mirror of
https://github.com/VictoriaMetrics/VictoriaMetrics.git
synced 2024-12-15 16:30:55 +01:00
7d7fbf890e
Updates https://github.com/VictoriaMetrics/VictoriaMetrics/issues/203 Updates https://github.com/VictoriaMetrics/VictoriaMetrics/issues/38
766 lines
20 KiB
Go
766 lines
20 KiB
Go
// Copyright 2013 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 ssa
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// This file implements the Function and BasicBlock types.
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import (
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"bytes"
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"fmt"
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"go/ast"
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"go/token"
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"go/types"
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"io"
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"os"
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"strings"
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)
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// addEdge adds a control-flow graph edge from from to to.
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func addEdge(from, to *BasicBlock) {
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from.Succs = append(from.Succs, to)
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to.Preds = append(to.Preds, from)
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}
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// Parent returns the function that contains block b.
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func (b *BasicBlock) Parent() *Function { return b.parent }
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// String returns a human-readable label of this block.
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// It is not guaranteed unique within the function.
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//
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func (b *BasicBlock) String() string {
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return fmt.Sprintf("%d", b.Index)
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}
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// emit appends an instruction to the current basic block.
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// If the instruction defines a Value, it is returned.
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//
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func (b *BasicBlock) emit(i Instruction) Value {
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i.setBlock(b)
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b.Instrs = append(b.Instrs, i)
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v, _ := i.(Value)
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return v
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}
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// predIndex returns the i such that b.Preds[i] == c or panics if
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// there is none.
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func (b *BasicBlock) predIndex(c *BasicBlock) int {
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for i, pred := range b.Preds {
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if pred == c {
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return i
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}
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}
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panic(fmt.Sprintf("no edge %s -> %s", c, b))
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}
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// hasPhi returns true if b.Instrs contains φ-nodes.
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func (b *BasicBlock) hasPhi() bool {
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_, ok := b.Instrs[0].(*Phi)
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return ok
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}
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func (b *BasicBlock) Phis() []Instruction {
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return b.phis()
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}
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// phis returns the prefix of b.Instrs containing all the block's φ-nodes.
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func (b *BasicBlock) phis() []Instruction {
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for i, instr := range b.Instrs {
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if _, ok := instr.(*Phi); !ok {
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return b.Instrs[:i]
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}
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}
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return nil // unreachable in well-formed blocks
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}
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// replacePred replaces all occurrences of p in b's predecessor list with q.
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// Ordinarily there should be at most one.
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//
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func (b *BasicBlock) replacePred(p, q *BasicBlock) {
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for i, pred := range b.Preds {
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if pred == p {
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b.Preds[i] = q
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}
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}
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}
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// replaceSucc replaces all occurrences of p in b's successor list with q.
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// Ordinarily there should be at most one.
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//
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func (b *BasicBlock) replaceSucc(p, q *BasicBlock) {
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for i, succ := range b.Succs {
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if succ == p {
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b.Succs[i] = q
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}
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}
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}
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func (b *BasicBlock) RemovePred(p *BasicBlock) {
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b.removePred(p)
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}
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// removePred removes all occurrences of p in b's
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// predecessor list and φ-nodes.
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// Ordinarily there should be at most one.
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//
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func (b *BasicBlock) removePred(p *BasicBlock) {
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phis := b.phis()
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// We must preserve edge order for φ-nodes.
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j := 0
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for i, pred := range b.Preds {
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if pred != p {
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b.Preds[j] = b.Preds[i]
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// Strike out φ-edge too.
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for _, instr := range phis {
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phi := instr.(*Phi)
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phi.Edges[j] = phi.Edges[i]
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}
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j++
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}
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}
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// Nil out b.Preds[j:] and φ-edges[j:] to aid GC.
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for i := j; i < len(b.Preds); i++ {
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b.Preds[i] = nil
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for _, instr := range phis {
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instr.(*Phi).Edges[i] = nil
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}
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}
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b.Preds = b.Preds[:j]
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for _, instr := range phis {
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phi := instr.(*Phi)
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phi.Edges = phi.Edges[:j]
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}
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}
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// Destinations associated with unlabelled for/switch/select stmts.
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// We push/pop one of these as we enter/leave each construct and for
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// each BranchStmt we scan for the innermost target of the right type.
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//
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type targets struct {
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tail *targets // rest of stack
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_break *BasicBlock
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_continue *BasicBlock
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_fallthrough *BasicBlock
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}
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// Destinations associated with a labelled block.
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// We populate these as labels are encountered in forward gotos or
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// labelled statements.
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//
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type lblock struct {
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_goto *BasicBlock
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_break *BasicBlock
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_continue *BasicBlock
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}
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// labelledBlock returns the branch target associated with the
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// specified label, creating it if needed.
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//
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func (f *Function) labelledBlock(label *ast.Ident) *lblock {
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lb := f.lblocks[label.Obj]
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if lb == nil {
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lb = &lblock{_goto: f.newBasicBlock(label.Name)}
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if f.lblocks == nil {
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f.lblocks = make(map[*ast.Object]*lblock)
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}
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f.lblocks[label.Obj] = lb
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}
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return lb
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}
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// addParam adds a (non-escaping) parameter to f.Params of the
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// specified name, type and source position.
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//
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func (f *Function) addParam(name string, typ types.Type, pos token.Pos) *Parameter {
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v := &Parameter{
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name: name,
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typ: typ,
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pos: pos,
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parent: f,
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}
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f.Params = append(f.Params, v)
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return v
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}
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func (f *Function) addParamObj(obj types.Object) *Parameter {
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name := obj.Name()
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if name == "" {
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name = fmt.Sprintf("arg%d", len(f.Params))
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}
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param := f.addParam(name, obj.Type(), obj.Pos())
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param.object = obj
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return param
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}
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// addSpilledParam declares a parameter that is pre-spilled to the
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// stack; the function body will load/store the spilled location.
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// Subsequent lifting will eliminate spills where possible.
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//
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func (f *Function) addSpilledParam(obj types.Object) {
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param := f.addParamObj(obj)
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spill := &Alloc{Comment: obj.Name()}
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spill.setType(types.NewPointer(obj.Type()))
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spill.setPos(obj.Pos())
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f.objects[obj] = spill
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f.Locals = append(f.Locals, spill)
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f.emit(spill)
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f.emit(&Store{Addr: spill, Val: param})
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}
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// startBody initializes the function prior to generating SSA code for its body.
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// Precondition: f.Type() already set.
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//
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func (f *Function) startBody() {
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f.currentBlock = f.newBasicBlock("entry")
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f.objects = make(map[types.Object]Value) // needed for some synthetics, e.g. init
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}
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// createSyntacticParams populates f.Params and generates code (spills
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// and named result locals) for all the parameters declared in the
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// syntax. In addition it populates the f.objects mapping.
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//
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// Preconditions:
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// f.startBody() was called.
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// Postcondition:
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// len(f.Params) == len(f.Signature.Params) + (f.Signature.Recv() ? 1 : 0)
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//
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func (f *Function) createSyntacticParams(recv *ast.FieldList, functype *ast.FuncType) {
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// Receiver (at most one inner iteration).
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if recv != nil {
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for _, field := range recv.List {
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for _, n := range field.Names {
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f.addSpilledParam(f.Pkg.info.Defs[n])
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}
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// Anonymous receiver? No need to spill.
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if field.Names == nil {
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f.addParamObj(f.Signature.Recv())
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}
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}
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}
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// Parameters.
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if functype.Params != nil {
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n := len(f.Params) // 1 if has recv, 0 otherwise
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for _, field := range functype.Params.List {
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for _, n := range field.Names {
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f.addSpilledParam(f.Pkg.info.Defs[n])
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}
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// Anonymous parameter? No need to spill.
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if field.Names == nil {
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f.addParamObj(f.Signature.Params().At(len(f.Params) - n))
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}
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}
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}
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// Named results.
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if functype.Results != nil {
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for _, field := range functype.Results.List {
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// Implicit "var" decl of locals for named results.
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for _, n := range field.Names {
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f.namedResults = append(f.namedResults, f.addLocalForIdent(n))
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}
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}
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}
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}
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// numberRegisters assigns numbers to all SSA registers
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// (value-defining Instructions) in f, to aid debugging.
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// (Non-Instruction Values are named at construction.)
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//
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func numberRegisters(f *Function) {
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v := 0
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for _, b := range f.Blocks {
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for _, instr := range b.Instrs {
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switch instr.(type) {
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case Value:
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instr.(interface {
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setNum(int)
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}).setNum(v)
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v++
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}
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}
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}
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}
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// buildReferrers populates the def/use information in all non-nil
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// Value.Referrers slice.
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// Precondition: all such slices are initially empty.
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func buildReferrers(f *Function) {
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var rands []*Value
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for _, b := range f.Blocks {
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for _, instr := range b.Instrs {
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rands = instr.Operands(rands[:0]) // recycle storage
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for _, rand := range rands {
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if r := *rand; r != nil {
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if ref := r.Referrers(); ref != nil {
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*ref = append(*ref, instr)
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}
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}
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}
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}
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}
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}
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// finishBody() finalizes the function after SSA code generation of its body.
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func (f *Function) finishBody() {
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f.objects = nil
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f.currentBlock = nil
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f.lblocks = nil
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// Don't pin the AST in memory (except in debug mode).
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if n := f.syntax; n != nil && !f.debugInfo() {
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f.syntax = extentNode{n.Pos(), n.End()}
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}
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// Remove from f.Locals any Allocs that escape to the heap.
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j := 0
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for _, l := range f.Locals {
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if !l.Heap {
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f.Locals[j] = l
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j++
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}
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}
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// Nil out f.Locals[j:] to aid GC.
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for i := j; i < len(f.Locals); i++ {
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f.Locals[i] = nil
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}
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f.Locals = f.Locals[:j]
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// comma-ok receiving from a time.Tick channel will never return
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// ok == false, so any branching on the value of ok can be
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// replaced with an unconditional jump. This will primarily match
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// `for range time.Tick(x)` loops, but it can also match
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// user-written code.
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for _, block := range f.Blocks {
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if len(block.Instrs) < 3 {
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continue
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}
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if len(block.Succs) != 2 {
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continue
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}
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var instrs []*Instruction
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for i, ins := range block.Instrs {
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if _, ok := ins.(*DebugRef); ok {
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continue
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}
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instrs = append(instrs, &block.Instrs[i])
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}
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for i, ins := range instrs {
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unop, ok := (*ins).(*UnOp)
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if !ok || unop.Op != token.ARROW {
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continue
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}
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call, ok := unop.X.(*Call)
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if !ok {
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continue
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}
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if call.Common().IsInvoke() {
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continue
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}
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// OPT(dh): surely there is a more efficient way of doing
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// this, than using FullName. We should already have
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// resolved time.Tick somewhere?
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v, ok := call.Common().Value.(*Function)
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if !ok {
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continue
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}
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t, ok := v.Object().(*types.Func)
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if !ok {
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continue
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}
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if t.FullName() != "time.Tick" {
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continue
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}
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ex, ok := (*instrs[i+1]).(*Extract)
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if !ok || ex.Tuple != unop || ex.Index != 1 {
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continue
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}
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ifstmt, ok := (*instrs[i+2]).(*If)
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if !ok || ifstmt.Cond != ex {
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continue
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}
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*instrs[i+2] = NewJump(block)
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succ := block.Succs[1]
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block.Succs = block.Succs[0:1]
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succ.RemovePred(block)
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}
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}
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optimizeBlocks(f)
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buildReferrers(f)
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buildDomTree(f)
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if f.Prog.mode&NaiveForm == 0 {
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// For debugging pre-state of lifting pass:
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// numberRegisters(f)
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// f.WriteTo(os.Stderr)
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lift(f)
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}
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f.namedResults = nil // (used by lifting)
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numberRegisters(f)
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if f.Prog.mode&PrintFunctions != 0 {
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printMu.Lock()
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f.WriteTo(os.Stdout)
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printMu.Unlock()
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}
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if f.Prog.mode&SanityCheckFunctions != 0 {
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mustSanityCheck(f, nil)
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}
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}
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func (f *Function) RemoveNilBlocks() {
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f.removeNilBlocks()
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}
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// removeNilBlocks eliminates nils from f.Blocks and updates each
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// BasicBlock.Index. Use this after any pass that may delete blocks.
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//
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func (f *Function) removeNilBlocks() {
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j := 0
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for _, b := range f.Blocks {
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if b != nil {
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b.Index = j
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f.Blocks[j] = b
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j++
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}
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}
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// Nil out f.Blocks[j:] to aid GC.
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for i := j; i < len(f.Blocks); i++ {
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f.Blocks[i] = nil
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}
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f.Blocks = f.Blocks[:j]
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}
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// SetDebugMode sets the debug mode for package pkg. If true, all its
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// functions will include full debug info. This greatly increases the
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// size of the instruction stream, and causes Functions to depend upon
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// the ASTs, potentially keeping them live in memory for longer.
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//
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func (pkg *Package) SetDebugMode(debug bool) {
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// TODO(adonovan): do we want ast.File granularity?
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pkg.debug = debug
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}
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// debugInfo reports whether debug info is wanted for this function.
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func (f *Function) debugInfo() bool {
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return f.Pkg != nil && f.Pkg.debug
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}
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// addNamedLocal creates a local variable, adds it to function f and
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// returns it. Its name and type are taken from obj. Subsequent
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// calls to f.lookup(obj) will return the same local.
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//
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func (f *Function) addNamedLocal(obj types.Object) *Alloc {
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l := f.addLocal(obj.Type(), obj.Pos())
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l.Comment = obj.Name()
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f.objects[obj] = l
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return l
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}
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func (f *Function) addLocalForIdent(id *ast.Ident) *Alloc {
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return f.addNamedLocal(f.Pkg.info.Defs[id])
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}
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// addLocal creates an anonymous local variable of type typ, adds it
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// to function f and returns it. pos is the optional source location.
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//
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func (f *Function) addLocal(typ types.Type, pos token.Pos) *Alloc {
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v := &Alloc{}
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v.setType(types.NewPointer(typ))
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v.setPos(pos)
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f.Locals = append(f.Locals, v)
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f.emit(v)
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return v
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}
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// lookup returns the address of the named variable identified by obj
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// that is local to function f or one of its enclosing functions.
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// If escaping, the reference comes from a potentially escaping pointer
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// expression and the referent must be heap-allocated.
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//
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func (f *Function) lookup(obj types.Object, escaping bool) Value {
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if v, ok := f.objects[obj]; ok {
|
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if alloc, ok := v.(*Alloc); ok && escaping {
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alloc.Heap = true
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}
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return v // function-local var (address)
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}
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// Definition must be in an enclosing function;
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// plumb it through intervening closures.
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if f.parent == nil {
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panic("no ssa.Value for " + obj.String())
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}
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outer := f.parent.lookup(obj, true) // escaping
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v := &FreeVar{
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name: obj.Name(),
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typ: outer.Type(),
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pos: outer.Pos(),
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outer: outer,
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parent: f,
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}
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f.objects[obj] = v
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f.FreeVars = append(f.FreeVars, v)
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return v
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}
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// emit emits the specified instruction to function f.
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func (f *Function) emit(instr Instruction) Value {
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return f.currentBlock.emit(instr)
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}
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|
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// RelString returns the full name of this function, qualified by
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// package name, receiver type, etc.
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//
|
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// The specific formatting rules are not guaranteed and may change.
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//
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// Examples:
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// "math.IsNaN" // a package-level function
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|
// "(*bytes.Buffer).Bytes" // a declared method or a wrapper
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// "(*bytes.Buffer).Bytes$thunk" // thunk (func wrapping method; receiver is param 0)
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// "(*bytes.Buffer).Bytes$bound" // bound (func wrapping method; receiver supplied by closure)
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// "main.main$1" // an anonymous function in main
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// "main.init#1" // a declared init function
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// "main.init" // the synthesized package initializer
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//
|
|
// When these functions are referred to from within the same package
|
|
// (i.e. from == f.Pkg.Object), they are rendered without the package path.
|
|
// For example: "IsNaN", "(*Buffer).Bytes", etc.
|
|
//
|
|
// All non-synthetic functions have distinct package-qualified names.
|
|
// (But two methods may have the same name "(T).f" if one is a synthetic
|
|
// wrapper promoting a non-exported method "f" from another package; in
|
|
// that case, the strings are equal but the identifiers "f" are distinct.)
|
|
//
|
|
func (f *Function) RelString(from *types.Package) string {
|
|
// Anonymous?
|
|
if f.parent != nil {
|
|
// An anonymous function's Name() looks like "parentName$1",
|
|
// but its String() should include the type/package/etc.
|
|
parent := f.parent.RelString(from)
|
|
for i, anon := range f.parent.AnonFuncs {
|
|
if anon == f {
|
|
return fmt.Sprintf("%s$%d", parent, 1+i)
|
|
}
|
|
}
|
|
|
|
return f.name // should never happen
|
|
}
|
|
|
|
// Method (declared or wrapper)?
|
|
if recv := f.Signature.Recv(); recv != nil {
|
|
return f.relMethod(from, recv.Type())
|
|
}
|
|
|
|
// Thunk?
|
|
if f.method != nil {
|
|
return f.relMethod(from, f.method.Recv())
|
|
}
|
|
|
|
// Bound?
|
|
if len(f.FreeVars) == 1 && strings.HasSuffix(f.name, "$bound") {
|
|
return f.relMethod(from, f.FreeVars[0].Type())
|
|
}
|
|
|
|
// Package-level function?
|
|
// Prefix with package name for cross-package references only.
|
|
if p := f.pkg(); p != nil && p != from {
|
|
return fmt.Sprintf("%s.%s", p.Path(), f.name)
|
|
}
|
|
|
|
// Unknown.
|
|
return f.name
|
|
}
|
|
|
|
func (f *Function) relMethod(from *types.Package, recv types.Type) string {
|
|
return fmt.Sprintf("(%s).%s", relType(recv, from), f.name)
|
|
}
|
|
|
|
// writeSignature writes to buf the signature sig in declaration syntax.
|
|
func writeSignature(buf *bytes.Buffer, from *types.Package, name string, sig *types.Signature, params []*Parameter) {
|
|
buf.WriteString("func ")
|
|
if recv := sig.Recv(); recv != nil {
|
|
buf.WriteString("(")
|
|
if n := params[0].Name(); n != "" {
|
|
buf.WriteString(n)
|
|
buf.WriteString(" ")
|
|
}
|
|
types.WriteType(buf, params[0].Type(), types.RelativeTo(from))
|
|
buf.WriteString(") ")
|
|
}
|
|
buf.WriteString(name)
|
|
types.WriteSignature(buf, sig, types.RelativeTo(from))
|
|
}
|
|
|
|
func (f *Function) pkg() *types.Package {
|
|
if f.Pkg != nil {
|
|
return f.Pkg.Pkg
|
|
}
|
|
return nil
|
|
}
|
|
|
|
var _ io.WriterTo = (*Function)(nil) // *Function implements io.Writer
|
|
|
|
func (f *Function) WriteTo(w io.Writer) (int64, error) {
|
|
var buf bytes.Buffer
|
|
WriteFunction(&buf, f)
|
|
n, err := w.Write(buf.Bytes())
|
|
return int64(n), err
|
|
}
|
|
|
|
// WriteFunction writes to buf a human-readable "disassembly" of f.
|
|
func WriteFunction(buf *bytes.Buffer, f *Function) {
|
|
fmt.Fprintf(buf, "# Name: %s\n", f.String())
|
|
if f.Pkg != nil {
|
|
fmt.Fprintf(buf, "# Package: %s\n", f.Pkg.Pkg.Path())
|
|
}
|
|
if syn := f.Synthetic; syn != "" {
|
|
fmt.Fprintln(buf, "# Synthetic:", syn)
|
|
}
|
|
if pos := f.Pos(); pos.IsValid() {
|
|
fmt.Fprintf(buf, "# Location: %s\n", f.Prog.Fset.Position(pos))
|
|
}
|
|
|
|
if f.parent != nil {
|
|
fmt.Fprintf(buf, "# Parent: %s\n", f.parent.Name())
|
|
}
|
|
|
|
if f.Recover != nil {
|
|
fmt.Fprintf(buf, "# Recover: %s\n", f.Recover)
|
|
}
|
|
|
|
from := f.pkg()
|
|
|
|
if f.FreeVars != nil {
|
|
buf.WriteString("# Free variables:\n")
|
|
for i, fv := range f.FreeVars {
|
|
fmt.Fprintf(buf, "# % 3d:\t%s %s\n", i, fv.Name(), relType(fv.Type(), from))
|
|
}
|
|
}
|
|
|
|
if len(f.Locals) > 0 {
|
|
buf.WriteString("# Locals:\n")
|
|
for i, l := range f.Locals {
|
|
fmt.Fprintf(buf, "# % 3d:\t%s %s\n", i, l.Name(), relType(deref(l.Type()), from))
|
|
}
|
|
}
|
|
writeSignature(buf, from, f.Name(), f.Signature, f.Params)
|
|
buf.WriteString(":\n")
|
|
|
|
if f.Blocks == nil {
|
|
buf.WriteString("\t(external)\n")
|
|
}
|
|
|
|
// NB. column calculations are confused by non-ASCII
|
|
// characters and assume 8-space tabs.
|
|
const punchcard = 80 // for old time's sake.
|
|
const tabwidth = 8
|
|
for _, b := range f.Blocks {
|
|
if b == nil {
|
|
// Corrupt CFG.
|
|
fmt.Fprintf(buf, ".nil:\n")
|
|
continue
|
|
}
|
|
n, _ := fmt.Fprintf(buf, "%d:", b.Index)
|
|
bmsg := fmt.Sprintf("%s P:%d S:%d", b.Comment, len(b.Preds), len(b.Succs))
|
|
fmt.Fprintf(buf, "%*s%s\n", punchcard-1-n-len(bmsg), "", bmsg)
|
|
|
|
if false { // CFG debugging
|
|
fmt.Fprintf(buf, "\t# CFG: %s --> %s --> %s\n", b.Preds, b, b.Succs)
|
|
}
|
|
for _, instr := range b.Instrs {
|
|
buf.WriteString("\t")
|
|
switch v := instr.(type) {
|
|
case Value:
|
|
l := punchcard - tabwidth
|
|
// Left-align the instruction.
|
|
if name := v.Name(); name != "" {
|
|
n, _ := fmt.Fprintf(buf, "%s = ", name)
|
|
l -= n
|
|
}
|
|
n, _ := buf.WriteString(instr.String())
|
|
l -= n
|
|
// Right-align the type if there's space.
|
|
if t := v.Type(); t != nil {
|
|
buf.WriteByte(' ')
|
|
ts := relType(t, from)
|
|
l -= len(ts) + len(" ") // (spaces before and after type)
|
|
if l > 0 {
|
|
fmt.Fprintf(buf, "%*s", l, "")
|
|
}
|
|
buf.WriteString(ts)
|
|
}
|
|
case nil:
|
|
// Be robust against bad transforms.
|
|
buf.WriteString("<deleted>")
|
|
default:
|
|
buf.WriteString(instr.String())
|
|
}
|
|
buf.WriteString("\n")
|
|
}
|
|
}
|
|
fmt.Fprintf(buf, "\n")
|
|
}
|
|
|
|
// newBasicBlock adds to f a new basic block and returns it. It does
|
|
// not automatically become the current block for subsequent calls to emit.
|
|
// comment is an optional string for more readable debugging output.
|
|
//
|
|
func (f *Function) newBasicBlock(comment string) *BasicBlock {
|
|
b := &BasicBlock{
|
|
Index: len(f.Blocks),
|
|
Comment: comment,
|
|
parent: f,
|
|
}
|
|
b.Succs = b.succs2[:0]
|
|
f.Blocks = append(f.Blocks, b)
|
|
return b
|
|
}
|
|
|
|
// NewFunction returns a new synthetic Function instance belonging to
|
|
// prog, with its name and signature fields set as specified.
|
|
//
|
|
// The caller is responsible for initializing the remaining fields of
|
|
// the function object, e.g. Pkg, Params, Blocks.
|
|
//
|
|
// It is practically impossible for clients to construct well-formed
|
|
// SSA functions/packages/programs directly, so we assume this is the
|
|
// job of the Builder alone. NewFunction exists to provide clients a
|
|
// little flexibility. For example, analysis tools may wish to
|
|
// construct fake Functions for the root of the callgraph, a fake
|
|
// "reflect" package, etc.
|
|
//
|
|
// TODO(adonovan): think harder about the API here.
|
|
//
|
|
func (prog *Program) NewFunction(name string, sig *types.Signature, provenance string) *Function {
|
|
return &Function{Prog: prog, name: name, Signature: sig, Synthetic: provenance}
|
|
}
|
|
|
|
type extentNode [2]token.Pos
|
|
|
|
func (n extentNode) Pos() token.Pos { return n[0] }
|
|
func (n extentNode) End() token.Pos { return n[1] }
|
|
|
|
// Syntax returns an ast.Node whose Pos/End methods provide the
|
|
// lexical extent of the function if it was defined by Go source code
|
|
// (f.Synthetic==""), or nil otherwise.
|
|
//
|
|
// If f was built with debug information (see Package.SetDebugRef),
|
|
// the result is the *ast.FuncDecl or *ast.FuncLit that declared the
|
|
// function. Otherwise, it is an opaque Node providing only position
|
|
// information; this avoids pinning the AST in memory.
|
|
//
|
|
func (f *Function) Syntax() ast.Node { return f.syntax }
|