// Copyright 2011 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package ssagen import ( "fmt" "internal/buildcfg" "os" "sort" "sync" "cmd/compile/internal/base" "cmd/compile/internal/inline" "cmd/compile/internal/ir" "cmd/compile/internal/liveness" "cmd/compile/internal/objw" "cmd/compile/internal/pgoir" "cmd/compile/internal/ssa" "cmd/compile/internal/types" "cmd/internal/obj" "cmd/internal/objabi" "cmd/internal/src" ) // cmpstackvarlt reports whether the stack variable a sorts before b. func cmpstackvarlt(a, b *ir.Name, mls *liveness.MergeLocalsState) bool { // Sort non-autos before autos. if needAlloc(a) != needAlloc(b) { return needAlloc(b) } // If both are non-auto (e.g., parameters, results), then sort by // frame offset (defined by ABI). if !needAlloc(a) { return a.FrameOffset() < b.FrameOffset() } // From here on, a and b are both autos (i.e., local variables). // Sort followers after leaders, if mls != nil if mls != nil { aFollow := mls.Subsumed(a) bFollow := mls.Subsumed(b) if aFollow != bFollow { return bFollow } } // Sort used before unused (so AllocFrame can truncate unused // variables). if a.Used() != b.Used() { return a.Used() } // Sort pointer-typed before non-pointer types. // Keeps the stack's GC bitmap compact. ap := a.Type().HasPointers() bp := b.Type().HasPointers() if ap != bp { return ap } // Group variables that need zeroing, so we can efficiently zero // them altogether. ap = a.Needzero() bp = b.Needzero() if ap != bp { return ap } // Sort variables in descending alignment order, so we can optimally // pack variables into the frame. if a.Type().Alignment() != b.Type().Alignment() { return a.Type().Alignment() > b.Type().Alignment() } // Sort normal variables before open-coded-defer slots, so that the // latter are grouped together and near the top of the frame (to // minimize varint encoding of their varp offset). if a.OpenDeferSlot() != b.OpenDeferSlot() { return a.OpenDeferSlot() } // If a and b are both open-coded defer slots, then order them by // index in descending order, so they'll be laid out in the frame in // ascending order. // // Their index was saved in FrameOffset in state.openDeferSave. if a.OpenDeferSlot() { return a.FrameOffset() > b.FrameOffset() } // Tie breaker for stable results. return a.Sym().Name < b.Sym().Name } // needAlloc reports whether n is within the current frame, for which we need to // allocate space. In particular, it excludes arguments and results, which are in // the callers frame. func needAlloc(n *ir.Name) bool { if n.Op() != ir.ONAME { base.FatalfAt(n.Pos(), "%v has unexpected Op %v", n, n.Op()) } switch n.Class { case ir.PAUTO: return true case ir.PPARAM: return false case ir.PPARAMOUT: return n.IsOutputParamInRegisters() default: base.FatalfAt(n.Pos(), "%v has unexpected Class %v", n, n.Class) return false } } func (s *ssafn) AllocFrame(f *ssa.Func) { s.stksize = 0 s.stkptrsize = 0 s.stkalign = int64(types.RegSize) fn := s.curfn // Mark the PAUTO's unused. for _, ln := range fn.Dcl { if ln.OpenDeferSlot() { // Open-coded defer slots have indices that were assigned // upfront during SSA construction, but the defer statement can // later get removed during deadcode elimination (#61895). To // keep their relative offsets correct, treat them all as used. continue } if needAlloc(ln) { ln.SetUsed(false) } } for _, l := range f.RegAlloc { if ls, ok := l.(ssa.LocalSlot); ok { ls.N.SetUsed(true) } } for _, b := range f.Blocks { for _, v := range b.Values { if n, ok := v.Aux.(*ir.Name); ok { switch n.Class { case ir.PPARAMOUT: if n.IsOutputParamInRegisters() && v.Op == ssa.OpVarDef { // ignore VarDef, look for "real" uses. // TODO: maybe do this for PAUTO as well? continue } fallthrough case ir.PPARAM, ir.PAUTO: n.SetUsed(true) } } } } var mls *liveness.MergeLocalsState var leaders map[*ir.Name]int64 if base.Debug.MergeLocals != 0 { mls = liveness.MergeLocals(fn, f) if base.Debug.MergeLocalsTrace > 0 && mls != nil { savedNP, savedP := mls.EstSavings() fmt.Fprintf(os.Stderr, "%s: %d bytes of stack space saved via stack slot merging (%d nonpointer %d pointer)\n", ir.FuncName(fn), savedNP+savedP, savedNP, savedP) if base.Debug.MergeLocalsTrace > 1 { fmt.Fprintf(os.Stderr, "=-= merge locals state for %v:\n%v", fn, mls) } } leaders = make(map[*ir.Name]int64) } // Use sort.SliceStable instead of sort.Slice so stack layout (and thus // compiler output) is less sensitive to frontend changes that // introduce or remove unused variables. sort.SliceStable(fn.Dcl, func(i, j int) bool { return cmpstackvarlt(fn.Dcl[i], fn.Dcl[j], mls) }) if mls != nil { // Rewrite fn.Dcl to reposition followers (subsumed vars) to // be immediately following the leader var in their partition. followers := []*ir.Name{} newdcl := make([]*ir.Name, 0, len(fn.Dcl)) for i := 0; i < len(fn.Dcl); i++ { n := fn.Dcl[i] if mls.Subsumed(n) { continue } newdcl = append(newdcl, n) if mls.IsLeader(n) { followers = mls.Followers(n, followers) // position followers immediately after leader newdcl = append(newdcl, followers...) } } fn.Dcl = newdcl } if base.Debug.MergeLocalsTrace > 1 && mls != nil { fmt.Fprintf(os.Stderr, "=-= sorted DCL for %v:\n", fn) for i, v := range fn.Dcl { if !ssa.IsMergeCandidate(v) { continue } fmt.Fprintf(os.Stderr, " %d: %q isleader=%v subsumed=%v used=%v sz=%d align=%d t=%s\n", i, v.Sym().Name, mls.IsLeader(v), mls.Subsumed(v), v.Used(), v.Type().Size(), v.Type().Alignment(), v.Type().String()) } } // Reassign stack offsets of the locals that are used. lastHasPtr := false for i, n := range fn.Dcl { if n.Op() != ir.ONAME || n.Class != ir.PAUTO && !(n.Class == ir.PPARAMOUT && n.IsOutputParamInRegisters()) { // i.e., stack assign if AUTO, or if PARAMOUT in registers (which has no predefined spill locations) continue } if mls != nil && mls.Subsumed(n) { continue } if !n.Used() { fn.DebugInfo.(*ssa.FuncDebug).OptDcl = fn.Dcl[i:] fn.Dcl = fn.Dcl[:i] break } types.CalcSize(n.Type()) w := n.Type().Size() if w >= types.MaxWidth || w < 0 { base.Fatalf("bad width") } if w == 0 && lastHasPtr { // Pad between a pointer-containing object and a zero-sized object. // This prevents a pointer to the zero-sized object from being interpreted // as a pointer to the pointer-containing object (and causing it // to be scanned when it shouldn't be). See issue 24993. w = 1 } s.stksize += w s.stksize = types.RoundUp(s.stksize, n.Type().Alignment()) if n.Type().Alignment() > int64(types.RegSize) { s.stkalign = n.Type().Alignment() } if n.Type().HasPointers() { s.stkptrsize = s.stksize lastHasPtr = true } else { lastHasPtr = false } n.SetFrameOffset(-s.stksize) if mls != nil && mls.IsLeader(n) { leaders[n] = -s.stksize } } if mls != nil { // Update offsets of followers (subsumed vars) to be the // same as the leader var in their partition. for i := 0; i < len(fn.Dcl); i++ { n := fn.Dcl[i] if !mls.Subsumed(n) { continue } leader := mls.Leader(n) off, ok := leaders[leader] if !ok { panic("internal error missing leader") } // Set the stack offset this subsumed (followed) var // to be the same as the leader. n.SetFrameOffset(off) } if base.Debug.MergeLocalsTrace > 1 { fmt.Fprintf(os.Stderr, "=-= stack layout for %v:\n", fn) for i, v := range fn.Dcl { if v.Op() != ir.ONAME || (v.Class != ir.PAUTO && !(v.Class == ir.PPARAMOUT && v.IsOutputParamInRegisters())) { continue } fmt.Fprintf(os.Stderr, " %d: %q frameoff %d isleader=%v subsumed=%v sz=%d align=%d t=%s\n", i, v.Sym().Name, v.FrameOffset(), mls.IsLeader(v), mls.Subsumed(v), v.Type().Size(), v.Type().Alignment(), v.Type().String()) } } } s.stksize = types.RoundUp(s.stksize, s.stkalign) s.stkptrsize = types.RoundUp(s.stkptrsize, s.stkalign) } const maxStackSize = 1 << 30 // Compile builds an SSA backend function, // uses it to generate a plist, // and flushes that plist to machine code. // worker indicates which of the backend workers is doing the processing. func Compile(fn *ir.Func, worker int, profile *pgoir.Profile) { f := buildssa(fn, worker, inline.IsPgoHotFunc(fn, profile) || inline.HasPgoHotInline(fn)) // Note: check arg size to fix issue 25507. if f.Frontend().(*ssafn).stksize >= maxStackSize || f.OwnAux.ArgWidth() >= maxStackSize { largeStackFramesMu.Lock() largeStackFrames = append(largeStackFrames, largeStack{locals: f.Frontend().(*ssafn).stksize, args: f.OwnAux.ArgWidth(), pos: fn.Pos()}) largeStackFramesMu.Unlock() return } pp := objw.NewProgs(fn, worker) defer pp.Free() genssa(f, pp) // Check frame size again. // The check above included only the space needed for local variables. // After genssa, the space needed includes local variables and the callee arg region. // We must do this check prior to calling pp.Flush. // If there are any oversized stack frames, // the assembler may emit inscrutable complaints about invalid instructions. if pp.Text.To.Offset >= maxStackSize { largeStackFramesMu.Lock() locals := f.Frontend().(*ssafn).stksize largeStackFrames = append(largeStackFrames, largeStack{locals: locals, args: f.OwnAux.ArgWidth(), callee: pp.Text.To.Offset - locals, pos: fn.Pos()}) largeStackFramesMu.Unlock() return } pp.Flush() // assemble, fill in boilerplate, etc. // If we're compiling the package init function, search for any // relocations that target global map init outline functions and // turn them into weak relocs. if fn.IsPackageInit() && base.Debug.WrapGlobalMapCtl != 1 { weakenGlobalMapInitRelocs(fn) } // fieldtrack must be called after pp.Flush. See issue 20014. fieldtrack(pp.Text.From.Sym, fn.FieldTrack) } // globalMapInitLsyms records the LSym of each map.init.NNN outlined // map initializer function created by the compiler. var globalMapInitLsyms map[*obj.LSym]struct{} // RegisterMapInitLsym records "s" in the set of outlined map initializer // functions. func RegisterMapInitLsym(s *obj.LSym) { if globalMapInitLsyms == nil { globalMapInitLsyms = make(map[*obj.LSym]struct{}) } globalMapInitLsyms[s] = struct{}{} } // weakenGlobalMapInitRelocs walks through all of the relocations on a // given a package init function "fn" and looks for relocs that target // outlined global map initializer functions; if it finds any such // relocs, it flags them as R_WEAK. func weakenGlobalMapInitRelocs(fn *ir.Func) { if globalMapInitLsyms == nil { return } for i := range fn.LSym.R { tgt := fn.LSym.R[i].Sym if tgt == nil { continue } if _, ok := globalMapInitLsyms[tgt]; !ok { continue } if base.Debug.WrapGlobalMapDbg > 1 { fmt.Fprintf(os.Stderr, "=-= weakify fn %v reloc %d %+v\n", fn, i, fn.LSym.R[i]) } // set the R_WEAK bit, leave rest of reloc type intact fn.LSym.R[i].Type |= objabi.R_WEAK } } // StackOffset returns the stack location of a LocalSlot relative to the // stack pointer, suitable for use in a DWARF location entry. This has nothing // to do with its offset in the user variable. func StackOffset(slot ssa.LocalSlot) int32 { n := slot.N var off int64 switch n.Class { case ir.PPARAM, ir.PPARAMOUT: if !n.IsOutputParamInRegisters() { off = n.FrameOffset() + base.Ctxt.Arch.FixedFrameSize break } fallthrough // PPARAMOUT in registers allocates like an AUTO case ir.PAUTO: off = n.FrameOffset() if base.Ctxt.Arch.FixedFrameSize == 0 { off -= int64(types.PtrSize) } if buildcfg.FramePointerEnabled { off -= int64(types.PtrSize) } } return int32(off + slot.Off) } // fieldtrack adds R_USEFIELD relocations to fnsym to record any // struct fields that it used. func fieldtrack(fnsym *obj.LSym, tracked map[*obj.LSym]struct{}) { if fnsym == nil { return } if !buildcfg.Experiment.FieldTrack || len(tracked) == 0 { return } trackSyms := make([]*obj.LSym, 0, len(tracked)) for sym := range tracked { trackSyms = append(trackSyms, sym) } sort.Slice(trackSyms, func(i, j int) bool { return trackSyms[i].Name < trackSyms[j].Name }) for _, sym := range trackSyms { r := obj.Addrel(fnsym) r.Sym = sym r.Type = objabi.R_USEFIELD } } // largeStack is info about a function whose stack frame is too large (rare). type largeStack struct { locals int64 args int64 callee int64 pos src.XPos } var ( largeStackFramesMu sync.Mutex // protects largeStackFrames largeStackFrames []largeStack ) func CheckLargeStacks() { // Check whether any of the functions we have compiled have gigantic stack frames. sort.Slice(largeStackFrames, func(i, j int) bool { return largeStackFrames[i].pos.Before(largeStackFrames[j].pos) }) for _, large := range largeStackFrames { if large.callee != 0 { base.ErrorfAt(large.pos, 0, "stack frame too large (>1GB): %d MB locals + %d MB args + %d MB callee", large.locals>>20, large.args>>20, large.callee>>20) } else { base.ErrorfAt(large.pos, 0, "stack frame too large (>1GB): %d MB locals + %d MB args", large.locals>>20, large.args>>20) } } }