bottom of the 1403*ae6f7882SJeremy Morse /// lattice. \returns true if we should downgrade; the value is the agreeing 1404*ae6f7882SJeremy Morse /// value number in a non-backedge predecessor. 1405*ae6f7882SJeremy Morse bool vlocDowngradeLattice(const MachineBasicBlock &MBB, 1406*ae6f7882SJeremy Morse const DbgValue &OldLiveInLocation, 1407*ae6f7882SJeremy Morse const SmallVectorImpl<InValueT> &Values, 1408*ae6f7882SJeremy Morse unsigned CurBlockRPONum); 1409*ae6f7882SJeremy Morse 1410*ae6f7882SJeremy Morse /// For the given block and live-outs feeding into it, try to find a 1411*ae6f7882SJeremy Morse /// machine location where they all join. If a solution for all predecessors 1412*ae6f7882SJeremy Morse /// can't be found, a location where all non-backedge-predecessors join 1413*ae6f7882SJeremy Morse /// will be returned instead. While this method finds a join location, this 1414*ae6f7882SJeremy Morse /// says nothing as to whether it should be used. 1415*ae6f7882SJeremy Morse /// \returns Pair of value ID if found, and true when the correct value 1416*ae6f7882SJeremy Morse /// is available on all predecessor edges, or false if it's only available 1417*ae6f7882SJeremy Morse /// for non-backedge predecessors. 1418*ae6f7882SJeremy Morse std::tuple<Optional<ValueIDNum>, bool> 1419*ae6f7882SJeremy Morse pickVPHILoc(MachineBasicBlock &MBB, const DebugVariable &Var, 1420*ae6f7882SJeremy Morse const LiveIdxT &LiveOuts, ValueIDNum **MOutLocs, 1421*ae6f7882SJeremy Morse ValueIDNum **MInLocs, 1422*ae6f7882SJeremy Morse const SmallVectorImpl<MachineBasicBlock *> &BlockOrders); 1423*ae6f7882SJeremy Morse 1424*ae6f7882SJeremy Morse /// Given the solutions to the two dataflow problems, machine value locations 1425*ae6f7882SJeremy Morse /// in \p MInLocs and live-in variable values in \p SavedLiveIns, runs the 1426*ae6f7882SJeremy Morse /// TransferTracker class over the function to produce live-in and transfer 1427*ae6f7882SJeremy Morse /// DBG_VALUEs, then inserts them. Groups of DBG_VALUEs are inserted in the 1428*ae6f7882SJeremy Morse /// order given by AllVarsNumbering -- this could be any stable order, but 1429*ae6f7882SJeremy Morse /// right now "order of appearence in function, when explored in RPO", so 1430*ae6f7882SJeremy Morse /// that we can compare explictly against VarLocBasedImpl. 1431*ae6f7882SJeremy Morse void emitLocations(MachineFunction &MF, LiveInsT SavedLiveIns, 1432*ae6f7882SJeremy Morse ValueIDNum **MInLocs, 1433*ae6f7882SJeremy Morse DenseMap<DebugVariable, unsigned> &AllVarsNumbering); 1434*ae6f7882SJeremy Morse 1435*ae6f7882SJeremy Morse /// Boilerplate computation of some initial sets, artifical blocks and 1436*ae6f7882SJeremy Morse /// RPOT block ordering. 1437*ae6f7882SJeremy Morse void initialSetup(MachineFunction &MF); 1438*ae6f7882SJeremy Morse 1439*ae6f7882SJeremy Morse bool ExtendRanges(MachineFunction &MF, TargetPassConfig *TPC) override; 1440*ae6f7882SJeremy Morse 1441*ae6f7882SJeremy Morse public: 1442*ae6f7882SJeremy Morse /// Default construct and initialize the pass. 1443*ae6f7882SJeremy Morse InstrRefBasedLDV(); 1444*ae6f7882SJeremy Morse 1445*ae6f7882SJeremy Morse LLVM_DUMP_METHOD 1446*ae6f7882SJeremy Morse void dump_mloc_transfer(const MLocTransferMap &mloc_transfer) const; 1447*ae6f7882SJeremy Morse 1448*ae6f7882SJeremy Morse bool isCalleeSaved(LocIdx L) { 1449*ae6f7882SJeremy Morse unsigned Reg = MTracker->LocIdxToLocID[L]; 1450*ae6f7882SJeremy Morse for (MCRegAliasIterator RAI(Reg, TRI, true); RAI.isValid(); ++RAI) 1451*ae6f7882SJeremy Morse if (CalleeSavedRegs.test(*RAI)) 1452*ae6f7882SJeremy Morse return true; 1453*ae6f7882SJeremy Morse return false; 1454*ae6f7882SJeremy Morse } 1455*ae6f7882SJeremy Morse }; 1456*ae6f7882SJeremy Morse 1457*ae6f7882SJeremy Morse } // end anonymous namespace 1458*ae6f7882SJeremy Morse 1459*ae6f7882SJeremy Morse //===----------------------------------------------------------------------===// 1460*ae6f7882SJeremy Morse // Implementation 1461*ae6f7882SJeremy Morse //===----------------------------------------------------------------------===// 1462*ae6f7882SJeremy Morse 1463*ae6f7882SJeremy Morse ValueIDNum ValueIDNum::EmptyValue = {UINT_MAX, UINT_MAX, UINT_MAX}; 1464*ae6f7882SJeremy Morse 1465*ae6f7882SJeremy Morse /// Default construct and initialize the pass. 1466*ae6f7882SJeremy Morse InstrRefBasedLDV::InstrRefBasedLDV() {} 1467*ae6f7882SJeremy Morse 1468*ae6f7882SJeremy Morse //===----------------------------------------------------------------------===// 1469*ae6f7882SJeremy Morse // Debug Range Extension Implementation 1470*ae6f7882SJeremy Morse //===----------------------------------------------------------------------===// 1471*ae6f7882SJeremy Morse 1472*ae6f7882SJeremy Morse #ifndef NDEBUG 1473*ae6f7882SJeremy Morse // Something to restore in the future. 1474*ae6f7882SJeremy Morse // void InstrRefBasedLDV::printVarLocInMBB(..) 1475*ae6f7882SJeremy Morse #endif 1476*ae6f7882SJeremy Morse 1477*ae6f7882SJeremy Morse SpillLoc 1478*ae6f7882SJeremy Morse InstrRefBasedLDV::extractSpillBaseRegAndOffset(const MachineInstr &MI) { 1479*ae6f7882SJeremy Morse assert(MI.hasOneMemOperand() && 1480*ae6f7882SJeremy Morse "Spill instruction does not have exactly one memory operand?"); 1481*ae6f7882SJeremy Morse auto MMOI = MI.memoperands_begin(); 1482*ae6f7882SJeremy Morse const PseudoSourceValue *PVal = (*MMOI)->getPseudoValue(); 1483*ae6f7882SJeremy Morse assert(PVal->kind() == PseudoSourceValue::FixedStack && 1484*ae6f7882SJeremy Morse "Inconsistent memory operand in spill instruction"); 1485*ae6f7882SJeremy Morse int FI = cast<FixedStackPseudoSourceValue>(PVal)->getFrameIndex(); 1486*ae6f7882SJeremy Morse const MachineBasicBlock *MBB = MI.getParent(); 1487*ae6f7882SJeremy Morse Register Reg; 1488*ae6f7882SJeremy Morse int Offset = TFI->getFrameIndexReference(*MBB->getParent(), FI, Reg); 1489*ae6f7882SJeremy Morse return {Reg, Offset}; 1490*ae6f7882SJeremy Morse } 1491*ae6f7882SJeremy Morse 1492*ae6f7882SJeremy Morse /// End all previous ranges related to @MI and start a new range from @MI 1493*ae6f7882SJeremy Morse /// if it is a DBG_VALUE instr. 1494*ae6f7882SJeremy Morse bool InstrRefBasedLDV::transferDebugValue(const MachineInstr &MI) { 1495*ae6f7882SJeremy Morse if (!MI.isDebugValue()) 1496*ae6f7882SJeremy Morse return false; 1497*ae6f7882SJeremy Morse 1498*ae6f7882SJeremy Morse const DILocalVariable *Var = MI.getDebugVariable(); 1499*ae6f7882SJeremy Morse const DIExpression *Expr = MI.getDebugExpression(); 1500*ae6f7882SJeremy Morse const DILocation *DebugLoc = MI.getDebugLoc(); 1501*ae6f7882SJeremy Morse const DILocation *InlinedAt = DebugLoc->getInlinedAt(); 1502*ae6f7882SJeremy Morse assert(Var->isValidLocationForIntrinsic(DebugLoc) && 1503*ae6f7882SJeremy Morse "Expected inlined-at fields to agree"); 1504*ae6f7882SJeremy Morse 1505*ae6f7882SJeremy Morse DebugVariable V(Var, Expr, InlinedAt); 1506*ae6f7882SJeremy Morse 1507*ae6f7882SJeremy Morse // If there are no instructions in this lexical scope, do no location tracking 1508*ae6f7882SJeremy Morse // at all, this variable shouldn't get a legitimate location range. 1509*ae6f7882SJeremy Morse auto *Scope = LS.findLexicalScope(MI.getDebugLoc().get()); 1510*ae6f7882SJeremy Morse if (Scope == nullptr) 1511*ae6f7882SJeremy Morse return true; // handled it; by doing nothing 1512*ae6f7882SJeremy Morse 1513*ae6f7882SJeremy Morse const MachineOperand &MO = MI.getOperand(0); 1514*ae6f7882SJeremy Morse 1515*ae6f7882SJeremy Morse // MLocTracker needs to know that this register is read, even if it's only 1516*ae6f7882SJeremy Morse // read by a debug inst. 1517*ae6f7882SJeremy Morse if (MO.isReg() && MO.getReg() != 0) 1518*ae6f7882SJeremy Morse (void)MTracker->readReg(MO.getReg()); 1519*ae6f7882SJeremy Morse 1520*ae6f7882SJeremy Morse // If we're preparing for the second analysis (variables), the machine value 1521*ae6f7882SJeremy Morse // locations are already solved, and we report this DBG_VALUE and the value 1522*ae6f7882SJeremy Morse // it refers to to VLocTracker. 1523*ae6f7882SJeremy Morse if (VTracker) { 1524*ae6f7882SJeremy Morse if (MO.isReg()) { 1525*ae6f7882SJeremy Morse // Feed defVar the new variable location, or if this is a 1526*ae6f7882SJeremy Morse // DBG_VALUE $noreg, feed defVar None. 1527*ae6f7882SJeremy Morse if (MO.getReg()) 1528*ae6f7882SJeremy Morse VTracker->defVar(MI, MTracker->readReg(MO.getReg())); 1529*ae6f7882SJeremy Morse else 1530*ae6f7882SJeremy Morse VTracker->defVar(MI, None); 1531*ae6f7882SJeremy Morse } else if (MI.getOperand(0).isImm() || MI.getOperand(0).isFPImm() || 1532*ae6f7882SJeremy Morse MI.getOperand(0).isCImm()) { 1533*ae6f7882SJeremy Morse VTracker->defVar(MI, MI.getOperand(0)); 1534*ae6f7882SJeremy Morse } 1535*ae6f7882SJeremy Morse } 1536*ae6f7882SJeremy Morse 1537*ae6f7882SJeremy Morse // If performing final tracking of transfers, report this variable definition 1538*ae6f7882SJeremy Morse // to the TransferTracker too. 1539*ae6f7882SJeremy Morse if (TTracker) 1540*ae6f7882SJeremy Morse TTracker->redefVar(MI); 1541*ae6f7882SJeremy Morse return true; 1542*ae6f7882SJeremy Morse } 1543*ae6f7882SJeremy Morse 1544*ae6f7882SJeremy Morse void InstrRefBasedLDV::transferRegisterDef(MachineInstr &MI) { 1545*ae6f7882SJeremy Morse // Meta Instructions do not affect the debug liveness of any register they 1546*ae6f7882SJeremy Morse // define. 1547*ae6f7882SJeremy Morse if (MI.isImplicitDef()) { 1548*ae6f7882SJeremy Morse // Except when there's an implicit def, and the location it's defining has 1549*ae6f7882SJeremy Morse // no value number. The whole point of an implicit def is to announce that 1550*ae6f7882SJeremy Morse // the register is live, without be specific about it's value. So define 1551*ae6f7882SJeremy Morse // a value if there isn't one already. 1552*ae6f7882SJeremy Morse ValueIDNum Num = MTracker->readReg(MI.getOperand(0).getReg()); 1553*ae6f7882SJeremy Morse // Has a legitimate value -> ignore the implicit def. 1554*ae6f7882SJeremy Morse if (Num.getLoc() != 0) 1555*ae6f7882SJeremy Morse return; 1556*ae6f7882SJeremy Morse // Otherwise, def it here. 1557*ae6f7882SJeremy Morse } else if (MI.isMetaInstruction()) 1558*ae6f7882SJeremy Morse return; 1559*ae6f7882SJeremy Morse 1560*ae6f7882SJeremy Morse MachineFunction *MF = MI.getMF(); 1561*ae6f7882SJeremy Morse const TargetLowering *TLI = MF->getSubtarget().getTargetLowering(); 1562*ae6f7882SJeremy Morse unsigned SP = TLI->getStackPointerRegisterToSaveRestore(); 1563*ae6f7882SJeremy Morse 1564*ae6f7882SJeremy Morse // Find the regs killed by MI, and find regmasks of preserved regs. 1565*ae6f7882SJeremy Morse // Max out the number of statically allocated elements in `DeadRegs`, as this 1566*ae6f7882SJeremy Morse // prevents fallback to std::set::count() operations. 1567*ae6f7882SJeremy Morse SmallSet<uint32_t, 32> DeadRegs; 1568*ae6f7882SJeremy Morse SmallVector<const uint32_t *, 4> RegMasks; 1569*ae6f7882SJeremy Morse SmallVector<const MachineOperand *, 4> RegMaskPtrs; 1570*ae6f7882SJeremy Morse for (const MachineOperand &MO : MI.operands()) { 1571*ae6f7882SJeremy Morse // Determine whether the operand is a register def. 1572*ae6f7882SJeremy Morse if (MO.isReg() && MO.isDef() && MO.getReg() && 1573*ae6f7882SJeremy Morse Register::isPhysicalRegister(MO.getReg()) && 1574*ae6f7882SJeremy Morse !(MI.isCall() && MO.getReg() == SP)) { 1575*ae6f7882SJeremy Morse // Remove ranges of all aliased registers. 1576*ae6f7882SJeremy Morse for (MCRegAliasIterator RAI(MO.getReg(), TRI, true); RAI.isValid(); ++RAI) 1577*ae6f7882SJeremy Morse // FIXME: Can we break out of this loop early if no insertion occurs? 1578*ae6f7882SJeremy Morse DeadRegs.insert(*RAI); 1579*ae6f7882SJeremy Morse } else if (MO.isRegMask()) { 1580*ae6f7882SJeremy Morse RegMasks.push_back(MO.getRegMask()); 1581*ae6f7882SJeremy Morse RegMaskPtrs.push_back(&MO); 1582*ae6f7882SJeremy Morse } 1583*ae6f7882SJeremy Morse } 1584*ae6f7882SJeremy Morse 1585*ae6f7882SJeremy Morse // Tell MLocTracker about all definitions, of regmasks and otherwise. 1586*ae6f7882SJeremy Morse for (uint32_t DeadReg : DeadRegs) 1587*ae6f7882SJeremy Morse MTracker->defReg(DeadReg, CurBB, CurInst); 1588*ae6f7882SJeremy Morse 1589*ae6f7882SJeremy Morse for (auto *MO : RegMaskPtrs) 1590*ae6f7882SJeremy Morse MTracker->writeRegMask(MO, CurBB, CurInst); 1591*ae6f7882SJeremy Morse } 1592*ae6f7882SJeremy Morse 1593*ae6f7882SJeremy Morse void InstrRefBasedLDV::performCopy(Register SrcRegNum, Register DstRegNum) { 1594*ae6f7882SJeremy Morse ValueIDNum SrcValue = MTracker->readReg(SrcRegNum); 1595*ae6f7882SJeremy Morse 1596*ae6f7882SJeremy Morse MTracker->setReg(DstRegNum, SrcValue); 1597*ae6f7882SJeremy Morse 1598*ae6f7882SJeremy Morse // In all circumstances, re-def the super registers. It's definitely a new 1599*ae6f7882SJeremy Morse // value now. This doesn't uniquely identify the composition of subregs, for 1600*ae6f7882SJeremy Morse // example, two identical values in subregisters composed in different 1601*ae6f7882SJeremy Morse // places would not get equal value numbers. 1602*ae6f7882SJeremy Morse for (MCSuperRegIterator SRI(DstRegNum, TRI); SRI.isValid(); ++SRI) 1603*ae6f7882SJeremy Morse MTracker->defReg(*SRI, CurBB, CurInst); 1604*ae6f7882SJeremy Morse 1605*ae6f7882SJeremy Morse // If we're emulating VarLocBasedImpl, just define all the subregisters. 1606*ae6f7882SJeremy Morse // DBG_VALUEs of them will expect to be tracked from the DBG_VALUE, not 1607*ae6f7882SJeremy Morse // through prior copies. 1608*ae6f7882SJeremy Morse if (EmulateOldLDV) { 1609*ae6f7882SJeremy Morse for (MCSubRegIndexIterator DRI(DstRegNum, TRI); DRI.isValid(); ++DRI) 1610*ae6f7882SJeremy Morse MTracker->defReg(DRI.getSubReg(), CurBB, CurInst); 1611*ae6f7882SJeremy Morse return; 1612*ae6f7882SJeremy Morse } 1613*ae6f7882SJeremy Morse 1614*ae6f7882SJeremy Morse // Otherwise, actually copy subregisters from one location to another. 1615*ae6f7882SJeremy Morse // XXX: in addition, any subregisters of DstRegNum that don't line up with 1616*ae6f7882SJeremy Morse // the source register should be def'd. 1617*ae6f7882SJeremy Morse for (MCSubRegIndexIterator SRI(SrcRegNum, TRI); SRI.isValid(); ++SRI) { 1618*ae6f7882SJeremy Morse unsigned SrcSubReg = SRI.getSubReg(); 1619*ae6f7882SJeremy Morse unsigned SubRegIdx = SRI.getSubRegIndex(); 1620*ae6f7882SJeremy Morse unsigned DstSubReg = TRI->getSubReg(DstRegNum, SubRegIdx); 1621*ae6f7882SJeremy Morse if (!DstSubReg) 1622*ae6f7882SJeremy Morse continue; 1623*ae6f7882SJeremy Morse 1624*ae6f7882SJeremy Morse // Do copy. There are two matching subregisters, the source value should 1625*ae6f7882SJeremy Morse // have been def'd when the super-reg was, the latter might not be tracked 1626*ae6f7882SJeremy Morse // yet. 1627*ae6f7882SJeremy Morse // This will force SrcSubReg to be tracked, if it isn't yet. 1628*ae6f7882SJeremy Morse (void)MTracker->readReg(SrcSubReg); 1629*ae6f7882SJeremy Morse LocIdx SrcL = MTracker->getRegMLoc(SrcSubReg); 1630*ae6f7882SJeremy Morse assert(SrcL.asU64()); 1631*ae6f7882SJeremy Morse (void)MTracker->readReg(DstSubReg); 1632*ae6f7882SJeremy Morse LocIdx DstL = MTracker->getRegMLoc(DstSubReg); 1633*ae6f7882SJeremy Morse assert(DstL.asU64()); 1634*ae6f7882SJeremy Morse (void)DstL; 1635*ae6f7882SJeremy Morse ValueIDNum CpyValue = {SrcValue.getBlock(), SrcValue.getInst(), SrcL}; 1636*ae6f7882SJeremy Morse 1637*ae6f7882SJeremy Morse MTracker->setReg(DstSubReg, CpyValue); 1638*ae6f7882SJeremy Morse } 1639*ae6f7882SJeremy Morse } 1640*ae6f7882SJeremy Morse 1641*ae6f7882SJeremy Morse bool InstrRefBasedLDV::isSpillInstruction(const MachineInstr &MI, 1642*ae6f7882SJeremy Morse MachineFunction *MF) { 1643*ae6f7882SJeremy Morse // TODO: Handle multiple stores folded into one. 1644*ae6f7882SJeremy Morse if (!MI.hasOneMemOperand()) 1645*ae6f7882SJeremy Morse return false; 1646*ae6f7882SJeremy Morse 1647*ae6f7882SJeremy Morse if (!MI.getSpillSize(TII) && !MI.getFoldedSpillSize(TII)) 1648*ae6f7882SJeremy Morse return false; // This is not a spill instruction, since no valid size was 1649*ae6f7882SJeremy Morse // returned from either function. 1650*ae6f7882SJeremy Morse 1651*ae6f7882SJeremy Morse return true; 1652*ae6f7882SJeremy Morse } 1653*ae6f7882SJeremy Morse 1654*ae6f7882SJeremy Morse bool InstrRefBasedLDV::isLocationSpill(const MachineInstr &MI, 1655*ae6f7882SJeremy Morse MachineFunction *MF, unsigned &Reg) { 1656*ae6f7882SJeremy Morse if (!isSpillInstruction(MI, MF)) 1657*ae6f7882SJeremy Morse return false; 1658*ae6f7882SJeremy Morse 1659*ae6f7882SJeremy Morse // XXX FIXME: On x86, isStoreToStackSlotPostFE returns '1' instead of an 1660*ae6f7882SJeremy Morse // actual register number. 1661*ae6f7882SJeremy Morse if (ObserveAllStackops) { 1662*ae6f7882SJeremy Morse int FI; 1663*ae6f7882SJeremy Morse Reg = TII->isStoreToStackSlotPostFE(MI, FI); 1664*ae6f7882SJeremy Morse return Reg != 0; 1665*ae6f7882SJeremy Morse } 1666*ae6f7882SJeremy Morse 1667*ae6f7882SJeremy Morse auto isKilledReg = [&](const MachineOperand MO, unsigned &Reg) { 1668*ae6f7882SJeremy Morse if (!MO.isReg() || !MO.isUse()) { 1669*ae6f7882SJeremy Morse Reg = 0; 1670*ae6f7882SJeremy Morse return false; 1671*ae6f7882SJeremy Morse } 1672*ae6f7882SJeremy Morse Reg = MO.getReg(); 1673*ae6f7882SJeremy Morse return MO.isKill(); 1674*ae6f7882SJeremy Morse }; 1675*ae6f7882SJeremy Morse 1676*ae6f7882SJeremy Morse for (const MachineOperand &MO : MI.operands()) { 1677*ae6f7882SJeremy Morse // In a spill instruction generated by the InlineSpiller the spilled 1678*ae6f7882SJeremy Morse // register has its kill flag set. 1679*ae6f7882SJeremy Morse if (isKilledReg(MO, Reg)) 1680*ae6f7882SJeremy Morse return true; 1681*ae6f7882SJeremy Morse if (Reg != 0) { 1682*ae6f7882SJeremy Morse // Check whether next instruction kills the spilled register. 1683*ae6f7882SJeremy Morse // FIXME: Current solution does not cover search for killed register in 1684*ae6f7882SJeremy Morse // bundles and instructions further down the chain. 1685*ae6f7882SJeremy Morse auto NextI = std::next(MI.getIterator()); 1686*ae6f7882SJeremy Morse // Skip next instruction that points to basic block end iterator. 1687*ae6f7882SJeremy Morse if (MI.getParent()->end() == NextI) 1688*ae6f7882SJeremy Morse continue; 1689*ae6f7882SJeremy Morse unsigned RegNext; 1690*ae6f7882SJeremy Morse for (const MachineOperand &MONext : NextI->operands()) { 1691*ae6f7882SJeremy Morse // Return true if we came across the register from the 1692*ae6f7882SJeremy Morse // previous spill instruction that is killed in NextI. 1693*ae6f7882SJeremy Morse if (isKilledReg(MONext, RegNext) && RegNext == Reg) 1694*ae6f7882SJeremy Morse return true; 1695*ae6f7882SJeremy Morse } 1696*ae6f7882SJeremy Morse } 1697*ae6f7882SJeremy Morse } 1698*ae6f7882SJeremy Morse // Return false if we didn't find spilled register. 1699*ae6f7882SJeremy Morse return false; 1700*ae6f7882SJeremy Morse } 1701*ae6f7882SJeremy Morse 1702*ae6f7882SJeremy Morse Optional<SpillLoc> 1703*ae6f7882SJeremy Morse InstrRefBasedLDV::isRestoreInstruction(const MachineInstr &MI, 1704*ae6f7882SJeremy Morse MachineFunction *MF, unsigned &Reg) { 1705*ae6f7882SJeremy Morse if (!MI.hasOneMemOperand()) 1706*ae6f7882SJeremy Morse return None; 1707*ae6f7882SJeremy Morse 1708*ae6f7882SJeremy Morse // FIXME: Handle folded restore instructions with more than one memory 1709*ae6f7882SJeremy Morse // operand. 1710*ae6f7882SJeremy Morse if (MI.getRestoreSize(TII)) { 1711*ae6f7882SJeremy Morse Reg = MI.getOperand(0).getReg(); 1712*ae6f7882SJeremy Morse return extractSpillBaseRegAndOffset(MI); 1713*ae6f7882SJeremy Morse } 1714*ae6f7882SJeremy Morse return None; 1715*ae6f7882SJeremy Morse } 1716*ae6f7882SJeremy Morse 1717*ae6f7882SJeremy Morse bool InstrRefBasedLDV::transferSpillOrRestoreInst(MachineInstr &MI) { 1718*ae6f7882SJeremy Morse // XXX -- it's too difficult to implement VarLocBasedImpl's stack location 1719*ae6f7882SJeremy Morse // limitations under the new model. Therefore, when comparing them, compare 1720*ae6f7882SJeremy Morse // versions that don't attempt spills or restores at all. 1721*ae6f7882SJeremy Morse if (EmulateOldLDV) 1722*ae6f7882SJeremy Morse return false; 1723*ae6f7882SJeremy Morse 1724*ae6f7882SJeremy Morse MachineFunction *MF = MI.getMF(); 1725*ae6f7882SJeremy Morse unsigned Reg; 1726*ae6f7882SJeremy Morse Optional<SpillLoc> Loc; 1727*ae6f7882SJeremy Morse 1728*ae6f7882SJeremy Morse LLVM_DEBUG(dbgs() << "Examining instruction: "; MI.dump();); 1729*ae6f7882SJeremy Morse 1730*ae6f7882SJeremy Morse // First, if there are any DBG_VALUEs pointing at a spill slot that is 1731*ae6f7882SJeremy Morse // written to, terminate that variable location. The value in memory 1732*ae6f7882SJeremy Morse // will have changed. DbgEntityHistoryCalculator doesn't try to detect this. 1733*ae6f7882SJeremy Morse if (isSpillInstruction(MI, MF)) { 1734*ae6f7882SJeremy Morse Loc = extractSpillBaseRegAndOffset(MI); 1735*ae6f7882SJeremy Morse 1736*ae6f7882SJeremy Morse if (TTracker) { 1737*ae6f7882SJeremy Morse Optional<LocIdx> MLoc = MTracker->getSpillMLoc(*Loc); 1738*ae6f7882SJeremy Morse if (MLoc) 1739*ae6f7882SJeremy Morse TTracker->clobberMloc(*MLoc, MI.getIterator()); 1740*ae6f7882SJeremy Morse } 1741*ae6f7882SJeremy Morse } 1742*ae6f7882SJeremy Morse 1743*ae6f7882SJeremy Morse // Try to recognise spill and restore instructions that may transfer a value. 1744*ae6f7882SJeremy Morse if (isLocationSpill(MI, MF, Reg)) { 1745*ae6f7882SJeremy Morse Loc = extractSpillBaseRegAndOffset(MI); 1746*ae6f7882SJeremy Morse auto ValueID = MTracker->readReg(Reg); 1747*ae6f7882SJeremy Morse 1748*ae6f7882SJeremy Morse // If the location is empty, produce a phi, signify it's the live-in value. 1749*ae6f7882SJeremy Morse if (ValueID.getLoc() == 0) 1750*ae6f7882SJeremy Morse ValueID = {CurBB, 0, MTracker->getRegMLoc(Reg)}; 1751*ae6f7882SJeremy Morse 1752*ae6f7882SJeremy Morse MTracker->setSpill(*Loc, ValueID); 1753*ae6f7882SJeremy Morse auto OptSpillLocIdx = MTracker->getSpillMLoc(*Loc); 1754*ae6f7882SJeremy Morse assert(OptSpillLocIdx && "Spill slot set but has no LocIdx?"); 1755*ae6f7882SJeremy Morse LocIdx SpillLocIdx = *OptSpillLocIdx; 1756*ae6f7882SJeremy Morse 1757*ae6f7882SJeremy Morse // Tell TransferTracker about this spill, produce DBG_VALUEs for it. 1758*ae6f7882SJeremy Morse if (TTracker) 1759*ae6f7882SJeremy Morse TTracker->transferMlocs(MTracker->getRegMLoc(Reg), SpillLocIdx, 1760*ae6f7882SJeremy Morse MI.getIterator()); 1761*ae6f7882SJeremy Morse 1762*ae6f7882SJeremy Morse // VarLocBasedImpl would, at this point, stop tracking the source 1763*ae6f7882SJeremy Morse // register of the store. 1764*ae6f7882SJeremy Morse if (EmulateOldLDV) { 1765*ae6f7882SJeremy Morse for (MCRegAliasIterator RAI(Reg, TRI, true); RAI.isValid(); ++RAI) 1766*ae6f7882SJeremy Morse MTracker->defReg(*RAI, CurBB, CurInst); 1767*ae6f7882SJeremy Morse } 1768*ae6f7882SJeremy Morse } else { 1769*ae6f7882SJeremy Morse if (!(Loc = isRestoreInstruction(MI, MF, Reg))) 1770*ae6f7882SJeremy Morse return false; 1771*ae6f7882SJeremy Morse 1772*ae6f7882SJeremy Morse // Is there a value to be restored? 1773*ae6f7882SJeremy Morse auto OptValueID = MTracker->readSpill(*Loc); 1774*ae6f7882SJeremy Morse if (OptValueID) { 1775*ae6f7882SJeremy Morse ValueIDNum ValueID = *OptValueID; 1776*ae6f7882SJeremy Morse LocIdx SpillLocIdx = *MTracker->getSpillMLoc(*Loc); 1777*ae6f7882SJeremy Morse // XXX -- can we recover sub-registers of this value? Until we can, first 1778*ae6f7882SJeremy Morse // overwrite all defs of the register being restored to. 1779*ae6f7882SJeremy Morse for (MCRegAliasIterator RAI(Reg, TRI, true); RAI.isValid(); ++RAI) 1780*ae6f7882SJeremy Morse MTracker->defReg(*RAI, CurBB, CurInst); 1781*ae6f7882SJeremy Morse 1782*ae6f7882SJeremy Morse // Now override the reg we're restoring to. 1783*ae6f7882SJeremy Morse MTracker->setReg(Reg, ValueID); 1784*ae6f7882SJeremy Morse 1785*ae6f7882SJeremy Morse // Report this restore to the transfer tracker too. 1786*ae6f7882SJeremy Morse if (TTracker) 1787*ae6f7882SJeremy Morse TTracker->transferMlocs(SpillLocIdx, MTracker->getRegMLoc(Reg), 1788*ae6f7882SJeremy Morse MI.getIterator()); 1789*ae6f7882SJeremy Morse } else { 1790*ae6f7882SJeremy Morse // There isn't anything in the location; not clear if this is a code path 1791*ae6f7882SJeremy Morse // that still runs. Def this register anyway just in case. 1792*ae6f7882SJeremy Morse for (MCRegAliasIterator RAI(Reg, TRI, true); RAI.isValid(); ++RAI) 1793*ae6f7882SJeremy Morse MTracker->defReg(*RAI, CurBB, CurInst); 1794*ae6f7882SJeremy Morse 1795*ae6f7882SJeremy Morse // Force the spill slot to be tracked. 1796*ae6f7882SJeremy Morse LocIdx L = MTracker->getOrTrackSpillLoc(*Loc); 1797*ae6f7882SJeremy Morse 1798*ae6f7882SJeremy Morse // Set the restored value to be a machine phi number, signifying that it's 1799*ae6f7882SJeremy Morse // whatever the spills live-in value is in this block. Definitely has 1800*ae6f7882SJeremy Morse // a LocIdx due to the setSpill above. 1801*ae6f7882SJeremy Morse ValueIDNum ValueID = {CurBB, 0, L}; 1802*ae6f7882SJeremy Morse MTracker->setReg(Reg, ValueID); 1803*ae6f7882SJeremy Morse MTracker->setSpill(*Loc, ValueID); 1804*ae6f7882SJeremy Morse } 1805*ae6f7882SJeremy Morse } 1806*ae6f7882SJeremy Morse return true; 1807*ae6f7882SJeremy Morse } 1808*ae6f7882SJeremy Morse 1809*ae6f7882SJeremy Morse bool InstrRefBasedLDV::transferRegisterCopy(MachineInstr &MI) { 1810*ae6f7882SJeremy Morse auto DestSrc = TII->isCopyInstr(MI); 1811*ae6f7882SJeremy Morse if (!DestSrc) 1812*ae6f7882SJeremy Morse return false; 1813*ae6f7882SJeremy Morse 1814*ae6f7882SJeremy Morse const MachineOperand *DestRegOp = DestSrc->Destination; 1815*ae6f7882SJeremy Morse const MachineOperand *SrcRegOp = DestSrc->Source; 1816*ae6f7882SJeremy Morse 1817*ae6f7882SJeremy Morse auto isCalleeSavedReg = [&](unsigned Reg) { 1818*ae6f7882SJeremy Morse for (MCRegAliasIterator RAI(Reg, TRI, true); RAI.isValid(); ++RAI) 1819*ae6f7882SJeremy Morse if (CalleeSavedRegs.test(*RAI)) 1820*ae6f7882SJeremy Morse return true; 1821*ae6f7882SJeremy Morse return false; 1822*ae6f7882SJeremy Morse }; 1823*ae6f7882SJeremy Morse 1824*ae6f7882SJeremy Morse Register SrcReg = SrcRegOp->getReg(); 1825*ae6f7882SJeremy Morse Register DestReg = DestRegOp->getReg(); 1826*ae6f7882SJeremy Morse 1827*ae6f7882SJeremy Morse // Ignore identity copies. Yep, these make it as far as LiveDebugValues. 1828*ae6f7882SJeremy Morse if (SrcReg == DestReg) 1829*ae6f7882SJeremy Morse return true; 1830*ae6f7882SJeremy Morse 1831*ae6f7882SJeremy Morse // For emulating VarLocBasedImpl: 1832*ae6f7882SJeremy Morse // We want to recognize instructions where destination register is callee 1833*ae6f7882SJeremy Morse // saved register. If register that could be clobbered by the call is 1834*ae6f7882SJeremy Morse // included, there would be a great chance that it is going to be clobbered 1835*ae6f7882SJeremy Morse // soon. It is more likely that previous register, which is callee saved, is 1836*ae6f7882SJeremy Morse // going to stay unclobbered longer, even if it is killed. 1837*ae6f7882SJeremy Morse // 1838*ae6f7882SJeremy Morse // For InstrRefBasedImpl, we can track multiple locations per value, so 1839*ae6f7882SJeremy Morse // ignore this condition. 1840*ae6f7882SJeremy Morse if (EmulateOldLDV && !isCalleeSavedReg(DestReg)) 1841*ae6f7882SJeremy Morse return false; 1842*ae6f7882SJeremy Morse 1843*ae6f7882SJeremy Morse // InstrRefBasedImpl only followed killing copies. 1844*ae6f7882SJeremy Morse if (EmulateOldLDV && !SrcRegOp->isKill()) 1845*ae6f7882SJeremy Morse return false; 1846*ae6f7882SJeremy Morse 1847*ae6f7882SJeremy Morse // Copy MTracker info, including subregs if available. 1848*ae6f7882SJeremy Morse InstrRefBasedLDV::performCopy(SrcReg, DestReg); 1849*ae6f7882SJeremy Morse 1850*ae6f7882SJeremy Morse // Only produce a transfer of DBG_VALUE within a block where old LDV 1851*ae6f7882SJeremy Morse // would have. We might make use of the additional value tracking in some 1852*ae6f7882SJeremy Morse // other way, later. 1853*ae6f7882SJeremy Morse if (TTracker && isCalleeSavedReg(DestReg) && SrcRegOp->isKill()) 1854*ae6f7882SJeremy Morse TTracker->transferMlocs(MTracker->getRegMLoc(SrcReg), 1855*ae6f7882SJeremy Morse MTracker->getRegMLoc(DestReg), MI.getIterator()); 1856*ae6f7882SJeremy Morse 1857*ae6f7882SJeremy Morse // VarLocBasedImpl would quit tracking the old location after copying. 1858*ae6f7882SJeremy Morse if (EmulateOldLDV && SrcReg != DestReg) 1859*ae6f7882SJeremy Morse MTracker->defReg(SrcReg, CurBB, CurInst); 1860*ae6f7882SJeremy Morse 1861*ae6f7882SJeremy Morse return true; 1862*ae6f7882SJeremy Morse } 1863*ae6f7882SJeremy Morse 1864*ae6f7882SJeremy Morse /// Accumulate a mapping between each DILocalVariable fragment and other 1865*ae6f7882SJeremy Morse /// fragments of that DILocalVariable which overlap. This reduces work during 1866*ae6f7882SJeremy Morse /// the data-flow stage from "Find any overlapping fragments" to "Check if the 1867*ae6f7882SJeremy Morse /// known-to-overlap fragments are present". 1868*ae6f7882SJeremy Morse /// \param MI A previously unprocessed DEBUG_VALUE instruction to analyze for 1869*ae6f7882SJeremy Morse /// fragment usage. 1870*ae6f7882SJeremy Morse void InstrRefBasedLDV::accumulateFragmentMap(MachineInstr &MI) { 1871*ae6f7882SJeremy Morse DebugVariable MIVar(MI.getDebugVariable(), MI.getDebugExpression(), 1872*ae6f7882SJeremy Morse MI.getDebugLoc()->getInlinedAt()); 1873*ae6f7882SJeremy Morse FragmentInfo ThisFragment = MIVar.getFragmentOrDefault(); 1874*ae6f7882SJeremy Morse 1875*ae6f7882SJeremy Morse // If this is the first sighting of this variable, then we are guaranteed 1876*ae6f7882SJeremy Morse // there are currently no overlapping fragments either. Initialize the set 1877*ae6f7882SJeremy Morse // of seen fragments, record no overlaps for the current one, and return. 1878*ae6f7882SJeremy Morse auto SeenIt = SeenFragments.find(MIVar.getVariable()); 1879*ae6f7882SJeremy Morse if (SeenIt == SeenFragments.end()) { 1880*ae6f7882SJeremy Morse SmallSet<FragmentInfo, 4> OneFragment; 1881*ae6f7882SJeremy Morse OneFragment.insert(ThisFragment); 1882*ae6f7882SJeremy Morse SeenFragments.insert({MIVar.getVariable(), OneFragment}); 1883*ae6f7882SJeremy Morse 1884*ae6f7882SJeremy Morse OverlapFragments.insert({{MIVar.getVariable(), ThisFragment}, {}}); 1885*ae6f7882SJeremy Morse return; 1886*ae6f7882SJeremy Morse } 1887*ae6f7882SJeremy Morse 1888*ae6f7882SJeremy Morse // If this particular Variable/Fragment pair already exists in the overlap 1889*ae6f7882SJeremy Morse // map, it has already been accounted for. 1890*ae6f7882SJeremy Morse auto IsInOLapMap = 1891*ae6f7882SJeremy Morse OverlapFragments.insert({{MIVar.getVariable(), ThisFragment}, {}}); 1892*ae6f7882SJeremy Morse if (!IsInOLapMap.second) 1893*ae6f7882SJeremy Morse return; 1894*ae6f7882SJeremy Morse 1895*ae6f7882SJeremy Morse auto &ThisFragmentsOverlaps = IsInOLapMap.first->second; 1896*ae6f7882SJeremy Morse auto &AllSeenFragments = SeenIt->second; 1897*ae6f7882SJeremy Morse 1898*ae6f7882SJeremy Morse // Otherwise, examine all other seen fragments for this variable, with "this" 1899*ae6f7882SJeremy Morse // fragment being a previously unseen fragment. Record any pair of 1900*ae6f7882SJeremy Morse // overlapping fragments. 1901*ae6f7882SJeremy Morse for (auto &ASeenFragment : AllSeenFragments) { 1902*ae6f7882SJeremy Morse // Does this previously seen fragment overlap? 1903*ae6f7882SJeremy Morse if (DIExpression::fragmentsOverlap(ThisFragment, ASeenFragment)) { 1904*ae6f7882SJeremy Morse // Yes: Mark the current fragment as being overlapped. 1905*ae6f7882SJeremy Morse ThisFragmentsOverlaps.push_back(ASeenFragment); 1906*ae6f7882SJeremy Morse // Mark the previously seen fragment as being overlapped by the current 1907*ae6f7882SJeremy Morse // one. 1908*ae6f7882SJeremy Morse auto ASeenFragmentsOverlaps = 1909*ae6f7882SJeremy Morse OverlapFragments.find({MIVar.getVariable(), ASeenFragment}); 1910*ae6f7882SJeremy Morse assert(ASeenFragmentsOverlaps != OverlapFragments.end() && 1911*ae6f7882SJeremy Morse "Previously seen var fragment has no vector of overlaps"); 1912*ae6f7882SJeremy Morse ASeenFragmentsOverlaps->second.push_back(ThisFragment); 1913*ae6f7882SJeremy Morse } 1914*ae6f7882SJeremy Morse } 1915*ae6f7882SJeremy Morse 1916*ae6f7882SJeremy Morse AllSeenFragments.insert(ThisFragment); 1917*ae6f7882SJeremy Morse } 1918*ae6f7882SJeremy Morse 1919*ae6f7882SJeremy Morse void InstrRefBasedLDV::process(MachineInstr &MI) { 1920*ae6f7882SJeremy Morse // Try to interpret an MI as a debug or transfer instruction. Only if it's 1921*ae6f7882SJeremy Morse // none of these should we interpret it's register defs as new value 1922*ae6f7882SJeremy Morse // definitions. 1923*ae6f7882SJeremy Morse if (transferDebugValue(MI)) 1924*ae6f7882SJeremy Morse return; 1925*ae6f7882SJeremy Morse if (transferRegisterCopy(MI)) 1926*ae6f7882SJeremy Morse return; 1927*ae6f7882SJeremy Morse if (transferSpillOrRestoreInst(MI)) 1928*ae6f7882SJeremy Morse return; 1929*ae6f7882SJeremy Morse transferRegisterDef(MI); 1930*ae6f7882SJeremy Morse } 1931*ae6f7882SJeremy Morse 1932*ae6f7882SJeremy Morse void InstrRefBasedLDV::produceTransferFunctions( 1933*ae6f7882SJeremy Morse MachineFunction &MF, SmallVectorImpl<MLocTransferMap> &MLocTransfer, 1934*ae6f7882SJeremy Morse unsigned MaxNumBlocks, SmallVectorImpl<VLocTracker> &VLocs) { 1935*ae6f7882SJeremy Morse // Because we try to optimize around register mask operands by ignoring regs 1936*ae6f7882SJeremy Morse // that aren't currently tracked, we set up something ugly for later: RegMask 1937*ae6f7882SJeremy Morse // operands that are seen earlier than the first use of a register, still need 1938*ae6f7882SJeremy Morse // to clobber that register in the transfer function. But this information 1939*ae6f7882SJeremy Morse // isn't actively recorded. Instead, we track each RegMask used in each block, 1940*ae6f7882SJeremy Morse // and accumulated the clobbered but untracked registers in each block into 1941*ae6f7882SJeremy Morse // the following bitvector. Later, if new values are tracked, we can add 1942*ae6f7882SJeremy Morse // appropriate clobbers. 1943*ae6f7882SJeremy Morse SmallVector<BitVector, 32> BlockMasks; 1944*ae6f7882SJeremy Morse BlockMasks.resize(MaxNumBlocks); 1945*ae6f7882SJeremy Morse 1946*ae6f7882SJeremy Morse // Reserve one bit per register for the masks described above. 1947*ae6f7882SJeremy Morse unsigned BVWords = MachineOperand::getRegMaskSize(TRI->getNumRegs()); 1948*ae6f7882SJeremy Morse for (auto &BV : BlockMasks) 1949*ae6f7882SJeremy Morse BV.resize(TRI->getNumRegs(), true); 1950*ae6f7882SJeremy Morse 1951*ae6f7882SJeremy Morse // Step through all instructions and inhale the transfer function. 1952*ae6f7882SJeremy Morse for (auto &MBB : MF) { 1953*ae6f7882SJeremy Morse // Object fields that are read by trackers to know where we are in the 1954*ae6f7882SJeremy Morse // function. 1955*ae6f7882SJeremy Morse CurBB = MBB.getNumber(); 1956*ae6f7882SJeremy Morse CurInst = 1; 1957*ae6f7882SJeremy Morse 1958*ae6f7882SJeremy Morse // Set all machine locations to a PHI value. For transfer function 1959*ae6f7882SJeremy Morse // production only, this signifies the live-in value to the block. 1960*ae6f7882SJeremy Morse MTracker->reset(); 1961*ae6f7882SJeremy Morse MTracker->setMPhis(CurBB); 1962*ae6f7882SJeremy Morse 1963*ae6f7882SJeremy Morse VTracker = &VLocs[CurBB]; 1964*ae6f7882SJeremy Morse VTracker->MBB = &MBB; 1965*ae6f7882SJeremy Morse 1966*ae6f7882SJeremy Morse // Step through each instruction in this block. 1967*ae6f7882SJeremy Morse for (auto &MI : MBB) { 1968*ae6f7882SJeremy Morse process(MI); 1969*ae6f7882SJeremy Morse // Also accumulate fragment map. 1970*ae6f7882SJeremy Morse if (MI.isDebugValue()) 1971*ae6f7882SJeremy Morse accumulateFragmentMap(MI); 1972*ae6f7882SJeremy Morse ++CurInst; 1973*ae6f7882SJeremy Morse } 1974*ae6f7882SJeremy Morse 1975*ae6f7882SJeremy Morse // Produce the transfer function, a map of machine location to new value. If 1976*ae6f7882SJeremy Morse // any machine location has the live-in phi value from the start of the 1977*ae6f7882SJeremy Morse // block, it's live-through and doesn't need recording in the transfer 1978*ae6f7882SJeremy Morse // function. 1979*ae6f7882SJeremy Morse for (auto Location : MTracker->locations()) { 1980*ae6f7882SJeremy Morse LocIdx Idx = Location.Idx; 1981*ae6f7882SJeremy Morse ValueIDNum &P = Location.Value; 1982*ae6f7882SJeremy Morse if (P.isPHI() && P.getLoc() == Idx.asU64()) 1983*ae6f7882SJeremy Morse continue; 1984*ae6f7882SJeremy Morse 1985*ae6f7882SJeremy Morse // Insert-or-update. 1986*ae6f7882SJeremy Morse auto &TransferMap = MLocTransfer[CurBB]; 1987*ae6f7882SJeremy Morse auto Result = TransferMap.insert(std::make_pair(Idx.asU64(), P)); 1988*ae6f7882SJeremy Morse if (!Result.second) 1989*ae6f7882SJeremy Morse Result.first->second = P; 1990*ae6f7882SJeremy Morse } 1991*ae6f7882SJeremy Morse 1992*ae6f7882SJeremy Morse // Accumulate any bitmask operands into the clobberred reg mask for this 1993*ae6f7882SJeremy Morse // block. 1994*ae6f7882SJeremy Morse for (auto &P : MTracker->Masks) { 1995*ae6f7882SJeremy Morse BlockMasks[CurBB].clearBitsNotInMask(P.first->getRegMask(), BVWords); 1996*ae6f7882SJeremy Morse } 1997*ae6f7882SJeremy Morse } 1998*ae6f7882SJeremy Morse 1999*ae6f7882SJeremy Morse // Compute a bitvector of all the registers that are tracked in this block. 2000*ae6f7882SJeremy Morse const TargetLowering *TLI = MF.getSubtarget().getTargetLowering(); 2001*ae6f7882SJeremy Morse unsigned SP = TLI->getStackPointerRegisterToSaveRestore(); 2002*ae6f7882SJeremy Morse BitVector UsedRegs(TRI->getNumRegs()); 2003*ae6f7882SJeremy Morse for (auto Location : MTracker->locations()) { 2004*ae6f7882SJeremy Morse unsigned ID = MTracker->LocIdxToLocID[Location.Idx]; 2005*ae6f7882SJeremy Morse if (ID >= TRI->getNumRegs() || ID == SP) 2006*ae6f7882SJeremy Morse continue; 2007*ae6f7882SJeremy Morse UsedRegs.set(ID); 2008*ae6f7882SJeremy Morse } 2009*ae6f7882SJeremy Morse 2010*ae6f7882SJeremy Morse // Check that any regmask-clobber of a register that gets tracked, is not 2011*ae6f7882SJeremy Morse // live-through in the transfer function. It needs to be clobbered at the 2012*ae6f7882SJeremy Morse // very least. 2013*ae6f7882SJeremy Morse for (unsigned int I = 0; I < MaxNumBlocks; ++I) { 2014*ae6f7882SJeremy Morse BitVector &BV = BlockMasks[I]; 2015*ae6f7882SJeremy Morse BV.flip(); 2016*ae6f7882SJeremy Morse BV &= UsedRegs; 2017*ae6f7882SJeremy Morse // This produces all the bits that we clobber, but also use. Check that 2018*ae6f7882SJeremy Morse // they're all clobbered or at least set in the designated transfer 2019*ae6f7882SJeremy Morse // elem. 2020*ae6f7882SJeremy Morse for (unsigned Bit : BV.set_bits()) { 2021*ae6f7882SJeremy Morse unsigned ID = MTracker->getLocID(Bit, false); 2022*ae6f7882SJeremy Morse LocIdx Idx = MTracker->LocIDToLocIdx[ID]; 2023*ae6f7882SJeremy Morse auto &TransferMap = MLocTransfer[I]; 2024*ae6f7882SJeremy Morse 2025*ae6f7882SJeremy Morse // Install a value representing the fact that this location is effectively 2026*ae6f7882SJeremy Morse // written to in this block. As there's no reserved value, instead use 2027*ae6f7882SJeremy Morse // a value number that is never generated. Pick the value number for the 2028*ae6f7882SJeremy Morse // first instruction in the block, def'ing this location, which we know 2029*ae6f7882SJeremy Morse // this block never used anyway. 2030*ae6f7882SJeremy Morse ValueIDNum NotGeneratedNum = ValueIDNum(I, 1, Idx); 2031*ae6f7882SJeremy Morse auto Result = 2032*ae6f7882SJeremy Morse TransferMap.insert(std::make_pair(Idx.asU64(), NotGeneratedNum)); 2033*ae6f7882SJeremy Morse if (!Result.second) { 2034*ae6f7882SJeremy Morse ValueIDNum &ValueID = Result.first->second; 2035*ae6f7882SJeremy Morse if (ValueID.getBlock() == I && ValueID.isPHI()) 2036*ae6f7882SJeremy Morse // It was left as live-through. Set it to clobbered. 2037*ae6f7882SJeremy Morse ValueID = NotGeneratedNum; 2038*ae6f7882SJeremy Morse } 2039*ae6f7882SJeremy Morse } 2040*ae6f7882SJeremy Morse } 2041*ae6f7882SJeremy Morse } 2042*ae6f7882SJeremy Morse 2043*ae6f7882SJeremy Morse std::tuple<bool, bool> 2044*ae6f7882SJeremy Morse InstrRefBasedLDV::mlocJoin(MachineBasicBlock &MBB, 2045*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 16> &Visited, 2046*ae6f7882SJeremy Morse ValueIDNum **OutLocs, ValueIDNum *InLocs) { 2047*ae6f7882SJeremy Morse LLVM_DEBUG(dbgs() << "join MBB: " << MBB.getNumber() << "\n"); 2048*ae6f7882SJeremy Morse bool Changed = false; 2049*ae6f7882SJeremy Morse bool DowngradeOccurred = false; 2050*ae6f7882SJeremy Morse 2051*ae6f7882SJeremy Morse // Collect predecessors that have been visited. Anything that hasn't been 2052*ae6f7882SJeremy Morse // visited yet is a backedge on the first iteration, and the meet of it's 2053*ae6f7882SJeremy Morse // lattice value for all locations will be unaffected. 2054*ae6f7882SJeremy Morse SmallVector<const MachineBasicBlock *, 8> BlockOrders; 2055*ae6f7882SJeremy Morse for (auto Pred : MBB.predecessors()) { 2056*ae6f7882SJeremy Morse if (Visited.count(Pred)) { 2057*ae6f7882SJeremy Morse BlockOrders.push_back(Pred); 2058*ae6f7882SJeremy Morse } 2059*ae6f7882SJeremy Morse } 2060*ae6f7882SJeremy Morse 2061*ae6f7882SJeremy Morse // Visit predecessors in RPOT order. 2062*ae6f7882SJeremy Morse auto Cmp = [&](const MachineBasicBlock *A, const MachineBasicBlock *B) { 2063*ae6f7882SJeremy Morse return BBToOrder.find(A)->second < BBToOrder.find(B)->second; 2064*ae6f7882SJeremy Morse }; 2065*ae6f7882SJeremy Morse llvm::sort(BlockOrders.begin(), BlockOrders.end(), Cmp); 2066*ae6f7882SJeremy Morse 2067*ae6f7882SJeremy Morse // Skip entry block. 2068*ae6f7882SJeremy Morse if (BlockOrders.size() == 0) 2069*ae6f7882SJeremy Morse return std::tuple<bool, bool>(false, false); 2070*ae6f7882SJeremy Morse 2071*ae6f7882SJeremy Morse // Step through all machine locations, then look at each predecessor and 2072*ae6f7882SJeremy Morse // detect disagreements. 2073*ae6f7882SJeremy Morse unsigned ThisBlockRPO = BBToOrder.find(&MBB)->second; 2074*ae6f7882SJeremy Morse for (auto Location : MTracker->locations()) { 2075*ae6f7882SJeremy Morse LocIdx Idx = Location.Idx; 2076*ae6f7882SJeremy Morse // Pick out the first predecessors live-out value for this location. It's 2077*ae6f7882SJeremy Morse // guaranteed to be not a backedge, as we order by RPO. 2078*ae6f7882SJeremy Morse ValueIDNum BaseVal = OutLocs[BlockOrders[0]->getNumber()][Idx.asU64()]; 2079*ae6f7882SJeremy Morse 2080*ae6f7882SJeremy Morse // Some flags for whether there's a disagreement, and whether it's a 2081*ae6f7882SJeremy Morse // disagreement with a backedge or not. 2082*ae6f7882SJeremy Morse bool Disagree = false; 2083*ae6f7882SJeremy Morse bool NonBackEdgeDisagree = false; 2084*ae6f7882SJeremy Morse 2085*ae6f7882SJeremy Morse // Loop around everything that wasn't 'base'. 2086*ae6f7882SJeremy Morse for (unsigned int I = 1; I < BlockOrders.size(); ++I) { 2087*ae6f7882SJeremy Morse auto *MBB = BlockOrders[I]; 2088*ae6f7882SJeremy Morse if (BaseVal != OutLocs[MBB->getNumber()][Idx.asU64()]) { 2089*ae6f7882SJeremy Morse // Live-out of a predecessor disagrees with the first predecessor. 2090*ae6f7882SJeremy Morse Disagree = true; 2091*ae6f7882SJeremy Morse 2092*ae6f7882SJeremy Morse // Test whether it's a disagreemnt in the backedges or not. 2093*ae6f7882SJeremy Morse if (BBToOrder.find(MBB)->second < ThisBlockRPO) // might be self b/e 2094*ae6f7882SJeremy Morse NonBackEdgeDisagree = true; 2095*ae6f7882SJeremy Morse } 2096*ae6f7882SJeremy Morse } 2097*ae6f7882SJeremy Morse 2098*ae6f7882SJeremy Morse bool OverRide = false; 2099*ae6f7882SJeremy Morse if (Disagree && !NonBackEdgeDisagree) { 2100*ae6f7882SJeremy Morse // Only the backedges disagree. Consider demoting the livein 2101*ae6f7882SJeremy Morse // lattice value, as per the file level comment. The value we consider 2102*ae6f7882SJeremy Morse // demoting to is the value that the non-backedge predecessors agree on. 2103*ae6f7882SJeremy Morse // The order of values is that non-PHIs are \top, a PHI at this block 2104*ae6f7882SJeremy Morse // \bot, and phis between the two are ordered by their RPO number. 2105*ae6f7882SJeremy Morse // If there's no agreement, or we've already demoted to this PHI value 2106*ae6f7882SJeremy Morse // before, replace with a PHI value at this block. 2107*ae6f7882SJeremy Morse 2108*ae6f7882SJeremy Morse // Calculate order numbers: zero means normal def, nonzero means RPO 2109*ae6f7882SJeremy Morse // number. 2110*ae6f7882SJeremy Morse unsigned BaseBlockRPONum = BBNumToRPO[BaseVal.getBlock()] + 1; 2111*ae6f7882SJeremy Morse if (!BaseVal.isPHI()) 2112*ae6f7882SJeremy Morse BaseBlockRPONum = 0; 2113*ae6f7882SJeremy Morse 2114*ae6f7882SJeremy Morse ValueIDNum &InLocID = InLocs[Idx.asU64()]; 2115*ae6f7882SJeremy Morse unsigned InLocRPONum = BBNumToRPO[InLocID.getBlock()] + 1; 2116*ae6f7882SJeremy Morse if (!InLocID.isPHI()) 2117*ae6f7882SJeremy Morse InLocRPONum = 0; 2118*ae6f7882SJeremy Morse 2119*ae6f7882SJeremy Morse // Should we ignore the disagreeing backedges, and override with the 2120*ae6f7882SJeremy Morse // value the other predecessors agree on (in "base")? 2121*ae6f7882SJeremy Morse unsigned ThisBlockRPONum = BBNumToRPO[MBB.getNumber()] + 1; 2122*ae6f7882SJeremy Morse if (BaseBlockRPONum > InLocRPONum && BaseBlockRPONum < ThisBlockRPONum) { 2123*ae6f7882SJeremy Morse // Override. 2124*ae6f7882SJeremy Morse OverRide = true; 2125*ae6f7882SJeremy Morse DowngradeOccurred = true; 2126*ae6f7882SJeremy Morse } 2127*ae6f7882SJeremy Morse } 2128*ae6f7882SJeremy Morse // else: if we disagree in the non-backedges, then this is definitely 2129*ae6f7882SJeremy Morse // a control flow merge where different values merge. Make it a PHI. 2130*ae6f7882SJeremy Morse 2131*ae6f7882SJeremy Morse // Generate a phi... 2132*ae6f7882SJeremy Morse ValueIDNum PHI = {(uint64_t)MBB.getNumber(), 0, Idx}; 2133*ae6f7882SJeremy Morse ValueIDNum NewVal = (Disagree && !OverRide) ? PHI : BaseVal; 2134*ae6f7882SJeremy Morse if (InLocs[Idx.asU64()] != NewVal) { 2135*ae6f7882SJeremy Morse Changed |= true; 2136*ae6f7882SJeremy Morse InLocs[Idx.asU64()] = NewVal; 2137*ae6f7882SJeremy Morse } 2138*ae6f7882SJeremy Morse } 2139*ae6f7882SJeremy Morse 2140*ae6f7882SJeremy Morse // Uhhhhhh, reimplement NumInserted and NumRemoved pls. 2141*ae6f7882SJeremy Morse return std::tuple<bool, bool>(Changed, DowngradeOccurred); 2142*ae6f7882SJeremy Morse } 2143*ae6f7882SJeremy Morse 2144*ae6f7882SJeremy Morse void InstrRefBasedLDV::mlocDataflow( 2145*ae6f7882SJeremy Morse ValueIDNum **MInLocs, ValueIDNum **MOutLocs, 2146*ae6f7882SJeremy Morse SmallVectorImpl<MLocTransferMap> &MLocTransfer) { 2147*ae6f7882SJeremy Morse std::priority_queue<unsigned int, std::vector<unsigned int>, 2148*ae6f7882SJeremy Morse std::greater<unsigned int>> 2149*ae6f7882SJeremy Morse Worklist, Pending; 2150*ae6f7882SJeremy Morse 2151*ae6f7882SJeremy Morse // We track what is on the current and pending worklist to avoid inserting 2152*ae6f7882SJeremy Morse // the same thing twice. We could avoid this with a custom priority queue, 2153*ae6f7882SJeremy Morse // but this is probably not worth it. 2154*ae6f7882SJeremy Morse SmallPtrSet<MachineBasicBlock *, 16> OnPending, OnWorklist; 2155*ae6f7882SJeremy Morse 2156*ae6f7882SJeremy Morse // Initialize worklist with every block to be visited. 2157*ae6f7882SJeremy Morse for (unsigned int I = 0; I < BBToOrder.size(); ++I) { 2158*ae6f7882SJeremy Morse Worklist.push(I); 2159*ae6f7882SJeremy Morse OnWorklist.insert(OrderToBB[I]); 2160*ae6f7882SJeremy Morse } 2161*ae6f7882SJeremy Morse 2162*ae6f7882SJeremy Morse MTracker->reset(); 2163*ae6f7882SJeremy Morse 2164*ae6f7882SJeremy Morse // Set inlocs for entry block -- each as a PHI at the entry block. Represents 2165*ae6f7882SJeremy Morse // the incoming value to the function. 2166*ae6f7882SJeremy Morse MTracker->setMPhis(0); 2167*ae6f7882SJeremy Morse for (auto Location : MTracker->locations()) 2168*ae6f7882SJeremy Morse MInLocs[0][Location.Idx.asU64()] = Location.Value; 2169*ae6f7882SJeremy Morse 2170*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 16> Visited; 2171*ae6f7882SJeremy Morse while (!Worklist.empty() || !Pending.empty()) { 2172*ae6f7882SJeremy Morse // Vector for storing the evaluated block transfer function. 2173*ae6f7882SJeremy Morse SmallVector<std::pair<LocIdx, ValueIDNum>, 32> ToRemap; 2174*ae6f7882SJeremy Morse 2175*ae6f7882SJeremy Morse while (!Worklist.empty()) { 2176*ae6f7882SJeremy Morse MachineBasicBlock *MBB = OrderToBB[Worklist.top()]; 2177*ae6f7882SJeremy Morse CurBB = MBB->getNumber(); 2178*ae6f7882SJeremy Morse Worklist.pop(); 2179*ae6f7882SJeremy Morse 2180*ae6f7882SJeremy Morse // Join the values in all predecessor blocks. 2181*ae6f7882SJeremy Morse bool InLocsChanged, DowngradeOccurred; 2182*ae6f7882SJeremy Morse std::tie(InLocsChanged, DowngradeOccurred) = 2183*ae6f7882SJeremy Morse mlocJoin(*MBB, Visited, MOutLocs, MInLocs[CurBB]); 2184*ae6f7882SJeremy Morse InLocsChanged |= Visited.insert(MBB).second; 2185*ae6f7882SJeremy Morse 2186*ae6f7882SJeremy Morse // If a downgrade occurred, book us in for re-examination on the next 2187*ae6f7882SJeremy Morse // iteration. 2188*ae6f7882SJeremy Morse if (DowngradeOccurred && OnPending.insert(MBB).second) 2189*ae6f7882SJeremy Morse Pending.push(BBToOrder[MBB]); 2190*ae6f7882SJeremy Morse 2191*ae6f7882SJeremy Morse // Don't examine transfer function if we've visited this loc at least 2192*ae6f7882SJeremy Morse // once, and inlocs haven't changed. 2193*ae6f7882SJeremy Morse if (!InLocsChanged) 2194*ae6f7882SJeremy Morse continue; 2195*ae6f7882SJeremy Morse 2196*ae6f7882SJeremy Morse // Load the current set of live-ins into MLocTracker. 2197*ae6f7882SJeremy Morse MTracker->loadFromArray(MInLocs[CurBB], CurBB); 2198*ae6f7882SJeremy Morse 2199*ae6f7882SJeremy Morse // Each element of the transfer function can be a new def, or a read of 2200*ae6f7882SJeremy Morse // a live-in value. Evaluate each element, and store to "ToRemap". 2201*ae6f7882SJeremy Morse ToRemap.clear(); 2202*ae6f7882SJeremy Morse for (auto &P : MLocTransfer[CurBB]) { 2203*ae6f7882SJeremy Morse if (P.second.getBlock() == CurBB && P.second.isPHI()) { 2204*ae6f7882SJeremy Morse // This is a movement of whatever was live in. Read it. 2205*ae6f7882SJeremy Morse ValueIDNum NewID = MTracker->getNumAtPos(P.second.getLoc()); 2206*ae6f7882SJeremy Morse ToRemap.push_back(std::make_pair(P.first, NewID)); 2207*ae6f7882SJeremy Morse } else { 2208*ae6f7882SJeremy Morse // It's a def. Just set it. 2209*ae6f7882SJeremy Morse assert(P.second.getBlock() == CurBB); 2210*ae6f7882SJeremy Morse ToRemap.push_back(std::make_pair(P.first, P.second)); 2211*ae6f7882SJeremy Morse } 2212*ae6f7882SJeremy Morse } 2213*ae6f7882SJeremy Morse 2214*ae6f7882SJeremy Morse // Commit the transfer function changes into mloc tracker, which 2215*ae6f7882SJeremy Morse // transforms the contents of the MLocTracker into the live-outs. 2216*ae6f7882SJeremy Morse for (auto &P : ToRemap) 2217*ae6f7882SJeremy Morse MTracker->setMLoc(P.first, P.second); 2218*ae6f7882SJeremy Morse 2219*ae6f7882SJeremy Morse // Now copy out-locs from mloc tracker into out-loc vector, checking 2220*ae6f7882SJeremy Morse // whether changes have occurred. These changes can have come from both 2221*ae6f7882SJeremy Morse // the transfer function, and mlocJoin. 2222*ae6f7882SJeremy Morse bool OLChanged = false; 2223*ae6f7882SJeremy Morse for (auto Location : MTracker->locations()) { 2224*ae6f7882SJeremy Morse OLChanged |= MOutLocs[CurBB][Location.Idx.asU64()] != Location.Value; 2225*ae6f7882SJeremy Morse MOutLocs[CurBB][Location.Idx.asU64()] = Location.Value; 2226*ae6f7882SJeremy Morse } 2227*ae6f7882SJeremy Morse 2228*ae6f7882SJeremy Morse MTracker->reset(); 2229*ae6f7882SJeremy Morse 2230*ae6f7882SJeremy Morse // No need to examine successors again if out-locs didn't change. 2231*ae6f7882SJeremy Morse if (!OLChanged) 2232*ae6f7882SJeremy Morse continue; 2233*ae6f7882SJeremy Morse 2234*ae6f7882SJeremy Morse // All successors should be visited: put any back-edges on the pending 2235*ae6f7882SJeremy Morse // list for the next dataflow iteration, and any other successors to be 2236*ae6f7882SJeremy Morse // visited this iteration, if they're not going to be already. 2237*ae6f7882SJeremy Morse for (auto s : MBB->successors()) { 2238*ae6f7882SJeremy Morse // Does branching to this successor represent a back-edge? 2239*ae6f7882SJeremy Morse if (BBToOrder[s] > BBToOrder[MBB]) { 2240*ae6f7882SJeremy Morse // No: visit it during this dataflow iteration. 2241*ae6f7882SJeremy Morse if (OnWorklist.insert(s).second) 2242*ae6f7882SJeremy Morse Worklist.push(BBToOrder[s]); 2243*ae6f7882SJeremy Morse } else { 2244*ae6f7882SJeremy Morse // Yes: visit it on the next iteration. 2245*ae6f7882SJeremy Morse if (OnPending.insert(s).second) 2246*ae6f7882SJeremy Morse Pending.push(BBToOrder[s]); 2247*ae6f7882SJeremy Morse } 2248*ae6f7882SJeremy Morse } 2249*ae6f7882SJeremy Morse } 2250*ae6f7882SJeremy Morse 2251*ae6f7882SJeremy Morse Worklist.swap(Pending); 2252*ae6f7882SJeremy Morse std::swap(OnPending, OnWorklist); 2253*ae6f7882SJeremy Morse OnPending.clear(); 2254*ae6f7882SJeremy Morse // At this point, pending must be empty, since it was just the empty 2255*ae6f7882SJeremy Morse // worklist 2256*ae6f7882SJeremy Morse assert(Pending.empty() && "Pending should be empty"); 2257*ae6f7882SJeremy Morse } 2258*ae6f7882SJeremy Morse 2259*ae6f7882SJeremy Morse // Once all the live-ins don't change on mlocJoin(), we've reached a 2260*ae6f7882SJeremy Morse // fixedpoint. 2261*ae6f7882SJeremy Morse } 2262*ae6f7882SJeremy Morse 2263*ae6f7882SJeremy Morse bool InstrRefBasedLDV::vlocDowngradeLattice( 2264*ae6f7882SJeremy Morse const MachineBasicBlock &MBB, const DbgValue &OldLiveInLocation, 2265*ae6f7882SJeremy Morse const SmallVectorImpl<InValueT> &Values, unsigned CurBlockRPONum) { 2266*ae6f7882SJeremy Morse // Ranking value preference: see file level comment, the highest rank is 2267*ae6f7882SJeremy Morse // a plain def, followed by PHI values in reverse post-order. Numerically, 2268*ae6f7882SJeremy Morse // we assign all defs the rank '0', all PHIs their blocks RPO number plus 2269*ae6f7882SJeremy Morse // one, and consider the lowest value the highest ranked. 2270*ae6f7882SJeremy Morse int OldLiveInRank = BBNumToRPO[OldLiveInLocation.ID.getBlock()] + 1; 2271*ae6f7882SJeremy Morse if (!OldLiveInLocation.ID.isPHI()) 2272*ae6f7882SJeremy Morse OldLiveInRank = 0; 2273*ae6f7882SJeremy Morse 2274*ae6f7882SJeremy Morse // Allow any unresolvable conflict to be over-ridden. 2275*ae6f7882SJeremy Morse if (OldLiveInLocation.Kind == DbgValue::NoVal) { 2276*ae6f7882SJeremy Morse // Although if it was an unresolvable conflict from _this_ block, then 2277*ae6f7882SJeremy Morse // all other seeking of downgrades and PHIs must have failed before hand. 2278*ae6f7882SJeremy Morse if (OldLiveInLocation.BlockNo == (unsigned)MBB.getNumber()) 2279*ae6f7882SJeremy Morse return false; 2280*ae6f7882SJeremy Morse OldLiveInRank = INT_MIN; 2281*ae6f7882SJeremy Morse } 2282*ae6f7882SJeremy Morse 2283*ae6f7882SJeremy Morse auto &InValue = *Values[0].second; 2284*ae6f7882SJeremy Morse 2285*ae6f7882SJeremy Morse if (InValue.Kind == DbgValue::Const || InValue.Kind == DbgValue::NoVal) 2286*ae6f7882SJeremy Morse return false; 2287*ae6f7882SJeremy Morse 2288*ae6f7882SJeremy Morse unsigned ThisRPO = BBNumToRPO[InValue.ID.getBlock()]; 2289*ae6f7882SJeremy Morse int ThisRank = ThisRPO + 1; 2290*ae6f7882SJeremy Morse if (!InValue.ID.isPHI()) 2291*ae6f7882SJeremy Morse ThisRank = 0; 2292*ae6f7882SJeremy Morse 2293*ae6f7882SJeremy Morse // Too far down the lattice? 2294*ae6f7882SJeremy Morse if (ThisRPO >= CurBlockRPONum) 2295*ae6f7882SJeremy Morse return false; 2296*ae6f7882SJeremy Morse 2297*ae6f7882SJeremy Morse // Higher in the lattice than what we've already explored? 2298*ae6f7882SJeremy Morse if (ThisRank <= OldLiveInRank) 2299*ae6f7882SJeremy Morse return false; 2300*ae6f7882SJeremy Morse 2301*ae6f7882SJeremy Morse return true; 2302*ae6f7882SJeremy Morse } 2303*ae6f7882SJeremy Morse 2304*ae6f7882SJeremy Morse std::tuple<Optional<ValueIDNum>, bool> InstrRefBasedLDV::pickVPHILoc( 2305*ae6f7882SJeremy Morse MachineBasicBlock &MBB, const DebugVariable &Var, const LiveIdxT &LiveOuts, 2306*ae6f7882SJeremy Morse ValueIDNum **MOutLocs, ValueIDNum **MInLocs, 2307*ae6f7882SJeremy Morse const SmallVectorImpl<MachineBasicBlock *> &BlockOrders) { 2308*ae6f7882SJeremy Morse // Collect a set of locations from predecessor where its live-out value can 2309*ae6f7882SJeremy Morse // be found. 2310*ae6f7882SJeremy Morse SmallVector<SmallVector<LocIdx, 4>, 8> Locs; 2311*ae6f7882SJeremy Morse unsigned NumLocs = MTracker->getNumLocs(); 2312*ae6f7882SJeremy Morse unsigned BackEdgesStart = 0; 2313*ae6f7882SJeremy Morse 2314*ae6f7882SJeremy Morse for (auto p : BlockOrders) { 2315*ae6f7882SJeremy Morse // Pick out where backedges start in the list of predecessors. Relies on 2316*ae6f7882SJeremy Morse // BlockOrders being sorted by RPO. 2317*ae6f7882SJeremy Morse if (BBToOrder[p] < BBToOrder[&MBB]) 2318*ae6f7882SJeremy Morse ++BackEdgesStart; 2319*ae6f7882SJeremy Morse 2320*ae6f7882SJeremy Morse // For each predecessor, create a new set of locations. 2321*ae6f7882SJeremy Morse Locs.resize(Locs.size() + 1); 2322*ae6f7882SJeremy Morse unsigned ThisBBNum = p->getNumber(); 2323*ae6f7882SJeremy Morse auto LiveOutMap = LiveOuts.find(p); 2324*ae6f7882SJeremy Morse if (LiveOutMap == LiveOuts.end()) 2325*ae6f7882SJeremy Morse // This predecessor isn't in scope, it must have no live-in/live-out 2326*ae6f7882SJeremy Morse // locations. 2327*ae6f7882SJeremy Morse continue; 2328*ae6f7882SJeremy Morse 2329*ae6f7882SJeremy Morse auto It = LiveOutMap->second->find(Var); 2330*ae6f7882SJeremy Morse if (It == LiveOutMap->second->end()) 2331*ae6f7882SJeremy Morse // There's no value recorded for this variable in this predecessor, 2332*ae6f7882SJeremy Morse // leave an empty set of locations. 2333*ae6f7882SJeremy Morse continue; 2334*ae6f7882SJeremy Morse 2335*ae6f7882SJeremy Morse const DbgValue &OutVal = It->second; 2336*ae6f7882SJeremy Morse 2337*ae6f7882SJeremy Morse if (OutVal.Kind == DbgValue::Const || OutVal.Kind == DbgValue::NoVal) 2338*ae6f7882SJeremy Morse // Consts and no-values cannot have locations we can join on. 2339*ae6f7882SJeremy Morse continue; 2340*ae6f7882SJeremy Morse 2341*ae6f7882SJeremy Morse assert(OutVal.Kind == DbgValue::Proposed || OutVal.Kind == DbgValue::Def); 2342*ae6f7882SJeremy Morse ValueIDNum ValToLookFor = OutVal.ID; 2343*ae6f7882SJeremy Morse 2344*ae6f7882SJeremy Morse // Search the live-outs of the predecessor for the specified value. 2345*ae6f7882SJeremy Morse for (unsigned int I = 0; I < NumLocs; ++I) { 2346*ae6f7882SJeremy Morse if (MOutLocs[ThisBBNum][I] == ValToLookFor) 2347*ae6f7882SJeremy Morse Locs.back().push_back(LocIdx(I)); 2348*ae6f7882SJeremy Morse } 2349*ae6f7882SJeremy Morse } 2350*ae6f7882SJeremy Morse 2351*ae6f7882SJeremy Morse // If there were no locations at all, return an empty result. 2352*ae6f7882SJeremy Morse if (Locs.empty()) 2353*ae6f7882SJeremy Morse return {None, false}; 2354*ae6f7882SJeremy Morse 2355*ae6f7882SJeremy Morse // Lambda for seeking a common location within a range of location-sets. 2356*ae6f7882SJeremy Morse typedef SmallVector<SmallVector<LocIdx, 4>, 8>::iterator LocsIt; 2357*ae6f7882SJeremy Morse auto SeekLocation = 2358*ae6f7882SJeremy Morse [&Locs](llvm::iterator_range<LocsIt> SearchRange) -> Optional<LocIdx> { 2359*ae6f7882SJeremy Morse // Starting with the first set of locations, take the intersection with 2360*ae6f7882SJeremy Morse // subsequent sets. 2361*ae6f7882SJeremy Morse SmallVector<LocIdx, 4> base = Locs[0]; 2362*ae6f7882SJeremy Morse for (auto &S : SearchRange) { 2363*ae6f7882SJeremy Morse SmallVector<LocIdx, 4> new_base; 2364*ae6f7882SJeremy Morse std::set_intersection(base.begin(), base.end(), S.begin(), S.end(), 2365*ae6f7882SJeremy Morse std::inserter(new_base, new_base.begin())); 2366*ae6f7882SJeremy Morse base = new_base; 2367*ae6f7882SJeremy Morse } 2368*ae6f7882SJeremy Morse if (base.empty()) 2369*ae6f7882SJeremy Morse return None; 2370*ae6f7882SJeremy Morse 2371*ae6f7882SJeremy Morse // We now have a set of LocIdxes that contain the right output value in 2372*ae6f7882SJeremy Morse // each of the predecessors. Pick the lowest; if there's a register loc, 2373*ae6f7882SJeremy Morse // that'll be it. 2374*ae6f7882SJeremy Morse return *base.begin(); 2375*ae6f7882SJeremy Morse }; 2376*ae6f7882SJeremy Morse 2377*ae6f7882SJeremy Morse // Search for a common location for all predecessors. If we can't, then fall 2378*ae6f7882SJeremy Morse // back to only finding a common location between non-backedge predecessors. 2379*ae6f7882SJeremy Morse bool ValidForAllLocs = true; 2380*ae6f7882SJeremy Morse auto TheLoc = SeekLocation(Locs); 2381*ae6f7882SJeremy Morse if (!TheLoc) { 2382*ae6f7882SJeremy Morse ValidForAllLocs = false; 2383*ae6f7882SJeremy Morse TheLoc = 2384*ae6f7882SJeremy Morse SeekLocation(make_range(Locs.begin(), Locs.begin() + BackEdgesStart)); 2385*ae6f7882SJeremy Morse } 2386*ae6f7882SJeremy Morse 2387*ae6f7882SJeremy Morse if (!TheLoc) 2388*ae6f7882SJeremy Morse return {None, false}; 2389*ae6f7882SJeremy Morse 2390*ae6f7882SJeremy Morse // Return a PHI-value-number for the found location. 2391*ae6f7882SJeremy Morse LocIdx L = *TheLoc; 2392*ae6f7882SJeremy Morse ValueIDNum PHIVal = {(unsigned)MBB.getNumber(), 0, L}; 2393*ae6f7882SJeremy Morse return {PHIVal, ValidForAllLocs}; 2394*ae6f7882SJeremy Morse } 2395*ae6f7882SJeremy Morse 2396*ae6f7882SJeremy Morse std::tuple<bool, bool> InstrRefBasedLDV::vlocJoin( 2397*ae6f7882SJeremy Morse MachineBasicBlock &MBB, LiveIdxT &VLOCOutLocs, LiveIdxT &VLOCInLocs, 2398*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 16> *VLOCVisited, unsigned BBNum, 2399*ae6f7882SJeremy Morse const SmallSet<DebugVariable, 4> &AllVars, ValueIDNum **MOutLocs, 2400*ae6f7882SJeremy Morse ValueIDNum **MInLocs, 2401*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 8> &InScopeBlocks, 2402*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 8> &BlocksToExplore, 2403*ae6f7882SJeremy Morse DenseMap<DebugVariable, DbgValue> &InLocsT) { 2404*ae6f7882SJeremy Morse bool DowngradeOccurred = false; 2405*ae6f7882SJeremy Morse 2406*ae6f7882SJeremy Morse // To emulate VarLocBasedImpl, process this block if it's not in scope but 2407*ae6f7882SJeremy Morse // _does_ assign a variable value. No live-ins for this scope are transferred 2408*ae6f7882SJeremy Morse // in though, so we can return immediately. 2409*ae6f7882SJeremy Morse if (InScopeBlocks.count(&MBB) == 0 && !ArtificialBlocks.count(&MBB)) { 2410*ae6f7882SJeremy Morse if (VLOCVisited) 2411*ae6f7882SJeremy Morse return std::tuple<bool, bool>(true, false); 2412*ae6f7882SJeremy Morse return std::tuple<bool, bool>(false, false); 2413*ae6f7882SJeremy Morse } 2414*ae6f7882SJeremy Morse 2415*ae6f7882SJeremy Morse LLVM_DEBUG(dbgs() << "join MBB: " << MBB.getNumber() << "\n"); 2416*ae6f7882SJeremy Morse bool Changed = false; 2417*ae6f7882SJeremy Morse 2418*ae6f7882SJeremy Morse // Find any live-ins computed in a prior iteration. 2419*ae6f7882SJeremy Morse auto ILSIt = VLOCInLocs.find(&MBB); 2420*ae6f7882SJeremy Morse assert(ILSIt != VLOCInLocs.end()); 2421*ae6f7882SJeremy Morse auto &ILS = *ILSIt->second; 2422*ae6f7882SJeremy Morse 2423*ae6f7882SJeremy Morse // Order predecessors by RPOT order, for exploring them in that order. 2424*ae6f7882SJeremy Morse SmallVector<MachineBasicBlock *, 8> BlockOrders; 2425*ae6f7882SJeremy Morse for (auto p : MBB.predecessors()) 2426*ae6f7882SJeremy Morse BlockOrders.push_back(p); 2427*ae6f7882SJeremy Morse 2428*ae6f7882SJeremy Morse auto Cmp = [&](MachineBasicBlock *A, MachineBasicBlock *B) { 2429*ae6f7882SJeremy Morse return BBToOrder[A] < BBToOrder[B]; 2430*ae6f7882SJeremy Morse }; 2431*ae6f7882SJeremy Morse 2432*ae6f7882SJeremy Morse llvm::sort(BlockOrders.begin(), BlockOrders.end(), Cmp); 2433*ae6f7882SJeremy Morse 2434*ae6f7882SJeremy Morse unsigned CurBlockRPONum = BBToOrder[&MBB]; 2435*ae6f7882SJeremy Morse 2436*ae6f7882SJeremy Morse // Force a re-visit to loop heads in the first dataflow iteration. 2437*ae6f7882SJeremy Morse // FIXME: if we could "propose" Const values this wouldn't be needed, 2438*ae6f7882SJeremy Morse // because they'd need to be confirmed before being emitted. 2439*ae6f7882SJeremy Morse if (!BlockOrders.empty() && 2440*ae6f7882SJeremy Morse BBToOrder[BlockOrders[BlockOrders.size() - 1]] >= CurBlockRPONum && 2441*ae6f7882SJeremy Morse VLOCVisited) 2442*ae6f7882SJeremy Morse DowngradeOccurred = true; 2443*ae6f7882SJeremy Morse 2444*ae6f7882SJeremy Morse auto ConfirmValue = [&InLocsT](const DebugVariable &DV, DbgValue VR) { 2445*ae6f7882SJeremy Morse auto Result = InLocsT.insert(std::make_pair(DV, VR)); 2446*ae6f7882SJeremy Morse (void)Result; 2447*ae6f7882SJeremy Morse assert(Result.second); 2448*ae6f7882SJeremy Morse }; 2449*ae6f7882SJeremy Morse 2450*ae6f7882SJeremy Morse auto ConfirmNoVal = [&ConfirmValue, &MBB](const DebugVariable &Var, const DbgValueProperties &Properties) { 2451*ae6f7882SJeremy Morse DbgValue NoLocPHIVal(MBB.getNumber(), Properties, DbgValue::NoVal); 2452*ae6f7882SJeremy Morse 2453*ae6f7882SJeremy Morse ConfirmValue(Var, NoLocPHIVal); 2454*ae6f7882SJeremy Morse }; 2455*ae6f7882SJeremy Morse 2456*ae6f7882SJeremy Morse // Attempt to join the values for each variable. 2457*ae6f7882SJeremy Morse for (auto &Var : AllVars) { 2458*ae6f7882SJeremy Morse // Collect all the DbgValues for this variable. 2459*ae6f7882SJeremy Morse SmallVector<InValueT, 8> Values; 2460*ae6f7882SJeremy Morse bool Bail = false; 2461*ae6f7882SJeremy Morse unsigned BackEdgesStart = 0; 2462*ae6f7882SJeremy Morse for (auto p : BlockOrders) { 2463*ae6f7882SJeremy Morse // If the predecessor isn't in scope / to be explored, we'll never be 2464*ae6f7882SJeremy Morse // able to join any locations. 2465*ae6f7882SJeremy Morse if (BlocksToExplore.find(p) == BlocksToExplore.end()) { 2466*ae6f7882SJeremy Morse Bail = true; 2467*ae6f7882SJeremy Morse break; 2468*ae6f7882SJeremy Morse } 2469*ae6f7882SJeremy Morse 2470*ae6f7882SJeremy Morse // Don't attempt to handle unvisited predecessors: they're implicitly 2471*ae6f7882SJeremy Morse // "unknown"s in the lattice. 2472*ae6f7882SJeremy Morse if (VLOCVisited && !VLOCVisited->count(p)) 2473*ae6f7882SJeremy Morse continue; 2474*ae6f7882SJeremy Morse 2475*ae6f7882SJeremy Morse // If the predecessors OutLocs is absent, there's not much we can do. 2476*ae6f7882SJeremy Morse auto OL = VLOCOutLocs.find(p); 2477*ae6f7882SJeremy Morse if (OL == VLOCOutLocs.end()) { 2478*ae6f7882SJeremy Morse Bail = true; 2479*ae6f7882SJeremy Morse break; 2480*ae6f7882SJeremy Morse } 2481*ae6f7882SJeremy Morse 2482*ae6f7882SJeremy Morse // No live-out value for this predecessor also means we can't produce 2483*ae6f7882SJeremy Morse // a joined value. 2484*ae6f7882SJeremy Morse auto VIt = OL->second->find(Var); 2485*ae6f7882SJeremy Morse if (VIt == OL->second->end()) { 2486*ae6f7882SJeremy Morse Bail = true; 2487*ae6f7882SJeremy Morse break; 2488*ae6f7882SJeremy Morse } 2489*ae6f7882SJeremy Morse 2490*ae6f7882SJeremy Morse // Keep track of where back-edges begin in the Values vector. Relies on 2491*ae6f7882SJeremy Morse // BlockOrders being sorted by RPO. 2492*ae6f7882SJeremy Morse unsigned ThisBBRPONum = BBToOrder[p]; 2493*ae6f7882SJeremy Morse if (ThisBBRPONum < CurBlockRPONum) 2494*ae6f7882SJeremy Morse ++BackEdgesStart; 2495*ae6f7882SJeremy Morse 2496*ae6f7882SJeremy Morse Values.push_back(std::make_pair(p, &VIt->second)); 2497*ae6f7882SJeremy Morse } 2498*ae6f7882SJeremy Morse 2499*ae6f7882SJeremy Morse // If there were no values, or one of the predecessors couldn't have a 2500*ae6f7882SJeremy Morse // value, then give up immediately. It's not safe to produce a live-in 2501*ae6f7882SJeremy Morse // value. 2502*ae6f7882SJeremy Morse if (Bail || Values.size() == 0) 2503*ae6f7882SJeremy Morse continue; 2504*ae6f7882SJeremy Morse 2505*ae6f7882SJeremy Morse // Enumeration identifying the current state of the predecessors values. 2506*ae6f7882SJeremy Morse enum { 2507*ae6f7882SJeremy Morse Unset = 0, 2508*ae6f7882SJeremy Morse Agreed, // All preds agree on the variable value. 2509*ae6f7882SJeremy Morse PropDisagree, // All preds agree, but the value kind is Proposed in some. 2510*ae6f7882SJeremy Morse BEDisagree, // Only back-edges disagree on variable value. 2511*ae6f7882SJeremy Morse PHINeeded, // Non-back-edge predecessors have conflicing values. 2512*ae6f7882SJeremy Morse NoSolution // Conflicting Value metadata makes solution impossible. 2513*ae6f7882SJeremy Morse } OurState = Unset; 2514*ae6f7882SJeremy Morse 2515*ae6f7882SJeremy Morse // All (non-entry) blocks have at least one non-backedge predecessor. 2516*ae6f7882SJeremy Morse // Pick the variable value from the first of these, to compare against 2517*ae6f7882SJeremy Morse // all others. 2518*ae6f7882SJeremy Morse const DbgValue &FirstVal = *Values[0].second; 2519*ae6f7882SJeremy Morse const ValueIDNum &FirstID = FirstVal.ID; 2520*ae6f7882SJeremy Morse 2521*ae6f7882SJeremy Morse // Scan for variable values that can't be resolved: if they have different 2522*ae6f7882SJeremy Morse // DIExpressions, different indirectness, or are mixed constants / 2523*ae6f7882SJeremy Morse // non-constants. 2524*ae6f7882SJeremy Morse for (auto &V : Values) { 2525*ae6f7882SJeremy Morse if (V.second->Properties != FirstVal.Properties) 2526*ae6f7882SJeremy Morse OurState = NoSolution; 2527*ae6f7882SJeremy Morse if (V.second->Kind == DbgValue::Const && FirstVal.Kind != DbgValue::Const) 2528*ae6f7882SJeremy Morse OurState = NoSolution; 2529*ae6f7882SJeremy Morse } 2530*ae6f7882SJeremy Morse 2531*ae6f7882SJeremy Morse // Flags diagnosing _how_ the values disagree. 2532*ae6f7882SJeremy Morse bool NonBackEdgeDisagree = false; 2533*ae6f7882SJeremy Morse bool DisagreeOnPHINess = false; 2534*ae6f7882SJeremy Morse bool IDDisagree = false; 2535*ae6f7882SJeremy Morse bool Disagree = false; 2536*ae6f7882SJeremy Morse if (OurState == Unset) { 2537*ae6f7882SJeremy Morse for (auto &V : Values) { 2538*ae6f7882SJeremy Morse if (*V.second == FirstVal) 2539*ae6f7882SJeremy Morse continue; // No disagreement. 2540*ae6f7882SJeremy Morse 2541*ae6f7882SJeremy Morse Disagree = true; 2542*ae6f7882SJeremy Morse 2543*ae6f7882SJeremy Morse // Flag whether the value number actually diagrees. 2544*ae6f7882SJeremy Morse if (V.second->ID != FirstID) 2545*ae6f7882SJeremy Morse IDDisagree = true; 2546*ae6f7882SJeremy Morse 2547*ae6f7882SJeremy Morse // Distinguish whether disagreement happens in backedges or not. 2548*ae6f7882SJeremy Morse // Relies on Values (and BlockOrders) being sorted by RPO. 2549*ae6f7882SJeremy Morse unsigned ThisBBRPONum = BBToOrder[V.first]; 2550*ae6f7882SJeremy Morse if (ThisBBRPONum < CurBlockRPONum) 2551*ae6f7882SJeremy Morse NonBackEdgeDisagree = true; 2552*ae6f7882SJeremy Morse 2553*ae6f7882SJeremy Morse // Is there a difference in whether the value is definite or only 2554*ae6f7882SJeremy Morse // proposed? 2555*ae6f7882SJeremy Morse if (V.second->Kind != FirstVal.Kind && 2556*ae6f7882SJeremy Morse (V.second->Kind == DbgValue::Proposed || 2557*ae6f7882SJeremy Morse V.second->Kind == DbgValue::Def) && 2558*ae6f7882SJeremy Morse (FirstVal.Kind == DbgValue::Proposed || 2559*ae6f7882SJeremy Morse FirstVal.Kind == DbgValue::Def)) 2560*ae6f7882SJeremy Morse DisagreeOnPHINess = true; 2561*ae6f7882SJeremy Morse } 2562*ae6f7882SJeremy Morse 2563*ae6f7882SJeremy Morse // Collect those flags together and determine an overall state for 2564*ae6f7882SJeremy Morse // what extend the predecessors agree on a live-in value. 2565*ae6f7882SJeremy Morse if (!Disagree) 2566*ae6f7882SJeremy Morse OurState = Agreed; 2567*ae6f7882SJeremy Morse else if (!IDDisagree && DisagreeOnPHINess) 2568*ae6f7882SJeremy Morse OurState = PropDisagree; 2569*ae6f7882SJeremy Morse else if (!NonBackEdgeDisagree) 2570*ae6f7882SJeremy Morse OurState = BEDisagree; 2571*ae6f7882SJeremy Morse else 2572*ae6f7882SJeremy Morse OurState = PHINeeded; 2573*ae6f7882SJeremy Morse } 2574*ae6f7882SJeremy Morse 2575*ae6f7882SJeremy Morse // An extra indicator: if we only disagree on whether the value is a 2576*ae6f7882SJeremy Morse // Def, or proposed, then also flag whether that disagreement happens 2577*ae6f7882SJeremy Morse // in backedges only. 2578*ae6f7882SJeremy Morse bool PropOnlyInBEs = Disagree && !IDDisagree && DisagreeOnPHINess && 2579*ae6f7882SJeremy Morse !NonBackEdgeDisagree && FirstVal.Kind == DbgValue::Def; 2580*ae6f7882SJeremy Morse 2581*ae6f7882SJeremy Morse const auto &Properties = FirstVal.Properties; 2582*ae6f7882SJeremy Morse 2583*ae6f7882SJeremy Morse auto OldLiveInIt = ILS.find(Var); 2584*ae6f7882SJeremy Morse const DbgValue *OldLiveInLocation = 2585*ae6f7882SJeremy Morse (OldLiveInIt != ILS.end()) ? &OldLiveInIt->second : nullptr; 2586*ae6f7882SJeremy Morse 2587*ae6f7882SJeremy Morse bool OverRide = false; 2588*ae6f7882SJeremy Morse if (OurState == BEDisagree && OldLiveInLocation) { 2589*ae6f7882SJeremy Morse // Only backedges disagree: we can consider downgrading. If there was a 2590*ae6f7882SJeremy Morse // previous live-in value, use it to work out whether the current 2591*ae6f7882SJeremy Morse // incoming value represents a lattice downgrade or not. 2592*ae6f7882SJeremy Morse OverRide = 2593*ae6f7882SJeremy Morse vlocDowngradeLattice(MBB, *OldLiveInLocation, Values, CurBlockRPONum); 2594*ae6f7882SJeremy Morse } 2595*ae6f7882SJeremy Morse 2596*ae6f7882SJeremy Morse // Use the current state of predecessor agreement and other flags to work 2597*ae6f7882SJeremy Morse // out what to do next. Possibilities include: 2598*ae6f7882SJeremy Morse // * Accept a value all predecessors agree on, or accept one that 2599*ae6f7882SJeremy Morse // represents a step down the exploration lattice, 2600*ae6f7882SJeremy Morse // * Use a PHI value number, if one can be found, 2601*ae6f7882SJeremy Morse // * Propose a PHI value number, and see if it gets confirmed later, 2602*ae6f7882SJeremy Morse // * Emit a 'NoVal' value, indicating we couldn't resolve anything. 2603*ae6f7882SJeremy Morse if (OurState == Agreed) { 2604*ae6f7882SJeremy Morse // Easiest solution: all predecessors agree on the variable value. 2605*ae6f7882SJeremy Morse ConfirmValue(Var, FirstVal); 2606*ae6f7882SJeremy Morse } else if (OurState == BEDisagree && OverRide) { 2607*ae6f7882SJeremy Morse // Only backedges disagree, and the other predecessors have produced 2608*ae6f7882SJeremy Morse // a new live-in value further down the exploration lattice. 2609*ae6f7882SJeremy Morse DowngradeOccurred = true; 2610*ae6f7882SJeremy Morse ConfirmValue(Var, FirstVal); 2611*ae6f7882SJeremy Morse } else if (OurState == PropDisagree) { 2612*ae6f7882SJeremy Morse // Predecessors agree on value, but some say it's only a proposed value. 2613*ae6f7882SJeremy Morse // Propagate it as proposed: unless it was proposed in this block, in 2614*ae6f7882SJeremy Morse // which case we're able to confirm the value. 2615*ae6f7882SJeremy Morse if (FirstID.getBlock() == (uint64_t)MBB.getNumber() && FirstID.isPHI()) { 2616*ae6f7882SJeremy Morse ConfirmValue(Var, DbgValue(FirstID, Properties, DbgValue::Def)); 2617*ae6f7882SJeremy Morse } else if (PropOnlyInBEs) { 2618*ae6f7882SJeremy Morse // If only backedges disagree, a higher (in RPO) block confirmed this 2619*ae6f7882SJeremy Morse // location, and we need to propagate it into this loop. 2620*ae6f7882SJeremy Morse ConfirmValue(Var, DbgValue(FirstID, Properties, DbgValue::Def)); 2621*ae6f7882SJeremy Morse } else { 2622*ae6f7882SJeremy Morse // Otherwise; a Def meeting a Proposed is still a Proposed. 2623*ae6f7882SJeremy Morse ConfirmValue(Var, DbgValue(FirstID, Properties, DbgValue::Proposed)); 2624*ae6f7882SJeremy Morse } 2625*ae6f7882SJeremy Morse } else if ((OurState == PHINeeded || OurState == BEDisagree)) { 2626*ae6f7882SJeremy Morse // Predecessors disagree and can't be downgraded: this can only be 2627*ae6f7882SJeremy Morse // solved with a PHI. Use pickVPHILoc to go look for one. 2628*ae6f7882SJeremy Morse Optional<ValueIDNum> VPHI; 2629*ae6f7882SJeremy Morse bool AllEdgesVPHI = false; 2630*ae6f7882SJeremy Morse std::tie(VPHI, AllEdgesVPHI) = 2631*ae6f7882SJeremy Morse pickVPHILoc(MBB, Var, VLOCOutLocs, MOutLocs, MInLocs, BlockOrders); 2632*ae6f7882SJeremy Morse 2633*ae6f7882SJeremy Morse if (VPHI && AllEdgesVPHI) { 2634*ae6f7882SJeremy Morse // There's a PHI value that's valid for all predecessors -- we can use 2635*ae6f7882SJeremy Morse // it. If any of the non-backedge predecessors have proposed values 2636*ae6f7882SJeremy Morse // though, this PHI is also only proposed, until the predecessors are 2637*ae6f7882SJeremy Morse // confirmed. 2638*ae6f7882SJeremy Morse DbgValue::KindT K = DbgValue::Def; 2639*ae6f7882SJeremy Morse for (unsigned int I = 0; I < BackEdgesStart; ++I) 2640*ae6f7882SJeremy Morse if (Values[I].second->Kind == DbgValue::Proposed) 2641*ae6f7882SJeremy Morse K = DbgValue::Proposed; 2642*ae6f7882SJeremy Morse 2643*ae6f7882SJeremy Morse ConfirmValue(Var, DbgValue(*VPHI, Properties, K)); 2644*ae6f7882SJeremy Morse } else if (VPHI) { 2645*ae6f7882SJeremy Morse // There's a PHI value, but it's only legal for backedges. Leave this 2646*ae6f7882SJeremy Morse // as a proposed PHI value: it might come back on the backedges, 2647*ae6f7882SJeremy Morse // and allow us to confirm it in the future. 2648*ae6f7882SJeremy Morse DbgValue NoBEValue = DbgValue(*VPHI, Properties, DbgValue::Proposed); 2649*ae6f7882SJeremy Morse ConfirmValue(Var, NoBEValue); 2650*ae6f7882SJeremy Morse } else { 2651*ae6f7882SJeremy Morse ConfirmNoVal(Var, Properties); 2652*ae6f7882SJeremy Morse } 2653*ae6f7882SJeremy Morse } else { 2654*ae6f7882SJeremy Morse // Otherwise: we don't know. Emit a "phi but no real loc" phi. 2655*ae6f7882SJeremy Morse ConfirmNoVal(Var, Properties); 2656*ae6f7882SJeremy Morse } 2657*ae6f7882SJeremy Morse } 2658*ae6f7882SJeremy Morse 2659*ae6f7882SJeremy Morse // Store newly calculated in-locs into VLOCInLocs, if they've changed. 2660*ae6f7882SJeremy Morse Changed = ILS != InLocsT; 2661*ae6f7882SJeremy Morse if (Changed) 2662*ae6f7882SJeremy Morse ILS = InLocsT; 2663*ae6f7882SJeremy Morse 2664*ae6f7882SJeremy Morse return std::tuple<bool, bool>(Changed, DowngradeOccurred); 2665*ae6f7882SJeremy Morse } 2666*ae6f7882SJeremy Morse 2667*ae6f7882SJeremy Morse void InstrRefBasedLDV::vlocDataflow( 2668*ae6f7882SJeremy Morse const LexicalScope *Scope, const DILocation *DILoc, 2669*ae6f7882SJeremy Morse const SmallSet<DebugVariable, 4> &VarsWeCareAbout, 2670*ae6f7882SJeremy Morse SmallPtrSetImpl<MachineBasicBlock *> &AssignBlocks, LiveInsT &Output, 2671*ae6f7882SJeremy Morse ValueIDNum **MOutLocs, ValueIDNum **MInLocs, 2672*ae6f7882SJeremy Morse SmallVectorImpl<VLocTracker> &AllTheVLocs) { 2673*ae6f7882SJeremy Morse // This method is much like mlocDataflow: but focuses on a single 2674*ae6f7882SJeremy Morse // LexicalScope at a time. Pick out a set of blocks and variables that are 2675*ae6f7882SJeremy Morse // to have their value assignments solved, then run our dataflow algorithm 2676*ae6f7882SJeremy Morse // until a fixedpoint is reached. 2677*ae6f7882SJeremy Morse std::priority_queue<unsigned int, std::vector<unsigned int>, 2678*ae6f7882SJeremy Morse std::greater<unsigned int>> 2679*ae6f7882SJeremy Morse Worklist, Pending; 2680*ae6f7882SJeremy Morse SmallPtrSet<MachineBasicBlock *, 16> OnWorklist, OnPending; 2681*ae6f7882SJeremy Morse 2682*ae6f7882SJeremy Morse // The set of blocks we'll be examining. 2683*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 8> BlocksToExplore; 2684*ae6f7882SJeremy Morse 2685*ae6f7882SJeremy Morse // The order in which to examine them (RPO). 2686*ae6f7882SJeremy Morse SmallVector<MachineBasicBlock *, 8> BlockOrders; 2687*ae6f7882SJeremy Morse 2688*ae6f7882SJeremy Morse // RPO ordering function. 2689*ae6f7882SJeremy Morse auto Cmp = [&](MachineBasicBlock *A, MachineBasicBlock *B) { 2690*ae6f7882SJeremy Morse return BBToOrder[A] < BBToOrder[B]; 2691*ae6f7882SJeremy Morse }; 2692*ae6f7882SJeremy Morse 2693*ae6f7882SJeremy Morse LS.getMachineBasicBlocks(DILoc, BlocksToExplore); 2694*ae6f7882SJeremy Morse 2695*ae6f7882SJeremy Morse // A separate container to distinguish "blocks we're exploring" versus 2696*ae6f7882SJeremy Morse // "blocks that are potentially in scope. See comment at start of vlocJoin. 2697*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 8> InScopeBlocks = BlocksToExplore; 2698*ae6f7882SJeremy Morse 2699*ae6f7882SJeremy Morse // Old LiveDebugValues tracks variable locations that come out of blocks 2700*ae6f7882SJeremy Morse // not in scope, where DBG_VALUEs occur. This is something we could 2701*ae6f7882SJeremy Morse // legitimately ignore, but lets allow it for now. 2702*ae6f7882SJeremy Morse if (EmulateOldLDV) 2703*ae6f7882SJeremy Morse BlocksToExplore.insert(AssignBlocks.begin(), AssignBlocks.end()); 2704*ae6f7882SJeremy Morse 2705*ae6f7882SJeremy Morse // We also need to propagate variable values through any artificial blocks 2706*ae6f7882SJeremy Morse // that immediately follow blocks in scope. 2707*ae6f7882SJeremy Morse DenseSet<const MachineBasicBlock *> ToAdd; 2708*ae6f7882SJeremy Morse 2709*ae6f7882SJeremy Morse // Helper lambda: For a given block in scope, perform a depth first search 2710*ae6f7882SJeremy Morse // of all the artificial successors, adding them to the ToAdd collection. 2711*ae6f7882SJeremy Morse auto AccumulateArtificialBlocks = 2712*ae6f7882SJeremy Morse [this, &ToAdd, &BlocksToExplore, 2713*ae6f7882SJeremy Morse &InScopeBlocks](const MachineBasicBlock *MBB) { 2714*ae6f7882SJeremy Morse // Depth-first-search state: each node is a block and which successor 2715*ae6f7882SJeremy Morse // we're currently exploring. 2716*ae6f7882SJeremy Morse SmallVector<std::pair<const MachineBasicBlock *, 2717*ae6f7882SJeremy Morse MachineBasicBlock::const_succ_iterator>, 2718*ae6f7882SJeremy Morse 8> 2719*ae6f7882SJeremy Morse DFS; 2720*ae6f7882SJeremy Morse 2721*ae6f7882SJeremy Morse // Find any artificial successors not already tracked. 2722*ae6f7882SJeremy Morse for (auto *succ : MBB->successors()) { 2723*ae6f7882SJeremy Morse if (BlocksToExplore.count(succ) || InScopeBlocks.count(succ)) 2724*ae6f7882SJeremy Morse continue; 2725*ae6f7882SJeremy Morse if (!ArtificialBlocks.count(succ)) 2726*ae6f7882SJeremy Morse continue; 2727*ae6f7882SJeremy Morse DFS.push_back(std::make_pair(succ, succ->succ_begin())); 2728*ae6f7882SJeremy Morse ToAdd.insert(succ); 2729*ae6f7882SJeremy Morse } 2730*ae6f7882SJeremy Morse 2731*ae6f7882SJeremy Morse // Search all those blocks, depth first. 2732*ae6f7882SJeremy Morse while (!DFS.empty()) { 2733*ae6f7882SJeremy Morse const MachineBasicBlock *CurBB = DFS.back().first; 2734*ae6f7882SJeremy Morse MachineBasicBlock::const_succ_iterator &CurSucc = DFS.back().second; 2735*ae6f7882SJeremy Morse // Walk back if we've explored this blocks successors to the end. 2736*ae6f7882SJeremy Morse if (CurSucc == CurBB->succ_end()) { 2737*ae6f7882SJeremy Morse DFS.pop_back(); 2738*ae6f7882SJeremy Morse continue; 2739*ae6f7882SJeremy Morse } 2740*ae6f7882SJeremy Morse 2741*ae6f7882SJeremy Morse // If the current successor is artificial and unexplored, descend into 2742*ae6f7882SJeremy Morse // it. 2743*ae6f7882SJeremy Morse if (!ToAdd.count(*CurSucc) && ArtificialBlocks.count(*CurSucc)) { 2744*ae6f7882SJeremy Morse DFS.push_back(std::make_pair(*CurSucc, (*CurSucc)->succ_begin())); 2745*ae6f7882SJeremy Morse ToAdd.insert(*CurSucc); 2746*ae6f7882SJeremy Morse continue; 2747*ae6f7882SJeremy Morse } 2748*ae6f7882SJeremy Morse 2749*ae6f7882SJeremy Morse ++CurSucc; 2750*ae6f7882SJeremy Morse } 2751*ae6f7882SJeremy Morse }; 2752*ae6f7882SJeremy Morse 2753*ae6f7882SJeremy Morse // Search in-scope blocks and those containing a DBG_VALUE from this scope 2754*ae6f7882SJeremy Morse // for artificial successors. 2755*ae6f7882SJeremy Morse for (auto *MBB : BlocksToExplore) 2756*ae6f7882SJeremy Morse AccumulateArtificialBlocks(MBB); 2757*ae6f7882SJeremy Morse for (auto *MBB : InScopeBlocks) 2758*ae6f7882SJeremy Morse AccumulateArtificialBlocks(MBB); 2759*ae6f7882SJeremy Morse 2760*ae6f7882SJeremy Morse BlocksToExplore.insert(ToAdd.begin(), ToAdd.end()); 2761*ae6f7882SJeremy Morse InScopeBlocks.insert(ToAdd.begin(), ToAdd.end()); 2762*ae6f7882SJeremy Morse 2763*ae6f7882SJeremy Morse // Single block scope: not interesting! No propagation at all. Note that 2764*ae6f7882SJeremy Morse // this could probably go above ArtificialBlocks without damage, but 2765*ae6f7882SJeremy Morse // that then produces output differences from original-live-debug-values, 2766*ae6f7882SJeremy Morse // which propagates from a single block into many artificial ones. 2767*ae6f7882SJeremy Morse if (BlocksToExplore.size() == 1) 2768*ae6f7882SJeremy Morse return; 2769*ae6f7882SJeremy Morse 2770*ae6f7882SJeremy Morse // Picks out relevants blocks RPO order and sort them. 2771*ae6f7882SJeremy Morse for (auto *MBB : BlocksToExplore) 2772*ae6f7882SJeremy Morse BlockOrders.push_back(const_cast<MachineBasicBlock *>(MBB)); 2773*ae6f7882SJeremy Morse 2774*ae6f7882SJeremy Morse llvm::sort(BlockOrders.begin(), BlockOrders.end(), Cmp); 2775*ae6f7882SJeremy Morse unsigned NumBlocks = BlockOrders.size(); 2776*ae6f7882SJeremy Morse 2777*ae6f7882SJeremy Morse // Allocate some vectors for storing the live ins and live outs. Large. 2778*ae6f7882SJeremy Morse SmallVector<DenseMap<DebugVariable, DbgValue>, 32> LiveIns, LiveOuts; 2779*ae6f7882SJeremy Morse LiveIns.resize(NumBlocks); 2780*ae6f7882SJeremy Morse LiveOuts.resize(NumBlocks); 2781*ae6f7882SJeremy Morse 2782*ae6f7882SJeremy Morse // Produce by-MBB indexes of live-in/live-outs, to ease lookup within 2783*ae6f7882SJeremy Morse // vlocJoin. 2784*ae6f7882SJeremy Morse LiveIdxT LiveOutIdx, LiveInIdx; 2785*ae6f7882SJeremy Morse LiveOutIdx.reserve(NumBlocks); 2786*ae6f7882SJeremy Morse LiveInIdx.reserve(NumBlocks); 2787*ae6f7882SJeremy Morse for (unsigned I = 0; I < NumBlocks; ++I) { 2788*ae6f7882SJeremy Morse LiveOutIdx[BlockOrders[I]] = &LiveOuts[I]; 2789*ae6f7882SJeremy Morse LiveInIdx[BlockOrders[I]] = &LiveIns[I]; 2790*ae6f7882SJeremy Morse } 2791*ae6f7882SJeremy Morse 2792*ae6f7882SJeremy Morse for (auto *MBB : BlockOrders) { 2793*ae6f7882SJeremy Morse Worklist.push(BBToOrder[MBB]); 2794*ae6f7882SJeremy Morse OnWorklist.insert(MBB); 2795*ae6f7882SJeremy Morse } 2796*ae6f7882SJeremy Morse 2797*ae6f7882SJeremy Morse // Iterate over all the blocks we selected, propagating variable values. 2798*ae6f7882SJeremy Morse bool FirstTrip = true; 2799*ae6f7882SJeremy Morse SmallPtrSet<const MachineBasicBlock *, 16> VLOCVisited; 2800*ae6f7882SJeremy Morse while (!Worklist.empty() || !Pending.empty()) { 2801*ae6f7882SJeremy Morse while (!Worklist.empty()) { 2802*ae6f7882SJeremy Morse auto *MBB = OrderToBB[Worklist.top()]; 2803*ae6f7882SJeremy Morse CurBB = MBB->getNumber(); 2804*ae6f7882SJeremy Morse Worklist.pop(); 2805*ae6f7882SJeremy Morse 2806*ae6f7882SJeremy Morse DenseMap<DebugVariable, DbgValue> JoinedInLocs; 2807*ae6f7882SJeremy Morse 2808*ae6f7882SJeremy Morse // Join values from predecessors. Updates LiveInIdx, and writes output 2809*ae6f7882SJeremy Morse // into JoinedInLocs. 2810*ae6f7882SJeremy Morse bool InLocsChanged, DowngradeOccurred; 2811*ae6f7882SJeremy Morse std::tie(InLocsChanged, DowngradeOccurred) = vlocJoin( 2812*ae6f7882SJeremy Morse *MBB, LiveOutIdx, LiveInIdx, (FirstTrip) ? &VLOCVisited : nullptr, 2813*ae6f7882SJeremy Morse CurBB, VarsWeCareAbout, MOutLocs, MInLocs, InScopeBlocks, 2814*ae6f7882SJeremy Morse BlocksToExplore, JoinedInLocs); 2815*ae6f7882SJeremy Morse 2816*ae6f7882SJeremy Morse auto &VTracker = AllTheVLocs[MBB->getNumber()]; 2817*ae6f7882SJeremy Morse bool FirstVisit = VLOCVisited.insert(MBB).second; 2818*ae6f7882SJeremy Morse 2819*ae6f7882SJeremy Morse // Always explore transfer function if inlocs changed, or if we've not 2820*ae6f7882SJeremy Morse // visited this block before. 2821*ae6f7882SJeremy Morse InLocsChanged |= FirstVisit; 2822*ae6f7882SJeremy Morse 2823*ae6f7882SJeremy Morse // If a downgrade occurred, book us in for re-examination on the next 2824*ae6f7882SJeremy Morse // iteration. 2825*ae6f7882SJeremy Morse if (DowngradeOccurred && OnPending.insert(MBB).second) 2826*ae6f7882SJeremy Morse Pending.push(BBToOrder[MBB]); 2827*ae6f7882SJeremy Morse 2828*ae6f7882SJeremy Morse // Patch up the variable value transfer function to use the live-in 2829*ae6f7882SJeremy Morse // machine values, now that that problem is solved. 2830*ae6f7882SJeremy Morse if (FirstVisit) { 2831*ae6f7882SJeremy Morse for (auto &Transfer : VTracker.Vars) { 2832*ae6f7882SJeremy Morse if (Transfer.second.Kind == DbgValue::Def && 2833*ae6f7882SJeremy Morse Transfer.second.ID.getBlock() == CurBB && 2834*ae6f7882SJeremy Morse Transfer.second.ID.isPHI()) { 2835*ae6f7882SJeremy Morse LocIdx Loc = Transfer.second.ID.getLoc(); 2836*ae6f7882SJeremy Morse Transfer.second.ID = MInLocs[CurBB][Loc.asU64()]; 2837*ae6f7882SJeremy Morse } 2838*ae6f7882SJeremy Morse } 2839*ae6f7882SJeremy Morse } 2840*ae6f7882SJeremy Morse 2841*ae6f7882SJeremy Morse if (!InLocsChanged) 2842*ae6f7882SJeremy Morse continue; 2843*ae6f7882SJeremy Morse 2844*ae6f7882SJeremy Morse // Do transfer function. 2845*ae6f7882SJeremy Morse for (auto &Transfer : VTracker.Vars) { 2846*ae6f7882SJeremy Morse // Is this var we're mangling in this scope? 2847*ae6f7882SJeremy Morse if (VarsWeCareAbout.count(Transfer.first)) { 2848*ae6f7882SJeremy Morse // Erase on empty transfer (DBG_VALUE $noreg). 2849*ae6f7882SJeremy Morse if (Transfer.second.Kind == DbgValue::Undef) { 2850*ae6f7882SJeremy Morse JoinedInLocs.erase(Transfer.first); 2851*ae6f7882SJeremy Morse } else { 2852*ae6f7882SJeremy Morse // Insert new variable value; or overwrite. 2853*ae6f7882SJeremy Morse auto NewValuePair = std::make_pair(Transfer.first, Transfer.second); 2854*ae6f7882SJeremy Morse auto Result = JoinedInLocs.insert(NewValuePair); 2855*ae6f7882SJeremy Morse if (!Result.second) 2856*ae6f7882SJeremy Morse Result.first->second = Transfer.second; 2857*ae6f7882SJeremy Morse } 2858*ae6f7882SJeremy Morse } 2859*ae6f7882SJeremy Morse } 2860*ae6f7882SJeremy Morse 2861*ae6f7882SJeremy Morse // Did the live-out locations change? 2862*ae6f7882SJeremy Morse bool OLChanged = JoinedInLocs != *LiveOutIdx[MBB]; 2863*ae6f7882SJeremy Morse 2864*ae6f7882SJeremy Morse // If they haven't changed, there's no need to explore further. 2865*ae6f7882SJeremy Morse if (!OLChanged) 2866*ae6f7882SJeremy Morse continue; 2867*ae6f7882SJeremy Morse 2868*ae6f7882SJeremy Morse // Commit to the live-out record. 2869*ae6f7882SJeremy Morse *LiveOutIdx[MBB] = JoinedInLocs; 2870*ae6f7882SJeremy Morse 2871*ae6f7882SJeremy Morse // We should visit all successors. Ensure we'll visit any non-backedge 2872*ae6f7882SJeremy Morse // successors during this dataflow iteration; book backedge successors 2873*ae6f7882SJeremy Morse // to be visited next time around. 2874*ae6f7882SJeremy Morse for (auto s : MBB->successors()) { 2875*ae6f7882SJeremy Morse // Ignore out of scope / not-to-be-explored successors. 2876*ae6f7882SJeremy Morse if (LiveInIdx.find(s) == LiveInIdx.end()) 2877*ae6f7882SJeremy Morse continue; 2878*ae6f7882SJeremy Morse 2879*ae6f7882SJeremy Morse if (BBToOrder[s] > BBToOrder[MBB]) { 2880*ae6f7882SJeremy Morse if (OnWorklist.insert(s).second) 2881*ae6f7882SJeremy Morse Worklist.push(BBToOrder[s]); 2882*ae6f7882SJeremy Morse } else if (OnPending.insert(s).second && (FirstTrip || OLChanged)) { 2883*ae6f7882SJeremy Morse Pending.push(BBToOrder[s]); 2884*ae6f7882SJeremy Morse } 2885*ae6f7882SJeremy Morse } 2886*ae6f7882SJeremy Morse } 2887*ae6f7882SJeremy Morse Worklist.swap(Pending); 2888*ae6f7882SJeremy Morse std::swap(OnWorklist, OnPending); 2889*ae6f7882SJeremy Morse OnPending.clear(); 2890*ae6f7882SJeremy Morse assert(Pending.empty()); 2891*ae6f7882SJeremy Morse FirstTrip = false; 2892*ae6f7882SJeremy Morse } 2893*ae6f7882SJeremy Morse 2894*ae6f7882SJeremy Morse // Dataflow done. Now what? Save live-ins. Ignore any that are still marked 2895*ae6f7882SJeremy Morse // as being variable-PHIs, because those did not have their machine-PHI 2896*ae6f7882SJeremy Morse // value confirmed. Such variable values are places that could have been 2897*ae6f7882SJeremy Morse // PHIs, but are not. 2898*ae6f7882SJeremy Morse for (auto *MBB : BlockOrders) { 2899*ae6f7882SJeremy Morse auto &VarMap = *LiveInIdx[MBB]; 2900*ae6f7882SJeremy Morse for (auto &P : VarMap) { 2901*ae6f7882SJeremy Morse if (P.second.Kind == DbgValue::Proposed || 2902*ae6f7882SJeremy Morse P.second.Kind == DbgValue::NoVal) 2903*ae6f7882SJeremy Morse continue; 2904*ae6f7882SJeremy Morse Output[MBB->getNumber()].push_back(P); 2905*ae6f7882SJeremy Morse } 2906*ae6f7882SJeremy Morse } 2907*ae6f7882SJeremy Morse 2908*ae6f7882SJeremy Morse BlockOrders.clear(); 2909*ae6f7882SJeremy Morse BlocksToExplore.clear(); 2910*ae6f7882SJeremy Morse } 2911*ae6f7882SJeremy Morse 2912*ae6f7882SJeremy Morse void InstrRefBasedLDV::dump_mloc_transfer( 2913*ae6f7882SJeremy Morse const MLocTransferMap &mloc_transfer) const { 2914*ae6f7882SJeremy Morse for (auto &P : mloc_transfer) { 2915*ae6f7882SJeremy Morse std::string foo = MTracker->LocIdxToName(P.first); 2916*ae6f7882SJeremy Morse std::string bar = MTracker->IDAsString(P.second); 2917*ae6f7882SJeremy Morse dbgs() << "Loc " << foo << " --> " << bar << "\n"; 2918*ae6f7882SJeremy Morse } 2919*ae6f7882SJeremy Morse } 2920*ae6f7882SJeremy Morse 2921*ae6f7882SJeremy Morse void InstrRefBasedLDV::emitLocations( 2922*ae6f7882SJeremy Morse MachineFunction &MF, LiveInsT SavedLiveIns, ValueIDNum **MInLocs, 2923*ae6f7882SJeremy Morse DenseMap<DebugVariable, unsigned> &AllVarsNumbering) { 2924*ae6f7882SJeremy Morse TTracker = new TransferTracker(TII, MTracker, MF, *TRI, CalleeSavedRegs); 2925*ae6f7882SJeremy Morse unsigned NumLocs = MTracker->getNumLocs(); 2926*ae6f7882SJeremy Morse 2927*ae6f7882SJeremy Morse // For each block, load in the machine value locations and variable value 2928*ae6f7882SJeremy Morse // live-ins, then step through each instruction in the block. New DBG_VALUEs 2929*ae6f7882SJeremy Morse // to be inserted will be created along the way. 2930*ae6f7882SJeremy Morse for (MachineBasicBlock &MBB : MF) { 2931*ae6f7882SJeremy Morse unsigned bbnum = MBB.getNumber(); 2932*ae6f7882SJeremy Morse MTracker->reset(); 2933*ae6f7882SJeremy Morse MTracker->loadFromArray(MInLocs[bbnum], bbnum); 2934*ae6f7882SJeremy Morse TTracker->loadInlocs(MBB, MInLocs[bbnum], SavedLiveIns[MBB.getNumber()], 2935*ae6f7882SJeremy Morse NumLocs); 2936*ae6f7882SJeremy Morse 2937*ae6f7882SJeremy Morse CurBB = bbnum; 2938*ae6f7882SJeremy Morse CurInst = 1; 2939*ae6f7882SJeremy Morse for (auto &MI : MBB) { 2940*ae6f7882SJeremy Morse process(MI); 2941*ae6f7882SJeremy Morse ++CurInst; 2942*ae6f7882SJeremy Morse } 2943*ae6f7882SJeremy Morse } 2944*ae6f7882SJeremy Morse 2945*ae6f7882SJeremy Morse // We have to insert DBG_VALUEs in a consistent order, otherwise they appeaer 2946*ae6f7882SJeremy Morse // in DWARF in different orders. Use the order that they appear when walking 2947*ae6f7882SJeremy Morse // through each block / each instruction, stored in AllVarsNumbering. 2948*ae6f7882SJeremy Morse auto OrderDbgValues = [&](const MachineInstr *A, 2949*ae6f7882SJeremy Morse const MachineInstr *B) -> bool { 2950*ae6f7882SJeremy Morse DebugVariable VarA(A->getDebugVariable(), A->getDebugExpression(), 2951*ae6f7882SJeremy Morse A->getDebugLoc()->getInlinedAt()); 2952*ae6f7882SJeremy Morse DebugVariable VarB(B->getDebugVariable(), B->getDebugExpression(), 2953*ae6f7882SJeremy Morse B->getDebugLoc()->getInlinedAt()); 2954*ae6f7882SJeremy Morse return AllVarsNumbering.find(VarA)->second < 2955*ae6f7882SJeremy Morse AllVarsNumbering.find(VarB)->second; 2956*ae6f7882SJeremy Morse }; 2957*ae6f7882SJeremy Morse 2958*ae6f7882SJeremy Morse // Go through all the transfers recorded in the TransferTracker -- this is 2959*ae6f7882SJeremy Morse // both the live-ins to a block, and any movements of values that happen 2960*ae6f7882SJeremy Morse // in the middle. 2961*ae6f7882SJeremy Morse for (auto &P : TTracker->Transfers) { 2962*ae6f7882SJeremy Morse // Sort them according to appearance order. 2963*ae6f7882SJeremy Morse llvm::sort(P.Insts.begin(), P.Insts.end(), OrderDbgValues); 2964*ae6f7882SJeremy Morse // Insert either before or after the designated point... 2965*ae6f7882SJeremy Morse if (P.MBB) { 2966*ae6f7882SJeremy Morse MachineBasicBlock &MBB = *P.MBB; 2967*ae6f7882SJeremy Morse for (auto *MI : P.Insts) { 2968*ae6f7882SJeremy Morse MBB.insert(P.Pos, MI); 2969*ae6f7882SJeremy Morse } 2970*ae6f7882SJeremy Morse } else { 2971*ae6f7882SJeremy Morse MachineBasicBlock &MBB = *P.Pos->getParent(); 2972*ae6f7882SJeremy Morse for (auto *MI : P.Insts) { 2973*ae6f7882SJeremy Morse MBB.insertAfter(P.Pos, MI); 2974*ae6f7882SJeremy Morse } 2975*ae6f7882SJeremy Morse } 2976*ae6f7882SJeremy Morse } 2977*ae6f7882SJeremy Morse } 2978*ae6f7882SJeremy Morse 2979*ae6f7882SJeremy Morse void InstrRefBasedLDV::initialSetup(MachineFunction &MF) { 2980*ae6f7882SJeremy Morse // Build some useful data structures. 2981*ae6f7882SJeremy Morse auto hasNonArtificialLocation = [](const MachineInstr &MI) -> bool { 2982*ae6f7882SJeremy Morse if (const DebugLoc &DL = MI.getDebugLoc()) 2983*ae6f7882SJeremy Morse return DL.getLine() != 0; 2984*ae6f7882SJeremy Morse return false; 2985*ae6f7882SJeremy Morse }; 2986*ae6f7882SJeremy Morse // Collect a set of all the artificial blocks. 2987*ae6f7882SJeremy Morse for (auto &MBB : MF) 2988*ae6f7882SJeremy Morse if (none_of(MBB.instrs(), hasNonArtificialLocation)) 2989*ae6f7882SJeremy Morse ArtificialBlocks.insert(&MBB); 2990*ae6f7882SJeremy Morse 2991*ae6f7882SJeremy Morse // Compute mappings of block <=> RPO order. 2992*ae6f7882SJeremy Morse ReversePostOrderTraversal<MachineFunction *> RPOT(&MF); 2993*ae6f7882SJeremy Morse unsigned int RPONumber = 0; 2994*ae6f7882SJeremy Morse for (auto RI = RPOT.begin(), RE = RPOT.end(); RI != RE; ++RI) { 2995*ae6f7882SJeremy Morse OrderToBB[RPONumber] = *RI; 2996*ae6f7882SJeremy Morse BBToOrder[*RI] = RPONumber; 2997*ae6f7882SJeremy Morse BBNumToRPO[(*RI)->getNumber()] = RPONumber; 2998*ae6f7882SJeremy Morse ++RPONumber; 2999*ae6f7882SJeremy Morse } 3000*ae6f7882SJeremy Morse } 3001*ae6f7882SJeremy Morse 3002*ae6f7882SJeremy Morse /// Calculate the liveness information for the given machine function and 3003*ae6f7882SJeremy Morse /// extend ranges across basic blocks. 3004*ae6f7882SJeremy Morse bool InstrRefBasedLDV::ExtendRanges(MachineFunction &MF, 3005*ae6f7882SJeremy Morse TargetPassConfig *TPC) { 3006*ae6f7882SJeremy Morse // No subprogram means this function contains no debuginfo. 3007*ae6f7882SJeremy Morse if (!MF.getFunction().getSubprogram()) 3008*ae6f7882SJeremy Morse return false; 3009*ae6f7882SJeremy Morse 3010*ae6f7882SJeremy Morse LLVM_DEBUG(dbgs() << "\nDebug Range Extension\n"); 3011*ae6f7882SJeremy Morse this->TPC = TPC; 3012*ae6f7882SJeremy Morse 3013*ae6f7882SJeremy Morse TRI = MF.getSubtarget().getRegisterInfo(); 3014*ae6f7882SJeremy Morse TII = MF.getSubtarget().getInstrInfo(); 3015*ae6f7882SJeremy Morse TFI = MF.getSubtarget().getFrameLowering(); 3016*ae6f7882SJeremy Morse TFI->getCalleeSaves(MF, CalleeSavedRegs); 3017*ae6f7882SJeremy Morse LS.initialize(MF); 3018*ae6f7882SJeremy Morse 3019*ae6f7882SJeremy Morse MTracker = 3020*ae6f7882SJeremy Morse new MLocTracker(MF, *TII, *TRI, *MF.getSubtarget().getTargetLowering()); 3021*ae6f7882SJeremy Morse VTracker = nullptr; 3022*ae6f7882SJeremy Morse TTracker = nullptr; 3023*ae6f7882SJeremy Morse 3024*ae6f7882SJeremy Morse SmallVector<MLocTransferMap, 32> MLocTransfer; 3025*ae6f7882SJeremy Morse SmallVector<VLocTracker, 8> vlocs; 3026*ae6f7882SJeremy Morse LiveInsT SavedLiveIns; 3027*ae6f7882SJeremy Morse 3028*ae6f7882SJeremy Morse int MaxNumBlocks = -1; 3029*ae6f7882SJeremy Morse for (auto &MBB : MF) 3030*ae6f7882SJeremy Morse MaxNumBlocks = std::max(MBB.getNumber(), MaxNumBlocks); 3031*ae6f7882SJeremy Morse assert(MaxNumBlocks >= 0); 3032*ae6f7882SJeremy Morse ++MaxNumBlocks; 3033*ae6f7882SJeremy Morse 3034*ae6f7882SJeremy Morse MLocTransfer.resize(MaxNumBlocks); 3035*ae6f7882SJeremy Morse vlocs.resize(MaxNumBlocks); 3036*ae6f7882SJeremy Morse SavedLiveIns.resize(MaxNumBlocks); 3037*ae6f7882SJeremy Morse 3038*ae6f7882SJeremy Morse initialSetup(MF); 3039*ae6f7882SJeremy Morse 3040*ae6f7882SJeremy Morse produceTransferFunctions(MF, MLocTransfer, MaxNumBlocks, vlocs); 3041*ae6f7882SJeremy Morse 3042*ae6f7882SJeremy Morse // Allocate and initialize two array-of-arrays for the live-in and live-out 3043*ae6f7882SJeremy Morse // machine values. The outer dimension is the block number; while the inner 3044*ae6f7882SJeremy Morse // dimension is a LocIdx from MLocTracker. 3045*ae6f7882SJeremy Morse ValueIDNum **MOutLocs = new ValueIDNum *[MaxNumBlocks]; 3046*ae6f7882SJeremy Morse ValueIDNum **MInLocs = new ValueIDNum *[MaxNumBlocks]; 3047*ae6f7882SJeremy Morse unsigned NumLocs = MTracker->getNumLocs(); 3048*ae6f7882SJeremy Morse for (int i = 0; i < MaxNumBlocks; ++i) { 3049*ae6f7882SJeremy Morse MOutLocs[i] = new ValueIDNum[NumLocs]; 3050*ae6f7882SJeremy Morse MInLocs[i] = new ValueIDNum[NumLocs]; 3051*ae6f7882SJeremy Morse } 3052*ae6f7882SJeremy Morse 3053*ae6f7882SJeremy Morse // Solve the machine value dataflow problem using the MLocTransfer function, 3054*ae6f7882SJeremy Morse // storing the computed live-ins / live-outs into the array-of-arrays. We use 3055*ae6f7882SJeremy Morse // both live-ins and live-outs for decision making in the variable value 3056*ae6f7882SJeremy Morse // dataflow problem. 3057*ae6f7882SJeremy Morse mlocDataflow(MInLocs, MOutLocs, MLocTransfer); 3058*ae6f7882SJeremy Morse 3059*ae6f7882SJeremy Morse // Number all variables in the order that they appear, to be used as a stable 3060*ae6f7882SJeremy Morse // insertion order later. 3061*ae6f7882SJeremy Morse DenseMap<DebugVariable, unsigned> AllVarsNumbering; 3062*ae6f7882SJeremy Morse 3063*ae6f7882SJeremy Morse // Map from one LexicalScope to all the variables in that scope. 3064*ae6f7882SJeremy Morse DenseMap<const LexicalScope *, SmallSet<DebugVariable, 4>> ScopeToVars; 3065*ae6f7882SJeremy Morse 3066*ae6f7882SJeremy Morse // Map from One lexical scope to all blocks in that scope. 3067*ae6f7882SJeremy Morse DenseMap<const LexicalScope *, SmallPtrSet<MachineBasicBlock *, 4>> 3068*ae6f7882SJeremy Morse ScopeToBlocks; 3069*ae6f7882SJeremy Morse 3070*ae6f7882SJeremy Morse // Store a DILocation that describes a scope. 3071*ae6f7882SJeremy Morse DenseMap<const LexicalScope *, const DILocation *> ScopeToDILocation; 3072*ae6f7882SJeremy Morse 3073*ae6f7882SJeremy Morse // To mirror old LiveDebugValues, enumerate variables in RPOT order. Otherwise 3074*ae6f7882SJeremy Morse // the order is unimportant, it just has to be stable. 3075*ae6f7882SJeremy Morse for (unsigned int I = 0; I < OrderToBB.size(); ++I) { 3076*ae6f7882SJeremy Morse auto *MBB = OrderToBB[I]; 3077*ae6f7882SJeremy Morse auto *VTracker = &vlocs[MBB->getNumber()]; 3078*ae6f7882SJeremy Morse // Collect each variable with a DBG_VALUE in this block. 3079*ae6f7882SJeremy Morse for (auto &idx : VTracker->Vars) { 3080*ae6f7882SJeremy Morse const auto &Var = idx.first; 3081*ae6f7882SJeremy Morse const DILocation *ScopeLoc = VTracker->Scopes[Var]; 3082*ae6f7882SJeremy Morse assert(ScopeLoc != nullptr); 3083*ae6f7882SJeremy Morse auto *Scope = LS.findLexicalScope(ScopeLoc); 3084*ae6f7882SJeremy Morse 3085*ae6f7882SJeremy Morse // No insts in scope -> shouldn't have been recorded. 3086*ae6f7882SJeremy Morse assert(Scope != nullptr); 3087*ae6f7882SJeremy Morse 3088*ae6f7882SJeremy Morse AllVarsNumbering.insert(std::make_pair(Var, AllVarsNumbering.size())); 3089*ae6f7882SJeremy Morse ScopeToVars[Scope].insert(Var); 3090*ae6f7882SJeremy Morse ScopeToBlocks[Scope].insert(VTracker->MBB); 3091*ae6f7882SJeremy Morse ScopeToDILocation[Scope] = ScopeLoc; 3092*ae6f7882SJeremy Morse } 3093*ae6f7882SJeremy Morse } 3094*ae6f7882SJeremy Morse 3095*ae6f7882SJeremy Morse // OK. Iterate over scopes: there might be something to be said for 3096*ae6f7882SJeremy Morse // ordering them by size/locality, but that's for the future. For each scope, 3097*ae6f7882SJeremy Morse // solve the variable value problem, producing a map of variables to values 3098*ae6f7882SJeremy Morse // in SavedLiveIns. 3099*ae6f7882SJeremy Morse for (auto &P : ScopeToVars) { 3100*ae6f7882SJeremy Morse vlocDataflow(P.first, ScopeToDILocation[P.first], P.second, 3101*ae6f7882SJeremy Morse ScopeToBlocks[P.first], SavedLiveIns, MOutLocs, MInLocs, 3102*ae6f7882SJeremy Morse vlocs); 3103*ae6f7882SJeremy Morse } 3104*ae6f7882SJeremy Morse 3105*ae6f7882SJeremy Morse // Using the computed value locations and variable values for each block, 3106*ae6f7882SJeremy Morse // create the DBG_VALUE instructions representing the extended variable 3107*ae6f7882SJeremy Morse // locations. 3108*ae6f7882SJeremy Morse emitLocations(MF, SavedLiveIns, MInLocs, AllVarsNumbering); 3109*ae6f7882SJeremy Morse 3110*ae6f7882SJeremy Morse for (int Idx = 0; Idx < MaxNumBlocks; ++Idx) { 3111*ae6f7882SJeremy Morse delete[] MOutLocs[Idx]; 3112*ae6f7882SJeremy Morse delete[] MInLocs[Idx]; 3113*ae6f7882SJeremy Morse } 3114*ae6f7882SJeremy Morse delete[] MOutLocs; 3115*ae6f7882SJeremy Morse delete[] MInLocs; 3116*ae6f7882SJeremy Morse 3117*ae6f7882SJeremy Morse // Did we actually make any changes? If we created any DBG_VALUEs, then yes. 3118*ae6f7882SJeremy Morse bool Changed = TTracker->Transfers.size() != 0; 3119*ae6f7882SJeremy Morse 3120*ae6f7882SJeremy Morse delete MTracker; 3121*ae6f7882SJeremy Morse VTracker = nullptr; 3122*ae6f7882SJeremy Morse TTracker = nullptr; 3123*ae6f7882SJeremy Morse 3124*ae6f7882SJeremy Morse ArtificialBlocks.clear(); 3125*ae6f7882SJeremy Morse OrderToBB.clear(); 3126*ae6f7882SJeremy Morse BBToOrder.clear(); 3127*ae6f7882SJeremy Morse BBNumToRPO.clear(); 3128*ae6f7882SJeremy Morse 3129*ae6f7882SJeremy Morse return Changed; 3130*ae6f7882SJeremy Morse } 3131*ae6f7882SJeremy Morse 3132*ae6f7882SJeremy Morse LDVImpl *llvm::makeInstrRefBasedLiveDebugValues() { 3133*ae6f7882SJeremy Morse return new InstrRefBasedLDV(); 3134*ae6f7882SJeremy Morse } 3135