| // Copyright 2018 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 gc |
| |
| import ( |
| "cmd/compile/internal/logopt" |
| "cmd/compile/internal/types" |
| "cmd/internal/src" |
| "fmt" |
| "math" |
| "strings" |
| ) |
| |
| // Escape analysis. |
| // |
| // Here we analyze functions to determine which Go variables |
| // (including implicit allocations such as calls to "new" or "make", |
| // composite literals, etc.) can be allocated on the stack. The two |
| // key invariants we have to ensure are: (1) pointers to stack objects |
| // cannot be stored in the heap, and (2) pointers to a stack object |
| // cannot outlive that object (e.g., because the declaring function |
| // returned and destroyed the object's stack frame, or its space is |
| // reused across loop iterations for logically distinct variables). |
| // |
| // We implement this with a static data-flow analysis of the AST. |
| // First, we construct a directed weighted graph where vertices |
| // (termed "locations") represent variables allocated by statements |
| // and expressions, and edges represent assignments between variables |
| // (with weights representing addressing/dereference counts). |
| // |
| // Next we walk the graph looking for assignment paths that might |
| // violate the invariants stated above. If a variable v's address is |
| // stored in the heap or elsewhere that may outlive it, then v is |
| // marked as requiring heap allocation. |
| // |
| // To support interprocedural analysis, we also record data-flow from |
| // each function's parameters to the heap and to its result |
| // parameters. This information is summarized as "parameter tags", |
| // which are used at static call sites to improve escape analysis of |
| // function arguments. |
| |
| // Constructing the location graph. |
| // |
| // Every allocating statement (e.g., variable declaration) or |
| // expression (e.g., "new" or "make") is first mapped to a unique |
| // "location." |
| // |
| // We also model every Go assignment as a directed edges between |
| // locations. The number of dereference operations minus the number of |
| // addressing operations is recorded as the edge's weight (termed |
| // "derefs"). For example: |
| // |
| // p = &q // -1 |
| // p = q // 0 |
| // p = *q // 1 |
| // p = **q // 2 |
| // |
| // p = **&**&q // 2 |
| // |
| // Note that the & operator can only be applied to addressable |
| // expressions, and the expression &x itself is not addressable, so |
| // derefs cannot go below -1. |
| // |
| // Every Go language construct is lowered into this representation, |
| // generally without sensitivity to flow, path, or context; and |
| // without distinguishing elements within a compound variable. For |
| // example: |
| // |
| // var x struct { f, g *int } |
| // var u []*int |
| // |
| // x.f = u[0] |
| // |
| // is modeled simply as |
| // |
| // x = *u |
| // |
| // That is, we don't distinguish x.f from x.g, or u[0] from u[1], |
| // u[2], etc. However, we do record the implicit dereference involved |
| // in indexing a slice. |
| |
| type Escape struct { |
| allLocs []*EscLocation |
| |
| curfn *Node |
| |
| // loopDepth counts the current loop nesting depth within |
| // curfn. It increments within each "for" loop and at each |
| // label with a corresponding backwards "goto" (i.e., |
| // unstructured loop). |
| loopDepth int |
| |
| heapLoc EscLocation |
| blankLoc EscLocation |
| } |
| |
| // An EscLocation represents an abstract location that stores a Go |
| // variable. |
| type EscLocation struct { |
| n *Node // represented variable or expression, if any |
| curfn *Node // enclosing function |
| edges []EscEdge // incoming edges |
| loopDepth int // loopDepth at declaration |
| |
| // derefs and walkgen are used during walkOne to track the |
| // minimal dereferences from the walk root. |
| derefs int // >= -1 |
| walkgen uint32 |
| |
| // dst and dstEdgeindex track the next immediate assignment |
| // destination location during walkone, along with the index |
| // of the edge pointing back to this location. |
| dst *EscLocation |
| dstEdgeIdx int |
| |
| // queued is used by walkAll to track whether this location is |
| // in the walk queue. |
| queued bool |
| |
| // escapes reports whether the represented variable's address |
| // escapes; that is, whether the variable must be heap |
| // allocated. |
| escapes bool |
| |
| // transient reports whether the represented expression's |
| // address does not outlive the statement; that is, whether |
| // its storage can be immediately reused. |
| transient bool |
| |
| // paramEsc records the represented parameter's leak set. |
| paramEsc EscLeaks |
| } |
| |
| // An EscEdge represents an assignment edge between two Go variables. |
| type EscEdge struct { |
| src *EscLocation |
| derefs int // >= -1 |
| notes *EscNote |
| } |
| |
| // escapeFuncs performs escape analysis on a minimal batch of |
| // functions. |
| func escapeFuncs(fns []*Node, recursive bool) { |
| for _, fn := range fns { |
| if fn.Op != ODCLFUNC { |
| Fatalf("unexpected node: %v", fn) |
| } |
| } |
| |
| var e Escape |
| e.heapLoc.escapes = true |
| |
| // Construct data-flow graph from syntax trees. |
| for _, fn := range fns { |
| e.initFunc(fn) |
| } |
| for _, fn := range fns { |
| e.walkFunc(fn) |
| } |
| e.curfn = nil |
| |
| e.walkAll() |
| e.finish(fns) |
| } |
| |
| func (e *Escape) initFunc(fn *Node) { |
| if fn.Op != ODCLFUNC || fn.Esc != EscFuncUnknown { |
| Fatalf("unexpected node: %v", fn) |
| } |
| fn.Esc = EscFuncPlanned |
| if Debug['m'] > 3 { |
| Dump("escAnalyze", fn) |
| } |
| |
| e.curfn = fn |
| e.loopDepth = 1 |
| |
| // Allocate locations for local variables. |
| for _, dcl := range fn.Func.Dcl { |
| if dcl.Op == ONAME { |
| e.newLoc(dcl, false) |
| } |
| } |
| } |
| |
| func (e *Escape) walkFunc(fn *Node) { |
| fn.Esc = EscFuncStarted |
| |
| // Identify labels that mark the head of an unstructured loop. |
| inspectList(fn.Nbody, func(n *Node) bool { |
| switch n.Op { |
| case OLABEL: |
| n.Sym.Label = asTypesNode(&nonlooping) |
| |
| case OGOTO: |
| // If we visited the label before the goto, |
| // then this is a looping label. |
| if n.Sym.Label == asTypesNode(&nonlooping) { |
| n.Sym.Label = asTypesNode(&looping) |
| } |
| } |
| |
| return true |
| }) |
| |
| e.curfn = fn |
| e.loopDepth = 1 |
| e.block(fn.Nbody) |
| } |
| |
| // Below we implement the methods for walking the AST and recording |
| // data flow edges. Note that because a sub-expression might have |
| // side-effects, it's important to always visit the entire AST. |
| // |
| // For example, write either: |
| // |
| // if x { |
| // e.discard(n.Left) |
| // } else { |
| // e.value(k, n.Left) |
| // } |
| // |
| // or |
| // |
| // if x { |
| // k = e.discardHole() |
| // } |
| // e.value(k, n.Left) |
| // |
| // Do NOT write: |
| // |
| // // BAD: possibly loses side-effects within n.Left |
| // if !x { |
| // e.value(k, n.Left) |
| // } |
| |
| // stmt evaluates a single Go statement. |
| func (e *Escape) stmt(n *Node) { |
| if n == nil { |
| return |
| } |
| |
| lno := setlineno(n) |
| defer func() { |
| lineno = lno |
| }() |
| |
| if Debug['m'] > 2 { |
| fmt.Printf("%v:[%d] %v stmt: %v\n", linestr(lineno), e.loopDepth, funcSym(e.curfn), n) |
| } |
| |
| e.stmts(n.Ninit) |
| |
| switch n.Op { |
| default: |
| Fatalf("unexpected stmt: %v", n) |
| |
| case ODCLCONST, ODCLTYPE, OEMPTY, OFALL, OINLMARK: |
| // nop |
| |
| case OBREAK, OCONTINUE, OGOTO: |
| // TODO(mdempsky): Handle dead code? |
| |
| case OBLOCK: |
| e.stmts(n.List) |
| |
| case ODCL: |
| // Record loop depth at declaration. |
| if !n.Left.isBlank() { |
| e.dcl(n.Left) |
| } |
| |
| case OLABEL: |
| switch asNode(n.Sym.Label) { |
| case &nonlooping: |
| if Debug['m'] > 2 { |
| fmt.Printf("%v:%v non-looping label\n", linestr(lineno), n) |
| } |
| case &looping: |
| if Debug['m'] > 2 { |
| fmt.Printf("%v: %v looping label\n", linestr(lineno), n) |
| } |
| e.loopDepth++ |
| default: |
| Fatalf("label missing tag") |
| } |
| n.Sym.Label = nil |
| |
| case OIF: |
| e.discard(n.Left) |
| e.block(n.Nbody) |
| e.block(n.Rlist) |
| |
| case OFOR, OFORUNTIL: |
| e.loopDepth++ |
| e.discard(n.Left) |
| e.stmt(n.Right) |
| e.block(n.Nbody) |
| e.loopDepth-- |
| |
| case ORANGE: |
| // for List = range Right { Nbody } |
| e.loopDepth++ |
| ks := e.addrs(n.List) |
| e.block(n.Nbody) |
| e.loopDepth-- |
| |
| // Right is evaluated outside the loop. |
| k := e.discardHole() |
| if len(ks) >= 2 { |
| if n.Right.Type.IsArray() { |
| k = ks[1].note(n, "range") |
| } else { |
| k = ks[1].deref(n, "range-deref") |
| } |
| } |
| e.expr(e.later(k), n.Right) |
| |
| case OSWITCH: |
| typesw := n.Left != nil && n.Left.Op == OTYPESW |
| |
| var ks []EscHole |
| for _, cas := range n.List.Slice() { // cases |
| if typesw && n.Left.Left != nil { |
| cv := cas.Rlist.First() |
| k := e.dcl(cv) // type switch variables have no ODCL. |
| if cv.Type.HasPointers() { |
| ks = append(ks, k.dotType(cv.Type, cas, "switch case")) |
| } |
| } |
| |
| e.discards(cas.List) |
| e.block(cas.Nbody) |
| } |
| |
| if typesw { |
| e.expr(e.teeHole(ks...), n.Left.Right) |
| } else { |
| e.discard(n.Left) |
| } |
| |
| case OSELECT: |
| for _, cas := range n.List.Slice() { |
| e.stmt(cas.Left) |
| e.block(cas.Nbody) |
| } |
| case OSELRECV: |
| e.assign(n.Left, n.Right, "selrecv", n) |
| case OSELRECV2: |
| e.assign(n.Left, n.Right, "selrecv", n) |
| e.assign(n.List.First(), nil, "selrecv", n) |
| case ORECV: |
| // TODO(mdempsky): Consider e.discard(n.Left). |
| e.exprSkipInit(e.discardHole(), n) // already visited n.Ninit |
| case OSEND: |
| e.discard(n.Left) |
| e.assignHeap(n.Right, "send", n) |
| |
| case OAS, OASOP: |
| e.assign(n.Left, n.Right, "assign", n) |
| |
| case OAS2: |
| for i, nl := range n.List.Slice() { |
| e.assign(nl, n.Rlist.Index(i), "assign-pair", n) |
| } |
| |
| case OAS2DOTTYPE: // v, ok = x.(type) |
| e.assign(n.List.First(), n.Right, "assign-pair-dot-type", n) |
| e.assign(n.List.Second(), nil, "assign-pair-dot-type", n) |
| case OAS2MAPR: // v, ok = m[k] |
| e.assign(n.List.First(), n.Right, "assign-pair-mapr", n) |
| e.assign(n.List.Second(), nil, "assign-pair-mapr", n) |
| case OAS2RECV: // v, ok = <-ch |
| e.assign(n.List.First(), n.Right, "assign-pair-receive", n) |
| e.assign(n.List.Second(), nil, "assign-pair-receive", n) |
| |
| case OAS2FUNC: |
| e.stmts(n.Right.Ninit) |
| e.call(e.addrs(n.List), n.Right, nil) |
| case ORETURN: |
| results := e.curfn.Type.Results().FieldSlice() |
| for i, v := range n.List.Slice() { |
| e.assign(asNode(results[i].Nname), v, "return", n) |
| } |
| case OCALLFUNC, OCALLMETH, OCALLINTER, OCLOSE, OCOPY, ODELETE, OPANIC, OPRINT, OPRINTN, ORECOVER: |
| e.call(nil, n, nil) |
| case OGO, ODEFER: |
| e.stmts(n.Left.Ninit) |
| e.call(nil, n.Left, n) |
| |
| case ORETJMP: |
| // TODO(mdempsky): What do? esc.go just ignores it. |
| } |
| } |
| |
| func (e *Escape) stmts(l Nodes) { |
| for _, n := range l.Slice() { |
| e.stmt(n) |
| } |
| } |
| |
| // block is like stmts, but preserves loopDepth. |
| func (e *Escape) block(l Nodes) { |
| old := e.loopDepth |
| e.stmts(l) |
| e.loopDepth = old |
| } |
| |
| // expr models evaluating an expression n and flowing the result into |
| // hole k. |
| func (e *Escape) expr(k EscHole, n *Node) { |
| if n == nil { |
| return |
| } |
| e.stmts(n.Ninit) |
| e.exprSkipInit(k, n) |
| } |
| |
| func (e *Escape) exprSkipInit(k EscHole, n *Node) { |
| if n == nil { |
| return |
| } |
| |
| lno := setlineno(n) |
| defer func() { |
| lineno = lno |
| }() |
| |
| uintptrEscapesHack := k.uintptrEscapesHack |
| k.uintptrEscapesHack = false |
| |
| if uintptrEscapesHack && n.Op == OCONVNOP && n.Left.Type.IsUnsafePtr() { |
| // nop |
| } else if k.derefs >= 0 && !n.Type.HasPointers() { |
| k = e.discardHole() |
| } |
| |
| switch n.Op { |
| default: |
| Fatalf("unexpected expr: %v", n) |
| |
| case OLITERAL, OGETG, OCLOSUREVAR, OTYPE: |
| // nop |
| |
| case ONAME: |
| if n.Class() == PFUNC || n.Class() == PEXTERN { |
| return |
| } |
| e.flow(k, e.oldLoc(n)) |
| |
| case OPLUS, ONEG, OBITNOT, ONOT: |
| e.discard(n.Left) |
| case OADD, OSUB, OOR, OXOR, OMUL, ODIV, OMOD, OLSH, ORSH, OAND, OANDNOT, OEQ, ONE, OLT, OLE, OGT, OGE, OANDAND, OOROR: |
| e.discard(n.Left) |
| e.discard(n.Right) |
| |
| case OADDR: |
| e.expr(k.addr(n, "address-of"), n.Left) // "address-of" |
| case ODEREF: |
| e.expr(k.deref(n, "indirection"), n.Left) // "indirection" |
| case ODOT, ODOTMETH, ODOTINTER: |
| e.expr(k.note(n, "dot"), n.Left) |
| case ODOTPTR: |
| e.expr(k.deref(n, "dot of pointer"), n.Left) // "dot of pointer" |
| case ODOTTYPE, ODOTTYPE2: |
| e.expr(k.dotType(n.Type, n, "dot"), n.Left) |
| case OINDEX: |
| if n.Left.Type.IsArray() { |
| e.expr(k.note(n, "fixed-array-index-of"), n.Left) |
| } else { |
| // TODO(mdempsky): Fix why reason text. |
| e.expr(k.deref(n, "dot of pointer"), n.Left) |
| } |
| e.discard(n.Right) |
| case OINDEXMAP: |
| e.discard(n.Left) |
| e.discard(n.Right) |
| case OSLICE, OSLICEARR, OSLICE3, OSLICE3ARR, OSLICESTR: |
| e.expr(k.note(n, "slice"), n.Left) |
| low, high, max := n.SliceBounds() |
| e.discard(low) |
| e.discard(high) |
| e.discard(max) |
| |
| case OCONV, OCONVNOP: |
| if checkPtr(e.curfn, 2) && n.Type.Etype == TUNSAFEPTR && n.Left.Type.IsPtr() { |
| // When -d=checkptr=2 is enabled, treat |
| // conversions to unsafe.Pointer as an |
| // escaping operation. This allows better |
| // runtime instrumentation, since we can more |
| // easily detect object boundaries on the heap |
| // than the stack. |
| e.assignHeap(n.Left, "conversion to unsafe.Pointer", n) |
| } else if n.Type.Etype == TUNSAFEPTR && n.Left.Type.Etype == TUINTPTR { |
| e.unsafeValue(k, n.Left) |
| } else { |
| e.expr(k, n.Left) |
| } |
| case OCONVIFACE: |
| if !n.Left.Type.IsInterface() && !isdirectiface(n.Left.Type) { |
| k = e.spill(k, n) |
| } |
| e.expr(k.note(n, "interface-converted"), n.Left) |
| |
| case ORECV: |
| e.discard(n.Left) |
| |
| case OCALLMETH, OCALLFUNC, OCALLINTER, OLEN, OCAP, OCOMPLEX, OREAL, OIMAG, OAPPEND, OCOPY: |
| e.call([]EscHole{k}, n, nil) |
| |
| case ONEW: |
| e.spill(k, n) |
| |
| case OMAKESLICE: |
| e.spill(k, n) |
| e.discard(n.Left) |
| e.discard(n.Right) |
| case OMAKECHAN: |
| e.discard(n.Left) |
| case OMAKEMAP: |
| e.spill(k, n) |
| e.discard(n.Left) |
| |
| case ORECOVER: |
| // nop |
| |
| case OCALLPART: |
| // Flow the receiver argument to both the closure and |
| // to the receiver parameter. |
| |
| closureK := e.spill(k, n) |
| |
| m := callpartMethod(n) |
| |
| // We don't know how the method value will be called |
| // later, so conservatively assume the result |
| // parameters all flow to the heap. |
| // |
| // TODO(mdempsky): Change ks into a callback, so that |
| // we don't have to create this dummy slice? |
| var ks []EscHole |
| for i := m.Type.NumResults(); i > 0; i-- { |
| ks = append(ks, e.heapHole()) |
| } |
| paramK := e.tagHole(ks, asNode(m.Type.Nname()), m.Type.Recv()) |
| |
| e.expr(e.teeHole(paramK, closureK), n.Left) |
| |
| case OPTRLIT: |
| e.expr(e.spill(k, n), n.Left) |
| |
| case OARRAYLIT: |
| for _, elt := range n.List.Slice() { |
| if elt.Op == OKEY { |
| elt = elt.Right |
| } |
| e.expr(k.note(n, "array literal element"), elt) |
| } |
| |
| case OSLICELIT: |
| k = e.spill(k, n) |
| k.uintptrEscapesHack = uintptrEscapesHack // for ...uintptr parameters |
| |
| for _, elt := range n.List.Slice() { |
| if elt.Op == OKEY { |
| elt = elt.Right |
| } |
| e.expr(k.note(n, "slice-literal-element"), elt) |
| } |
| |
| case OSTRUCTLIT: |
| for _, elt := range n.List.Slice() { |
| e.expr(k.note(n, "struct literal element"), elt.Left) |
| } |
| |
| case OMAPLIT: |
| e.spill(k, n) |
| |
| // Map keys and values are always stored in the heap. |
| for _, elt := range n.List.Slice() { |
| e.assignHeap(elt.Left, "map literal key", n) |
| e.assignHeap(elt.Right, "map literal value", n) |
| } |
| |
| case OCLOSURE: |
| k = e.spill(k, n) |
| |
| // Link addresses of captured variables to closure. |
| for _, v := range n.Func.Closure.Func.Cvars.Slice() { |
| if v.Op == OXXX { // unnamed out argument; see dcl.go:/^funcargs |
| continue |
| } |
| |
| k := k |
| if !v.Name.Byval() { |
| k = k.addr(v, "reference") |
| } |
| |
| e.expr(k.note(n, "captured by a closure"), v.Name.Defn) |
| } |
| |
| case ORUNES2STR, OBYTES2STR, OSTR2RUNES, OSTR2BYTES, ORUNESTR: |
| e.spill(k, n) |
| e.discard(n.Left) |
| |
| case OADDSTR: |
| e.spill(k, n) |
| |
| // Arguments of OADDSTR never escape; |
| // runtime.concatstrings makes sure of that. |
| e.discards(n.List) |
| } |
| } |
| |
| // unsafeValue evaluates a uintptr-typed arithmetic expression looking |
| // for conversions from an unsafe.Pointer. |
| func (e *Escape) unsafeValue(k EscHole, n *Node) { |
| if n.Type.Etype != TUINTPTR { |
| Fatalf("unexpected type %v for %v", n.Type, n) |
| } |
| |
| e.stmts(n.Ninit) |
| |
| switch n.Op { |
| case OCONV, OCONVNOP: |
| if n.Left.Type.Etype == TUNSAFEPTR { |
| e.expr(k, n.Left) |
| } else { |
| e.discard(n.Left) |
| } |
| case ODOTPTR: |
| if isReflectHeaderDataField(n) { |
| e.expr(k.deref(n, "reflect.Header.Data"), n.Left) |
| } else { |
| e.discard(n.Left) |
| } |
| case OPLUS, ONEG, OBITNOT: |
| e.unsafeValue(k, n.Left) |
| case OADD, OSUB, OOR, OXOR, OMUL, ODIV, OMOD, OAND, OANDNOT: |
| e.unsafeValue(k, n.Left) |
| e.unsafeValue(k, n.Right) |
| case OLSH, ORSH: |
| e.unsafeValue(k, n.Left) |
| // RHS need not be uintptr-typed (#32959) and can't meaningfully |
| // flow pointers anyway. |
| e.discard(n.Right) |
| default: |
| e.exprSkipInit(e.discardHole(), n) |
| } |
| } |
| |
| // discard evaluates an expression n for side-effects, but discards |
| // its value. |
| func (e *Escape) discard(n *Node) { |
| e.expr(e.discardHole(), n) |
| } |
| |
| func (e *Escape) discards(l Nodes) { |
| for _, n := range l.Slice() { |
| e.discard(n) |
| } |
| } |
| |
| // addr evaluates an addressable expression n and returns an EscHole |
| // that represents storing into the represented location. |
| func (e *Escape) addr(n *Node) EscHole { |
| if n == nil || n.isBlank() { |
| // Can happen at least in OSELRECV. |
| // TODO(mdempsky): Anywhere else? |
| return e.discardHole() |
| } |
| |
| k := e.heapHole() |
| |
| switch n.Op { |
| default: |
| Fatalf("unexpected addr: %v", n) |
| case ONAME: |
| if n.Class() == PEXTERN { |
| break |
| } |
| k = e.oldLoc(n).asHole() |
| case ODOT: |
| k = e.addr(n.Left) |
| case OINDEX: |
| e.discard(n.Right) |
| if n.Left.Type.IsArray() { |
| k = e.addr(n.Left) |
| } else { |
| e.discard(n.Left) |
| } |
| case ODEREF, ODOTPTR: |
| e.discard(n) |
| case OINDEXMAP: |
| e.discard(n.Left) |
| e.assignHeap(n.Right, "key of map put", n) |
| } |
| |
| if !n.Type.HasPointers() { |
| k = e.discardHole() |
| } |
| |
| return k |
| } |
| |
| func (e *Escape) addrs(l Nodes) []EscHole { |
| var ks []EscHole |
| for _, n := range l.Slice() { |
| ks = append(ks, e.addr(n)) |
| } |
| return ks |
| } |
| |
| // assign evaluates the assignment dst = src. |
| func (e *Escape) assign(dst, src *Node, why string, where *Node) { |
| // Filter out some no-op assignments for escape analysis. |
| ignore := dst != nil && src != nil && isSelfAssign(dst, src) |
| if ignore && Debug['m'] != 0 { |
| Warnl(where.Pos, "%v ignoring self-assignment in %S", funcSym(e.curfn), where) |
| } |
| |
| k := e.addr(dst) |
| if dst != nil && dst.Op == ODOTPTR && isReflectHeaderDataField(dst) { |
| e.unsafeValue(e.heapHole().note(where, why), src) |
| } else { |
| if ignore { |
| k = e.discardHole() |
| } |
| e.expr(k.note(where, why), src) |
| } |
| } |
| |
| func (e *Escape) assignHeap(src *Node, why string, where *Node) { |
| e.expr(e.heapHole().note(where, why), src) |
| } |
| |
| // call evaluates a call expressions, including builtin calls. ks |
| // should contain the holes representing where the function callee's |
| // results flows; where is the OGO/ODEFER context of the call, if any. |
| func (e *Escape) call(ks []EscHole, call, where *Node) { |
| topLevelDefer := where != nil && where.Op == ODEFER && e.loopDepth == 1 |
| if topLevelDefer { |
| // force stack allocation of defer record, unless |
| // open-coded defers are used (see ssa.go) |
| where.Esc = EscNever |
| } |
| |
| argument := func(k EscHole, arg *Node) { |
| if topLevelDefer { |
| // Top level defers arguments don't escape to |
| // heap, but they do need to last until end of |
| // function. |
| k = e.later(k) |
| } else if where != nil { |
| k = e.heapHole() |
| } |
| |
| e.expr(k.note(call, "call parameter"), arg) |
| } |
| |
| switch call.Op { |
| default: |
| Fatalf("unexpected call op: %v", call.Op) |
| |
| case OCALLFUNC, OCALLMETH, OCALLINTER: |
| fixVariadicCall(call) |
| |
| // Pick out the function callee, if statically known. |
| var fn *Node |
| switch call.Op { |
| case OCALLFUNC: |
| if call.Left.Op == ONAME && call.Left.Class() == PFUNC { |
| fn = call.Left |
| } else if call.Left.Op == OCLOSURE { |
| fn = call.Left.Func.Closure.Func.Nname |
| } |
| case OCALLMETH: |
| fn = asNode(call.Left.Type.FuncType().Nname) |
| } |
| |
| fntype := call.Left.Type |
| if fn != nil { |
| fntype = fn.Type |
| } |
| |
| if ks != nil && fn != nil && e.inMutualBatch(fn) { |
| for i, result := range fn.Type.Results().FieldSlice() { |
| e.expr(ks[i], asNode(result.Nname)) |
| } |
| } |
| |
| if r := fntype.Recv(); r != nil { |
| argument(e.tagHole(ks, fn, r), call.Left.Left) |
| } else { |
| // Evaluate callee function expression. |
| argument(e.discardHole(), call.Left) |
| } |
| |
| args := call.List.Slice() |
| for i, param := range fntype.Params().FieldSlice() { |
| argument(e.tagHole(ks, fn, param), args[i]) |
| } |
| |
| case OAPPEND: |
| args := call.List.Slice() |
| |
| // Appendee slice may flow directly to the result, if |
| // it has enough capacity. Alternatively, a new heap |
| // slice might be allocated, and all slice elements |
| // might flow to heap. |
| appendeeK := ks[0] |
| if args[0].Type.Elem().HasPointers() { |
| appendeeK = e.teeHole(appendeeK, e.heapHole().deref(call, "appendee slice")) |
| } |
| argument(appendeeK, args[0]) |
| |
| if call.IsDDD() { |
| appendedK := e.discardHole() |
| if args[1].Type.IsSlice() && args[1].Type.Elem().HasPointers() { |
| appendedK = e.heapHole().deref(call, "appended slice...") |
| } |
| argument(appendedK, args[1]) |
| } else { |
| for _, arg := range args[1:] { |
| argument(e.heapHole(), arg) |
| } |
| } |
| |
| case OCOPY: |
| argument(e.discardHole(), call.Left) |
| |
| copiedK := e.discardHole() |
| if call.Right.Type.IsSlice() && call.Right.Type.Elem().HasPointers() { |
| copiedK = e.heapHole().deref(call, "copied slice") |
| } |
| argument(copiedK, call.Right) |
| |
| case OPANIC: |
| argument(e.heapHole(), call.Left) |
| |
| case OCOMPLEX: |
| argument(e.discardHole(), call.Left) |
| argument(e.discardHole(), call.Right) |
| case ODELETE, OPRINT, OPRINTN, ORECOVER: |
| for _, arg := range call.List.Slice() { |
| argument(e.discardHole(), arg) |
| } |
| case OLEN, OCAP, OREAL, OIMAG, OCLOSE: |
| argument(e.discardHole(), call.Left) |
| } |
| } |
| |
| // tagHole returns a hole for evaluating an argument passed to param. |
| // ks should contain the holes representing where the function |
| // callee's results flows. fn is the statically-known callee function, |
| // if any. |
| func (e *Escape) tagHole(ks []EscHole, fn *Node, param *types.Field) EscHole { |
| // If this is a dynamic call, we can't rely on param.Note. |
| if fn == nil { |
| return e.heapHole() |
| } |
| |
| if e.inMutualBatch(fn) { |
| return e.addr(asNode(param.Nname)) |
| } |
| |
| // Call to previously tagged function. |
| |
| if param.Note == uintptrEscapesTag { |
| k := e.heapHole() |
| k.uintptrEscapesHack = true |
| return k |
| } |
| |
| var tagKs []EscHole |
| |
| esc := ParseLeaks(param.Note) |
| if x := esc.Heap(); x >= 0 { |
| tagKs = append(tagKs, e.heapHole().shift(x)) |
| } |
| |
| if ks != nil { |
| for i := 0; i < numEscResults; i++ { |
| if x := esc.Result(i); x >= 0 { |
| tagKs = append(tagKs, ks[i].shift(x)) |
| } |
| } |
| } |
| |
| return e.teeHole(tagKs...) |
| } |
| |
| // inMutualBatch reports whether function fn is in the batch of |
| // mutually recursive functions being analyzed. When this is true, |
| // fn has not yet been analyzed, so its parameters and results |
| // should be incorporated directly into the flow graph instead of |
| // relying on its escape analysis tagging. |
| func (e *Escape) inMutualBatch(fn *Node) bool { |
| if fn.Name.Defn != nil && fn.Name.Defn.Esc < EscFuncTagged { |
| if fn.Name.Defn.Esc == EscFuncUnknown { |
| Fatalf("graph inconsistency") |
| } |
| return true |
| } |
| return false |
| } |
| |
| // An EscHole represents a context for evaluation a Go |
| // expression. E.g., when evaluating p in "x = **p", we'd have a hole |
| // with dst==x and derefs==2. |
| type EscHole struct { |
| dst *EscLocation |
| derefs int // >= -1 |
| notes *EscNote |
| |
| // uintptrEscapesHack indicates this context is evaluating an |
| // argument for a //go:uintptrescapes function. |
| uintptrEscapesHack bool |
| } |
| |
| type EscNote struct { |
| next *EscNote |
| where *Node |
| why string |
| } |
| |
| func (k EscHole) note(where *Node, why string) EscHole { |
| if where == nil || why == "" { |
| Fatalf("note: missing where/why") |
| } |
| if Debug['m'] >= 2 || logopt.Enabled() { |
| k.notes = &EscNote{ |
| next: k.notes, |
| where: where, |
| why: why, |
| } |
| } |
| return k |
| } |
| |
| func (k EscHole) shift(delta int) EscHole { |
| k.derefs += delta |
| if k.derefs < -1 { |
| Fatalf("derefs underflow: %v", k.derefs) |
| } |
| return k |
| } |
| |
| func (k EscHole) deref(where *Node, why string) EscHole { return k.shift(1).note(where, why) } |
| func (k EscHole) addr(where *Node, why string) EscHole { return k.shift(-1).note(where, why) } |
| |
| func (k EscHole) dotType(t *types.Type, where *Node, why string) EscHole { |
| if !t.IsInterface() && !isdirectiface(t) { |
| k = k.shift(1) |
| } |
| return k.note(where, why) |
| } |
| |
| // teeHole returns a new hole that flows into each hole of ks, |
| // similar to the Unix tee(1) command. |
| func (e *Escape) teeHole(ks ...EscHole) EscHole { |
| if len(ks) == 0 { |
| return e.discardHole() |
| } |
| if len(ks) == 1 { |
| return ks[0] |
| } |
| // TODO(mdempsky): Optimize if there's only one non-discard hole? |
| |
| // Given holes "l1 = _", "l2 = **_", "l3 = *_", ..., create a |
| // new temporary location ltmp, wire it into place, and return |
| // a hole for "ltmp = _". |
| loc := e.newLoc(nil, true) |
| for _, k := range ks { |
| // N.B., "p = &q" and "p = &tmp; tmp = q" are not |
| // semantically equivalent. To combine holes like "l1 |
| // = _" and "l2 = &_", we'd need to wire them as "l1 = |
| // *ltmp" and "l2 = ltmp" and return "ltmp = &_" |
| // instead. |
| if k.derefs < 0 { |
| Fatalf("teeHole: negative derefs") |
| } |
| |
| e.flow(k, loc) |
| } |
| return loc.asHole() |
| } |
| |
| func (e *Escape) dcl(n *Node) EscHole { |
| loc := e.oldLoc(n) |
| loc.loopDepth = e.loopDepth |
| return loc.asHole() |
| } |
| |
| // spill allocates a new location associated with expression n, flows |
| // its address to k, and returns a hole that flows values to it. It's |
| // intended for use with most expressions that allocate storage. |
| func (e *Escape) spill(k EscHole, n *Node) EscHole { |
| loc := e.newLoc(n, true) |
| e.flow(k.addr(n, "spill"), loc) |
| return loc.asHole() |
| } |
| |
| // later returns a new hole that flows into k, but some time later. |
| // Its main effect is to prevent immediate reuse of temporary |
| // variables introduced during Order. |
| func (e *Escape) later(k EscHole) EscHole { |
| loc := e.newLoc(nil, false) |
| e.flow(k, loc) |
| return loc.asHole() |
| } |
| |
| // canonicalNode returns the canonical *Node that n logically |
| // represents. |
| func canonicalNode(n *Node) *Node { |
| if n != nil && n.Op == ONAME && n.Name.IsClosureVar() { |
| n = n.Name.Defn |
| if n.Name.IsClosureVar() { |
| Fatalf("still closure var") |
| } |
| } |
| |
| return n |
| } |
| |
| func (e *Escape) newLoc(n *Node, transient bool) *EscLocation { |
| if e.curfn == nil { |
| Fatalf("e.curfn isn't set") |
| } |
| |
| n = canonicalNode(n) |
| loc := &EscLocation{ |
| n: n, |
| curfn: e.curfn, |
| loopDepth: e.loopDepth, |
| transient: transient, |
| } |
| e.allLocs = append(e.allLocs, loc) |
| if n != nil { |
| if n.Op == ONAME && n.Name.Curfn != e.curfn { |
| Fatalf("curfn mismatch: %v != %v", n.Name.Curfn, e.curfn) |
| } |
| |
| if n.HasOpt() { |
| Fatalf("%v already has a location", n) |
| } |
| n.SetOpt(loc) |
| |
| if mustHeapAlloc(n) { |
| why := "too large for stack" |
| if n.Op == OMAKESLICE && (!Isconst(n.Left, CTINT) || !Isconst(n.Right, CTINT)) { |
| why = "non-constant size" |
| } |
| e.flow(e.heapHole().addr(n, why), loc) |
| } |
| } |
| return loc |
| } |
| |
| func (e *Escape) oldLoc(n *Node) *EscLocation { |
| n = canonicalNode(n) |
| return n.Opt().(*EscLocation) |
| } |
| |
| func (l *EscLocation) asHole() EscHole { |
| return EscHole{dst: l} |
| } |
| |
| func (e *Escape) flow(k EscHole, src *EscLocation) { |
| dst := k.dst |
| if dst == &e.blankLoc { |
| return |
| } |
| if dst == src && k.derefs >= 0 { // dst = dst, dst = *dst, ... |
| return |
| } |
| if dst.escapes && k.derefs < 0 { // dst = &src |
| if Debug['m'] >= 2 || logopt.Enabled() { |
| pos := linestr(src.n.Pos) |
| if Debug['m'] >= 2 { |
| fmt.Printf("%s: %v escapes to heap:\n", pos, src.n) |
| } |
| explanation := e.explainFlow(pos, dst, src, k.derefs, k.notes, []*logopt.LoggedOpt{}) |
| if logopt.Enabled() { |
| logopt.LogOpt(src.n.Pos, "escapes", "escape", e.curfn.funcname(), fmt.Sprintf("%v escapes to heap", src.n), explanation) |
| } |
| |
| } |
| src.escapes = true |
| return |
| } |
| |
| // TODO(mdempsky): Deduplicate edges? |
| dst.edges = append(dst.edges, EscEdge{src: src, derefs: k.derefs, notes: k.notes}) |
| } |
| |
| func (e *Escape) heapHole() EscHole { return e.heapLoc.asHole() } |
| func (e *Escape) discardHole() EscHole { return e.blankLoc.asHole() } |
| |
| // walkAll computes the minimal dereferences between all pairs of |
| // locations. |
| func (e *Escape) walkAll() { |
| // We use a work queue to keep track of locations that we need |
| // to visit, and repeatedly walk until we reach a fixed point. |
| // |
| // We walk once from each location (including the heap), and |
| // then re-enqueue each location on its transition from |
| // transient->!transient and !escapes->escapes, which can each |
| // happen at most once. So we take Θ(len(e.allLocs)) walks. |
| |
| // LIFO queue, has enough room for e.allLocs and e.heapLoc. |
| todo := make([]*EscLocation, 0, len(e.allLocs)+1) |
| enqueue := func(loc *EscLocation) { |
| if !loc.queued { |
| todo = append(todo, loc) |
| loc.queued = true |
| } |
| } |
| |
| for _, loc := range e.allLocs { |
| enqueue(loc) |
| } |
| enqueue(&e.heapLoc) |
| |
| var walkgen uint32 |
| for len(todo) > 0 { |
| root := todo[len(todo)-1] |
| todo = todo[:len(todo)-1] |
| root.queued = false |
| |
| walkgen++ |
| e.walkOne(root, walkgen, enqueue) |
| } |
| } |
| |
| // walkOne computes the minimal number of dereferences from root to |
| // all other locations. |
| func (e *Escape) walkOne(root *EscLocation, walkgen uint32, enqueue func(*EscLocation)) { |
| // The data flow graph has negative edges (from addressing |
| // operations), so we use the Bellman-Ford algorithm. However, |
| // we don't have to worry about infinite negative cycles since |
| // we bound intermediate dereference counts to 0. |
| |
| root.walkgen = walkgen |
| root.derefs = 0 |
| root.dst = nil |
| |
| todo := []*EscLocation{root} // LIFO queue |
| for len(todo) > 0 { |
| l := todo[len(todo)-1] |
| todo = todo[:len(todo)-1] |
| |
| base := l.derefs |
| |
| // If l.derefs < 0, then l's address flows to root. |
| addressOf := base < 0 |
| if addressOf { |
| // For a flow path like "root = &l; l = x", |
| // l's address flows to root, but x's does |
| // not. We recognize this by lower bounding |
| // base at 0. |
| base = 0 |
| |
| // If l's address flows to a non-transient |
| // location, then l can't be transiently |
| // allocated. |
| if !root.transient && l.transient { |
| l.transient = false |
| enqueue(l) |
| } |
| } |
| |
| if e.outlives(root, l) { |
| // l's value flows to root. If l is a function |
| // parameter and root is the heap or a |
| // corresponding result parameter, then record |
| // that value flow for tagging the function |
| // later. |
| if l.isName(PPARAM) { |
| if (logopt.Enabled() || Debug['m'] >= 2) && !l.escapes { |
| if Debug['m'] >= 2 { |
| fmt.Printf("%s: parameter %v leaks to %s with derefs=%d:\n", linestr(l.n.Pos), l.n, e.explainLoc(root), base) |
| } |
| explanation := e.explainPath(root, l) |
| if logopt.Enabled() { |
| logopt.LogOpt(l.n.Pos, "leak", "escape", e.curfn.funcname(), |
| fmt.Sprintf("parameter %v leaks to %s with derefs=%d", l.n, e.explainLoc(root), base), explanation) |
| } |
| } |
| l.leakTo(root, base) |
| } |
| |
| // If l's address flows somewhere that |
| // outlives it, then l needs to be heap |
| // allocated. |
| if addressOf && !l.escapes { |
| if logopt.Enabled() || Debug['m'] >= 2 { |
| if Debug['m'] >= 2 { |
| fmt.Printf("%s: %v escapes to heap:\n", linestr(l.n.Pos), l.n) |
| } |
| explanation := e.explainPath(root, l) |
| if logopt.Enabled() { |
| logopt.LogOpt(l.n.Pos, "escape", "escape", e.curfn.funcname(), fmt.Sprintf("%v escapes to heap", l.n), explanation) |
| } |
| } |
| l.escapes = true |
| enqueue(l) |
| continue |
| } |
| } |
| |
| for i, edge := range l.edges { |
| if edge.src.escapes { |
| continue |
| } |
| derefs := base + edge.derefs |
| if edge.src.walkgen != walkgen || edge.src.derefs > derefs { |
| edge.src.walkgen = walkgen |
| edge.src.derefs = derefs |
| edge.src.dst = l |
| edge.src.dstEdgeIdx = i |
| todo = append(todo, edge.src) |
| } |
| } |
| } |
| } |
| |
| // explainPath prints an explanation of how src flows to the walk root. |
| func (e *Escape) explainPath(root, src *EscLocation) []*logopt.LoggedOpt { |
| visited := make(map[*EscLocation]bool) |
| pos := linestr(src.n.Pos) |
| var explanation []*logopt.LoggedOpt |
| for { |
| // Prevent infinite loop. |
| if visited[src] { |
| if Debug['m'] >= 2 { |
| fmt.Printf("%s: warning: truncated explanation due to assignment cycle; see golang.org/issue/35518\n", pos) |
| } |
| break |
| } |
| visited[src] = true |
| dst := src.dst |
| edge := &dst.edges[src.dstEdgeIdx] |
| if edge.src != src { |
| Fatalf("path inconsistency: %v != %v", edge.src, src) |
| } |
| |
| explanation = e.explainFlow(pos, dst, src, edge.derefs, edge.notes, explanation) |
| |
| if dst == root { |
| break |
| } |
| src = dst |
| } |
| |
| return explanation |
| } |
| |
| func (e *Escape) explainFlow(pos string, dst, srcloc *EscLocation, derefs int, notes *EscNote, explanation []*logopt.LoggedOpt) []*logopt.LoggedOpt { |
| ops := "&" |
| if derefs >= 0 { |
| ops = strings.Repeat("*", derefs) |
| } |
| print := Debug['m'] >= 2 |
| |
| flow := fmt.Sprintf(" flow: %s = %s%v:", e.explainLoc(dst), ops, e.explainLoc(srcloc)) |
| if print { |
| fmt.Printf("%s:%s\n", pos, flow) |
| } |
| if logopt.Enabled() { |
| var epos src.XPos |
| if notes != nil { |
| epos = notes.where.Pos |
| } else if srcloc != nil && srcloc.n != nil { |
| epos = srcloc.n.Pos |
| } |
| explanation = append(explanation, logopt.NewLoggedOpt(epos, "escflow", "escape", e.curfn.funcname(), flow)) |
| } |
| |
| for note := notes; note != nil; note = note.next { |
| if print { |
| fmt.Printf("%s: from %v (%v) at %s\n", pos, note.where, note.why, linestr(note.where.Pos)) |
| } |
| if logopt.Enabled() { |
| explanation = append(explanation, logopt.NewLoggedOpt(note.where.Pos, "escflow", "escape", e.curfn.funcname(), |
| fmt.Sprintf(" from %v (%v)", note.where, note.why))) |
| } |
| } |
| return explanation |
| } |
| |
| func (e *Escape) explainLoc(l *EscLocation) string { |
| if l == &e.heapLoc { |
| return "{heap}" |
| } |
| if l.n == nil { |
| // TODO(mdempsky): Omit entirely. |
| return "{temp}" |
| } |
| if l.n.Op == ONAME { |
| return fmt.Sprintf("%v", l.n) |
| } |
| return fmt.Sprintf("{storage for %v}", l.n) |
| } |
| |
| // outlives reports whether values stored in l may survive beyond |
| // other's lifetime if stack allocated. |
| func (e *Escape) outlives(l, other *EscLocation) bool { |
| // The heap outlives everything. |
| if l.escapes { |
| return true |
| } |
| |
| // We don't know what callers do with returned values, so |
| // pessimistically we need to assume they flow to the heap and |
| // outlive everything too. |
| if l.isName(PPARAMOUT) { |
| // Exception: Directly called closures can return |
| // locations allocated outside of them without forcing |
| // them to the heap. For example: |
| // |
| // var u int // okay to stack allocate |
| // *(func() *int { return &u }()) = 42 |
| if containsClosure(other.curfn, l.curfn) && l.curfn.Func.Closure.Func.Top&ctxCallee != 0 { |
| return false |
| } |
| |
| return true |
| } |
| |
| // If l and other are within the same function, then l |
| // outlives other if it was declared outside other's loop |
| // scope. For example: |
| // |
| // var l *int |
| // for { |
| // l = new(int) |
| // } |
| if l.curfn == other.curfn && l.loopDepth < other.loopDepth { |
| return true |
| } |
| |
| // If other is declared within a child closure of where l is |
| // declared, then l outlives it. For example: |
| // |
| // var l *int |
| // func() { |
| // l = new(int) |
| // } |
| if containsClosure(l.curfn, other.curfn) { |
| return true |
| } |
| |
| return false |
| } |
| |
| // containsClosure reports whether c is a closure contained within f. |
| func containsClosure(f, c *Node) bool { |
| if f.Op != ODCLFUNC || c.Op != ODCLFUNC { |
| Fatalf("bad containsClosure: %v, %v", f, c) |
| } |
| |
| // Common case. |
| if f == c { |
| return false |
| } |
| |
| // Closures within function Foo are named like "Foo.funcN..." |
| // TODO(mdempsky): Better way to recognize this. |
| fn := f.Func.Nname.Sym.Name |
| cn := c.Func.Nname.Sym.Name |
| return len(cn) > len(fn) && cn[:len(fn)] == fn && cn[len(fn)] == '.' |
| } |
| |
| // leak records that parameter l leaks to sink. |
| func (l *EscLocation) leakTo(sink *EscLocation, derefs int) { |
| // If sink is a result parameter and we can fit return bits |
| // into the escape analysis tag, then record a return leak. |
| if sink.isName(PPARAMOUT) && sink.curfn == l.curfn { |
| // TODO(mdempsky): Eliminate dependency on Vargen here. |
| ri := int(sink.n.Name.Vargen) - 1 |
| if ri < numEscResults { |
| // Leak to result parameter. |
| l.paramEsc.AddResult(ri, derefs) |
| return |
| } |
| } |
| |
| // Otherwise, record as heap leak. |
| l.paramEsc.AddHeap(derefs) |
| } |
| |
| func (e *Escape) finish(fns []*Node) { |
| // Record parameter tags for package export data. |
| for _, fn := range fns { |
| fn.Esc = EscFuncTagged |
| |
| narg := 0 |
| for _, fs := range &types.RecvsParams { |
| for _, f := range fs(fn.Type).Fields().Slice() { |
| narg++ |
| f.Note = e.paramTag(fn, narg, f) |
| } |
| } |
| } |
| |
| for _, loc := range e.allLocs { |
| n := loc.n |
| if n == nil { |
| continue |
| } |
| n.SetOpt(nil) |
| |
| // Update n.Esc based on escape analysis results. |
| |
| if loc.escapes { |
| if n.Op != ONAME { |
| if Debug['m'] != 0 { |
| Warnl(n.Pos, "%S escapes to heap", n) |
| } |
| if logopt.Enabled() { |
| logopt.LogOpt(n.Pos, "escape", "escape", e.curfn.funcname()) |
| } |
| } |
| n.Esc = EscHeap |
| addrescapes(n) |
| } else { |
| if Debug['m'] != 0 && n.Op != ONAME { |
| Warnl(n.Pos, "%S does not escape", n) |
| } |
| n.Esc = EscNone |
| if loc.transient { |
| n.SetTransient(true) |
| } |
| } |
| } |
| } |
| |
| func (l *EscLocation) isName(c Class) bool { |
| return l.n != nil && l.n.Op == ONAME && l.n.Class() == c |
| } |
| |
| const numEscResults = 7 |
| |
| // An EscLeaks represents a set of assignment flows from a parameter |
| // to the heap or to any of its function's (first numEscResults) |
| // result parameters. |
| type EscLeaks [1 + numEscResults]uint8 |
| |
| // Empty reports whether l is an empty set (i.e., no assignment flows). |
| func (l EscLeaks) Empty() bool { return l == EscLeaks{} } |
| |
| // Heap returns the minimum deref count of any assignment flow from l |
| // to the heap. If no such flows exist, Heap returns -1. |
| func (l EscLeaks) Heap() int { return l.get(0) } |
| |
| // Result returns the minimum deref count of any assignment flow from |
| // l to its function's i'th result parameter. If no such flows exist, |
| // Result returns -1. |
| func (l EscLeaks) Result(i int) int { return l.get(1 + i) } |
| |
| // AddHeap adds an assignment flow from l to the heap. |
| func (l *EscLeaks) AddHeap(derefs int) { l.add(0, derefs) } |
| |
| // AddResult adds an assignment flow from l to its function's i'th |
| // result parameter. |
| func (l *EscLeaks) AddResult(i, derefs int) { l.add(1+i, derefs) } |
| |
| func (l *EscLeaks) setResult(i, derefs int) { l.set(1+i, derefs) } |
| |
| func (l EscLeaks) get(i int) int { return int(l[i]) - 1 } |
| |
| func (l *EscLeaks) add(i, derefs int) { |
| if old := l.get(i); old < 0 || derefs < old { |
| l.set(i, derefs) |
| } |
| } |
| |
| func (l *EscLeaks) set(i, derefs int) { |
| v := derefs + 1 |
| if v < 0 { |
| Fatalf("invalid derefs count: %v", derefs) |
| } |
| if v > math.MaxUint8 { |
| v = math.MaxUint8 |
| } |
| |
| l[i] = uint8(v) |
| } |
| |
| // Optimize removes result flow paths that are equal in length or |
| // longer than the shortest heap flow path. |
| func (l *EscLeaks) Optimize() { |
| // If we have a path to the heap, then there's no use in |
| // keeping equal or longer paths elsewhere. |
| if x := l.Heap(); x >= 0 { |
| for i := 0; i < numEscResults; i++ { |
| if l.Result(i) >= x { |
| l.setResult(i, -1) |
| } |
| } |
| } |
| } |
| |
| var leakTagCache = map[EscLeaks]string{} |
| |
| // Encode converts l into a binary string for export data. |
| func (l EscLeaks) Encode() string { |
| if l.Heap() == 0 { |
| // Space optimization: empty string encodes more |
| // efficiently in export data. |
| return "" |
| } |
| if s, ok := leakTagCache[l]; ok { |
| return s |
| } |
| |
| n := len(l) |
| for n > 0 && l[n-1] == 0 { |
| n-- |
| } |
| s := "esc:" + string(l[:n]) |
| leakTagCache[l] = s |
| return s |
| } |
| |
| // ParseLeaks parses a binary string representing an EscLeaks. |
| func ParseLeaks(s string) EscLeaks { |
| var l EscLeaks |
| if !strings.HasPrefix(s, "esc:") { |
| l.AddHeap(0) |
| return l |
| } |
| copy(l[:], s[4:]) |
| return l |
| } |