| // 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 gc |
| |
| import ( |
| "fmt" |
| "strconv" |
| "strings" |
| ) |
| |
| // Run analysis on minimal sets of mutually recursive functions |
| // or single non-recursive functions, bottom up. |
| // |
| // Finding these sets is finding strongly connected components |
| // by reverse topological order in the static call graph. |
| // The algorithm (known as Tarjan's algorithm) for doing that is taken from |
| // Sedgewick, Algorithms, Second Edition, p. 482, with two adaptations. |
| // |
| // First, a hidden closure function (n.Func.IsHiddenClosure) cannot be the |
| // root of a connected component. Refusing to use it as a root |
| // forces it into the component of the function in which it appears. |
| // This is more convenient for escape analysis. |
| // |
| // Second, each function becomes two virtual nodes in the graph, |
| // with numbers n and n+1. We record the function's node number as n |
| // but search from node n+1. If the search tells us that the component |
| // number (min) is n+1, we know that this is a trivial component: one function |
| // plus its closures. If the search tells us that the component number is |
| // n, then there was a path from node n+1 back to node n, meaning that |
| // the function set is mutually recursive. The escape analysis can be |
| // more precise when analyzing a single non-recursive function than |
| // when analyzing a set of mutually recursive functions. |
| |
| type bottomUpVisitor struct { |
| analyze func([]*Node, bool) |
| visitgen uint32 |
| nodeID map[*Node]uint32 |
| stack []*Node |
| } |
| |
| // visitBottomUp invokes analyze on the ODCLFUNC nodes listed in list. |
| // It calls analyze with successive groups of functions, working from |
| // the bottom of the call graph upward. Each time analyze is called with |
| // a list of functions, every function on that list only calls other functions |
| // on the list or functions that have been passed in previous invocations of |
| // analyze. Closures appear in the same list as their outer functions. |
| // The lists are as short as possible while preserving those requirements. |
| // (In a typical program, many invocations of analyze will be passed just |
| // a single function.) The boolean argument 'recursive' passed to analyze |
| // specifies whether the functions on the list are mutually recursive. |
| // If recursive is false, the list consists of only a single function and its closures. |
| // If recursive is true, the list may still contain only a single function, |
| // if that function is itself recursive. |
| func visitBottomUp(list []*Node, analyze func(list []*Node, recursive bool)) { |
| var v bottomUpVisitor |
| v.analyze = analyze |
| v.nodeID = make(map[*Node]uint32) |
| for _, n := range list { |
| if n.Op == ODCLFUNC && !n.Func.IsHiddenClosure { |
| v.visit(n) |
| } |
| } |
| } |
| |
| func (v *bottomUpVisitor) visit(n *Node) uint32 { |
| if id := v.nodeID[n]; id > 0 { |
| // already visited |
| return id |
| } |
| |
| v.visitgen++ |
| id := v.visitgen |
| v.nodeID[n] = id |
| v.visitgen++ |
| min := v.visitgen |
| |
| v.stack = append(v.stack, n) |
| min = v.visitcodelist(n.Nbody, min) |
| if (min == id || min == id+1) && !n.Func.IsHiddenClosure { |
| // This node is the root of a strongly connected component. |
| |
| // The original min passed to visitcodelist was v.nodeID[n]+1. |
| // If visitcodelist found its way back to v.nodeID[n], then this |
| // block is a set of mutually recursive functions. |
| // Otherwise it's just a lone function that does not recurse. |
| recursive := min == id |
| |
| // Remove connected component from stack. |
| // Mark walkgen so that future visits return a large number |
| // so as not to affect the caller's min. |
| |
| var i int |
| for i = len(v.stack) - 1; i >= 0; i-- { |
| x := v.stack[i] |
| if x == n { |
| break |
| } |
| v.nodeID[x] = ^uint32(0) |
| } |
| v.nodeID[n] = ^uint32(0) |
| block := v.stack[i:] |
| // Run escape analysis on this set of functions. |
| v.stack = v.stack[:i] |
| v.analyze(block, recursive) |
| } |
| |
| return min |
| } |
| |
| func (v *bottomUpVisitor) visitcodelist(l Nodes, min uint32) uint32 { |
| for _, n := range l.Slice() { |
| min = v.visitcode(n, min) |
| } |
| return min |
| } |
| |
| func (v *bottomUpVisitor) visitcode(n *Node, min uint32) uint32 { |
| if n == nil { |
| return min |
| } |
| |
| min = v.visitcodelist(n.Ninit, min) |
| min = v.visitcode(n.Left, min) |
| min = v.visitcode(n.Right, min) |
| min = v.visitcodelist(n.List, min) |
| min = v.visitcodelist(n.Nbody, min) |
| min = v.visitcodelist(n.Rlist, min) |
| |
| if n.Op == OCALLFUNC || n.Op == OCALLMETH { |
| fn := n.Left |
| if n.Op == OCALLMETH { |
| fn = n.Left.Sym.Def |
| } |
| if fn != nil && fn.Op == ONAME && fn.Class == PFUNC && fn.Name.Defn != nil { |
| m := v.visit(fn.Name.Defn) |
| if m < min { |
| min = m |
| } |
| } |
| } |
| |
| if n.Op == OCLOSURE { |
| m := v.visit(n.Func.Closure) |
| if m < min { |
| min = m |
| } |
| } |
| |
| return min |
| } |
| |
| // Escape analysis. |
| |
| // An escape analysis pass for a set of functions. |
| // The analysis assumes that closures and the functions in which they |
| // appear are analyzed together, so that the aliasing between their |
| // variables can be modeled more precisely. |
| // |
| // First escfunc, esc and escassign recurse over the ast of each |
| // function to dig out flow(dst,src) edges between any |
| // pointer-containing nodes and store them in e.nodeEscState(dst).Flowsrc. For |
| // variables assigned to a variable in an outer scope or used as a |
| // return value, they store a flow(theSink, src) edge to a fake node |
| // 'the Sink'. For variables referenced in closures, an edge |
| // flow(closure, &var) is recorded and the flow of a closure itself to |
| // an outer scope is tracked the same way as other variables. |
| // |
| // Then escflood walks the graph starting at theSink and tags all |
| // variables of it can reach an & node as escaping and all function |
| // parameters it can reach as leaking. |
| // |
| // If a value's address is taken but the address does not escape, |
| // then the value can stay on the stack. If the value new(T) does |
| // not escape, then new(T) can be rewritten into a stack allocation. |
| // The same is true of slice literals. |
| // |
| // If optimizations are disabled (-N), this code is not used. |
| // Instead, the compiler assumes that any value whose address |
| // is taken without being immediately dereferenced |
| // needs to be moved to the heap, and new(T) and slice |
| // literals are always real allocations. |
| |
| func escapes(all []*Node) { |
| visitBottomUp(all, escAnalyze) |
| } |
| |
| const ( |
| EscFuncUnknown = 0 + iota |
| EscFuncPlanned |
| EscFuncStarted |
| EscFuncTagged |
| ) |
| |
| // There appear to be some loops in the escape graph, causing |
| // arbitrary recursion into deeper and deeper levels. |
| // Cut this off safely by making minLevel sticky: once you |
| // get that deep, you cannot go down any further but you also |
| // cannot go up any further. This is a conservative fix. |
| // Making minLevel smaller (more negative) would handle more |
| // complex chains of indirections followed by address-of operations, |
| // at the cost of repeating the traversal once for each additional |
| // allowed level when a loop is encountered. Using -2 suffices to |
| // pass all the tests we have written so far, which we assume matches |
| // the level of complexity we want the escape analysis code to handle. |
| const ( |
| MinLevel = -2 |
| ) |
| |
| // A Level encodes the reference state and context applied to |
| // (stack, heap) allocated memory. |
| // |
| // value is the overall sum of *(1) and &(-1) operations encountered |
| // along a path from a destination (sink, return value) to a source |
| // (allocation, parameter). |
| // |
| // suffixValue is the maximum-copy-started-suffix-level applied to a sink. |
| // For example: |
| // sink = x.left.left --> level=2, x is dereferenced twice and does not escape to sink. |
| // sink = &Node{x} --> level=-1, x is accessible from sink via one "address of" |
| // sink = &Node{&Node{x}} --> level=-2, x is accessible from sink via two "address of" |
| // sink = &Node{&Node{x.left}} --> level=-1, but x is NOT accessible from sink because it was indirected and then copied. |
| // (The copy operations are sometimes implicit in the source code; in this case, |
| // value of x.left was copied into a field of a newly allocated Node) |
| // |
| // There's one of these for each Node, and the integer values |
| // rarely exceed even what can be stored in 4 bits, never mind 8. |
| type Level struct { |
| value, suffixValue int8 |
| } |
| |
| func (l Level) int() int { |
| return int(l.value) |
| } |
| |
| func levelFrom(i int) Level { |
| if i <= MinLevel { |
| return Level{value: MinLevel} |
| } |
| return Level{value: int8(i)} |
| } |
| |
| func satInc8(x int8) int8 { |
| if x == 127 { |
| return 127 |
| } |
| return x + 1 |
| } |
| |
| func min8(a, b int8) int8 { |
| if a < b { |
| return a |
| } |
| return b |
| } |
| |
| func max8(a, b int8) int8 { |
| if a > b { |
| return a |
| } |
| return b |
| } |
| |
| // inc returns the level l + 1, representing the effect of an indirect (*) operation. |
| func (l Level) inc() Level { |
| if l.value <= MinLevel { |
| return Level{value: MinLevel} |
| } |
| return Level{value: satInc8(l.value), suffixValue: satInc8(l.suffixValue)} |
| } |
| |
| // dec returns the level l - 1, representing the effect of an address-of (&) operation. |
| func (l Level) dec() Level { |
| if l.value <= MinLevel { |
| return Level{value: MinLevel} |
| } |
| return Level{value: l.value - 1, suffixValue: l.suffixValue - 1} |
| } |
| |
| // copy returns the level for a copy of a value with level l. |
| func (l Level) copy() Level { |
| return Level{value: l.value, suffixValue: max8(l.suffixValue, 0)} |
| } |
| |
| func (l1 Level) min(l2 Level) Level { |
| return Level{ |
| value: min8(l1.value, l2.value), |
| suffixValue: min8(l1.suffixValue, l2.suffixValue)} |
| } |
| |
| // guaranteedDereference returns the number of dereferences |
| // applied to a pointer before addresses are taken/generated. |
| // This is the maximum level computed from path suffixes starting |
| // with copies where paths flow from destination to source. |
| func (l Level) guaranteedDereference() int { |
| return int(l.suffixValue) |
| } |
| |
| // An EscStep documents one step in the path from memory |
| // that is heap allocated to the (alleged) reason for the |
| // heap allocation. |
| type EscStep struct { |
| src, dst *Node // the endpoints of this edge in the escape-to-heap chain. |
| where *Node // sometimes the endpoints don't match source locations; set 'where' to make that right |
| parent *EscStep // used in flood to record path |
| why string // explanation for this step in the escape-to-heap chain |
| busy bool // used in prevent to snip cycles. |
| } |
| |
| type NodeEscState struct { |
| Curfn *Node |
| Flowsrc []EscStep // flow(this, src) |
| Retval Nodes // on OCALLxxx, list of dummy return values |
| Loopdepth int32 // -1: global, 0: return variables, 1:function top level, increased inside function for every loop or label to mark scopes |
| Level Level |
| Walkgen uint32 |
| Maxextraloopdepth int32 |
| } |
| |
| func (e *EscState) nodeEscState(n *Node) *NodeEscState { |
| if nE, ok := n.Opt().(*NodeEscState); ok { |
| return nE |
| } |
| if n.Opt() != nil { |
| Fatalf("nodeEscState: opt in use (%T)", n.Opt()) |
| } |
| nE := &NodeEscState{ |
| Curfn: Curfn, |
| } |
| n.SetOpt(nE) |
| e.opts = append(e.opts, n) |
| return nE |
| } |
| |
| func (e *EscState) track(n *Node) { |
| if Curfn == nil { |
| Fatalf("EscState.track: Curfn nil") |
| } |
| n.Esc = EscNone // until proven otherwise |
| nE := e.nodeEscState(n) |
| nE.Loopdepth = e.loopdepth |
| e.noesc = append(e.noesc, n) |
| } |
| |
| // Escape constants are numbered in order of increasing "escapiness" |
| // to help make inferences be monotonic. With the exception of |
| // EscNever which is sticky, eX < eY means that eY is more exposed |
| // than eX, and hence replaces it in a conservative analysis. |
| const ( |
| EscUnknown = iota |
| EscNone // Does not escape to heap, result, or parameters. |
| EscReturn // Is returned or reachable from returned. |
| EscHeap // Reachable from the heap |
| EscNever // By construction will not escape. |
| EscBits = 3 |
| EscMask = (1 << EscBits) - 1 |
| EscContentEscapes = 1 << EscBits // value obtained by indirect of parameter escapes to heap |
| EscReturnBits = EscBits + 1 |
| // Node.esc encoding = | escapeReturnEncoding:(width-4) | contentEscapes:1 | escEnum:3 |
| ) |
| |
| // escMax returns the maximum of an existing escape value |
| // (and its additional parameter flow flags) and a new escape type. |
| func escMax(e, etype uint16) uint16 { |
| if e&EscMask >= EscHeap { |
| // normalize |
| if e&^EscMask != 0 { |
| Fatalf("Escape information had unexpected return encoding bits (w/ EscHeap, EscNever), e&EscMask=%v", e&EscMask) |
| } |
| } |
| if e&EscMask > etype { |
| return e |
| } |
| if etype == EscNone || etype == EscReturn { |
| return (e &^ EscMask) | etype |
| } |
| return etype |
| } |
| |
| // For each input parameter to a function, the escapeReturnEncoding describes |
| // how the parameter may leak to the function's outputs. This is currently the |
| // "level" of the leak where level is 0 or larger (negative level means stored into |
| // something whose address is returned -- but that implies stored into the heap, |
| // hence EscHeap, which means that the details are not currently relevant. ) |
| const ( |
| bitsPerOutputInTag = 3 // For each output, the number of bits for a tag |
| bitsMaskForTag = uint16(1<<bitsPerOutputInTag) - 1 // The bit mask to extract a single tag. |
| maxEncodedLevel = int(bitsMaskForTag - 1) // The largest level that can be stored in a tag. |
| ) |
| |
| type EscState struct { |
| // Fake node that all |
| // - return values and output variables |
| // - parameters on imported functions not marked 'safe' |
| // - assignments to global variables |
| // flow to. |
| theSink Node |
| |
| dsts []*Node // all dst nodes |
| loopdepth int32 // for detecting nested loop scopes |
| pdepth int // for debug printing in recursions. |
| dstcount int // diagnostic |
| edgecount int // diagnostic |
| noesc []*Node // list of possible non-escaping nodes, for printing |
| recursive bool // recursive function or group of mutually recursive functions. |
| opts []*Node // nodes with .Opt initialized |
| walkgen uint32 |
| } |
| |
| func newEscState(recursive bool) *EscState { |
| e := new(EscState) |
| e.theSink.Op = ONAME |
| e.theSink.Orig = &e.theSink |
| e.theSink.Class = PEXTERN |
| e.theSink.Sym = lookup(".sink") |
| e.nodeEscState(&e.theSink).Loopdepth = -1 |
| e.recursive = recursive |
| return e |
| } |
| |
| func (e *EscState) stepWalk(dst, src *Node, why string, parent *EscStep) *EscStep { |
| // TODO: keep a cache of these, mark entry/exit in escwalk to avoid allocation |
| // Or perhaps never mind, since it is disabled unless printing is on. |
| // We may want to revisit this, since the EscStep nodes would make |
| // an excellent replacement for the poorly-separated graph-build/graph-flood |
| // stages. |
| if Debug['m'] == 0 { |
| return nil |
| } |
| return &EscStep{src: src, dst: dst, why: why, parent: parent} |
| } |
| |
| func (e *EscState) stepAssign(step *EscStep, dst, src *Node, why string) *EscStep { |
| if Debug['m'] == 0 { |
| return nil |
| } |
| if step != nil { // Caller may have known better. |
| if step.why == "" { |
| step.why = why |
| } |
| if step.dst == nil { |
| step.dst = dst |
| } |
| if step.src == nil { |
| step.src = src |
| } |
| return step |
| } |
| return &EscStep{src: src, dst: dst, why: why} |
| } |
| |
| func (e *EscState) stepAssignWhere(dst, src *Node, why string, where *Node) *EscStep { |
| if Debug['m'] == 0 { |
| return nil |
| } |
| return &EscStep{src: src, dst: dst, why: why, where: where} |
| } |
| |
| // funcSym returns fn.Func.Nname.Sym if no nils are encountered along the way. |
| func funcSym(fn *Node) *Sym { |
| if fn == nil || fn.Func.Nname == nil { |
| return nil |
| } |
| return fn.Func.Nname.Sym |
| } |
| |
| // curfnSym returns n.Curfn.Nname.Sym if no nils are encountered along the way. |
| func (e *EscState) curfnSym(n *Node) *Sym { |
| nE := e.nodeEscState(n) |
| return funcSym(nE.Curfn) |
| } |
| |
| func escAnalyze(all []*Node, recursive bool) { |
| e := newEscState(recursive) |
| |
| for _, n := range all { |
| if n.Op == ODCLFUNC { |
| n.Esc = EscFuncPlanned |
| if Debug['m'] > 3 { |
| Dump("escAnalyze", n) |
| } |
| |
| } |
| } |
| |
| // flow-analyze functions |
| for _, n := range all { |
| if n.Op == ODCLFUNC { |
| e.escfunc(n) |
| } |
| } |
| |
| // print("escapes: %d e.dsts, %d edges\n", e.dstcount, e.edgecount); |
| |
| // visit the upstream of each dst, mark address nodes with |
| // addrescapes, mark parameters unsafe |
| escapes := make([]uint16, len(e.dsts)) |
| for i, n := range e.dsts { |
| escapes[i] = n.Esc |
| } |
| for _, n := range e.dsts { |
| e.escflood(n) |
| } |
| for { |
| done := true |
| for i, n := range e.dsts { |
| if n.Esc != escapes[i] { |
| done = false |
| if Debug['m'] > 2 { |
| Warnl(n.Lineno, "Reflooding %v %S", e.curfnSym(n), n) |
| } |
| escapes[i] = n.Esc |
| e.escflood(n) |
| } |
| } |
| if done { |
| break |
| } |
| } |
| |
| // for all top level functions, tag the typenodes corresponding to the param nodes |
| for _, n := range all { |
| if n.Op == ODCLFUNC { |
| e.esctag(n) |
| } |
| } |
| |
| if Debug['m'] != 0 { |
| for _, n := range e.noesc { |
| if n.Esc == EscNone { |
| Warnl(n.Lineno, "%v %S does not escape", e.curfnSym(n), n) |
| } |
| } |
| } |
| |
| for _, x := range e.opts { |
| x.SetOpt(nil) |
| } |
| } |
| |
| func (e *EscState) escfunc(fn *Node) { |
| // print("escfunc %N %s\n", fn.Func.Nname, e.recursive?"(recursive)":""); |
| if fn.Esc != EscFuncPlanned { |
| Fatalf("repeat escfunc %v", fn.Func.Nname) |
| } |
| fn.Esc = EscFuncStarted |
| |
| saveld := e.loopdepth |
| e.loopdepth = 1 |
| savefn := Curfn |
| Curfn = fn |
| |
| for _, ln := range Curfn.Func.Dcl { |
| if ln.Op != ONAME { |
| continue |
| } |
| lnE := e.nodeEscState(ln) |
| switch ln.Class { |
| // out params are in a loopdepth between the sink and all local variables |
| case PPARAMOUT: |
| lnE.Loopdepth = 0 |
| |
| case PPARAM: |
| lnE.Loopdepth = 1 |
| if ln.Type != nil && !haspointers(ln.Type) { |
| break |
| } |
| if Curfn.Nbody.Len() == 0 && !Curfn.Noescape { |
| ln.Esc = EscHeap |
| } else { |
| ln.Esc = EscNone // prime for escflood later |
| } |
| e.noesc = append(e.noesc, ln) |
| } |
| } |
| |
| // in a mutually recursive group we lose track of the return values |
| if e.recursive { |
| for _, ln := range Curfn.Func.Dcl { |
| if ln.Op == ONAME && ln.Class == PPARAMOUT { |
| e.escflows(&e.theSink, ln, e.stepAssign(nil, ln, ln, "returned from recursive function")) |
| } |
| } |
| } |
| |
| e.escloopdepthlist(Curfn.Nbody) |
| e.esclist(Curfn.Nbody, Curfn) |
| Curfn = savefn |
| e.loopdepth = saveld |
| } |
| |
| // Mark labels that have no backjumps to them as not increasing e.loopdepth. |
| // Walk hasn't generated (goto|label).Left.Sym.Label yet, so we'll cheat |
| // and set it to one of the following two. Then in esc we'll clear it again. |
| var ( |
| looping Node |
| nonlooping Node |
| ) |
| |
| func (e *EscState) escloopdepthlist(l Nodes) { |
| for _, n := range l.Slice() { |
| e.escloopdepth(n) |
| } |
| } |
| |
| func (e *EscState) escloopdepth(n *Node) { |
| if n == nil { |
| return |
| } |
| |
| e.escloopdepthlist(n.Ninit) |
| |
| switch n.Op { |
| case OLABEL: |
| if n.Left == nil || n.Left.Sym == nil { |
| Fatalf("esc:label without label: %+v", n) |
| } |
| |
| // Walk will complain about this label being already defined, but that's not until |
| // after escape analysis. in the future, maybe pull label & goto analysis out of walk and put before esc |
| // if(n.Left.Sym.Label != nil) |
| // fatal("escape analysis messed up analyzing label: %+N", n); |
| n.Left.Sym.Label = &nonlooping |
| |
| case OGOTO: |
| if n.Left == nil || n.Left.Sym == nil { |
| Fatalf("esc:goto without label: %+v", n) |
| } |
| |
| // If we come past one that's uninitialized, this must be a (harmless) forward jump |
| // but if it's set to nonlooping the label must have preceded this goto. |
| if n.Left.Sym.Label == &nonlooping { |
| n.Left.Sym.Label = &looping |
| } |
| } |
| |
| e.escloopdepth(n.Left) |
| e.escloopdepth(n.Right) |
| e.escloopdepthlist(n.List) |
| e.escloopdepthlist(n.Nbody) |
| e.escloopdepthlist(n.Rlist) |
| } |
| |
| func (e *EscState) esclist(l Nodes, parent *Node) { |
| for _, n := range l.Slice() { |
| e.esc(n, parent) |
| } |
| } |
| |
| func (e *EscState) esc(n *Node, parent *Node) { |
| if n == nil { |
| return |
| } |
| |
| lno := setlineno(n) |
| |
| // ninit logically runs at a different loopdepth than the rest of the for loop. |
| e.esclist(n.Ninit, n) |
| |
| if n.Op == OFOR || n.Op == ORANGE { |
| e.loopdepth++ |
| } |
| |
| // type switch variables have no ODCL. |
| // process type switch as declaration. |
| // must happen before processing of switch body, |
| // so before recursion. |
| if n.Op == OSWITCH && n.Left != nil && n.Left.Op == OTYPESW { |
| for _, n1 := range n.List.Slice() { // cases |
| // it.N().Rlist is the variable per case |
| if n1.Rlist.Len() != 0 { |
| e.nodeEscState(n1.Rlist.First()).Loopdepth = e.loopdepth |
| } |
| } |
| } |
| |
| // Big stuff escapes unconditionally |
| // "Big" conditions that were scattered around in walk have been gathered here |
| if n.Esc != EscHeap && n.Type != nil && |
| (n.Type.Width > MaxStackVarSize || |
| (n.Op == ONEW || n.Op == OPTRLIT) && n.Type.Elem().Width >= 1<<16 || |
| n.Op == OMAKESLICE && !isSmallMakeSlice(n)) { |
| if Debug['m'] > 2 { |
| Warnl(n.Lineno, "%v is too large for stack", n) |
| } |
| n.Esc = EscHeap |
| addrescapes(n) |
| e.escassignSinkWhy(n, n, "too large for stack") // TODO category: tooLarge |
| } |
| |
| e.esc(n.Left, n) |
| e.esc(n.Right, n) |
| e.esclist(n.Nbody, n) |
| e.esclist(n.List, n) |
| e.esclist(n.Rlist, n) |
| |
| if n.Op == OFOR || n.Op == ORANGE { |
| e.loopdepth-- |
| } |
| |
| if Debug['m'] > 2 { |
| fmt.Printf("%v:[%d] %v esc: %v\n", linestr(lineno), e.loopdepth, funcSym(Curfn), n) |
| } |
| |
| switch n.Op { |
| // Record loop depth at declaration. |
| case ODCL: |
| if n.Left != nil { |
| e.nodeEscState(n.Left).Loopdepth = e.loopdepth |
| } |
| |
| case OLABEL: |
| if n.Left.Sym.Label == &nonlooping { |
| if Debug['m'] > 2 { |
| fmt.Printf("%v:%v non-looping label\n", linestr(lineno), n) |
| } |
| } else if n.Left.Sym.Label == &looping { |
| if Debug['m'] > 2 { |
| fmt.Printf("%v: %v looping label\n", linestr(lineno), n) |
| } |
| e.loopdepth++ |
| } |
| |
| // See case OLABEL in escloopdepth above |
| // else if(n.Left.Sym.Label == nil) |
| // fatal("escape analysis missed or messed up a label: %+N", n); |
| |
| n.Left.Sym.Label = nil |
| |
| case ORANGE: |
| if n.List.Len() >= 2 { |
| // Everything but fixed array is a dereference. |
| |
| // If fixed array is really the address of fixed array, |
| // it is also a dereference, because it is implicitly |
| // dereferenced (see #12588) |
| if n.Type.IsArray() && |
| !(n.Right.Type.IsPtr() && eqtype(n.Right.Type.Elem(), n.Type)) { |
| e.escassignWhyWhere(n.List.Second(), n.Right, "range", n) |
| } else { |
| e.escassignDereference(n.List.Second(), n.Right, e.stepAssignWhere(n.List.Second(), n.Right, "range-deref", n)) |
| } |
| } |
| |
| case OSWITCH: |
| if n.Left != nil && n.Left.Op == OTYPESW { |
| for _, n2 := range n.List.Slice() { |
| // cases |
| // n.Left.Right is the argument of the .(type), |
| // it.N().Rlist is the variable per case |
| if n2.Rlist.Len() != 0 { |
| e.escassignWhyWhere(n2.Rlist.First(), n.Left.Right, "switch case", n) |
| } |
| } |
| } |
| |
| // Filter out the following special case. |
| // |
| // func (b *Buffer) Foo() { |
| // n, m := ... |
| // b.buf = b.buf[n:m] |
| // } |
| // |
| // This assignment is a no-op for escape analysis, |
| // it does not store any new pointers into b that were not already there. |
| // However, without this special case b will escape, because we assign to OIND/ODOTPTR. |
| case OAS, OASOP, OASWB: |
| if (n.Left.Op == OIND || n.Left.Op == ODOTPTR) && n.Left.Left.Op == ONAME && // dst is ONAME dereference |
| (n.Right.Op == OSLICE || n.Right.Op == OSLICE3 || n.Right.Op == OSLICESTR) && // src is slice operation |
| (n.Right.Left.Op == OIND || n.Right.Left.Op == ODOTPTR) && n.Right.Left.Left.Op == ONAME && // slice is applied to ONAME dereference |
| n.Left.Left == n.Right.Left.Left { // dst and src reference the same base ONAME |
| |
| // Here we also assume that the statement will not contain calls, |
| // that is, that order will move any calls to init. |
| // Otherwise base ONAME value could change between the moments |
| // when we evaluate it for dst and for src. |
| // |
| // Note, this optimization does not apply to OSLICEARR, |
| // because it does introduce a new pointer into b that was not already there |
| // (pointer to b itself). After such assignment, if b contents escape, |
| // b escapes as well. If we ignore such OSLICEARR, we will conclude |
| // that b does not escape when b contents do. |
| if Debug['m'] != 0 { |
| Warnl(n.Lineno, "%v ignoring self-assignment to %S", e.curfnSym(n), n.Left) |
| } |
| |
| break |
| } |
| |
| e.escassign(n.Left, n.Right, e.stepAssignWhere(nil, nil, "", n)) |
| |
| case OAS2: // x,y = a,b |
| if n.List.Len() == n.Rlist.Len() { |
| rs := n.Rlist.Slice() |
| for i, n := range n.List.Slice() { |
| e.escassignWhyWhere(n, rs[i], "assign-pair", n) |
| } |
| } |
| |
| case OAS2RECV: // v, ok = <-ch |
| e.escassignWhyWhere(n.List.First(), n.Rlist.First(), "assign-pair-receive", n) |
| case OAS2MAPR: // v, ok = m[k] |
| e.escassignWhyWhere(n.List.First(), n.Rlist.First(), "assign-pair-mapr", n) |
| case OAS2DOTTYPE: // v, ok = x.(type) |
| e.escassignWhyWhere(n.List.First(), n.Rlist.First(), "assign-pair-dot-type", n) |
| |
| case OSEND: // ch <- x |
| e.escassignSinkWhy(n, n.Right, "send") |
| |
| case ODEFER: |
| if e.loopdepth == 1 { // top level |
| break |
| } |
| // arguments leak out of scope |
| // TODO: leak to a dummy node instead |
| // defer f(x) - f and x escape |
| e.escassignSinkWhy(n, n.Left.Left, "defer func") |
| |
| e.escassignSinkWhy(n, n.Left.Right, "defer func ...") // ODDDARG for call |
| for _, n4 := range n.Left.List.Slice() { |
| e.escassignSinkWhy(n, n4, "defer func arg") |
| } |
| |
| case OPROC: |
| // go f(x) - f and x escape |
| e.escassignSinkWhy(n, n.Left.Left, "go func") |
| |
| e.escassignSinkWhy(n, n.Left.Right, "go func ...") // ODDDARG for call |
| for _, n4 := range n.Left.List.Slice() { |
| e.escassignSinkWhy(n, n4, "go func arg") |
| } |
| |
| case OCALLMETH, OCALLFUNC, OCALLINTER: |
| e.esccall(n, parent) |
| |
| // esccall already done on n.Rlist.First(). tie it's Retval to n.List |
| case OAS2FUNC: // x,y = f() |
| rs := e.nodeEscState(n.Rlist.First()).Retval.Slice() |
| for i, n := range n.List.Slice() { |
| if i >= len(rs) { |
| break |
| } |
| e.escassignWhyWhere(n, rs[i], "assign-pair-func-call", n) |
| } |
| if n.List.Len() != len(rs) { |
| Fatalf("esc oas2func") |
| } |
| |
| case ORETURN: |
| retList := n.List |
| if retList.Len() == 1 && Curfn.Type.Results().NumFields() > 1 { |
| // OAS2FUNC in disguise |
| // esccall already done on n.List.First() |
| // tie e.nodeEscState(n.List.First()).Retval to Curfn.Func.Dcl PPARAMOUT's |
| retList = e.nodeEscState(n.List.First()).Retval |
| } |
| |
| i := 0 |
| for _, lrn := range Curfn.Func.Dcl { |
| if i >= retList.Len() { |
| break |
| } |
| if lrn.Op != ONAME || lrn.Class != PPARAMOUT { |
| continue |
| } |
| e.escassignWhyWhere(lrn, retList.Index(i), "return", n) |
| i++ |
| } |
| |
| if i < retList.Len() { |
| Fatalf("esc return list") |
| } |
| |
| // Argument could leak through recover. |
| case OPANIC: |
| e.escassignSinkWhy(n, n.Left, "panic") |
| |
| case OAPPEND: |
| if !n.Isddd { |
| for _, nn := range n.List.Slice()[1:] { |
| e.escassignSinkWhy(n, nn, "appended to slice") // lose track of assign to dereference |
| } |
| } else { |
| // append(slice1, slice2...) -- slice2 itself does not escape, but contents do. |
| slice2 := n.List.Second() |
| e.escassignDereference(&e.theSink, slice2, e.stepAssignWhere(n, slice2, "appended slice...", n)) // lose track of assign of dereference |
| if Debug['m'] > 3 { |
| Warnl(n.Lineno, "%v special treatment of append(slice1, slice2...) %S", e.curfnSym(n), n) |
| } |
| } |
| e.escassignDereference(&e.theSink, n.List.First(), e.stepAssignWhere(n, n.List.First(), "appendee slice", n)) // The original elements are now leaked, too |
| |
| case OCOPY: |
| e.escassignDereference(&e.theSink, n.Right, e.stepAssignWhere(n, n.Right, "copied slice", n)) // lose track of assign of dereference |
| |
| case OCONV, OCONVNOP: |
| e.escassignWhyWhere(n, n.Left, "converted", n) |
| |
| case OCONVIFACE: |
| e.track(n) |
| e.escassignWhyWhere(n, n.Left, "interface-converted", n) |
| |
| case OARRAYLIT: |
| // Link values to array |
| for _, n2 := range n.List.Slice() { |
| if n2.Op == OKEY { |
| n2 = n2.Right |
| } |
| e.escassign(n, n2, e.stepAssignWhere(n, n2, "array literal element", n)) |
| } |
| |
| case OSLICELIT: |
| // Slice is not leaked until proven otherwise |
| e.track(n) |
| // Link values to slice |
| for _, n2 := range n.List.Slice() { |
| if n2.Op == OKEY { |
| n2 = n2.Right |
| } |
| e.escassign(n, n2, e.stepAssignWhere(n, n2, "slice literal element", n)) |
| } |
| |
| // Link values to struct. |
| case OSTRUCTLIT: |
| for _, n6 := range n.List.Slice() { |
| e.escassignWhyWhere(n, n6.Left, "struct literal element", n) |
| } |
| |
| case OPTRLIT: |
| e.track(n) |
| |
| // Link OSTRUCTLIT to OPTRLIT; if OPTRLIT escapes, OSTRUCTLIT elements do too. |
| e.escassignWhyWhere(n, n.Left, "pointer literal [assign]", n) |
| |
| case OCALLPART: |
| e.track(n) |
| |
| // Contents make it to memory, lose track. |
| e.escassignSinkWhy(n, n.Left, "call part") |
| |
| case OMAPLIT: |
| e.track(n) |
| // Keys and values make it to memory, lose track. |
| for _, n7 := range n.List.Slice() { |
| e.escassignSinkWhy(n, n7.Left, "map literal key") |
| e.escassignSinkWhy(n, n7.Right, "map literal value") |
| } |
| |
| case OCLOSURE: |
| // Link addresses of captured variables to closure. |
| for _, v := range n.Func.Cvars.Slice() { |
| if v.Op == OXXX { // unnamed out argument; see dcl.go:/^funcargs |
| continue |
| } |
| a := v.Name.Defn |
| if !v.Name.Byval { |
| a = nod(OADDR, a, nil) |
| a.Lineno = v.Lineno |
| e.nodeEscState(a).Loopdepth = e.loopdepth |
| a = typecheck(a, Erv) |
| } |
| |
| e.escassignWhyWhere(n, a, "captured by a closure", n) |
| } |
| fallthrough |
| |
| case OMAKECHAN, |
| OMAKEMAP, |
| OMAKESLICE, |
| ONEW, |
| OARRAYRUNESTR, |
| OARRAYBYTESTR, |
| OSTRARRAYRUNE, |
| OSTRARRAYBYTE, |
| ORUNESTR: |
| e.track(n) |
| |
| case OADDSTR: |
| e.track(n) |
| // Arguments of OADDSTR do not escape. |
| |
| case OADDR: |
| // current loop depth is an upper bound on actual loop depth |
| // of addressed value. |
| e.track(n) |
| |
| // for &x, use loop depth of x if known. |
| // it should always be known, but if not, be conservative |
| // and keep the current loop depth. |
| if n.Left.Op == ONAME { |
| switch n.Left.Class { |
| case PAUTO: |
| nE := e.nodeEscState(n) |
| leftE := e.nodeEscState(n.Left) |
| if leftE.Loopdepth != 0 { |
| nE.Loopdepth = leftE.Loopdepth |
| } |
| |
| // PPARAM is loop depth 1 always. |
| // PPARAMOUT is loop depth 0 for writes |
| // but considered loop depth 1 for address-of, |
| // so that writing the address of one result |
| // to another (or the same) result makes the |
| // first result move to the heap. |
| case PPARAM, PPARAMOUT: |
| nE := e.nodeEscState(n) |
| nE.Loopdepth = 1 |
| } |
| } |
| } |
| |
| lineno = lno |
| } |
| |
| // escassignWhyWhere bundles a common case of |
| // escassign(e, dst, src, e.stepAssignWhere(dst, src, reason, where)) |
| func (e *EscState) escassignWhyWhere(dst, src *Node, reason string, where *Node) { |
| var step *EscStep |
| if Debug['m'] != 0 { |
| step = e.stepAssignWhere(dst, src, reason, where) |
| } |
| e.escassign(dst, src, step) |
| } |
| |
| // escassignSinkWhy bundles a common case of |
| // escassign(e, &e.theSink, src, e.stepAssign(nil, dst, src, reason)) |
| func (e *EscState) escassignSinkWhy(dst, src *Node, reason string) { |
| var step *EscStep |
| if Debug['m'] != 0 { |
| step = e.stepAssign(nil, dst, src, reason) |
| } |
| e.escassign(&e.theSink, src, step) |
| } |
| |
| // escassignSinkWhyWhere is escassignSinkWhy but includes a call site |
| // for accurate location reporting. |
| func (e *EscState) escassignSinkWhyWhere(dst, src *Node, reason string, call *Node) { |
| var step *EscStep |
| if Debug['m'] != 0 { |
| step = e.stepAssignWhere(dst, src, reason, call) |
| } |
| e.escassign(&e.theSink, src, step) |
| } |
| |
| // Assert that expr somehow gets assigned to dst, if non nil. for |
| // dst==nil, any name node expr still must be marked as being |
| // evaluated in curfn. For expr==nil, dst must still be examined for |
| // evaluations inside it (e.g *f(x) = y) |
| func (e *EscState) escassign(dst, src *Node, step *EscStep) { |
| if isblank(dst) || dst == nil || src == nil || src.Op == ONONAME || src.Op == OXXX { |
| return |
| } |
| |
| if Debug['m'] > 2 { |
| fmt.Printf("%v:[%d] %v escassign: %S(%0j)[%v] = %S(%0j)[%v]\n", |
| linestr(lineno), e.loopdepth, funcSym(Curfn), |
| dst, dst, dst.Op, |
| src, src, src.Op) |
| } |
| |
| setlineno(dst) |
| |
| originalDst := dst |
| dstwhy := "assigned" |
| |
| // Analyze lhs of assignment. |
| // Replace dst with &e.theSink if we can't track it. |
| switch dst.Op { |
| default: |
| Dump("dst", dst) |
| Fatalf("escassign: unexpected dst") |
| |
| case OARRAYLIT, |
| OSLICELIT, |
| OCLOSURE, |
| OCONV, |
| OCONVIFACE, |
| OCONVNOP, |
| OMAPLIT, |
| OSTRUCTLIT, |
| OPTRLIT, |
| ODDDARG, |
| OCALLPART: |
| |
| case ONAME: |
| if dst.Class == PEXTERN { |
| dstwhy = "assigned to top level variable" |
| dst = &e.theSink |
| } |
| |
| case ODOT: // treat "dst.x = src" as "dst = src" |
| e.escassign(dst.Left, src, e.stepAssign(step, originalDst, src, "dot-equals")) |
| return |
| |
| case OINDEX: |
| if dst.Left.Type.IsArray() { |
| e.escassign(dst.Left, src, e.stepAssign(step, originalDst, src, "array-element-equals")) |
| return |
| } |
| |
| dstwhy = "slice-element-equals" |
| dst = &e.theSink // lose track of dereference |
| |
| case OIND: |
| dstwhy = "star-equals" |
| dst = &e.theSink // lose track of dereference |
| |
| case ODOTPTR: |
| dstwhy = "star-dot-equals" |
| dst = &e.theSink // lose track of dereference |
| |
| // lose track of key and value |
| case OINDEXMAP: |
| e.escassign(&e.theSink, dst.Right, e.stepAssign(nil, originalDst, src, "key of map put")) |
| dstwhy = "value of map put" |
| dst = &e.theSink |
| } |
| |
| lno := setlineno(src) |
| e.pdepth++ |
| |
| switch src.Op { |
| case OADDR, // dst = &x |
| OIND, // dst = *x |
| ODOTPTR, // dst = (*x).f |
| ONAME, |
| ODDDARG, |
| OPTRLIT, |
| OARRAYLIT, |
| OSLICELIT, |
| OMAPLIT, |
| OSTRUCTLIT, |
| OMAKECHAN, |
| OMAKEMAP, |
| OMAKESLICE, |
| OARRAYRUNESTR, |
| OARRAYBYTESTR, |
| OSTRARRAYRUNE, |
| OSTRARRAYBYTE, |
| OADDSTR, |
| ONEW, |
| OCALLPART, |
| ORUNESTR, |
| OCONVIFACE: |
| e.escflows(dst, src, e.stepAssign(step, originalDst, src, dstwhy)) |
| |
| case OCLOSURE: |
| // OCLOSURE is lowered to OPTRLIT, |
| // insert OADDR to account for the additional indirection. |
| a := nod(OADDR, src, nil) |
| a.Lineno = src.Lineno |
| e.nodeEscState(a).Loopdepth = e.nodeEscState(src).Loopdepth |
| a.Type = ptrto(src.Type) |
| e.escflows(dst, a, e.stepAssign(nil, originalDst, src, dstwhy)) |
| |
| // Flowing multiple returns to a single dst happens when |
| // analyzing "go f(g())": here g() flows to sink (issue 4529). |
| case OCALLMETH, OCALLFUNC, OCALLINTER: |
| for _, n := range e.nodeEscState(src).Retval.Slice() { |
| e.escflows(dst, n, e.stepAssign(nil, originalDst, n, dstwhy)) |
| } |
| |
| // A non-pointer escaping from a struct does not concern us. |
| case ODOT: |
| if src.Type != nil && !haspointers(src.Type) { |
| break |
| } |
| fallthrough |
| |
| // Conversions, field access, slice all preserve the input value. |
| case OCONV, |
| OCONVNOP, |
| ODOTMETH, |
| // treat recv.meth as a value with recv in it, only happens in ODEFER and OPROC |
| // iface.method already leaks iface in esccall, no need to put in extra ODOTINTER edge here |
| OSLICE, |
| OSLICE3, |
| OSLICEARR, |
| OSLICE3ARR, |
| OSLICESTR: |
| // Conversions, field access, slice all preserve the input value. |
| e.escassign(dst, src.Left, e.stepAssign(step, originalDst, src, dstwhy)) |
| |
| case ODOTTYPE, |
| ODOTTYPE2: |
| if src.Type != nil && !haspointers(src.Type) { |
| break |
| } |
| e.escassign(dst, src.Left, e.stepAssign(step, originalDst, src, dstwhy)) |
| |
| case OAPPEND: |
| // Append returns first argument. |
| // Subsequent arguments are already leaked because they are operands to append. |
| e.escassign(dst, src.List.First(), e.stepAssign(step, dst, src.List.First(), dstwhy)) |
| |
| case OINDEX: |
| // Index of array preserves input value. |
| if src.Left.Type.IsArray() { |
| e.escassign(dst, src.Left, e.stepAssign(step, originalDst, src, dstwhy)) |
| } else { |
| e.escflows(dst, src, e.stepAssign(step, originalDst, src, dstwhy)) |
| } |
| |
| // Might be pointer arithmetic, in which case |
| // the operands flow into the result. |
| // TODO(rsc): Decide what the story is here. This is unsettling. |
| case OADD, |
| OSUB, |
| OOR, |
| OXOR, |
| OMUL, |
| ODIV, |
| OMOD, |
| OLSH, |
| ORSH, |
| OAND, |
| OANDNOT, |
| OPLUS, |
| OMINUS, |
| OCOM: |
| e.escassign(dst, src.Left, e.stepAssign(step, originalDst, src, dstwhy)) |
| |
| e.escassign(dst, src.Right, e.stepAssign(step, originalDst, src, dstwhy)) |
| } |
| |
| e.pdepth-- |
| lineno = lno |
| } |
| |
| // Common case for escapes is 16 bits 000000000xxxEEEE |
| // where commonest cases for xxx encoding in-to-out pointer |
| // flow are 000, 001, 010, 011 and EEEE is computed Esc bits. |
| // Note width of xxx depends on value of constant |
| // bitsPerOutputInTag -- expect 2 or 3, so in practice the |
| // tag cache array is 64 or 128 long. Some entries will |
| // never be populated. |
| var tags [1 << (bitsPerOutputInTag + EscReturnBits)]string |
| |
| // mktag returns the string representation for an escape analysis tag. |
| func mktag(mask int) string { |
| switch mask & EscMask { |
| case EscNone, EscReturn: |
| default: |
| Fatalf("escape mktag") |
| } |
| |
| if mask < len(tags) && tags[mask] != "" { |
| return tags[mask] |
| } |
| |
| s := fmt.Sprintf("esc:0x%x", mask) |
| if mask < len(tags) { |
| tags[mask] = s |
| } |
| return s |
| } |
| |
| // parsetag decodes an escape analysis tag and returns the esc value. |
| func parsetag(note string) uint16 { |
| if !strings.HasPrefix(note, "esc:") { |
| return EscUnknown |
| } |
| n, _ := strconv.ParseInt(note[4:], 0, 0) |
| em := uint16(n) |
| if em == 0 { |
| return EscNone |
| } |
| return em |
| } |
| |
| // describeEscape returns a string describing the escape tag. |
| // The result is either one of {EscUnknown, EscNone, EscHeap} which all have no further annotation |
| // or a description of parameter flow, which takes the form of an optional "contentToHeap" |
| // indicating that the content of this parameter is leaked to the heap, followed by a sequence |
| // of level encodings separated by spaces, one for each parameter, where _ means no flow, |
| // = means direct flow, and N asterisks (*) encodes content (obtained by indirection) flow. |
| // e.g., "contentToHeap _ =" means that a parameter's content (one or more dereferences) |
| // escapes to the heap, the parameter does not leak to the first output, but does leak directly |
| // to the second output (and if there are more than two outputs, there is no flow to those.) |
| func describeEscape(em uint16) string { |
| var s string |
| if em&EscMask == EscUnknown { |
| s = "EscUnknown" |
| } |
| if em&EscMask == EscNone { |
| s = "EscNone" |
| } |
| if em&EscMask == EscHeap { |
| s = "EscHeap" |
| } |
| if em&EscMask == EscReturn { |
| s = "EscReturn" |
| } |
| if em&EscContentEscapes != 0 { |
| if s != "" { |
| s += " " |
| } |
| s += "contentToHeap" |
| } |
| for em >>= EscReturnBits; em != 0; em = em >> bitsPerOutputInTag { |
| // See encoding description above |
| if s != "" { |
| s += " " |
| } |
| switch embits := em & bitsMaskForTag; embits { |
| case 0: |
| s += "_" |
| case 1: |
| s += "=" |
| default: |
| for i := uint16(0); i < embits-1; i++ { |
| s += "*" |
| } |
| } |
| |
| } |
| return s |
| } |
| |
| // escassignfromtag models the input-to-output assignment flow of one of a function |
| // calls arguments, where the flow is encoded in "note". |
| func (e *EscState) escassignfromtag(note string, dsts Nodes, src, call *Node) uint16 { |
| em := parsetag(note) |
| if src.Op == OLITERAL { |
| return em |
| } |
| |
| if Debug['m'] > 3 { |
| fmt.Printf("%v::assignfromtag:: src=%S, em=%s\n", |
| linestr(lineno), src, describeEscape(em)) |
| } |
| |
| if em == EscUnknown { |
| e.escassignSinkWhyWhere(src, src, "passed to call[argument escapes]", call) |
| return em |
| } |
| |
| if em == EscNone { |
| return em |
| } |
| |
| // If content inside parameter (reached via indirection) |
| // escapes to heap, mark as such. |
| if em&EscContentEscapes != 0 { |
| e.escassign(&e.theSink, e.addDereference(src), e.stepAssignWhere(src, src, "passed to call[argument content escapes]", call)) |
| } |
| |
| em0 := em |
| dstsi := 0 |
| for em >>= EscReturnBits; em != 0 && dstsi < dsts.Len(); em = em >> bitsPerOutputInTag { |
| // Prefer the lowest-level path to the reference (for escape purposes). |
| // Two-bit encoding (for example. 1, 3, and 4 bits are other options) |
| // 01 = 0-level |
| // 10 = 1-level, (content escapes), |
| // 11 = 2-level, (content of content escapes), |
| embits := em & bitsMaskForTag |
| if embits > 0 { |
| n := src |
| for i := uint16(0); i < embits-1; i++ { |
| n = e.addDereference(n) // encode level>0 as indirections |
| } |
| e.escassign(dsts.Index(dstsi), n, e.stepAssignWhere(dsts.Index(dstsi), src, "passed-to-and-returned-from-call", call)) |
| } |
| dstsi++ |
| } |
| // If there are too many outputs to fit in the tag, |
| // that is handled at the encoding end as EscHeap, |
| // so there is no need to check here. |
| |
| if em != 0 && dstsi >= dsts.Len() { |
| Fatalf("corrupt esc tag %q or messed up escretval list\n", note) |
| } |
| return em0 |
| } |
| |
| func (e *EscState) escassignDereference(dst *Node, src *Node, step *EscStep) { |
| if src.Op == OLITERAL { |
| return |
| } |
| e.escassign(dst, e.addDereference(src), step) |
| } |
| |
| // addDereference constructs a suitable OIND note applied to src. |
| // Because this is for purposes of escape accounting, not execution, |
| // some semantically dubious node combinations are (currently) possible. |
| func (e *EscState) addDereference(n *Node) *Node { |
| ind := nod(OIND, n, nil) |
| e.nodeEscState(ind).Loopdepth = e.nodeEscState(n).Loopdepth |
| ind.Lineno = n.Lineno |
| t := n.Type |
| if t.IsKind(Tptr) { |
| // This should model our own sloppy use of OIND to encode |
| // decreasing levels of indirection; i.e., "indirecting" an array |
| // might yield the type of an element. To be enhanced... |
| t = t.Elem() |
| } |
| ind.Type = t |
| return ind |
| } |
| |
| // escNoteOutputParamFlow encodes maxEncodedLevel/.../1/0-level flow to the vargen'th parameter. |
| // Levels greater than maxEncodedLevel are replaced with maxEncodedLevel. |
| // If the encoding cannot describe the modified input level and output number, then EscHeap is returned. |
| func escNoteOutputParamFlow(e uint16, vargen int32, level Level) uint16 { |
| // Flow+level is encoded in two bits. |
| // 00 = not flow, xx = level+1 for 0 <= level <= maxEncodedLevel |
| // 16 bits for Esc allows 6x2bits or 4x3bits or 3x4bits if additional information would be useful. |
| if level.int() <= 0 && level.guaranteedDereference() > 0 { |
| return escMax(e|EscContentEscapes, EscNone) // At least one deref, thus only content. |
| } |
| if level.int() < 0 { |
| return EscHeap |
| } |
| if level.int() > maxEncodedLevel { |
| // Cannot encode larger values than maxEncodedLevel. |
| level = levelFrom(maxEncodedLevel) |
| } |
| encoded := uint16(level.int() + 1) |
| |
| shift := uint(bitsPerOutputInTag*(vargen-1) + EscReturnBits) |
| old := (e >> shift) & bitsMaskForTag |
| if old == 0 || encoded != 0 && encoded < old { |
| old = encoded |
| } |
| |
| encodedFlow := old << shift |
| if (encodedFlow>>shift)&bitsMaskForTag != old { |
| // Encoding failure defaults to heap. |
| return EscHeap |
| } |
| |
| return (e &^ (bitsMaskForTag << shift)) | encodedFlow |
| } |
| |
| func (e *EscState) initEscRetval(call *Node, fntype *Type) { |
| cE := e.nodeEscState(call) |
| cE.Retval.Set(nil) // Suspect this is not nil for indirect calls. |
| for i, f := range fntype.Results().Fields().Slice() { |
| ret := nod(ONAME, nil, nil) |
| buf := fmt.Sprintf(".out%d", i) |
| ret.Sym = lookup(buf) |
| ret.Type = f.Type |
| ret.Class = PAUTO |
| ret.Name.Curfn = Curfn |
| e.nodeEscState(ret).Loopdepth = e.loopdepth |
| ret.Used = true |
| ret.Lineno = call.Lineno |
| cE.Retval.Append(ret) |
| } |
| } |
| |
| // This is a bit messier than fortunate, pulled out of esc's big |
| // switch for clarity. We either have the paramnodes, which may be |
| // connected to other things through flows or we have the parameter type |
| // nodes, which may be marked "noescape". Navigating the ast is slightly |
| // different for methods vs plain functions and for imported vs |
| // this-package |
| func (e *EscState) esccall(call *Node, parent *Node) { |
| var fntype *Type |
| var indirect bool |
| var fn *Node |
| switch call.Op { |
| default: |
| Fatalf("esccall") |
| |
| case OCALLFUNC: |
| fn = call.Left |
| fntype = fn.Type |
| indirect = fn.Op != ONAME || fn.Class != PFUNC |
| |
| case OCALLMETH: |
| fn = call.Left.Sym.Def |
| if fn != nil { |
| fntype = fn.Type |
| } else { |
| fntype = call.Left.Type |
| } |
| |
| case OCALLINTER: |
| fntype = call.Left.Type |
| indirect = true |
| } |
| |
| argList := call.List |
| if argList.Len() == 1 { |
| arg := argList.First() |
| if arg.Type.IsFuncArgStruct() { // f(g()) |
| argList = e.nodeEscState(arg).Retval |
| } |
| } |
| |
| args := argList.Slice() |
| |
| if indirect { |
| // We know nothing! |
| // Leak all the parameters |
| for _, arg := range args { |
| e.escassignSinkWhy(call, arg, "parameter to indirect call") |
| if Debug['m'] > 3 { |
| fmt.Printf("%v::esccall:: indirect call <- %S, untracked\n", linestr(lineno), arg) |
| } |
| } |
| // Set up bogus outputs |
| e.initEscRetval(call, fntype) |
| // If there is a receiver, it also leaks to heap. |
| if call.Op != OCALLFUNC { |
| rf := fntype.Recv() |
| r := call.Left.Left |
| if haspointers(rf.Type) { |
| e.escassignSinkWhy(call, r, "receiver in indirect call") |
| } |
| } else { // indirect and OCALLFUNC = could be captured variables, too. (#14409) |
| rets := e.nodeEscState(call).Retval.Slice() |
| for _, ret := range rets { |
| e.escassignDereference(ret, fn, e.stepAssignWhere(ret, fn, "captured by called closure", call)) |
| } |
| } |
| return |
| } |
| |
| cE := e.nodeEscState(call) |
| if fn != nil && fn.Op == ONAME && fn.Class == PFUNC && |
| fn.Name.Defn != nil && fn.Name.Defn.Nbody.Len() != 0 && fn.Name.Param.Ntype != nil && fn.Name.Defn.Esc < EscFuncTagged { |
| if Debug['m'] > 3 { |
| fmt.Printf("%v::esccall:: %S in recursive group\n", linestr(lineno), call) |
| } |
| |
| // function in same mutually recursive group. Incorporate into flow graph. |
| // print("esc local fn: %N\n", fn.Func.Ntype); |
| if fn.Name.Defn.Esc == EscFuncUnknown || cE.Retval.Len() != 0 { |
| Fatalf("graph inconsistency") |
| } |
| |
| sawRcvr := false |
| for _, n := range fn.Name.Defn.Func.Dcl { |
| switch n.Class { |
| case PPARAM: |
| if call.Op != OCALLFUNC && !sawRcvr { |
| e.escassignWhyWhere(n, call.Left.Left, "call receiver", call) |
| sawRcvr = true |
| continue |
| } |
| if len(args) == 0 { |
| continue |
| } |
| arg := args[0] |
| if n.Isddd && !call.Isddd { |
| // Introduce ODDDARG node to represent ... allocation. |
| arg = nod(ODDDARG, nil, nil) |
| arr := typArray(n.Type.Elem(), int64(len(args))) |
| arg.Type = ptrto(arr) // make pointer so it will be tracked |
| arg.Lineno = call.Lineno |
| e.track(arg) |
| call.Right = arg |
| } |
| e.escassignWhyWhere(n, arg, "arg to recursive call", call) // TODO this message needs help. |
| if arg != args[0] { |
| // "..." arguments are untracked |
| for _, a := range args { |
| if Debug['m'] > 3 { |
| fmt.Printf("%v::esccall:: ... <- %S, untracked\n", linestr(lineno), a) |
| } |
| e.escassignSinkWhyWhere(arg, a, "... arg to recursive call", call) |
| } |
| // No more PPARAM processing, but keep |
| // going for PPARAMOUT. |
| args = nil |
| continue |
| } |
| args = args[1:] |
| |
| case PPARAMOUT: |
| cE.Retval.Append(n) |
| } |
| } |
| |
| return |
| } |
| |
| // Imported or completely analyzed function. Use the escape tags. |
| if cE.Retval.Len() != 0 { |
| Fatalf("esc already decorated call %+v\n", call) |
| } |
| |
| if Debug['m'] > 3 { |
| fmt.Printf("%v::esccall:: %S not recursive\n", linestr(lineno), call) |
| } |
| |
| // set up out list on this call node with dummy auto ONAMES in the current (calling) function. |
| e.initEscRetval(call, fntype) |
| |
| // print("esc analyzed fn: %#N (%+T) returning (%+H)\n", fn, fntype, e.nodeEscState(call).Retval); |
| |
| // Receiver. |
| if call.Op != OCALLFUNC { |
| rf := fntype.Recv() |
| r := call.Left.Left |
| if haspointers(rf.Type) { |
| e.escassignfromtag(rf.Note, cE.Retval, r, call) |
| } |
| } |
| |
| var arg *Node |
| var note string |
| param, it := iterFields(fntype.Params()) |
| i := 0 |
| for ; i < len(args); i++ { |
| arg = args[i] |
| note = param.Note |
| if param.Isddd && !call.Isddd { |
| // Introduce ODDDARG node to represent ... allocation. |
| arg = nod(ODDDARG, nil, nil) |
| arg.Lineno = call.Lineno |
| arr := typArray(param.Type.Elem(), int64(len(args)-i)) |
| arg.Type = ptrto(arr) // make pointer so it will be tracked |
| e.track(arg) |
| call.Right = arg |
| } |
| |
| if haspointers(param.Type) { |
| if e.escassignfromtag(note, cE.Retval, arg, call)&EscMask == EscNone && parent.Op != ODEFER && parent.Op != OPROC { |
| a := arg |
| for a.Op == OCONVNOP { |
| a = a.Left |
| } |
| switch a.Op { |
| // The callee has already been analyzed, so its arguments have esc tags. |
| // The argument is marked as not escaping at all. |
| // Record that fact so that any temporary used for |
| // synthesizing this expression can be reclaimed when |
| // the function returns. |
| // This 'noescape' is even stronger than the usual esc == EscNone. |
| // arg.Esc == EscNone means that arg does not escape the current function. |
| // arg.Noescape = true here means that arg does not escape this statement |
| // in the current function. |
| case OCALLPART, |
| OCLOSURE, |
| ODDDARG, |
| OARRAYLIT, |
| OSLICELIT, |
| OPTRLIT, |
| OSTRUCTLIT: |
| a.Noescape = true |
| } |
| } |
| } |
| |
| if arg != args[i] { |
| // This occurs when function parameter field Isddd and call not Isddd |
| break |
| } |
| |
| if note == uintptrEscapesTag { |
| e.escassignSinkWhy(arg, arg, "escaping uintptr") |
| } |
| |
| param = it.Next() |
| } |
| |
| // Store arguments into slice for ... arg. |
| for ; i < len(args); i++ { |
| if Debug['m'] > 3 { |
| fmt.Printf("%v::esccall:: ... <- %S\n", linestr(lineno), args[i]) |
| } |
| if note == uintptrEscapesTag { |
| e.escassignSinkWhyWhere(arg, args[i], "arg to uintptrescapes ...", call) |
| } else { |
| e.escassignWhyWhere(arg, args[i], "arg to ...", call) |
| } |
| } |
| } |
| |
| // escflows records the link src->dst in dst, throwing out some quick wins, |
| // and also ensuring that dst is noted as a flow destination. |
| func (e *EscState) escflows(dst, src *Node, why *EscStep) { |
| if dst == nil || src == nil || dst == src { |
| return |
| } |
| |
| // Don't bother building a graph for scalars. |
| if src.Type != nil && !haspointers(src.Type) && !isReflectHeaderDataField(src) { |
| if Debug['m'] > 3 { |
| fmt.Printf("%v::NOT flows:: %S <- %S\n", linestr(lineno), dst, src) |
| } |
| return |
| } |
| |
| if Debug['m'] > 3 { |
| fmt.Printf("%v::flows:: %S <- %S\n", linestr(lineno), dst, src) |
| } |
| |
| dstE := e.nodeEscState(dst) |
| if len(dstE.Flowsrc) == 0 { |
| e.dsts = append(e.dsts, dst) |
| e.dstcount++ |
| } |
| |
| e.edgecount++ |
| |
| if why == nil { |
| dstE.Flowsrc = append(dstE.Flowsrc, EscStep{src: src}) |
| } else { |
| starwhy := *why |
| starwhy.src = src // TODO: need to reconcile this w/ needs of explanations. |
| dstE.Flowsrc = append(dstE.Flowsrc, starwhy) |
| } |
| } |
| |
| // Whenever we hit a reference node, the level goes up by one, and whenever |
| // we hit an OADDR, the level goes down by one. as long as we're on a level > 0 |
| // finding an OADDR just means we're following the upstream of a dereference, |
| // so this address doesn't leak (yet). |
| // If level == 0, it means the /value/ of this node can reach the root of this flood. |
| // so if this node is an OADDR, its argument should be marked as escaping iff |
| // its currfn/e.loopdepth are different from the flood's root. |
| // Once an object has been moved to the heap, all of its upstream should be considered |
| // escaping to the global scope. |
| func (e *EscState) escflood(dst *Node) { |
| switch dst.Op { |
| case ONAME, OCLOSURE: |
| default: |
| return |
| } |
| |
| dstE := e.nodeEscState(dst) |
| if Debug['m'] > 2 { |
| fmt.Printf("\nescflood:%d: dst %S scope:%v[%d]\n", e.walkgen, dst, e.curfnSym(dst), dstE.Loopdepth) |
| } |
| |
| for i := range dstE.Flowsrc { |
| e.walkgen++ |
| s := &dstE.Flowsrc[i] |
| s.parent = nil |
| e.escwalk(levelFrom(0), dst, s.src, s) |
| } |
| } |
| |
| // funcOutputAndInput reports whether dst and src correspond to output and input parameters of the same function. |
| func funcOutputAndInput(dst, src *Node) bool { |
| // Note if dst is marked as escaping, then "returned" is too weak. |
| return dst.Op == ONAME && dst.Class == PPARAMOUT && |
| src.Op == ONAME && src.Class == PPARAM && src.Name.Curfn == dst.Name.Curfn |
| } |
| |
| func (es *EscStep) describe(src *Node) { |
| if Debug['m'] < 2 { |
| return |
| } |
| step0 := es |
| for step := step0; step != nil && !step.busy; step = step.parent { |
| // TODO: We get cycles. Trigger is i = &i (where var i interface{}) |
| step.busy = true |
| // The trail is a little odd because of how the |
| // graph is constructed. The link to the current |
| // Node is parent.src unless parent is nil in which |
| // case it is step.dst. |
| nextDest := step.parent |
| dst := step.dst |
| where := step.where |
| if nextDest != nil { |
| dst = nextDest.src |
| } |
| if where == nil { |
| where = dst |
| } |
| Warnl(src.Lineno, "\tfrom %v (%s) at %s", dst, step.why, where.Line()) |
| } |
| for step := step0; step != nil && step.busy; step = step.parent { |
| step.busy = false |
| } |
| } |
| |
| const NOTALOOPDEPTH = -1 |
| |
| func (e *EscState) escwalk(level Level, dst *Node, src *Node, step *EscStep) { |
| e.escwalkBody(level, dst, src, step, NOTALOOPDEPTH) |
| } |
| |
| func (e *EscState) escwalkBody(level Level, dst *Node, src *Node, step *EscStep, extraloopdepth int32) { |
| if src.Op == OLITERAL { |
| return |
| } |
| srcE := e.nodeEscState(src) |
| if srcE.Walkgen == e.walkgen { |
| // Esclevels are vectors, do not compare as integers, |
| // and must use "min" of old and new to guarantee |
| // convergence. |
| level = level.min(srcE.Level) |
| if level == srcE.Level { |
| // Have we been here already with an extraloopdepth, |
| // or is the extraloopdepth provided no improvement on |
| // what's already been seen? |
| if srcE.Maxextraloopdepth >= extraloopdepth || srcE.Loopdepth >= extraloopdepth { |
| return |
| } |
| srcE.Maxextraloopdepth = extraloopdepth |
| } |
| } else { // srcE.Walkgen < e.walkgen -- first time, reset this. |
| srcE.Maxextraloopdepth = NOTALOOPDEPTH |
| } |
| |
| srcE.Walkgen = e.walkgen |
| srcE.Level = level |
| modSrcLoopdepth := srcE.Loopdepth |
| |
| if extraloopdepth > modSrcLoopdepth { |
| modSrcLoopdepth = extraloopdepth |
| } |
| |
| if Debug['m'] > 2 { |
| fmt.Printf("escwalk: level:%d depth:%d %.*s op=%v %S(%0j) scope:%v[%d] extraloopdepth=%v\n", |
| level, e.pdepth, e.pdepth, "\t\t\t\t\t\t\t\t\t\t", src.Op, src, src, e.curfnSym(src), srcE.Loopdepth, extraloopdepth) |
| } |
| |
| e.pdepth++ |
| |
| // Input parameter flowing to output parameter? |
| var leaks bool |
| var osrcesc uint16 // used to prevent duplicate error messages |
| |
| dstE := e.nodeEscState(dst) |
| if funcOutputAndInput(dst, src) && src.Esc&EscMask < EscHeap && dst.Esc != EscHeap { |
| // This case handles: |
| // 1. return in |
| // 2. return &in |
| // 3. tmp := in; return &tmp |
| // 4. return *in |
| if Debug['m'] != 0 { |
| if Debug['m'] <= 2 { |
| Warnl(src.Lineno, "leaking param: %S to result %v level=%v", src, dst.Sym, level.int()) |
| step.describe(src) |
| } else { |
| Warnl(src.Lineno, "leaking param: %S to result %v level=%v", src, dst.Sym, level) |
| } |
| } |
| if src.Esc&EscMask != EscReturn { |
| src.Esc = EscReturn | src.Esc&EscContentEscapes |
| } |
| src.Esc = escNoteOutputParamFlow(src.Esc, dst.Name.Vargen, level) |
| goto recurse |
| } |
| |
| // If parameter content escapes to heap, set EscContentEscapes |
| // Note minor confusion around escape from pointer-to-struct vs escape from struct |
| if dst.Esc == EscHeap && |
| src.Op == ONAME && src.Class == PPARAM && src.Esc&EscMask < EscHeap && |
| level.int() > 0 { |
| src.Esc = escMax(EscContentEscapes|src.Esc, EscNone) |
| if Debug['m'] != 0 { |
| Warnl(src.Lineno, "mark escaped content: %S", src) |
| step.describe(src) |
| } |
| } |
| |
| leaks = level.int() <= 0 && level.guaranteedDereference() <= 0 && dstE.Loopdepth < modSrcLoopdepth |
| leaks = leaks || level.int() <= 0 && dst.Esc&EscMask == EscHeap |
| |
| osrcesc = src.Esc |
| switch src.Op { |
| case ONAME: |
| if src.Class == PPARAM && (leaks || dstE.Loopdepth < 0) && src.Esc&EscMask < EscHeap { |
| if level.guaranteedDereference() > 0 { |
| src.Esc = escMax(EscContentEscapes|src.Esc, EscNone) |
| if Debug['m'] != 0 { |
| if Debug['m'] <= 2 { |
| if osrcesc != src.Esc { |
| Warnl(src.Lineno, "leaking param content: %S", src) |
| step.describe(src) |
| } |
| } else { |
| Warnl(src.Lineno, "leaking param content: %S level=%v dst.eld=%v src.eld=%v dst=%S", |
| src, level, dstE.Loopdepth, modSrcLoopdepth, dst) |
| } |
| } |
| } else { |
| src.Esc = EscHeap |
| if Debug['m'] != 0 { |
| if Debug['m'] <= 2 { |
| Warnl(src.Lineno, "leaking param: %S", src) |
| step.describe(src) |
| } else { |
| Warnl(src.Lineno, "leaking param: %S level=%v dst.eld=%v src.eld=%v dst=%S", |
| src, level, dstE.Loopdepth, modSrcLoopdepth, dst) |
| } |
| } |
| } |
| } |
| |
| // Treat a captured closure variable as equivalent to the |
| // original variable. |
| if src.isClosureVar() { |
| if leaks && Debug['m'] != 0 { |
| Warnl(src.Lineno, "leaking closure reference %S", src) |
| step.describe(src) |
| } |
| e.escwalk(level, dst, src.Name.Defn, e.stepWalk(dst, src.Name.Defn, "closure-var", step)) |
| } |
| |
| case OPTRLIT, OADDR: |
| why := "pointer literal" |
| if src.Op == OADDR { |
| why = "address-of" |
| } |
| if leaks { |
| src.Esc = EscHeap |
| if Debug['m'] != 0 && osrcesc != src.Esc { |
| p := src |
| if p.Left.Op == OCLOSURE { |
| p = p.Left // merely to satisfy error messages in tests |
| } |
| if Debug['m'] > 2 { |
| Warnl(src.Lineno, "%S escapes to heap, level=%v, dst=%v dst.eld=%v, src.eld=%v", |
| p, level, dst, dstE.Loopdepth, modSrcLoopdepth) |
| } else { |
| Warnl(src.Lineno, "%S escapes to heap", p) |
| step.describe(src) |
| } |
| } |
| addrescapes(src.Left) |
| e.escwalkBody(level.dec(), dst, src.Left, e.stepWalk(dst, src.Left, why, step), modSrcLoopdepth) |
| extraloopdepth = modSrcLoopdepth // passes to recursive case, seems likely a no-op |
| } else { |
| e.escwalk(level.dec(), dst, src.Left, e.stepWalk(dst, src.Left, why, step)) |
| } |
| |
| case OAPPEND: |
| e.escwalk(level, dst, src.List.First(), e.stepWalk(dst, src.List.First(), "append-first-arg", step)) |
| |
| case ODDDARG: |
| if leaks { |
| src.Esc = EscHeap |
| if Debug['m'] != 0 && osrcesc != src.Esc { |
| Warnl(src.Lineno, "%S escapes to heap", src) |
| step.describe(src) |
| } |
| extraloopdepth = modSrcLoopdepth |
| } |
| // similar to a slice arraylit and its args. |
| level = level.dec() |
| |
| case OSLICELIT: |
| for _, n1 := range src.List.Slice() { |
| if n1.Op == OKEY { |
| n1 = n1.Right |
| } |
| e.escwalk(level.dec(), dst, n1, e.stepWalk(dst, n1, "slice-literal-element", step)) |
| } |
| |
| fallthrough |
| |
| case OMAKECHAN, |
| OMAKEMAP, |
| OMAKESLICE, |
| OARRAYRUNESTR, |
| OARRAYBYTESTR, |
| OSTRARRAYRUNE, |
| OSTRARRAYBYTE, |
| OADDSTR, |
| OMAPLIT, |
| ONEW, |
| OCLOSURE, |
| OCALLPART, |
| ORUNESTR, |
| OCONVIFACE: |
| if leaks { |
| src.Esc = EscHeap |
| if Debug['m'] != 0 && osrcesc != src.Esc { |
| Warnl(src.Lineno, "%S escapes to heap", src) |
| step.describe(src) |
| } |
| extraloopdepth = modSrcLoopdepth |
| } |
| |
| case ODOT, |
| ODOTTYPE: |
| e.escwalk(level, dst, src.Left, e.stepWalk(dst, src.Left, "dot", step)) |
| |
| case |
| OSLICE, |
| OSLICEARR, |
| OSLICE3, |
| OSLICE3ARR, |
| OSLICESTR: |
| e.escwalk(level, dst, src.Left, e.stepWalk(dst, src.Left, "slice", step)) |
| |
| case OINDEX: |
| if src.Left.Type.IsArray() { |
| e.escwalk(level, dst, src.Left, e.stepWalk(dst, src.Left, "fixed-array-index-of", step)) |
| break |
| } |
| fallthrough |
| |
| case ODOTPTR: |
| e.escwalk(level.inc(), dst, src.Left, e.stepWalk(dst, src.Left, "dot of pointer", step)) |
| case OINDEXMAP: |
| e.escwalk(level.inc(), dst, src.Left, e.stepWalk(dst, src.Left, "map index", step)) |
| case OIND: |
| e.escwalk(level.inc(), dst, src.Left, e.stepWalk(dst, src.Left, "indirection", step)) |
| |
| // In this case a link went directly to a call, but should really go |
| // to the dummy .outN outputs that were created for the call that |
| // themselves link to the inputs with levels adjusted. |
| // See e.g. #10466 |
| // This can only happen with functions returning a single result. |
| case OCALLMETH, OCALLFUNC, OCALLINTER: |
| if srcE.Retval.Len() != 0 { |
| if Debug['m'] > 2 { |
| fmt.Printf("%v:[%d] dst %S escwalk replace src: %S with %S\n", |
| linestr(lineno), e.loopdepth, |
| dst, src, srcE.Retval.First()) |
| } |
| src = srcE.Retval.First() |
| srcE = e.nodeEscState(src) |
| } |
| } |
| |
| recurse: |
| level = level.copy() |
| |
| for i := range srcE.Flowsrc { |
| s := &srcE.Flowsrc[i] |
| s.parent = step |
| e.escwalkBody(level, dst, s.src, s, extraloopdepth) |
| s.parent = nil |
| } |
| |
| e.pdepth-- |
| } |
| |
| // This special tag is applied to uintptr variables |
| // that we believe may hold unsafe.Pointers for |
| // calls into assembly functions. |
| // It is logically a constant, but using a var |
| // lets us take the address below to get a *string. |
| var unsafeUintptrTag = "unsafe-uintptr" |
| |
| // This special tag is applied to uintptr parameters of functions |
| // marked go:uintptrescapes. |
| const uintptrEscapesTag = "uintptr-escapes" |
| |
| func (e *EscState) esctag(fn *Node) { |
| fn.Esc = EscFuncTagged |
| |
| name := func(s *Sym, narg int) string { |
| if s != nil { |
| return s.Name |
| } |
| return fmt.Sprintf("arg#%d", narg) |
| } |
| |
| // External functions are assumed unsafe, |
| // unless //go:noescape is given before the declaration. |
| if fn.Nbody.Len() == 0 { |
| if fn.Noescape { |
| for _, f := range fn.Type.Params().Fields().Slice() { |
| if haspointers(f.Type) { |
| f.Note = mktag(EscNone) |
| } |
| } |
| } |
| |
| // Assume that uintptr arguments must be held live across the call. |
| // This is most important for syscall.Syscall. |
| // See golang.org/issue/13372. |
| // This really doesn't have much to do with escape analysis per se, |
| // but we are reusing the ability to annotate an individual function |
| // argument and pass those annotations along to importing code. |
| narg := 0 |
| for _, f := range fn.Type.Params().Fields().Slice() { |
| narg++ |
| if f.Type.Etype == TUINTPTR { |
| if Debug['m'] != 0 { |
| Warnl(fn.Lineno, "%v assuming %v is unsafe uintptr", funcSym(fn), name(f.Sym, narg)) |
| } |
| f.Note = unsafeUintptrTag |
| } |
| } |
| |
| return |
| } |
| |
| if fn.Func.Pragma&UintptrEscapes != 0 { |
| narg := 0 |
| for _, f := range fn.Type.Params().Fields().Slice() { |
| narg++ |
| if f.Type.Etype == TUINTPTR { |
| if Debug['m'] != 0 { |
| Warnl(fn.Lineno, "%v marking %v as escaping uintptr", funcSym(fn), name(f.Sym, narg)) |
| } |
| f.Note = uintptrEscapesTag |
| } |
| |
| if f.Isddd && f.Type.Elem().Etype == TUINTPTR { |
| // final argument is ...uintptr. |
| if Debug['m'] != 0 { |
| Warnl(fn.Lineno, "%v marking %v as escaping ...uintptr", funcSym(fn), name(f.Sym, narg)) |
| } |
| f.Note = uintptrEscapesTag |
| } |
| } |
| } |
| |
| for _, ln := range fn.Func.Dcl { |
| if ln.Op != ONAME { |
| continue |
| } |
| |
| switch ln.Esc & EscMask { |
| case EscNone, // not touched by escflood |
| EscReturn: |
| if haspointers(ln.Type) { // don't bother tagging for scalars |
| if ln.Name.Param.Field.Note != uintptrEscapesTag { |
| ln.Name.Param.Field.Note = mktag(int(ln.Esc)) |
| } |
| } |
| |
| case EscHeap: // touched by escflood, moved to heap |
| } |
| } |
| } |