mirror of
https://github.com/golang/go
synced 2024-11-19 04:04:47 -07:00
87ced824bd
Motivation: Previously, we assumed that the set of types for which a complete method set (containing all synthesized wrapper functions) is required at runtime was the set of types used as operands to some *ssa.MakeInterface instruction. In fact, this is an underapproximation because types can be derived from other ones via reflection, and some of these may need methods. The reflect.Type API allows *T to be derived from T, and these may have different method sets. Reflection also allows almost any subcomponent of a type to be accessed (with one exception: given T, defined 'type T struct{S}', you can reach S but not struct{S}). As a result, the pointer analysis was unable to generate all necessary constraints before running the solver, causing a crash when reflection derives types whose methods are unavailable. (A similar problem would afflict an ahead-of-time compiler based on ssa. The ssa/interp interpreter was immune only because it does not require all wrapper methods to be created before execution begins.) Description: This change causes the SSA builder to record, for each package, the set of all types with non-empty method sets that are referenced within that package. This set is accessed via Packages.TypesWithMethodSets(). Program.TypesWithMethodSets() returns its union across all packages. The set of references that matter are: - types of operands to some MakeInterface instruction (as before) - types of all exported package members - all subcomponents of the above, recursively. This is a conservative approximation to the set of types whose methods may be called dynamically. We define the owning package of a type as follows: - the owner of a named type is the package in which it is defined; - the owner of a pointer-to-named type is the owner of that named type; - the owner of all other types is nil. A package must include the method sets for all types that it owns, and all subcomponents of that type that are not owned by another package, recursively. Types with an owner appear in exactly one package; types with no owner (such as struct{T}) may appear within multiple packages. (A typical Go compiler would emit multiple copies of these methods as weak symbols; a typical linker would eliminate duplicates.) Also: - go/types/typemap: implement hash function for *Tuple. - pointer: generate nodes/constraints for all of ssa.Program.TypesWithMethodSets(). Add rtti.go regression test. - Add API test of Package.TypesWithMethodSets(). - Set Function.Pkg to nil (again) for wrapper functions, since these may be shared by many packages. - Remove a redundant logging statement. - Document that ssa CREATE phase is in fact sequential. Fixes golang/go#6605 R=gri CC=golang-dev https://golang.org/cl/14920056
415 lines
11 KiB
Go
415 lines
11 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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// An optional pass for sanity-checking invariants of the SSA representation.
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// Currently it checks CFG invariants but little at the instruction level.
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import (
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"fmt"
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"io"
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"os"
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"strings"
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"code.google.com/p/go.tools/go/types"
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)
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type sanity struct {
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reporter io.Writer
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fn *Function
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block *BasicBlock
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insane bool
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}
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// sanityCheck performs integrity checking of the SSA representation
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// of the function fn and returns true if it was valid. Diagnostics
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// are written to reporter if non-nil, os.Stderr otherwise. Some
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// diagnostics are only warnings and do not imply a negative result.
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//
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// Sanity-checking is intended to facilitate the debugging of code
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// transformation passes.
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//
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func sanityCheck(fn *Function, reporter io.Writer) bool {
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if reporter == nil {
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reporter = os.Stderr
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}
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return (&sanity{reporter: reporter}).checkFunction(fn)
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}
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// mustSanityCheck is like sanityCheck but panics instead of returning
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// a negative result.
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//
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func mustSanityCheck(fn *Function, reporter io.Writer) {
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if !sanityCheck(fn, reporter) {
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fn.DumpTo(os.Stderr)
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panic("SanityCheck failed")
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}
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}
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func (s *sanity) diagnostic(prefix, format string, args ...interface{}) {
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fmt.Fprintf(s.reporter, "%s: function %s", prefix, s.fn)
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if s.block != nil {
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fmt.Fprintf(s.reporter, ", block %s", s.block)
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}
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io.WriteString(s.reporter, ": ")
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fmt.Fprintf(s.reporter, format, args...)
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io.WriteString(s.reporter, "\n")
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}
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func (s *sanity) errorf(format string, args ...interface{}) {
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s.insane = true
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s.diagnostic("Error", format, args...)
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}
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func (s *sanity) warnf(format string, args ...interface{}) {
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s.diagnostic("Warning", format, args...)
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}
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// findDuplicate returns an arbitrary basic block that appeared more
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// than once in blocks, or nil if all were unique.
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func findDuplicate(blocks []*BasicBlock) *BasicBlock {
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if len(blocks) < 2 {
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return nil
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}
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if blocks[0] == blocks[1] {
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return blocks[0]
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}
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// Slow path:
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m := make(map[*BasicBlock]bool)
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for _, b := range blocks {
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if m[b] {
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return b
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}
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m[b] = true
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}
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return nil
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}
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func (s *sanity) checkInstr(idx int, instr Instruction) {
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switch instr := instr.(type) {
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case *If, *Jump, *Return, *Panic:
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s.errorf("control flow instruction not at end of block")
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case *Phi:
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if idx == 0 {
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// It suffices to apply this check to just the first phi node.
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if dup := findDuplicate(s.block.Preds); dup != nil {
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s.errorf("phi node in block with duplicate predecessor %s", dup)
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}
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} else {
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prev := s.block.Instrs[idx-1]
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if _, ok := prev.(*Phi); !ok {
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s.errorf("Phi instruction follows a non-Phi: %T", prev)
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}
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}
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if ne, np := len(instr.Edges), len(s.block.Preds); ne != np {
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s.errorf("phi node has %d edges but %d predecessors", ne, np)
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} else {
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for i, e := range instr.Edges {
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if e == nil {
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s.errorf("phi node '%s' has no value for edge #%d from %s", instr.Comment, i, s.block.Preds[i])
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}
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}
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}
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case *Alloc:
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if !instr.Heap {
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found := false
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for _, l := range s.fn.Locals {
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if l == instr {
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found = true
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break
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}
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}
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if !found {
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s.errorf("local alloc %s = %s does not appear in Function.Locals", instr.Name(), instr)
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}
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}
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case *BinOp:
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case *Call:
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case *ChangeInterface:
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case *ChangeType:
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case *Convert:
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if _, ok := instr.X.Type().Underlying().(*types.Basic); !ok {
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if _, ok := instr.Type().Underlying().(*types.Basic); !ok {
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s.errorf("convert %s -> %s: at least one type must be basic", instr.X.Type(), instr.Type())
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}
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}
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case *Defer:
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case *Extract:
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case *Field:
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case *FieldAddr:
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case *Go:
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case *Index:
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case *IndexAddr:
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case *Lookup:
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case *MakeChan:
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case *MakeClosure:
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numFree := len(instr.Fn.(*Function).FreeVars)
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numBind := len(instr.Bindings)
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if numFree != numBind {
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s.errorf("MakeClosure has %d Bindings for function %s with %d free vars",
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numBind, instr.Fn, numFree)
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}
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if recv := instr.Type().(*types.Signature).Recv(); recv != nil {
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s.errorf("MakeClosure's type includes receiver %s", recv.Type())
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}
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case *MakeInterface:
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case *MakeMap:
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case *MakeSlice:
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case *MapUpdate:
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case *Next:
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case *Range:
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case *RunDefers:
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case *Select:
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case *Send:
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case *Slice:
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case *Store:
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case *TypeAssert:
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case *UnOp:
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case *DebugRef:
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// TODO(adonovan): implement checks.
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default:
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panic(fmt.Sprintf("Unknown instruction type: %T", instr))
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}
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// Check that value-defining instructions have valid types.
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if v, ok := instr.(Value); ok {
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t := v.Type()
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if t == nil {
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s.errorf("no type: %s = %s", v.Name(), v)
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} else if t == tRangeIter {
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// not a proper type; ignore.
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} else if b, ok := t.Underlying().(*types.Basic); ok && b.Info()&types.IsUntyped != 0 {
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s.errorf("instruction has 'untyped' result: %s = %s : %s", v.Name(), v, t)
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}
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}
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// TODO(adonovan): sanity-check Consts used as instruction Operands(),
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// e.g. reject Consts with "untyped" types.
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//
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// All other non-Instruction Values can be found via their
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// enclosing Function or Package.
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}
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func (s *sanity) checkFinalInstr(idx int, instr Instruction) {
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switch instr.(type) {
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case *If:
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if nsuccs := len(s.block.Succs); nsuccs != 2 {
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s.errorf("If-terminated block has %d successors; expected 2", nsuccs)
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return
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}
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if s.block.Succs[0] == s.block.Succs[1] {
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s.errorf("If-instruction has same True, False target blocks: %s", s.block.Succs[0])
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return
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}
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case *Jump:
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if nsuccs := len(s.block.Succs); nsuccs != 1 {
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s.errorf("Jump-terminated block has %d successors; expected 1", nsuccs)
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return
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}
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case *Return:
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if nsuccs := len(s.block.Succs); nsuccs != 0 {
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s.errorf("Return-terminated block has %d successors; expected none", nsuccs)
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return
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}
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// TODO(adonovan): check number and types of results
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case *Panic:
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if nsuccs := len(s.block.Succs); nsuccs != 0 {
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s.errorf("Panic-terminated block has %d successors; expected none", nsuccs)
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return
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}
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default:
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s.errorf("non-control flow instruction at end of block")
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}
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}
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func (s *sanity) checkBlock(b *BasicBlock, index int) {
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s.block = b
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if b.Index != index {
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s.errorf("block has incorrect Index %d", b.Index)
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}
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if b.parent != s.fn {
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s.errorf("block has incorrect parent %s", b.parent)
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}
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// Check all blocks are reachable.
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// (The entry block is always implicitly reachable,
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// as is the Recover block, if any.)
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if (index > 0 && b != b.parent.Recover) && len(b.Preds) == 0 {
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s.warnf("unreachable block")
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if b.Instrs == nil {
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// Since this block is about to be pruned,
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// tolerating transient problems in it
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// simplifies other optimizations.
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return
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}
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}
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// Check predecessor and successor relations are dual,
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// and that all blocks in CFG belong to same function.
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for _, a := range b.Preds {
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found := false
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for _, bb := range a.Succs {
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if bb == b {
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found = true
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break
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}
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}
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if !found {
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s.errorf("expected successor edge in predecessor %s; found only: %s", a, a.Succs)
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}
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if a.parent != s.fn {
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s.errorf("predecessor %s belongs to different function %s", a, a.parent)
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}
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}
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for _, c := range b.Succs {
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found := false
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for _, bb := range c.Preds {
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if bb == b {
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found = true
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break
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}
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}
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if !found {
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s.errorf("expected predecessor edge in successor %s; found only: %s", c, c.Preds)
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}
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if c.parent != s.fn {
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s.errorf("successor %s belongs to different function %s", c, c.parent)
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}
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}
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// Check each instruction is sane.
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// TODO(adonovan): check Instruction invariants:
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// - check Operands is dual to Value.Referrers.
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// - check all Operands that are also Instructions belong to s.fn too
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// (and for bonus marks, that their block dominates block b).
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n := len(b.Instrs)
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if n == 0 {
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s.errorf("basic block contains no instructions")
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}
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for j, instr := range b.Instrs {
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if instr == nil {
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s.errorf("nil instruction at index %d", j)
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continue
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}
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if b2 := instr.Block(); b2 == nil {
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s.errorf("nil Block() for instruction at index %d", j)
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continue
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} else if b2 != b {
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s.errorf("wrong Block() (%s) for instruction at index %d ", b2, j)
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continue
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}
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if j < n-1 {
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s.checkInstr(j, instr)
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} else {
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s.checkFinalInstr(j, instr)
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}
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}
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}
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func (s *sanity) checkFunction(fn *Function) bool {
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// TODO(adonovan): check Function invariants:
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// - check params match signature
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// - check transient fields are nil
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// - warn if any fn.Locals do not appear among block instructions.
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s.fn = fn
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if fn.Prog == nil {
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s.errorf("nil Prog")
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}
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// All functions have a package, except wrappers (which are
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// shared across packages, or duplicated as weak symbols in a
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// separate-compilation model), and error.Error.
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if fn.Pkg == nil {
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if strings.Contains(fn.Synthetic, "wrapper") ||
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strings.HasSuffix(fn.name, "Error") {
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// ok
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} else {
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s.errorf("nil Pkg")
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}
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}
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for i, l := range fn.Locals {
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if l.Parent() != fn {
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s.errorf("Local %s at index %d has wrong parent", l.Name(), i)
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}
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if l.Heap {
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s.errorf("Local %s at index %d has Heap flag set", l.Name(), i)
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}
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}
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for i, p := range fn.Params {
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if p.Parent() != fn {
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s.errorf("Param %s at index %d has wrong parent", p.Name(), i)
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}
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}
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for i, fv := range fn.FreeVars {
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if fv.Parent() != fn {
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s.errorf("FreeVar %s at index %d has wrong parent", fv.Name(), i)
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}
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}
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if fn.Blocks != nil && len(fn.Blocks) == 0 {
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// Function _had_ blocks (so it's not external) but
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// they were "optimized" away, even the entry block.
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s.errorf("Blocks slice is non-nil but empty")
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}
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for i, b := range fn.Blocks {
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if b == nil {
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s.warnf("nil *BasicBlock at f.Blocks[%d]", i)
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continue
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}
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s.checkBlock(b, i)
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}
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if fn.Recover != nil && fn.Blocks[fn.Recover.Index] != fn.Recover {
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s.errorf("Recover block is not in Blocks slice")
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}
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s.block = nil
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for i, anon := range fn.AnonFuncs {
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if anon.Enclosing != fn {
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s.errorf("AnonFuncs[%d]=%s but %s.Enclosing=%s", i, anon, anon, anon.Enclosing)
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}
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}
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s.fn = nil
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return !s.insane
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}
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// sanityCheckPackage checks invariants of packages upon creation.
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// It does not require that the package is built.
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// Unlike sanityCheck (for functions), it just panics at the first error.
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func sanityCheckPackage(pkg *Package) {
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for name, mem := range pkg.Members {
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if name != mem.Name() {
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panic(fmt.Sprintf("%s: %T.Name() = %s, want %s",
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pkg.Object.Path(), mem, mem.Name(), name))
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}
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obj := mem.Object()
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if obj == nil {
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// This check is sound because fields
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// {Global,Function}.object have type
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// types.Object. (If they were declared as
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// *types.{Var,Func}, we'd have a non-empty
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// interface containing a nil pointer.)
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continue // not all members have typechecker objects
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}
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if obj.Name() != name {
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panic(fmt.Sprintf("%s: %T.Object().Name() = %s, want %s",
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pkg.Object.Path(), mem, obj.Name(), name))
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}
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if obj.Pos() != mem.Pos() {
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panic(fmt.Sprintf("%s Pos=%d obj.Pos=%d", mem, mem.Pos(), obj.Pos()))
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}
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}
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}
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