VictoriaMetrics/vendor/honnef.co/go/tools/ir/lift.go
Aliaksandr Valialkin 8c2d396e8a make vendor-update
2020-02-26 20:46:24 +02:00

1064 lines
26 KiB
Go
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

// Copyright 2013 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 ir
// This file defines the lifting pass which tries to "lift" Alloc
// cells (new/local variables) into SSA registers, replacing loads
// with the dominating stored value, eliminating loads and stores, and
// inserting φ- and σ-nodes as needed.
// Cited papers and resources:
//
// Ron Cytron et al. 1991. Efficiently computing SSA form...
// http://doi.acm.org/10.1145/115372.115320
//
// Cooper, Harvey, Kennedy. 2001. A Simple, Fast Dominance Algorithm.
// Software Practice and Experience 2001, 4:1-10.
// http://www.hipersoft.rice.edu/grads/publications/dom14.pdf
//
// Daniel Berlin, llvmdev mailing list, 2012.
// http://lists.cs.uiuc.edu/pipermail/llvmdev/2012-January/046638.html
// (Be sure to expand the whole thread.)
//
// C. Scott Ananian. 1997. The static single information form.
//
// Jeremy Singer. 2006. Static program analysis based on virtual register renaming.
// TODO(adonovan): opt: there are many optimizations worth evaluating, and
// the conventional wisdom for SSA construction is that a simple
// algorithm well engineered often beats those of better asymptotic
// complexity on all but the most egregious inputs.
//
// Danny Berlin suggests that the Cooper et al. algorithm for
// computing the dominance frontier is superior to Cytron et al.
// Furthermore he recommends that rather than computing the DF for the
// whole function then renaming all alloc cells, it may be cheaper to
// compute the DF for each alloc cell separately and throw it away.
//
// Consider exploiting liveness information to avoid creating dead
// φ-nodes which we then immediately remove.
//
// Also see many other "TODO: opt" suggestions in the code.
import (
"fmt"
"go/types"
"os"
)
// If true, show diagnostic information at each step of lifting.
// Very verbose.
const debugLifting = false
// domFrontier maps each block to the set of blocks in its dominance
// frontier. The outer slice is conceptually a map keyed by
// Block.Index. The inner slice is conceptually a set, possibly
// containing duplicates.
//
// TODO(adonovan): opt: measure impact of dups; consider a packed bit
// representation, e.g. big.Int, and bitwise parallel operations for
// the union step in the Children loop.
//
// domFrontier's methods mutate the slice's elements but not its
// length, so their receivers needn't be pointers.
//
type domFrontier [][]*BasicBlock
func (df domFrontier) add(u, v *BasicBlock) {
df[u.Index] = append(df[u.Index], v)
}
// build builds the dominance frontier df for the dominator tree of
// fn, using the algorithm found in A Simple, Fast Dominance
// Algorithm, Figure 5.
//
// TODO(adonovan): opt: consider Berlin approach, computing pruned SSA
// by pruning the entire IDF computation, rather than merely pruning
// the DF -> IDF step.
func (df domFrontier) build(fn *Function) {
for _, b := range fn.Blocks {
if len(b.Preds) >= 2 {
for _, p := range b.Preds {
runner := p
for runner != b.dom.idom {
df.add(runner, b)
runner = runner.dom.idom
}
}
}
}
}
func buildDomFrontier(fn *Function) domFrontier {
df := make(domFrontier, len(fn.Blocks))
df.build(fn)
return df
}
type postDomFrontier [][]*BasicBlock
func (rdf postDomFrontier) add(u, v *BasicBlock) {
rdf[u.Index] = append(rdf[u.Index], v)
}
func (rdf postDomFrontier) build(fn *Function) {
for _, b := range fn.Blocks {
if len(b.Succs) >= 2 {
for _, s := range b.Succs {
runner := s
for runner != b.pdom.idom {
rdf.add(runner, b)
runner = runner.pdom.idom
}
}
}
}
}
func buildPostDomFrontier(fn *Function) postDomFrontier {
rdf := make(postDomFrontier, len(fn.Blocks))
rdf.build(fn)
return rdf
}
func removeInstr(refs []Instruction, instr Instruction) []Instruction {
i := 0
for _, ref := range refs {
if ref == instr {
continue
}
refs[i] = ref
i++
}
for j := i; j != len(refs); j++ {
refs[j] = nil // aid GC
}
return refs[:i]
}
func clearInstrs(instrs []Instruction) {
for i := range instrs {
instrs[i] = nil
}
}
// lift replaces local and new Allocs accessed only with
// load/store by IR registers, inserting φ- and σ-nodes where necessary.
// The result is a program in pruned SSI form.
//
// Preconditions:
// - fn has no dead blocks (blockopt has run).
// - Def/use info (Operands and Referrers) is up-to-date.
// - The dominator tree is up-to-date.
//
func lift(fn *Function) {
// TODO(adonovan): opt: lots of little optimizations may be
// worthwhile here, especially if they cause us to avoid
// buildDomFrontier. For example:
//
// - Alloc never loaded? Eliminate.
// - Alloc never stored? Replace all loads with a zero constant.
// - Alloc stored once? Replace loads with dominating store;
// don't forget that an Alloc is itself an effective store
// of zero.
// - Alloc used only within a single block?
// Use degenerate algorithm avoiding φ-nodes.
// - Consider synergy with scalar replacement of aggregates (SRA).
// e.g. *(&x.f) where x is an Alloc.
// Perhaps we'd get better results if we generated this as x.f
// i.e. Field(x, .f) instead of Load(FieldIndex(x, .f)).
// Unclear.
//
// But we will start with the simplest correct code.
var df domFrontier
var rdf postDomFrontier
var closure *closure
var newPhis newPhiMap
var newSigmas newSigmaMap
// During this pass we will replace some BasicBlock.Instrs
// (allocs, loads and stores) with nil, keeping a count in
// BasicBlock.gaps. At the end we will reset Instrs to the
// concatenation of all non-dead newPhis and non-nil Instrs
// for the block, reusing the original array if space permits.
// While we're here, we also eliminate 'rundefers'
// instructions in functions that contain no 'defer'
// instructions.
usesDefer := false
// Determine which allocs we can lift and number them densely.
// The renaming phase uses this numbering for compact maps.
numAllocs := 0
for _, b := range fn.Blocks {
b.gaps = 0
b.rundefers = 0
for _, instr := range b.Instrs {
switch instr := instr.(type) {
case *Alloc:
if !liftable(instr) {
instr.index = -1
continue
}
index := -1
if numAllocs == 0 {
df = buildDomFrontier(fn)
rdf = buildPostDomFrontier(fn)
if len(fn.Blocks) > 2 {
closure = transitiveClosure(fn)
}
newPhis = make(newPhiMap, len(fn.Blocks))
newSigmas = make(newSigmaMap, len(fn.Blocks))
if debugLifting {
title := false
for i, blocks := range df {
if blocks != nil {
if !title {
fmt.Fprintf(os.Stderr, "Dominance frontier of %s:\n", fn)
title = true
}
fmt.Fprintf(os.Stderr, "\t%s: %s\n", fn.Blocks[i], blocks)
}
}
}
}
liftAlloc(closure, df, rdf, instr, newPhis, newSigmas)
index = numAllocs
numAllocs++
instr.index = index
case *Defer:
usesDefer = true
case *RunDefers:
b.rundefers++
}
}
}
if numAllocs > 0 {
// renaming maps an alloc (keyed by index) to its replacement
// value. Initially the renaming contains nil, signifying the
// zero constant of the appropriate type; we construct the
// Const lazily at most once on each path through the domtree.
// TODO(adonovan): opt: cache per-function not per subtree.
renaming := make([]Value, numAllocs)
// Renaming.
rename(fn.Blocks[0], renaming, newPhis, newSigmas)
simplifyPhis(newPhis)
// Eliminate dead φ- and σ-nodes.
markLiveNodes(fn.Blocks, newPhis, newSigmas)
}
// Prepend remaining live φ-nodes to each block and possibly kill rundefers.
for _, b := range fn.Blocks {
var head []Instruction
if numAllocs > 0 {
nps := newPhis[b.Index]
head = make([]Instruction, 0, len(nps))
for _, pred := range b.Preds {
nss := newSigmas[pred.Index]
idx := pred.succIndex(b)
for _, newSigma := range nss {
if sigma := newSigma.sigmas[idx]; sigma != nil && sigma.live {
head = append(head, sigma)
// we didn't populate referrers before, as most
// sigma nodes will be killed
if refs := sigma.X.Referrers(); refs != nil {
*refs = append(*refs, sigma)
}
} else if sigma != nil {
sigma.block = nil
}
}
}
for _, np := range nps {
if np.phi.live {
head = append(head, np.phi)
} else {
for _, edge := range np.phi.Edges {
if refs := edge.Referrers(); refs != nil {
*refs = removeInstr(*refs, np.phi)
}
}
np.phi.block = nil
}
}
}
rundefersToKill := b.rundefers
if usesDefer {
rundefersToKill = 0
}
j := len(head)
if j+b.gaps+rundefersToKill == 0 {
continue // fast path: no new phis or gaps
}
// We could do straight copies instead of element-wise copies
// when both b.gaps and rundefersToKill are zero. However,
// that seems to only be the case ~1% of the time, which
// doesn't seem worth the extra branch.
// Remove dead instructions, add phis and sigmas
ns := len(b.Instrs) + j - b.gaps - rundefersToKill
if ns <= cap(b.Instrs) {
// b.Instrs has enough capacity to store all instructions
// OPT(dh): check cap vs the actually required space; if
// there is a big enough difference, it may be worth
// allocating a new slice, to avoid pinning memory.
dst := b.Instrs[:cap(b.Instrs)]
i := len(dst) - 1
for n := len(b.Instrs) - 1; n >= 0; n-- {
instr := dst[n]
if instr == nil {
continue
}
if !usesDefer {
if _, ok := instr.(*RunDefers); ok {
continue
}
}
dst[i] = instr
i--
}
off := i + 1 - len(head)
// aid GC
clearInstrs(dst[:off])
dst = dst[off:]
copy(dst, head)
b.Instrs = dst
} else {
// not enough space, so allocate a new slice and copy
// over.
dst := make([]Instruction, ns)
copy(dst, head)
for _, instr := range b.Instrs {
if instr == nil {
continue
}
if !usesDefer {
if _, ok := instr.(*RunDefers); ok {
continue
}
}
dst[j] = instr
j++
}
b.Instrs = dst
}
}
// Remove any fn.Locals that were lifted.
j := 0
for _, l := range fn.Locals {
if l.index < 0 {
fn.Locals[j] = l
j++
}
}
// Nil out fn.Locals[j:] to aid GC.
for i := j; i < len(fn.Locals); i++ {
fn.Locals[i] = nil
}
fn.Locals = fn.Locals[:j]
}
func hasDirectReferrer(instr Instruction) bool {
for _, instr := range *instr.Referrers() {
switch instr.(type) {
case *Phi, *Sigma:
// ignore
default:
return true
}
}
return false
}
func markLiveNodes(blocks []*BasicBlock, newPhis newPhiMap, newSigmas newSigmaMap) {
// Phi and sigma nodes are considered live if a non-phi, non-sigma
// node uses them. Once we find a node that is live, we mark all
// of its operands as used, too.
for _, npList := range newPhis {
for _, np := range npList {
phi := np.phi
if !phi.live && hasDirectReferrer(phi) {
markLivePhi(phi)
}
}
}
for _, npList := range newSigmas {
for _, np := range npList {
for _, sigma := range np.sigmas {
if sigma != nil && !sigma.live && hasDirectReferrer(sigma) {
markLiveSigma(sigma)
}
}
}
}
// Existing φ-nodes due to && and || operators
// are all considered live (see Go issue 19622).
for _, b := range blocks {
for _, phi := range b.phis() {
markLivePhi(phi.(*Phi))
}
}
}
func markLivePhi(phi *Phi) {
phi.live = true
for _, rand := range phi.Edges {
switch rand := rand.(type) {
case *Phi:
if !rand.live {
markLivePhi(rand)
}
case *Sigma:
if !rand.live {
markLiveSigma(rand)
}
}
}
}
func markLiveSigma(sigma *Sigma) {
sigma.live = true
switch rand := sigma.X.(type) {
case *Phi:
if !rand.live {
markLivePhi(rand)
}
case *Sigma:
if !rand.live {
markLiveSigma(rand)
}
}
}
// simplifyPhis replaces trivial phis with non-phi alternatives. Phi
// nodes where all edges are identical, or consist of only the phi
// itself and one other value, may be replaced with the value.
func simplifyPhis(newPhis newPhiMap) {
// find all phis that are trivial and can be replaced with a
// non-phi value. run until we reach a fixpoint, because replacing
// a phi may make other phis trivial.
for changed := true; changed; {
changed = false
for _, npList := range newPhis {
for _, np := range npList {
if np.phi.live {
// we're reusing 'live' to mean 'dead' in the context of simplifyPhis
continue
}
if r, ok := isUselessPhi(np.phi); ok {
// useless phi, replace its uses with the
// replacement value. the dead phi pass will clean
// up the phi afterwards.
replaceAll(np.phi, r)
np.phi.live = true
changed = true
}
}
}
}
for _, npList := range newPhis {
for _, np := range npList {
np.phi.live = false
}
}
}
type BlockSet struct {
idx int
values []bool
count int
}
func NewBlockSet(size int) *BlockSet {
return &BlockSet{values: make([]bool, size)}
}
func (s *BlockSet) Set(s2 *BlockSet) {
copy(s.values, s2.values)
s.count = 0
for _, v := range s.values {
if v {
s.count++
}
}
}
func (s *BlockSet) Num() int {
return s.count
}
func (s *BlockSet) Has(b *BasicBlock) bool {
if b.Index >= len(s.values) {
return false
}
return s.values[b.Index]
}
// add adds b to the set and returns true if the set changed.
func (s *BlockSet) Add(b *BasicBlock) bool {
if s.values[b.Index] {
return false
}
s.count++
s.values[b.Index] = true
s.idx = b.Index
return true
}
func (s *BlockSet) Clear() {
for j := range s.values {
s.values[j] = false
}
s.count = 0
}
// take removes an arbitrary element from a set s and
// returns its index, or returns -1 if empty.
func (s *BlockSet) Take() int {
// [i, end]
for i := s.idx; i < len(s.values); i++ {
if s.values[i] {
s.values[i] = false
s.idx = i
s.count--
return i
}
}
// [start, i)
for i := 0; i < s.idx; i++ {
if s.values[i] {
s.values[i] = false
s.idx = i
s.count--
return i
}
}
return -1
}
type closure struct {
span []uint32
reachables []interval
}
type interval uint32
const (
flagMask = 1 << 31
numBits = 20
lengthBits = 32 - numBits - 1
lengthMask = (1<<lengthBits - 1) << numBits
numMask = 1<<numBits - 1
)
func (c closure) has(s, v *BasicBlock) bool {
idx := uint32(v.Index)
if idx == 1 || s.Dominates(v) {
return true
}
r := c.reachable(s.Index)
for i := 0; i < len(r); i++ {
inv := r[i]
var start, end uint32
if inv&flagMask == 0 {
// small interval
start = uint32(inv & numMask)
end = start + uint32(inv&lengthMask)>>numBits
} else {
// large interval
i++
start = uint32(inv & numMask)
end = uint32(r[i])
}
if idx >= start && idx <= end {
return true
}
}
return false
}
func (c closure) reachable(id int) []interval {
return c.reachables[c.span[id]:c.span[id+1]]
}
func (c closure) walk(current *BasicBlock, b *BasicBlock, visited []bool) {
visited[b.Index] = true
for _, succ := range b.Succs {
if visited[succ.Index] {
continue
}
visited[succ.Index] = true
c.walk(current, succ, visited)
}
}
func transitiveClosure(fn *Function) *closure {
reachable := make([]bool, len(fn.Blocks))
c := &closure{}
c.span = make([]uint32, len(fn.Blocks)+1)
addInterval := func(start, end uint32) {
if l := end - start; l <= 1<<lengthBits-1 {
n := interval(l<<numBits | start)
c.reachables = append(c.reachables, n)
} else {
n1 := interval(1<<31 | start)
n2 := interval(end)
c.reachables = append(c.reachables, n1, n2)
}
}
for i, b := range fn.Blocks[1:] {
for i := range reachable {
reachable[i] = false
}
c.walk(b, b, reachable)
start := ^uint32(0)
for id, isReachable := range reachable {
if !isReachable {
if start != ^uint32(0) {
end := uint32(id) - 1
addInterval(start, end)
start = ^uint32(0)
}
continue
} else if start == ^uint32(0) {
start = uint32(id)
}
}
if start != ^uint32(0) {
addInterval(start, uint32(len(reachable))-1)
}
c.span[i+2] = uint32(len(c.reachables))
}
return c
}
// newPhi is a pair of a newly introduced φ-node and the lifted Alloc
// it replaces.
type newPhi struct {
phi *Phi
alloc *Alloc
}
type newSigma struct {
alloc *Alloc
sigmas []*Sigma
}
// newPhiMap records for each basic block, the set of newPhis that
// must be prepended to the block.
type newPhiMap [][]newPhi
type newSigmaMap [][]newSigma
func liftable(alloc *Alloc) bool {
// Don't lift aggregates into registers, because we don't have
// a way to express their zero-constants.
switch deref(alloc.Type()).Underlying().(type) {
case *types.Array, *types.Struct:
return false
}
fn := alloc.Parent()
// Don't lift named return values in functions that defer
// calls that may recover from panic.
if fn.hasDefer {
for _, nr := range fn.namedResults {
if nr == alloc {
return false
}
}
}
for _, instr := range *alloc.Referrers() {
switch instr := instr.(type) {
case *Store:
if instr.Val == alloc {
return false // address used as value
}
if instr.Addr != alloc {
panic("Alloc.Referrers is inconsistent")
}
case *Load:
if instr.X != alloc {
panic("Alloc.Referrers is inconsistent")
}
case *DebugRef:
// ok
default:
return false
}
}
return true
}
// liftAlloc determines whether alloc can be lifted into registers,
// and if so, it populates newPhis with all the φ-nodes it may require
// and returns true.
func liftAlloc(closure *closure, df domFrontier, rdf postDomFrontier, alloc *Alloc, newPhis newPhiMap, newSigmas newSigmaMap) {
fn := alloc.Parent()
defblocks := fn.blockset(0)
useblocks := fn.blockset(1)
Aphi := fn.blockset(2)
Asigma := fn.blockset(3)
W := fn.blockset(4)
// Compute defblocks, the set of blocks containing a
// definition of the alloc cell.
for _, instr := range *alloc.Referrers() {
// Bail out if we discover the alloc is not liftable;
// the only operations permitted to use the alloc are
// loads/stores into the cell, and DebugRef.
switch instr := instr.(type) {
case *Store:
defblocks.Add(instr.Block())
case *Load:
useblocks.Add(instr.Block())
for _, ref := range *instr.Referrers() {
useblocks.Add(ref.Block())
}
}
}
// The Alloc itself counts as a (zero) definition of the cell.
defblocks.Add(alloc.Block())
if debugLifting {
fmt.Fprintln(os.Stderr, "\tlifting ", alloc, alloc.Name())
}
// Φ-insertion.
//
// What follows is the body of the main loop of the insert-φ
// function described by Cytron et al, but instead of using
// counter tricks, we just reset the 'hasAlready' and 'work'
// sets each iteration. These are bitmaps so it's pretty cheap.
// Initialize W and work to defblocks.
for change := true; change; {
change = false
{
// Traverse iterated dominance frontier, inserting φ-nodes.
W.Set(defblocks)
for i := W.Take(); i != -1; i = W.Take() {
n := fn.Blocks[i]
for _, y := range df[n.Index] {
if Aphi.Add(y) {
if len(*alloc.Referrers()) == 0 {
continue
}
live := false
if closure == nil {
live = true
} else {
for _, ref := range *alloc.Referrers() {
if _, ok := ref.(*Load); ok {
if closure.has(y, ref.Block()) {
live = true
break
}
}
}
}
if !live {
continue
}
// Create φ-node.
// It will be prepended to v.Instrs later, if needed.
phi := &Phi{
Edges: make([]Value, len(y.Preds)),
}
phi.source = alloc.source
phi.setType(deref(alloc.Type()))
phi.block = y
if debugLifting {
fmt.Fprintf(os.Stderr, "\tplace %s = %s at block %s\n", phi.Name(), phi, y)
}
newPhis[y.Index] = append(newPhis[y.Index], newPhi{phi, alloc})
for _, p := range y.Preds {
useblocks.Add(p)
}
change = true
if defblocks.Add(y) {
W.Add(y)
}
}
}
}
}
{
W.Set(useblocks)
for i := W.Take(); i != -1; i = W.Take() {
n := fn.Blocks[i]
for _, y := range rdf[n.Index] {
if Asigma.Add(y) {
sigmas := make([]*Sigma, 0, len(y.Succs))
anyLive := false
for _, succ := range y.Succs {
live := false
for _, ref := range *alloc.Referrers() {
if closure == nil || closure.has(succ, ref.Block()) {
live = true
anyLive = true
break
}
}
if live {
sigma := &Sigma{
From: y,
X: alloc,
}
sigma.source = alloc.source
sigma.setType(deref(alloc.Type()))
sigma.block = succ
sigmas = append(sigmas, sigma)
} else {
sigmas = append(sigmas, nil)
}
}
if anyLive {
newSigmas[y.Index] = append(newSigmas[y.Index], newSigma{alloc, sigmas})
for _, s := range y.Succs {
defblocks.Add(s)
}
change = true
if useblocks.Add(y) {
W.Add(y)
}
}
}
}
}
}
}
}
// replaceAll replaces all intraprocedural uses of x with y,
// updating x.Referrers and y.Referrers.
// Precondition: x.Referrers() != nil, i.e. x must be local to some function.
//
func replaceAll(x, y Value) {
var rands []*Value
pxrefs := x.Referrers()
pyrefs := y.Referrers()
for _, instr := range *pxrefs {
rands = instr.Operands(rands[:0]) // recycle storage
for _, rand := range rands {
if *rand != nil {
if *rand == x {
*rand = y
}
}
}
if pyrefs != nil {
*pyrefs = append(*pyrefs, instr) // dups ok
}
}
*pxrefs = nil // x is now unreferenced
}
// renamed returns the value to which alloc is being renamed,
// constructing it lazily if it's the implicit zero initialization.
//
func renamed(fn *Function, renaming []Value, alloc *Alloc) Value {
v := renaming[alloc.index]
if v == nil {
v = emitConst(fn, zeroConst(deref(alloc.Type())))
renaming[alloc.index] = v
}
return v
}
// rename implements the Cytron et al-based SSI renaming algorithm, a
// preorder traversal of the dominator tree replacing all loads of
// Alloc cells with the value stored to that cell by the dominating
// store instruction.
//
// renaming is a map from *Alloc (keyed by index number) to its
// dominating stored value; newPhis[x] is the set of new φ-nodes to be
// prepended to block x.
//
func rename(u *BasicBlock, renaming []Value, newPhis newPhiMap, newSigmas newSigmaMap) {
// Each φ-node becomes the new name for its associated Alloc.
for _, np := range newPhis[u.Index] {
phi := np.phi
alloc := np.alloc
renaming[alloc.index] = phi
}
// Rename loads and stores of allocs.
for i, instr := range u.Instrs {
switch instr := instr.(type) {
case *Alloc:
if instr.index >= 0 { // store of zero to Alloc cell
// Replace dominated loads by the zero value.
renaming[instr.index] = nil
if debugLifting {
fmt.Fprintf(os.Stderr, "\tkill alloc %s\n", instr)
}
// Delete the Alloc.
u.Instrs[i] = nil
u.gaps++
}
case *Store:
if alloc, ok := instr.Addr.(*Alloc); ok && alloc.index >= 0 { // store to Alloc cell
// Replace dominated loads by the stored value.
renaming[alloc.index] = instr.Val
if debugLifting {
fmt.Fprintf(os.Stderr, "\tkill store %s; new value: %s\n",
instr, instr.Val.Name())
}
if refs := instr.Addr.Referrers(); refs != nil {
*refs = removeInstr(*refs, instr)
}
if refs := instr.Val.Referrers(); refs != nil {
*refs = removeInstr(*refs, instr)
}
// Delete the Store.
u.Instrs[i] = nil
u.gaps++
}
case *Load:
if alloc, ok := instr.X.(*Alloc); ok && alloc.index >= 0 { // load of Alloc cell
// In theory, we wouldn't be able to replace loads
// directly, because a loaded value could be used in
// different branches, in which case it should be
// replaced with different sigma nodes. But we can't
// simply defer replacement, either, because then
// later stores might incorrectly affect this load.
//
// To avoid doing renaming on _all_ values (instead of
// just loads and stores like we're doing), we make
// sure during code generation that each load is only
// used in one block. For example, in constant switch
// statements, where the tag is only evaluated once,
// we store it in a temporary and load it for each
// comparison, so that we have individual loads to
// replace.
newval := renamed(u.Parent(), renaming, alloc)
if debugLifting {
fmt.Fprintf(os.Stderr, "\tupdate load %s = %s with %s\n",
instr.Name(), instr, newval)
}
replaceAll(instr, newval)
u.Instrs[i] = nil
u.gaps++
}
case *DebugRef:
if x, ok := instr.X.(*Alloc); ok && x.index >= 0 {
if instr.IsAddr {
instr.X = renamed(u.Parent(), renaming, x)
instr.IsAddr = false
// Add DebugRef to instr.X's referrers.
if refs := instr.X.Referrers(); refs != nil {
*refs = append(*refs, instr)
}
} else {
// A source expression denotes the address
// of an Alloc that was optimized away.
instr.X = nil
// Delete the DebugRef.
u.Instrs[i] = nil
u.gaps++
}
}
}
}
// update all outgoing sigma nodes with the dominating store
for _, sigmas := range newSigmas[u.Index] {
for _, sigma := range sigmas.sigmas {
if sigma == nil {
continue
}
sigma.X = renamed(u.Parent(), renaming, sigmas.alloc)
}
}
// For each φ-node in a CFG successor, rename the edge.
for succi, v := range u.Succs {
phis := newPhis[v.Index]
if len(phis) == 0 {
continue
}
i := v.predIndex(u)
for _, np := range phis {
phi := np.phi
alloc := np.alloc
// if there's a sigma node, use it, else use the dominating value
var newval Value
for _, sigmas := range newSigmas[u.Index] {
if sigmas.alloc == alloc && sigmas.sigmas[succi] != nil {
newval = sigmas.sigmas[succi]
break
}
}
if newval == nil {
newval = renamed(u.Parent(), renaming, alloc)
}
if debugLifting {
fmt.Fprintf(os.Stderr, "\tsetphi %s edge %s -> %s (#%d) (alloc=%s) := %s\n",
phi.Name(), u, v, i, alloc.Name(), newval.Name())
}
phi.Edges[i] = newval
if prefs := newval.Referrers(); prefs != nil {
*prefs = append(*prefs, phi)
}
}
}
// Continue depth-first recursion over domtree, pushing a
// fresh copy of the renaming map for each subtree.
r := make([]Value, len(renaming))
for _, v := range u.dom.children {
// XXX add debugging
copy(r, renaming)
// on entry to a block, the incoming sigma nodes become the new values for their alloc
if idx := u.succIndex(v); idx != -1 {
for _, sigma := range newSigmas[u.Index] {
if sigma.sigmas[idx] != nil {
r[sigma.alloc.index] = sigma.sigmas[idx]
}
}
}
rename(v, r, newPhis, newSigmas)
}
}