go/src/cmd/compile/internal/gc/escape.go

// 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/base"
	"cmd/compile/internal/ir"
	"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 *ir.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         *ir.Node  // represented variable or expression, if any
	curfn     *ir.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
}

func init() {
	ir.EscFmt = escFmt
}

// escFmt is called from node printing to print information about escape analysis results.
func escFmt(n *ir.Node, short bool) string {
	text := ""
	switch n.Esc {
	case EscUnknown:
		break

	case EscHeap:
		text = "esc(h)"

	case EscNone:
		text = "esc(no)"

	case EscNever:
		if !short {
			text = "esc(N)"
		}

	default:
		text = fmt.Sprintf("esc(%d)", n.Esc)
	}

	if e, ok := n.Opt().(*EscLocation); ok && e.loopDepth != 0 {
		if text != "" {
			text += " "
		}
		text += fmt.Sprintf("ld(%d)", e.loopDepth)
	}
	return text
}

// escapeFuncs performs escape analysis on a minimal batch of
// functions.
func escapeFuncs(fns []*ir.Node, recursive bool) {
	for _, fn := range fns {
		if fn.Op != ir.ODCLFUNC {
			base.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 *ir.Node) {
	if fn.Op != ir.ODCLFUNC || fn.Esc != EscFuncUnknown {
		base.Fatalf("unexpected node: %v", fn)
	}
	fn.Esc = EscFuncPlanned
	if base.Flag.LowerM > 3 {
		ir.Dump("escAnalyze", fn)
	}

	e.curfn = fn
	e.loopDepth = 1

	// Allocate locations for local variables.
	for _, dcl := range fn.Func.Dcl {
		if dcl.Op == ir.ONAME {
			e.newLoc(dcl, false)
		}
	}
}

func (e *Escape) walkFunc(fn *ir.Node) {
	fn.Esc = EscFuncStarted

	// Identify labels that mark the head of an unstructured loop.
	ir.InspectList(fn.Nbody, func(n *ir.Node) bool {
		switch n.Op {
		case ir.OLABEL:
			n.Sym.Label = ir.AsTypesNode(nonlooping)

		case ir.OGOTO:
			// If we visited the label before the goto,
			// then this is a looping label.
			if n.Sym.Label == ir.AsTypesNode(nonlooping) {
				n.Sym.Label = ir.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 *ir.Node) {
	if n == nil {
		return
	}

	lno := setlineno(n)
	defer func() {
		base.Pos = lno
	}()

	if base.Flag.LowerM > 2 {
		fmt.Printf("%v:[%d] %v stmt: %v\n", base.FmtPos(base.Pos), e.loopDepth, funcSym(e.curfn), n)
	}

	e.stmts(n.Ninit)

	switch n.Op {
	default:
		base.Fatalf("unexpected stmt: %v", n)

	case ir.ODCLCONST, ir.ODCLTYPE, ir.OEMPTY, ir.OFALL, ir.OINLMARK:
		// nop

	case ir.OBREAK, ir.OCONTINUE, ir.OGOTO:
		// TODO(mdempsky): Handle dead code?

	case ir.OBLOCK:
		e.stmts(n.List)

	case ir.ODCL:
		// Record loop depth at declaration.
		if !ir.IsBlank(n.Left) {
			e.dcl(n.Left)
		}

	case ir.OLABEL:
		switch ir.AsNode(n.Sym.Label) {
		case nonlooping:
			if base.Flag.LowerM > 2 {
				fmt.Printf("%v:%v non-looping label\n", base.FmtPos(base.Pos), n)
			}
		case looping:
			if base.Flag.LowerM > 2 {
				fmt.Printf("%v: %v looping label\n", base.FmtPos(base.Pos), n)
			}
			e.loopDepth++
		default:
			base.Fatalf("label missing tag")
		}
		n.Sym.Label = nil

	case ir.OIF:
		e.discard(n.Left)
		e.block(n.Nbody)
		e.block(n.Rlist)

	case ir.OFOR, ir.OFORUNTIL:
		e.loopDepth++
		e.discard(n.Left)
		e.stmt(n.Right)
		e.block(n.Nbody)
		e.loopDepth--

	case ir.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 ir.OSWITCH:
		typesw := n.Left != nil && n.Left.Op == ir.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 ir.OSELECT:
		for _, cas := range n.List.Slice() {
			e.stmt(cas.Left)
			e.block(cas.Nbody)
		}
	case ir.OSELRECV:
		e.assign(n.Left, n.Right, "selrecv", n)
	case ir.OSELRECV2:
		e.assign(n.Left, n.Right, "selrecv", n)
		e.assign(n.List.First(), nil, "selrecv", n)
	case ir.ORECV:
		// TODO(mdempsky): Consider e.discard(n.Left).
		e.exprSkipInit(e.discardHole(), n) // already visited n.Ninit
	case ir.OSEND:
		e.discard(n.Left)
		e.assignHeap(n.Right, "send", n)

	case ir.OAS, ir.OASOP:
		e.assign(n.Left, n.Right, "assign", n)

	case ir.OAS2:
		for i, nl := range n.List.Slice() {
			e.assign(nl, n.Rlist.Index(i), "assign-pair", n)
		}

	case ir.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 ir.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 ir.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 ir.OAS2FUNC:
		e.stmts(n.Right.Ninit)
		e.call(e.addrs(n.List), n.Right, nil)
	case ir.ORETURN:
		results := e.curfn.Type.Results().FieldSlice()
		for i, v := range n.List.Slice() {
			e.assign(ir.AsNode(results[i].Nname), v, "return", n)
		}
	case ir.OCALLFUNC, ir.OCALLMETH, ir.OCALLINTER, ir.OCLOSE, ir.OCOPY, ir.ODELETE, ir.OPANIC, ir.OPRINT, ir.OPRINTN, ir.ORECOVER:
		e.call(nil, n, nil)
	case ir.OGO, ir.ODEFER:
		e.stmts(n.Left.Ninit)
		e.call(nil, n.Left, n)

	case ir.ORETJMP:
		// TODO(mdempsky): What do? esc.go just ignores it.
	}
}

func (e *Escape) stmts(l ir.Nodes) {
	for _, n := range l.Slice() {
		e.stmt(n)
	}
}

// block is like stmts, but preserves loopDepth.
func (e *Escape) block(l ir.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 *ir.Node) {
	if n == nil {
		return
	}
	e.stmts(n.Ninit)
	e.exprSkipInit(k, n)
}

func (e *Escape) exprSkipInit(k EscHole, n *ir.Node) {
	if n == nil {
		return
	}

	lno := setlineno(n)
	defer func() {
		base.Pos = lno
	}()

	uintptrEscapesHack := k.uintptrEscapesHack
	k.uintptrEscapesHack = false

	if uintptrEscapesHack && n.Op == ir.OCONVNOP && n.Left.Type.IsUnsafePtr() {
		// nop
	} else if k.derefs >= 0 && !n.Type.HasPointers() {
		k = e.discardHole()
	}

	switch n.Op {
	default:
		base.Fatalf("unexpected expr: %v", n)

	case ir.OLITERAL, ir.ONIL, ir.OGETG, ir.OCLOSUREVAR, ir.OTYPE, ir.OMETHEXPR:
		// nop

	case ir.ONAME:
		if n.Class() == ir.PFUNC || n.Class() == ir.PEXTERN {
			return
		}
		e.flow(k, e.oldLoc(n))

	case ir.OPLUS, ir.ONEG, ir.OBITNOT, ir.ONOT:
		e.discard(n.Left)
	case ir.OADD, ir.OSUB, ir.OOR, ir.OXOR, ir.OMUL, ir.ODIV, ir.OMOD, ir.OLSH, ir.ORSH, ir.OAND, ir.OANDNOT, ir.OEQ, ir.ONE, ir.OLT, ir.OLE, ir.OGT, ir.OGE, ir.OANDAND, ir.OOROR:
		e.discard(n.Left)
		e.discard(n.Right)

	case ir.OADDR:
		e.expr(k.addr(n, "address-of"), n.Left) // "address-of"
	case ir.ODEREF:
		e.expr(k.deref(n, "indirection"), n.Left) // "indirection"
	case ir.ODOT, ir.ODOTMETH, ir.ODOTINTER:
		e.expr(k.note(n, "dot"), n.Left)
	case ir.ODOTPTR:
		e.expr(k.deref(n, "dot of pointer"), n.Left) // "dot of pointer"
	case ir.ODOTTYPE, ir.ODOTTYPE2:
		e.expr(k.dotType(n.Type, n, "dot"), n.Left)
	case ir.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 ir.OINDEXMAP:
		e.discard(n.Left)
		e.discard(n.Right)
	case ir.OSLICE, ir.OSLICEARR, ir.OSLICE3, ir.OSLICE3ARR, ir.OSLICESTR:
		e.expr(k.note(n, "slice"), n.Left)
		low, high, max := n.SliceBounds()
		e.discard(low)
		e.discard(high)
		e.discard(max)

	case ir.OCONV, ir.OCONVNOP:
		if checkPtr(e.curfn, 2) && n.Type.IsUnsafePtr() && 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.IsUnsafePtr() && n.Left.Type.IsUintptr() {
			e.unsafeValue(k, n.Left)
		} else {
			e.expr(k, n.Left)
		}
	case ir.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 ir.ORECV:
		e.discard(n.Left)

	case ir.OCALLMETH, ir.OCALLFUNC, ir.OCALLINTER, ir.OLEN, ir.OCAP, ir.OCOMPLEX, ir.OREAL, ir.OIMAG, ir.OAPPEND, ir.OCOPY:
		e.call([]EscHole{k}, n, nil)

	case ir.ONEW:
		e.spill(k, n)

	case ir.OMAKESLICE:
		e.spill(k, n)
		e.discard(n.Left)
		e.discard(n.Right)
	case ir.OMAKECHAN:
		e.discard(n.Left)
	case ir.OMAKEMAP:
		e.spill(k, n)
		e.discard(n.Left)

	case ir.ORECOVER:
		// nop

	case ir.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 slice?
		var ks []EscHole
		for i := m.Type.NumResults(); i > 0; i-- {
			ks = append(ks, e.heapHole())
		}
		paramK := e.tagHole(ks, ir.AsNode(m.Nname), m.Type.Recv())

		e.expr(e.teeHole(paramK, closureK), n.Left)

	case ir.OPTRLIT:
		e.expr(e.spill(k, n), n.Left)

	case ir.OARRAYLIT:
		for _, elt := range n.List.Slice() {
			if elt.Op == ir.OKEY {
				elt = elt.Right
			}
			e.expr(k.note(n, "array literal element"), elt)
		}

	case ir.OSLICELIT:
		k = e.spill(k, n)
		k.uintptrEscapesHack = uintptrEscapesHack // for ...uintptr parameters

		for _, elt := range n.List.Slice() {
			if elt.Op == ir.OKEY {
				elt = elt.Right
			}
			e.expr(k.note(n, "slice-literal-element"), elt)
		}

	case ir.OSTRUCTLIT:
		for _, elt := range n.List.Slice() {
			e.expr(k.note(n, "struct literal element"), elt.Left)
		}

	case ir.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 ir.OCLOSURE:
		k = e.spill(k, n)

		// Link addresses of captured variables to closure.
		for _, v := range n.Func.ClosureVars.Slice() {
			if v.Op == ir.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 ir.ORUNES2STR, ir.OBYTES2STR, ir.OSTR2RUNES, ir.OSTR2BYTES, ir.ORUNESTR:
		e.spill(k, n)
		e.discard(n.Left)

	case ir.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 *ir.Node) {
	if n.Type.Etype != types.TUINTPTR {
		base.Fatalf("unexpected type %v for %v", n.Type, n)
	}

	e.stmts(n.Ninit)

	switch n.Op {
	case ir.OCONV, ir.OCONVNOP:
		if n.Left.Type.IsUnsafePtr() {
			e.expr(k, n.Left)
		} else {
			e.discard(n.Left)
		}
	case ir.ODOTPTR:
		if isReflectHeaderDataField(n) {
			e.expr(k.deref(n, "reflect.Header.Data"), n.Left)
		} else {
			e.discard(n.Left)
		}
	case ir.OPLUS, ir.ONEG, ir.OBITNOT:
		e.unsafeValue(k, n.Left)
	case ir.OADD, ir.OSUB, ir.OOR, ir.OXOR, ir.OMUL, ir.ODIV, ir.OMOD, ir.OAND, ir.OANDNOT:
		e.unsafeValue(k, n.Left)
		e.unsafeValue(k, n.Right)
	case ir.OLSH, ir.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 *ir.Node) {
	e.expr(e.discardHole(), n)
}

func (e *Escape) discards(l ir.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 *ir.Node) EscHole {
	if n == nil || ir.IsBlank(n) {
		// Can happen at least in OSELRECV.
		// TODO(mdempsky): Anywhere else?
		return e.discardHole()
	}

	k := e.heapHole()

	switch n.Op {
	default:
		base.Fatalf("unexpected addr: %v", n)
	case ir.ONAME:
		if n.Class() == ir.PEXTERN {
			break
		}
		k = e.oldLoc(n).asHole()
	case ir.ODOT:
		k = e.addr(n.Left)
	case ir.OINDEX:
		e.discard(n.Right)
		if n.Left.Type.IsArray() {
			k = e.addr(n.Left)
		} else {
			e.discard(n.Left)
		}
	case ir.ODEREF, ir.ODOTPTR:
		e.discard(n)
	case ir.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 ir.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 *ir.Node, why string, where *ir.Node) {
	// Filter out some no-op assignments for escape analysis.
	ignore := dst != nil && src != nil && isSelfAssign(dst, src)
	if ignore && base.Flag.LowerM != 0 {
		base.WarnfAt(where.Pos, "%v ignoring self-assignment in %S", funcSym(e.curfn), where)
	}

	k := e.addr(dst)
	if dst != nil && dst.Op == ir.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 *ir.Node, why string, where *ir.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 *ir.Node) {
	topLevelDefer := where != nil && where.Op == ir.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 *ir.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:
		base.Fatalf("unexpected call op: %v", call.Op)

	case ir.OCALLFUNC, ir.OCALLMETH, ir.OCALLINTER:
		fixVariadicCall(call)

		// Pick out the function callee, if statically known.
		var fn *ir.Node
		switch call.Op {
		case ir.OCALLFUNC:
			switch v := staticValue(call.Left); {
			case v.Op == ir.ONAME && v.Class() == ir.PFUNC:
				fn = v
			case v.Op == ir.OCLOSURE:
				fn = v.Func.Nname
			}
		case ir.OCALLMETH:
			fn = methodExprName(call.Left)
		}

		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], ir.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 ir.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 ir.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 ir.OPANIC:
		argument(e.heapHole(), call.Left)

	case ir.OCOMPLEX:
		argument(e.discardHole(), call.Left)
		argument(e.discardHole(), call.Right)
	case ir.ODELETE, ir.OPRINT, ir.OPRINTN, ir.ORECOVER:
		for _, arg := range call.List.Slice() {
			argument(e.discardHole(), arg)
		}
	case ir.OLEN, ir.OCAP, ir.OREAL, ir.OIMAG, ir.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 *ir.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(ir.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 *ir.Node) bool {
	if fn.Name.Defn != nil && fn.Name.Defn.Esc < EscFuncTagged {
		if fn.Name.Defn.Esc == EscFuncUnknown {
			base.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 *ir.Node
	why   string
}

func (k EscHole) note(where *ir.Node, why string) EscHole {
	if where == nil || why == "" {
		base.Fatalf("note: missing where/why")
	}
	if base.Flag.LowerM >= 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 {
		base.Fatalf("derefs underflow: %v", k.derefs)
	}
	return k
}

func (k EscHole) deref(where *ir.Node, why string) EscHole { return k.shift(1).note(where, why) }
func (k EscHole) addr(where *ir.Node, why string) EscHole  { return k.shift(-1).note(where, why) }

func (k EscHole) dotType(t *types.Type, where *ir.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 {
			base.Fatalf("teeHole: negative derefs")
		}

		e.flow(k, loc)
	}
	return loc.asHole()
}

func (e *Escape) dcl(n *ir.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 *ir.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 *ir.Node) *ir.Node {
	if n != nil && n.Op == ir.ONAME && n.Name.IsClosureVar() {
		n = n.Name.Defn
		if n.Name.IsClosureVar() {
			base.Fatalf("still closure var")
		}
	}

	return n
}

func (e *Escape) newLoc(n *ir.Node, transient bool) *EscLocation {
	if e.curfn == nil {
		base.Fatalf("e.curfn isn't set")
	}
	if n != nil && n.Type != nil && n.Type.NotInHeap() {
		base.ErrorfAt(n.Pos, "%v is incomplete (or unallocatable); stack allocation disallowed", n.Type)
	}

	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 == ir.ONAME && n.Name.Curfn != e.curfn {
			base.Fatalf("curfn mismatch: %v != %v", n.Name.Curfn, e.curfn)
		}

		if n.HasOpt() {
			base.Fatalf("%v already has a location", n)
		}
		n.SetOpt(loc)

		if why := heapAllocReason(n); why != "" {
			e.flow(e.heapHole().addr(n, why), loc)
		}
	}
	return loc
}

func (e *Escape) oldLoc(n *ir.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 base.Flag.LowerM >= 2 || logopt.Enabled() {
			pos := base.FmtPos(src.n.Pos)
			if base.Flag.LowerM >= 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", ir.FuncName(e.curfn), 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]

		derefs := l.derefs

		// If l.derefs < 0, then l's address flows to root.
		addressOf := derefs < 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
			// derefs at 0.
			derefs = 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(ir.PPARAM) {
				if (logopt.Enabled() || base.Flag.LowerM >= 2) && !l.escapes {
					if base.Flag.LowerM >= 2 {
						fmt.Printf("%s: parameter %v leaks to %s with derefs=%d:\n", base.FmtPos(l.n.Pos), l.n, e.explainLoc(root), derefs)
					}
					explanation := e.explainPath(root, l)
					if logopt.Enabled() {
						logopt.LogOpt(l.n.Pos, "leak", "escape", ir.FuncName(e.curfn),
							fmt.Sprintf("parameter %v leaks to %s with derefs=%d", l.n, e.explainLoc(root), derefs), explanation)
					}
				}
				l.leakTo(root, derefs)
			}

			// If l's address flows somewhere that
			// outlives it, then l needs to be heap
			// allocated.
			if addressOf && !l.escapes {
				if logopt.Enabled() || base.Flag.LowerM >= 2 {
					if base.Flag.LowerM >= 2 {
						fmt.Printf("%s: %v escapes to heap:\n", base.FmtPos(l.n.Pos), l.n)
					}
					explanation := e.explainPath(root, l)
					if logopt.Enabled() {
						logopt.LogOpt(l.n.Pos, "escape", "escape", ir.FuncName(e.curfn), 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
			}
			d := derefs + edge.derefs
			if edge.src.walkgen != walkgen || edge.src.derefs > d {
				edge.src.walkgen = walkgen
				edge.src.derefs = d
				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 := base.FmtPos(src.n.Pos)
	var explanation []*logopt.LoggedOpt
	for {
		// Prevent infinite loop.
		if visited[src] {
			if base.Flag.LowerM >= 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 {
			base.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 := base.Flag.LowerM >= 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", ir.FuncName(e.curfn), 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, base.FmtPos(note.where.Pos))
		}
		if logopt.Enabled() {
			explanation = append(explanation, logopt.NewLoggedOpt(note.where.Pos, "escflow", "escape", ir.FuncName(e.curfn),
				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 == ir.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(ir.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.ClosureCalled {
			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 *ir.Node) bool {
	if f.Op != ir.ODCLFUNC || c.Op != ir.ODCLFUNC {
		base.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(ir.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 []*ir.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 != ir.ONAME {
				if base.Flag.LowerM != 0 {
					base.WarnfAt(n.Pos, "%S escapes to heap", n)
				}
				if logopt.Enabled() {
					logopt.LogOpt(n.Pos, "escape", "escape", ir.FuncName(e.curfn))
				}
			}
			n.Esc = EscHeap
			addrescapes(n)
		} else {
			if base.Flag.LowerM != 0 && n.Op != ir.ONAME {
				base.WarnfAt(n.Pos, "%S does not escape", n)
			}
			n.Esc = EscNone
			if loc.transient {
				n.SetTransient(true)
			}
		}
	}
}

func (l *EscLocation) isName(c ir.Class) bool {
	return l.n != nil && l.n.Op == ir.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 {
		base.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
}

func escapes(all []*ir.Node) {
	visitBottomUp(all, escapeFuncs)
}

const (
	EscFuncUnknown = 0 + iota
	EscFuncPlanned
	EscFuncStarted
	EscFuncTagged
)

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
}

const (
	EscUnknown = iota
	EscNone    // Does not escape to heap, result, or parameters.
	EscHeap    // Reachable from the heap
	EscNever   // By construction will not escape.
)

// funcSym returns fn.Func.Nname.Sym if no nils are encountered along the way.
func funcSym(fn *ir.Node) *types.Sym {
	if fn == nil || fn.Func.Nname == nil {
		return nil
	}
	return fn.Func.Nname.Sym
}

// 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    = ir.Nod(ir.OXXX, nil, nil)
	nonlooping = ir.Nod(ir.OXXX, nil, nil)
)

func isSliceSelfAssign(dst, src *ir.Node) bool {
	// Detect 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.
	// Here we 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.

	// dst is ONAME dereference.
	if dst.Op != ir.ODEREF && dst.Op != ir.ODOTPTR || dst.Left.Op != ir.ONAME {
		return false
	}
	// src is a slice operation.
	switch src.Op {
	case ir.OSLICE, ir.OSLICE3, ir.OSLICESTR:
		// OK.
	case ir.OSLICEARR, ir.OSLICE3ARR:
		// Since arrays are embedded into containing object,
		// slice of non-pointer array will 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.
		//
		// Pointer to an array is OK since it's not stored inside b directly.
		// For slicing an array (not pointer to array), there is an implicit OADDR.
		// We check that to determine non-pointer array slicing.
		if src.Left.Op == ir.OADDR {
			return false
		}
	default:
		return false
	}
	// slice is applied to ONAME dereference.
	if src.Left.Op != ir.ODEREF && src.Left.Op != ir.ODOTPTR || src.Left.Left.Op != ir.ONAME {
		return false
	}
	// dst and src reference the same base ONAME.
	return dst.Left == src.Left.Left
}

// isSelfAssign reports whether assignment from src to dst can
// be ignored by the escape analysis as it's effectively a self-assignment.
func isSelfAssign(dst, src *ir.Node) bool {
	if isSliceSelfAssign(dst, src) {
		return true
	}

	// Detect trivial assignments that assign back to the same object.
	//
	// It covers these cases:
	//	val.x = val.y
	//	val.x[i] = val.y[j]
	//	val.x1.x2 = val.x1.y2
	//	... etc
	//
	// These assignments do not change assigned object lifetime.

	if dst == nil || src == nil || dst.Op != src.Op {
		return false
	}

	switch dst.Op {
	case ir.ODOT, ir.ODOTPTR:
		// Safe trailing accessors that are permitted to differ.
	case ir.OINDEX:
		if mayAffectMemory(dst.Right) || mayAffectMemory(src.Right) {
			return false
		}
	default:
		return false
	}

	// The expression prefix must be both "safe" and identical.
	return samesafeexpr(dst.Left, src.Left)
}

// mayAffectMemory reports whether evaluation of n may affect the program's
// memory state. If the expression can't affect memory state, then it can be
// safely ignored by the escape analysis.
func mayAffectMemory(n *ir.Node) bool {
	// We may want to use a list of "memory safe" ops instead of generally
	// "side-effect free", which would include all calls and other ops that can
	// allocate or change global state. For now, it's safer to start with the latter.
	//
	// We're ignoring things like division by zero, index out of range,
	// and nil pointer dereference here.
	switch n.Op {
	case ir.ONAME, ir.OCLOSUREVAR, ir.OLITERAL, ir.ONIL:
		return false

	// Left+Right group.
	case ir.OINDEX, ir.OADD, ir.OSUB, ir.OOR, ir.OXOR, ir.OMUL, ir.OLSH, ir.ORSH, ir.OAND, ir.OANDNOT, ir.ODIV, ir.OMOD:
		return mayAffectMemory(n.Left) || mayAffectMemory(n.Right)

	// Left group.
	case ir.ODOT, ir.ODOTPTR, ir.ODEREF, ir.OCONVNOP, ir.OCONV, ir.OLEN, ir.OCAP,
		ir.ONOT, ir.OBITNOT, ir.OPLUS, ir.ONEG, ir.OALIGNOF, ir.OOFFSETOF, ir.OSIZEOF:
		return mayAffectMemory(n.Left)

	default:
		return true
	}
}

// heapAllocReason returns the reason the given Node must be heap
// allocated, or the empty string if it doesn't.
func heapAllocReason(n *ir.Node) string {
	if n.Type == nil {
		return ""
	}

	// Parameters are always passed via the stack.
	if n.Op == ir.ONAME && (n.Class() == ir.PPARAM || n.Class() == ir.PPARAMOUT) {
		return ""
	}

	if n.Type.Width > maxStackVarSize {
		return "too large for stack"
	}

	if (n.Op == ir.ONEW || n.Op == ir.OPTRLIT) && n.Type.Elem().Width >= maxImplicitStackVarSize {
		return "too large for stack"
	}

	if n.Op == ir.OCLOSURE && closureType(n).Size() >= maxImplicitStackVarSize {
		return "too large for stack"
	}
	if n.Op == ir.OCALLPART && partialCallType(n).Size() >= maxImplicitStackVarSize {
		return "too large for stack"
	}

	if n.Op == ir.OMAKESLICE {
		r := n.Right
		if r == nil {
			r = n.Left
		}
		if !smallintconst(r) {
			return "non-constant size"
		}
		if t := n.Type; t.Elem().Width != 0 && r.Int64Val() >= maxImplicitStackVarSize/t.Elem().Width {
			return "too large for stack"
		}
	}

	return ""
}

// addrescapes tags node n as having had its address taken
// by "increasing" the "value" of n.Esc to EscHeap.
// Storage is allocated as necessary to allow the address
// to be taken.
func addrescapes(n *ir.Node) {
	switch n.Op {
	default:
		// Unexpected Op, probably due to a previous type error. Ignore.

	case ir.ODEREF, ir.ODOTPTR:
		// Nothing to do.

	case ir.ONAME:
		if n == nodfp {
			break
		}

		// if this is a tmpname (PAUTO), it was tagged by tmpname as not escaping.
		// on PPARAM it means something different.
		if n.Class() == ir.PAUTO && n.Esc == EscNever {
			break
		}

		// If a closure reference escapes, mark the outer variable as escaping.
		if n.Name.IsClosureVar() {
			addrescapes(n.Name.Defn)
			break
		}

		if n.Class() != ir.PPARAM && n.Class() != ir.PPARAMOUT && n.Class() != ir.PAUTO {
			break
		}

		// This is a plain parameter or local variable that needs to move to the heap,
		// but possibly for the function outside the one we're compiling.
		// That is, if we have:
		//
		//	func f(x int) {
		//		func() {
		//			global = &x
		//		}
		//	}
		//
		// then we're analyzing the inner closure but we need to move x to the
		// heap in f, not in the inner closure. Flip over to f before calling moveToHeap.
		oldfn := Curfn
		Curfn = n.Name.Curfn
		if Curfn.Op == ir.OCLOSURE {
			Curfn = Curfn.Func.Decl
			panic("can't happen")
		}
		ln := base.Pos
		base.Pos = Curfn.Pos
		moveToHeap(n)
		Curfn = oldfn
		base.Pos = ln

	// ODOTPTR has already been introduced,
	// so these are the non-pointer ODOT and OINDEX.
	// In &x[0], if x is a slice, then x does not
	// escape--the pointer inside x does, but that
	// is always a heap pointer anyway.
	case ir.ODOT, ir.OINDEX, ir.OPAREN, ir.OCONVNOP:
		if !n.Left.Type.IsSlice() {
			addrescapes(n.Left)
		}
	}
}

// moveToHeap records the parameter or local variable n as moved to the heap.
func moveToHeap(n *ir.Node) {
	if base.Flag.LowerR != 0 {
		ir.Dump("MOVE", n)
	}
	if base.Flag.CompilingRuntime {
		base.Errorf("%v escapes to heap, not allowed in runtime", n)
	}
	if n.Class() == ir.PAUTOHEAP {
		ir.Dump("n", n)
		base.Fatalf("double move to heap")
	}

	// Allocate a local stack variable to hold the pointer to the heap copy.
	// temp will add it to the function declaration list automatically.
	heapaddr := temp(types.NewPtr(n.Type))
	heapaddr.Sym = lookup("&" + n.Sym.Name)
	heapaddr.Orig.Sym = heapaddr.Sym
	heapaddr.Pos = n.Pos

	// Unset AutoTemp to persist the &foo variable name through SSA to
	// liveness analysis.
	// TODO(mdempsky/drchase): Cleaner solution?
	heapaddr.Name.SetAutoTemp(false)

	// Parameters have a local stack copy used at function start/end
	// in addition to the copy in the heap that may live longer than
	// the function.
	if n.Class() == ir.PPARAM || n.Class() == ir.PPARAMOUT {
		if n.Xoffset == types.BADWIDTH {
			base.Fatalf("addrescapes before param assignment")
		}

		// We rewrite n below to be a heap variable (indirection of heapaddr).
		// Preserve a copy so we can still write code referring to the original,
		// and substitute that copy into the function declaration list
		// so that analyses of the local (on-stack) variables use it.
		stackcopy := NewName(n.Sym)
		stackcopy.Type = n.Type
		stackcopy.Xoffset = n.Xoffset
		stackcopy.SetClass(n.Class())
		stackcopy.Name.Param.Heapaddr = heapaddr
		if n.Class() == ir.PPARAMOUT {
			// Make sure the pointer to the heap copy is kept live throughout the function.
			// The function could panic at any point, and then a defer could recover.
			// Thus, we need the pointer to the heap copy always available so the
			// post-deferreturn code can copy the return value back to the stack.
			// See issue 16095.
			heapaddr.Name.SetIsOutputParamHeapAddr(true)
		}
		n.Name.Param.Stackcopy = stackcopy

		// Substitute the stackcopy into the function variable list so that
		// liveness and other analyses use the underlying stack slot
		// and not the now-pseudo-variable n.
		found := false
		for i, d := range Curfn.Func.Dcl {
			if d == n {
				Curfn.Func.Dcl[i] = stackcopy
				found = true
				break
			}
			// Parameters are before locals, so can stop early.
			// This limits the search even in functions with many local variables.
			if d.Class() == ir.PAUTO {
				break
			}
		}
		if !found {
			base.Fatalf("cannot find %v in local variable list", n)
		}
		Curfn.Func.Dcl = append(Curfn.Func.Dcl, n)
	}

	// Modify n in place so that uses of n now mean indirection of the heapaddr.
	n.SetClass(ir.PAUTOHEAP)
	n.Xoffset = 0
	n.Name.Param.Heapaddr = heapaddr
	n.Esc = EscHeap
	if base.Flag.LowerM != 0 {
		base.WarnfAt(n.Pos, "moved to heap: %v", n)
	}
}

// This special tag is applied to uintptr variables
// that we believe may hold unsafe.Pointers for
// calls into assembly functions.
const unsafeUintptrTag = "unsafe-uintptr"

// This special tag is applied to uintptr parameters of functions
// marked go:uintptrescapes.
const uintptrEscapesTag = "uintptr-escapes"

func (e *Escape) paramTag(fn *ir.Node, narg int, f *types.Field) string {
	name := func() string {
		if f.Sym != nil {
			return f.Sym.Name
		}
		return fmt.Sprintf("arg#%d", narg)
	}

	if fn.Nbody.Len() == 0 {
		// 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.
		if f.Type.IsUintptr() {
			if base.Flag.LowerM != 0 {
				base.WarnfAt(f.Pos, "assuming %v is unsafe uintptr", name())
			}
			return unsafeUintptrTag
		}

		if !f.Type.HasPointers() { // don't bother tagging for scalars
			return ""
		}

		var esc EscLeaks

		// External functions are assumed unsafe, unless
		// //go:noescape is given before the declaration.
		if fn.Func.Pragma&ir.Noescape != 0 {
			if base.Flag.LowerM != 0 && f.Sym != nil {
				base.WarnfAt(f.Pos, "%v does not escape", name())
			}
		} else {
			if base.Flag.LowerM != 0 && f.Sym != nil {
				base.WarnfAt(f.Pos, "leaking param: %v", name())
			}
			esc.AddHeap(0)
		}

		return esc.Encode()
	}

	if fn.Func.Pragma&ir.UintptrEscapes != 0 {
		if f.Type.IsUintptr() {
			if base.Flag.LowerM != 0 {
				base.WarnfAt(f.Pos, "marking %v as escaping uintptr", name())
			}
			return uintptrEscapesTag
		}
		if f.IsDDD() && f.Type.Elem().IsUintptr() {
			// final argument is ...uintptr.
			if base.Flag.LowerM != 0 {
				base.WarnfAt(f.Pos, "marking %v as escaping ...uintptr", name())
			}
			return uintptrEscapesTag
		}
	}

	if !f.Type.HasPointers() { // don't bother tagging for scalars
		return ""
	}

	// Unnamed parameters are unused and therefore do not escape.
	if f.Sym == nil || f.Sym.IsBlank() {
		var esc EscLeaks
		return esc.Encode()
	}

	n := ir.AsNode(f.Nname)
	loc := e.oldLoc(n)
	esc := loc.paramEsc
	esc.Optimize()

	if base.Flag.LowerM != 0 && !loc.escapes {
		if esc.Empty() {
			base.WarnfAt(f.Pos, "%v does not escape", name())
		}
		if x := esc.Heap(); x >= 0 {
			if x == 0 {
				base.WarnfAt(f.Pos, "leaking param: %v", name())
			} else {
				// TODO(mdempsky): Mention level=x like below?
				base.WarnfAt(f.Pos, "leaking param content: %v", name())
			}
		}
		for i := 0; i < numEscResults; i++ {
			if x := esc.Result(i); x >= 0 {
				res := fn.Type.Results().Field(i).Sym
				base.WarnfAt(f.Pos, "leaking param: %v to result %v level=%d", name(), res, x)
			}
		}
	}

	return esc.Encode()
}