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2accef29d7
A function such as this: func one() (x int) { defer func() { recover() }() x = 1 panic("return") } that combines named return parameters (NRPs) with deferred calls that call recover, may return non-zero values despite the fact it doesn't even contain a return statement. (!) This requires a change to the SSA API: all functions' control-flow graphs now have a second entry point, called Recover, which is the block at which control flow resumes after a recovered panic. The Recover block simply loads the NRPs and returns them. As an optimization, most functions don't need a Recover block, so it is omitted. In fact it is only needed for functions that have NRPs and defer a call to another function that _may_ call recover. Dataflow analysis of SSA now requires extra work, since every may-panic instruction has an implicit control-flow edge to the Recover block. The only dataflow analysis so far implemented is SSA renaming, for which we make the following simplifying assumption: the Recover block only loads the NRPs and returns. This means we don't really need to analyze it, we can just skip the "lifting" of such NRPs. We also special-case the Recover block in the dominance computation. Rejected alternative approaches: - Specifying a Recover block for every defer instruction (like a traditional exception handler). This seemed like excessive generality, since Go programs only need the same degenerate form of Recover block. - Adding an instruction to set the Recover block immediately after the named return values are set up, so that dominance can be computed without special-casing. This didn't seem worth the effort. Interpreter: - This CL completely reimplements the panic/recover/ defer logic in the interpreter. It's clearer and simpler and closer to the model in the spec. - Some runtime panic messages have been changed to be closer to gc's, since tests depend on it. - The interpreter now requires that the runtime.runtimeError type be part of the SSA program. This requires that clients import this package prior to invoking the interpreter. This in turn requires (Importer).ImportPackage(path string), which this CL adds. - All $GOROOT/test/recover{,1,2,3}.go tests are now passing. NB, the bug described in coverage.go (defer/recover in a concatenated init function) remains. Will be fixed in a follow-up. Fixes golang/go#6381 R=gri CC=crawshaw, golang-dev https://golang.org/cl/13844043
531 lines
15 KiB
Go
531 lines
15 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 defines the lifting pass which tries to "lift" Alloc
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// cells (new/local variables) into SSA registers, replacing loads
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// with the dominating stored value, eliminating loads and stores, and
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// inserting φ-nodes as needed.
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// Cited papers and resources:
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//
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// Ron Cytron et al. 1991. Efficiently computing SSA form...
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// http://doi.acm.org/10.1145/115372.115320
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//
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// Cooper, Harvey, Kennedy. 2001. A Simple, Fast Dominance Algorithm.
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// Software Practice and Experience 2001, 4:1-10.
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// http://www.hipersoft.rice.edu/grads/publications/dom14.pdf
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//
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// Daniel Berlin, llvmdev mailing list, 2012.
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// http://lists.cs.uiuc.edu/pipermail/llvmdev/2012-January/046638.html
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// (Be sure to expand the whole thread.)
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// TODO(adonovan): opt: there are many optimizations worth evaluating, and
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// the conventional wisdom for SSA construction is that a simple
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// algorithm well engineered often beats those of better asymptotic
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// complexity on all but the most egregious inputs.
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//
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// Danny Berlin suggests that the Cooper et al. algorithm for
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// computing the dominance frontier is superior to Cytron et al.
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// Furthermore he recommends that rather than computing the DF for the
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// whole function then renaming all alloc cells, it may be cheaper to
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// compute the DF for each alloc cell separately and throw it away.
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//
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// Consider exploiting liveness information to avoid creating dead
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// φ-nodes which we then immediately remove.
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//
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// Integrate lifting with scalar replacement of aggregates (SRA) since
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// the two are synergistic.
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//
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// Also see many other "TODO: opt" suggestions in the code.
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import (
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"fmt"
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"go/token"
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"math/big"
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"os"
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"code.google.com/p/go.tools/go/types"
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)
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// If true, perform sanity checking and show diagnostic information at
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// each step of lifting. Very verbose.
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const debugLifting = false
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// domFrontier maps each block to the set of blocks in its dominance
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// frontier. The outer slice is conceptually a map keyed by
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// Block.Index. The inner slice is conceptually a set, possibly
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// containing duplicates.
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//
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// TODO(adonovan): opt: measure impact of dups; consider a packed bit
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// representation, e.g. big.Int, and bitwise parallel operations for
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// the union step in the Children loop.
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//
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// domFrontier's methods mutate the slice's elements but not its
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// length, so their receivers needn't be pointers.
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//
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type domFrontier [][]*BasicBlock
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func (df domFrontier) add(u, v *domNode) {
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p := &df[u.Block.Index]
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*p = append(*p, v.Block)
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}
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// build builds the dominance frontier df for the dominator (sub)tree
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// rooted at u, using the Cytron et al. algorithm.
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//
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// TODO(adonovan): opt: consider Berlin approach, computing pruned SSA
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// by pruning the entire IDF computation, rather than merely pruning
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// the DF -> IDF step.
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func (df domFrontier) build(u *domNode) {
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// Encounter each node u in postorder of dom tree.
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for _, child := range u.Children {
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df.build(child)
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}
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for _, vb := range u.Block.Succs {
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if v := vb.dom; v.Idom != u {
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df.add(u, v)
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}
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}
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for _, w := range u.Children {
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for _, vb := range df[w.Block.Index] {
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// TODO(adonovan): opt: use word-parallel bitwise union.
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if v := vb.dom; v.Idom != u {
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df.add(u, v)
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}
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}
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}
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}
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func buildDomFrontier(fn *Function) domFrontier {
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df := make(domFrontier, len(fn.Blocks))
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df.build(fn.Blocks[0].dom)
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if fn.Recover != nil {
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df.build(fn.Recover.dom)
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}
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return df
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}
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// lift attempts to replace local and new Allocs accessed only with
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// load/store by SSA registers, inserting φ-nodes where necessary.
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// The result is a program in classical pruned SSA form.
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//
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// Preconditions:
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// - fn has no dead blocks (blockopt has run).
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// - Def/use info (Operands and Referrers) is up-to-date.
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//
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func lift(fn *Function) {
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// TODO(adonovan): opt: lots of little optimizations may be
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// worthwhile here, especially if they cause us to avoid
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// buildDomTree. For example:
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//
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// - Alloc never loaded? Eliminate.
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// - Alloc never stored? Replace all loads with a zero constant.
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// - Alloc stored once? Replace loads with dominating store;
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// don't forget that an Alloc is itself an effective store
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// of zero.
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// - Alloc used only within a single block?
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// Use degenerate algorithm avoiding φ-nodes.
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// - Consider synergy with scalar replacement of aggregates (SRA).
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// e.g. *(&x.f) where x is an Alloc.
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// Perhaps we'd get better results if we generated this as x.f
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// i.e. Field(x, .f) instead of Load(FieldIndex(x, .f)).
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// Unclear.
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//
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// But we will start with the simplest correct code.
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buildDomTree(fn)
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df := buildDomFrontier(fn)
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if debugLifting {
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title := false
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for i, blocks := range df {
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if blocks != nil {
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if !title {
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fmt.Fprintln(os.Stderr, "Dominance frontier:")
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title = true
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}
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fmt.Fprintf(os.Stderr, "\t%s: %s\n", fn.Blocks[i], blocks)
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}
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}
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}
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newPhis := make(newPhiMap)
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// During this pass we will replace some BasicBlock.Instrs
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// (allocs, loads and stores) with nil, keeping a count in
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// BasicBlock.gaps. At the end we will reset Instrs to the
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// concatenation of all non-dead newPhis and non-nil Instrs
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// for the block, reusing the original array if space permits.
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// While we're here, we also eliminate 'rundefers'
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// instructions in functions that contain no 'defer'
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// instructions.
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usesDefer := false
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// Determine which allocs we can lift and number them densely.
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// The renaming phase uses this numbering for compact maps.
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numAllocs := 0
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for _, b := range fn.Blocks {
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b.gaps = 0
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b.rundefers = 0
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for i, instr := range b.Instrs {
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switch instr := instr.(type) {
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case *Alloc:
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if liftAlloc(df, instr, newPhis) {
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instr.index = numAllocs
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numAllocs++
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// Delete the alloc.
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b.Instrs[i] = nil
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b.gaps++
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} else {
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instr.index = -1
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}
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case *Defer:
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usesDefer = true
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case *RunDefers:
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b.rundefers++
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}
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}
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}
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// renaming maps an alloc (keyed by index) to its replacement
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// value. Initially the renaming contains nil, signifying the
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// zero constant of the appropriate type; we construct the
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// Const lazily at most once on each path through the domtree.
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// TODO(adonovan): opt: cache per-function not per subtree.
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renaming := make([]Value, numAllocs)
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// Renaming.
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rename(fn.Blocks[0], renaming, newPhis)
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// Eliminate dead new phis, then prepend the live ones to each block.
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for _, b := range fn.Blocks {
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// Compress the newPhis slice to eliminate unused phis.
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// TODO(adonovan): opt: compute liveness to avoid
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// placing phis in blocks for which the alloc cell is
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// not live.
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nps := newPhis[b]
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j := 0
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for _, np := range nps {
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if len(*np.phi.Referrers()) == 0 {
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continue // unreferenced phi
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}
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nps[j] = np
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j++
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}
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nps = nps[:j]
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rundefersToKill := b.rundefers
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if usesDefer {
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rundefersToKill = 0
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}
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if j+b.gaps+rundefersToKill == 0 {
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continue // fast path: no new phis or gaps
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}
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// Compact nps + non-nil Instrs into a new slice.
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// TODO(adonovan): opt: compact in situ if there is
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// sufficient space or slack in the slice.
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dst := make([]Instruction, len(b.Instrs)+j-b.gaps-rundefersToKill)
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for i, np := range nps {
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dst[i] = np.phi
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}
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for _, instr := range b.Instrs {
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if instr == nil {
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continue
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}
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if !usesDefer {
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if _, ok := instr.(*RunDefers); ok {
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continue
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}
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}
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dst[j] = instr
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j++
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}
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for i, np := range nps {
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dst[i] = np.phi
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}
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b.Instrs = dst
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}
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// Remove any fn.Locals that were lifted.
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j := 0
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for _, l := range fn.Locals {
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if l.index == -1 {
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fn.Locals[j] = l
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j++
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}
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}
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// Nil out fn.Locals[j:] to aid GC.
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for i := j; i < len(fn.Locals); i++ {
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fn.Locals[i] = nil
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}
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fn.Locals = fn.Locals[:j]
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}
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type blockSet struct{ big.Int } // (inherit methods from Int)
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// add adds b to the set and returns true if the set changed.
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func (s *blockSet) add(b *BasicBlock) bool {
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i := b.Index
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if s.Bit(i) != 0 {
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return false
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}
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s.SetBit(&s.Int, i, 1)
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return true
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}
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// take removes an arbitrary element from a set s and
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// returns its index, or returns -1 if empty.
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func (s *blockSet) take() int {
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l := s.BitLen()
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for i := 0; i < l; i++ {
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if s.Bit(i) == 1 {
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s.SetBit(&s.Int, i, 0)
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return i
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}
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}
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return -1
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}
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// newPhi is a pair of a newly introduced φ-node and the lifted Alloc
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// it replaces.
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type newPhi struct {
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phi *Phi
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alloc *Alloc
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}
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// newPhiMap records for each basic block, the set of newPhis that
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// must be prepended to the block.
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type newPhiMap map[*BasicBlock][]newPhi
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// liftAlloc determines whether alloc can be lifted into registers,
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// and if so, it populates newPhis with all the φ-nodes it may require
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// and returns true.
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//
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func liftAlloc(df domFrontier, alloc *Alloc, newPhis newPhiMap) bool {
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// Don't lift aggregates into registers, because we don't have
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// a way to express their zero-constants.
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switch deref(alloc.Type()).Underlying().(type) {
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case *types.Array, *types.Struct:
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return false
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}
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// Don't lift named return values in functions that defer
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// calls that may recover from panic.
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if fn := alloc.Parent(); fn.Recover != nil {
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for _, nr := range fn.namedResults {
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if nr == alloc {
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return false
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}
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}
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}
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// Compute defblocks, the set of blocks containing a
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// definition of the alloc cell.
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var defblocks blockSet
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for _, instr := range *alloc.Referrers() {
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// Bail out if we discover the alloc is not liftable;
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// the only operations permitted to use the alloc are
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// loads/stores into the cell.
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switch instr := instr.(type) {
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case *Store:
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if instr.Val == alloc {
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return false // address used as value
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}
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if instr.Addr != alloc {
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panic("Alloc.Referrers is inconsistent")
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}
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defblocks.add(instr.Block())
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case *UnOp:
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if instr.Op != token.MUL {
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return false // not a load
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}
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if instr.X != alloc {
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panic("Alloc.Referrers is inconsistent")
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}
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default:
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return false // some other instruction
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}
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}
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// The Alloc itself counts as a (zero) definition of the cell.
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defblocks.add(alloc.Block())
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if debugLifting {
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fmt.Fprintln(os.Stderr, "liftAlloc: lifting ", alloc, alloc.Name())
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}
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fn := alloc.Parent()
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// Φ-insertion.
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//
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// What follows is the body of the main loop of the insert-φ
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// function described by Cytron et al, but instead of using
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// counter tricks, we just reset the 'hasAlready' and 'work'
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// sets each iteration. These are bitmaps so it's pretty cheap.
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//
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// TODO(adonovan): opt: recycle slice storage for W,
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// hasAlready, defBlocks across liftAlloc calls.
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var hasAlready blockSet
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// Initialize W and work to defblocks.
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var work blockSet = defblocks // blocks seen
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var W blockSet // blocks to do
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W.Set(&defblocks.Int)
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// Traverse iterated dominance frontier, inserting φ-nodes.
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for i := W.take(); i != -1; i = W.take() {
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u := fn.Blocks[i]
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for _, v := range df[u.Index] {
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if hasAlready.add(v) {
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// Create φ-node.
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// It will be prepended to v.Instrs later, if needed.
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phi := &Phi{
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Edges: make([]Value, len(v.Preds)),
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Comment: alloc.Name(),
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}
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phi.pos = alloc.Pos()
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phi.setType(deref(alloc.Type()))
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phi.block = v
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if debugLifting {
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fmt.Fprintf(os.Stderr, "place %s = %s at block %s\n", phi.Name(), phi, v)
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}
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newPhis[v] = append(newPhis[v], newPhi{phi, alloc})
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if work.add(v) {
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W.add(v)
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}
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}
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}
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}
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return true
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}
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// replaceAll replaces all intraprocedural uses of x with y,
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// updating x.Referrers and y.Referrers.
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// Precondition: x.Referrers() != nil, i.e. x must be local to some function.
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//
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func replaceAll(x, y Value) {
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var rands []*Value
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pxrefs := x.Referrers()
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pyrefs := y.Referrers()
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for _, instr := range *pxrefs {
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rands = instr.Operands(rands[:0]) // recycle storage
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for _, rand := range rands {
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if *rand != nil {
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if *rand == x {
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*rand = y
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}
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}
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}
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if pyrefs != nil {
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*pyrefs = append(*pyrefs, instr) // dups ok
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}
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}
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*pxrefs = nil // x is now unreferenced
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}
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// renamed returns the value to which alloc is being renamed,
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// constructing it lazily if it's the implicit zero initialization.
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//
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func renamed(renaming []Value, alloc *Alloc) Value {
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v := renaming[alloc.index]
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if v == nil {
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v = zeroConst(deref(alloc.Type()))
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renaming[alloc.index] = v
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}
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return v
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}
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// rename implements the (Cytron et al) SSA renaming algorithm, a
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// preorder traversal of the dominator tree replacing all loads of
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// Alloc cells with the value stored to that cell by the dominating
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// store instruction. For lifting, we need only consider loads,
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// stores and φ-nodes.
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//
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// renaming is a map from *Alloc (keyed by index number) to its
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// dominating stored value; newPhis[x] is the set of new φ-nodes to be
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// prepended to block x.
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//
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func rename(u *BasicBlock, renaming []Value, newPhis newPhiMap) {
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// Each φ-node becomes the new name for its associated Alloc.
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for _, np := range newPhis[u] {
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phi := np.phi
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alloc := np.alloc
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renaming[alloc.index] = phi
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}
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// Rename loads and stores of allocs.
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for i, instr := range u.Instrs {
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_ = i
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switch instr := instr.(type) {
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case *Store:
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if alloc, ok := instr.Addr.(*Alloc); ok && alloc.index != -1 { // store to Alloc cell
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// Delete the Store.
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u.Instrs[i] = nil
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u.gaps++
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// Replace dominated loads by the
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// stored value.
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renaming[alloc.index] = instr.Val
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if debugLifting {
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fmt.Fprintln(os.Stderr, "Kill store ", instr, "; current value is now ", instr.Val.Name())
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}
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}
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case *UnOp:
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if instr.Op == token.MUL {
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if alloc, ok := instr.X.(*Alloc); ok && alloc.index != -1 { // load of Alloc cell
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newval := renamed(renaming, alloc)
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if debugLifting {
|
|
fmt.Fprintln(os.Stderr, "Replace refs to load", instr.Name(), "=", instr, "with", newval.Name())
|
|
}
|
|
// Replace all references to
|
|
// the loaded value by the
|
|
// dominating stored value.
|
|
replaceAll(instr, newval)
|
|
// Delete the Load.
|
|
u.Instrs[i] = nil
|
|
u.gaps++
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
// For each φ-node in a CFG successor, rename the edge.
|
|
for _, v := range u.Succs {
|
|
phis := newPhis[v]
|
|
if len(phis) == 0 {
|
|
continue
|
|
}
|
|
i := v.predIndex(u)
|
|
for _, np := range phis {
|
|
phi := np.phi
|
|
alloc := np.alloc
|
|
newval := renamed(renaming, alloc)
|
|
if debugLifting {
|
|
fmt.Fprintf(os.Stderr, "setphi %s edge %s -> %s (#%d) (alloc=%s) := %s\n \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.
|
|
for _, v := range u.dom.Children {
|
|
// TODO(adonovan): opt: avoid copy on final iteration; use destructive update.
|
|
r := make([]Value, len(renaming))
|
|
copy(r, renaming)
|
|
rename(v.Block, r, newPhis)
|
|
}
|
|
}
|