2019-03-14 13:54:05 -07:00
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// Copyright 2011 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package gc
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// Strongly connected components.
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//
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// Run analysis on minimal sets of mutually recursive functions
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// or single non-recursive functions, bottom up.
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//
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// Finding these sets is finding strongly connected components
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// by reverse topological order in the static call graph.
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// The algorithm (known as Tarjan's algorithm) for doing that is taken from
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// Sedgewick, Algorithms, Second Edition, p. 482, with two adaptations.
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//
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// First, a hidden closure function (n.Func.IsHiddenClosure()) cannot be the
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// root of a connected component. Refusing to use it as a root
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// forces it into the component of the function in which it appears.
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// This is more convenient for escape analysis.
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//
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// Second, each function becomes two virtual nodes in the graph,
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// with numbers n and n+1. We record the function's node number as n
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// but search from node n+1. If the search tells us that the component
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// number (min) is n+1, we know that this is a trivial component: one function
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// plus its closures. If the search tells us that the component number is
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// n, then there was a path from node n+1 back to node n, meaning that
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// the function set is mutually recursive. The escape analysis can be
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// more precise when analyzing a single non-recursive function than
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// when analyzing a set of mutually recursive functions.
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type bottomUpVisitor struct {
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analyze func([]*Node, bool)
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visitgen uint32
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nodeID map[*Node]uint32
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stack []*Node
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}
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// visitBottomUp invokes analyze on the ODCLFUNC nodes listed in list.
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// It calls analyze with successive groups of functions, working from
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// the bottom of the call graph upward. Each time analyze is called with
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// a list of functions, every function on that list only calls other functions
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// on the list or functions that have been passed in previous invocations of
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// analyze. Closures appear in the same list as their outer functions.
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// The lists are as short as possible while preserving those requirements.
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// (In a typical program, many invocations of analyze will be passed just
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// a single function.) The boolean argument 'recursive' passed to analyze
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// specifies whether the functions on the list are mutually recursive.
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// If recursive is false, the list consists of only a single function and its closures.
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// If recursive is true, the list may still contain only a single function,
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// if that function is itself recursive.
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func visitBottomUp(list []*Node, analyze func(list []*Node, recursive bool)) {
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var v bottomUpVisitor
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v.analyze = analyze
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v.nodeID = make(map[*Node]uint32)
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for _, n := range list {
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if n.Op == ODCLFUNC && !n.Func.IsHiddenClosure() {
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v.visit(n)
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}
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}
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}
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func (v *bottomUpVisitor) visit(n *Node) uint32 {
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if id := v.nodeID[n]; id > 0 {
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// already visited
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return id
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}
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v.visitgen++
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id := v.visitgen
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v.nodeID[n] = id
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v.visitgen++
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min := v.visitgen
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v.stack = append(v.stack, n)
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2019-04-22 14:22:25 -07:00
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inspectList(n.Nbody, func(n *Node) bool {
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switch n.Op {
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2020-10-24 02:08:06 -07:00
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case ONAME:
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if n.Class() == PFUNC {
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if n.isMethodExpression() {
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n = asNode(n.Type.Nname())
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}
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if n != nil && n.Name.Defn != nil {
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if m := v.visit(n.Name.Defn); m < min {
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min = m
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}
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}
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}
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case ODOTMETH:
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fn := asNode(n.Type.Nname())
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2019-04-22 14:22:25 -07:00
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if fn != nil && fn.Op == ONAME && fn.Class() == PFUNC && fn.Name.Defn != nil {
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if m := v.visit(fn.Name.Defn); m < min {
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2020-04-20 11:14:36 -07:00
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min = m
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}
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}
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case OCALLPART:
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fn := asNode(callpartMethod(n).Type.Nname())
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if fn != nil && fn.Op == ONAME && fn.Class() == PFUNC && fn.Name.Defn != nil {
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if m := v.visit(fn.Name.Defn); m < min {
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2019-04-22 14:22:25 -07:00
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min = m
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}
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}
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case OCLOSURE:
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if m := v.visit(n.Func.Closure); m < min {
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min = m
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}
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}
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return true
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})
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2019-03-14 13:54:05 -07:00
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if (min == id || min == id+1) && !n.Func.IsHiddenClosure() {
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// This node is the root of a strongly connected component.
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// The original min passed to visitcodelist was v.nodeID[n]+1.
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// If visitcodelist found its way back to v.nodeID[n], then this
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// block is a set of mutually recursive functions.
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// Otherwise it's just a lone function that does not recurse.
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recursive := min == id
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// Remove connected component from stack.
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// Mark walkgen so that future visits return a large number
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// so as not to affect the caller's min.
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var i int
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for i = len(v.stack) - 1; i >= 0; i-- {
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x := v.stack[i]
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if x == n {
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break
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}
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v.nodeID[x] = ^uint32(0)
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}
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v.nodeID[n] = ^uint32(0)
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block := v.stack[i:]
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// Run escape analysis on this set of functions.
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v.stack = v.stack[:i]
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v.analyze(block, recursive)
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}
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return min
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}
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