mirror of
https://github.com/golang/go
synced 2024-11-18 22:55:23 -07:00
c28bf6e069
CanonicalPos was inadequate since many pairs of instruction share the same pos (e.g. Allocs and Phis). Instead, we generalize the DebugRef instruction to associate not just Idents but Exprs with ssa.Values. We no longer store any DebugRefs for constant expressions, to save space. (The type and value of such expressions can be obtained by other means, at a cost in complexity.) Function.ValueForExpr queries the DebugRef info to return the ssa.Value of a given Expr. Added tests. Also: - the DebugInfo flag is now per package, not global. It must be set between Create and Build phases if desired. - {Value,Instruction}.Pos() documentation updated: we still maintain this information in the instruction stream even in non-debug mode, but we make fewer claims about its invariants. - Go and Defer instructions can now use their respective go/defer token positions (not the call's lparen), so they do. - SelectState: Posn token.Pos indicates the <- position DebugNode ast.Expr is the send stmt or receive expr. - In building SelectStmt, we introduce extra temporaries in debug mode to hold the result of the receive in 'case <-ch' even though this value isn't ordinarily needed. - Use *SelectState (indirectly) since the struct is getting bigger. - Document some missing instructions in doc.go. R=gri CC=golang-dev https://golang.org/cl/12147043
402 lines
10 KiB
Go
402 lines
10 KiB
Go
package ssa
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// Helpers for emitting SSA instructions.
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import (
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"go/ast"
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"go/token"
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"code.google.com/p/go.tools/go/types"
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)
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// emitNew emits to f a new (heap Alloc) instruction allocating an
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// object of type typ. pos is the optional source location.
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//
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func emitNew(f *Function, typ types.Type, pos token.Pos) Value {
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return f.emit(&Alloc{
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typ: types.NewPointer(typ),
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Heap: true,
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pos: pos,
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})
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}
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// emitLoad emits to f an instruction to load the address addr into a
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// new temporary, and returns the value so defined.
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//
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func emitLoad(f *Function, addr Value) *UnOp {
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v := &UnOp{Op: token.MUL, X: addr}
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v.setType(deref(addr.Type()))
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f.emit(v)
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return v
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}
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// emitDebugRef emits to f a DebugRef pseudo-instruction associating
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// expression e with value v.
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//
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func emitDebugRef(f *Function, e ast.Expr, v Value) {
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if !f.debugInfo() {
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return // debugging not enabled
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}
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if v == nil || e == nil {
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panic("nil")
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}
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var obj types.Object
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if id, ok := e.(*ast.Ident); ok {
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if isBlankIdent(id) {
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return
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}
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obj = f.Pkg.objectOf(id)
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if _, ok := obj.(*types.Const); ok {
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return
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}
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}
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f.emit(&DebugRef{
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X: v,
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Expr: unparen(e),
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object: obj,
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})
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}
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// emitArith emits to f code to compute the binary operation op(x, y)
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// where op is an eager shift, logical or arithmetic operation.
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// (Use emitCompare() for comparisons and Builder.logicalBinop() for
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// non-eager operations.)
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//
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func emitArith(f *Function, op token.Token, x, y Value, t types.Type, pos token.Pos) Value {
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switch op {
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case token.SHL, token.SHR:
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x = emitConv(f, x, t)
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// y may be signed or an 'untyped' constant.
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// TODO(adonovan): whence signed values?
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if b, ok := y.Type().Underlying().(*types.Basic); ok && b.Info()&types.IsUnsigned == 0 {
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y = emitConv(f, y, types.Typ[types.Uint64])
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}
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case token.ADD, token.SUB, token.MUL, token.QUO, token.REM, token.AND, token.OR, token.XOR, token.AND_NOT:
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x = emitConv(f, x, t)
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y = emitConv(f, y, t)
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default:
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panic("illegal op in emitArith: " + op.String())
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}
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v := &BinOp{
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Op: op,
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X: x,
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Y: y,
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}
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v.setPos(pos)
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v.setType(t)
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return f.emit(v)
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}
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// emitCompare emits to f code compute the boolean result of
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// comparison comparison 'x op y'.
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//
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func emitCompare(f *Function, op token.Token, x, y Value, pos token.Pos) Value {
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xt := x.Type().Underlying()
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yt := y.Type().Underlying()
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// Special case to optimise a tagless SwitchStmt so that
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// these are equivalent
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// switch { case e: ...}
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// switch true { case e: ... }
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// if e==true { ... }
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// even in the case when e's type is an interface.
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// TODO(adonovan): opt: generalise to x==true, false!=y, etc.
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if x == vTrue && op == token.EQL {
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if yt, ok := yt.(*types.Basic); ok && yt.Info()&types.IsBoolean != 0 {
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return y
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}
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}
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if types.IsIdentical(xt, yt) {
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// no conversion necessary
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} else if _, ok := xt.(*types.Interface); ok {
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y = emitConv(f, y, x.Type())
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} else if _, ok := yt.(*types.Interface); ok {
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x = emitConv(f, x, y.Type())
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} else if _, ok := x.(*Const); ok {
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x = emitConv(f, x, y.Type())
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} else if _, ok := y.(*Const); ok {
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y = emitConv(f, y, x.Type())
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} else {
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// other cases, e.g. channels. No-op.
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}
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v := &BinOp{
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Op: op,
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X: x,
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Y: y,
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}
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v.setPos(pos)
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v.setType(tBool)
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return f.emit(v)
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}
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// isValuePreserving returns true if a conversion from ut_src to
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// ut_dst is value-preserving, i.e. just a change of type.
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// Precondition: neither argument is a named type.
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//
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func isValuePreserving(ut_src, ut_dst types.Type) bool {
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// Identical underlying types?
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if types.IsIdentical(ut_dst, ut_src) {
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return true
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}
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switch ut_dst.(type) {
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case *types.Chan:
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// Conversion between channel types?
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_, ok := ut_src.(*types.Chan)
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return ok
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case *types.Pointer:
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// Conversion between pointers with identical base types?
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_, ok := ut_src.(*types.Pointer)
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return ok
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case *types.Signature:
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// Conversion from (T) func f() method to f(T) function?
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_, ok := ut_src.(*types.Signature)
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return ok
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}
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return false
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}
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// emitConv emits to f code to convert Value val to exactly type typ,
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// and returns the converted value. Implicit conversions are required
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// by language assignability rules in assignments, parameter passing,
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// etc. Conversions cannot fail dynamically.
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//
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func emitConv(f *Function, val Value, typ types.Type) Value {
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t_src := val.Type()
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// Identical types? Conversion is a no-op.
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if types.IsIdentical(t_src, typ) {
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return val
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}
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ut_dst := typ.Underlying()
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ut_src := t_src.Underlying()
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// Just a change of type, but not value or representation?
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if isValuePreserving(ut_src, ut_dst) {
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c := &ChangeType{X: val}
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c.setType(typ)
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return f.emit(c)
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}
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// Conversion to, or construction of a value of, an interface type?
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if _, ok := ut_dst.(*types.Interface); ok {
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// Assignment from one interface type to another?
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if _, ok := ut_src.(*types.Interface); ok {
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c := &ChangeInterface{X: val}
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c.setType(typ)
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return f.emit(c)
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}
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// Untyped nil constant? Return interface-typed nil constant.
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if ut_src == tUntypedNil {
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return nilConst(typ)
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}
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// Convert (non-nil) "untyped" literals to their default type.
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if t, ok := ut_src.(*types.Basic); ok && t.Info()&types.IsUntyped != 0 {
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val = emitConv(f, val, DefaultType(ut_src))
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}
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mi := &MakeInterface{X: val}
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mi.setType(typ)
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return f.emit(mi)
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}
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// Conversion of a constant to a non-interface type results in
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// a new constant of the destination type and (initially) the
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// same abstract value. We don't compute the representation
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// change yet; this defers the point at which the number of
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// possible representations explodes.
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if c, ok := val.(*Const); ok {
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return NewConst(c.Value, typ)
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}
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// A representation-changing conversion.
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c := &Convert{X: val}
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c.setType(typ)
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return f.emit(c)
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}
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// emitStore emits to f an instruction to store value val at location
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// addr, applying implicit conversions as required by assignabilty rules.
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//
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func emitStore(f *Function, addr, val Value) *Store {
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s := &Store{
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Addr: addr,
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Val: emitConv(f, val, deref(addr.Type())),
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}
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f.emit(s)
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return s
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}
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// emitJump emits to f a jump to target, and updates the control-flow graph.
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// Postcondition: f.currentBlock is nil.
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//
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func emitJump(f *Function, target *BasicBlock) {
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b := f.currentBlock
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b.emit(new(Jump))
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addEdge(b, target)
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f.currentBlock = nil
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}
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// emitIf emits to f a conditional jump to tblock or fblock based on
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// cond, and updates the control-flow graph.
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// Postcondition: f.currentBlock is nil.
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//
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func emitIf(f *Function, cond Value, tblock, fblock *BasicBlock) {
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b := f.currentBlock
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b.emit(&If{Cond: cond})
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addEdge(b, tblock)
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addEdge(b, fblock)
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f.currentBlock = nil
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}
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// emitExtract emits to f an instruction to extract the index'th
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// component of tuple, ascribing it type typ. It returns the
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// extracted value.
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//
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func emitExtract(f *Function, tuple Value, index int, typ types.Type) Value {
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e := &Extract{Tuple: tuple, Index: index}
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// In all cases but one (tSelect's recv), typ is redundant w.r.t.
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// tuple.Type().(*types.Tuple).Values[index].Type.
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e.setType(typ)
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return f.emit(e)
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}
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// emitTypeAssert emits to f a type assertion value := x.(t) and
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// returns the value. x.Type() must be an interface.
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//
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func emitTypeAssert(f *Function, x Value, t types.Type, pos token.Pos) Value {
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a := &TypeAssert{X: x, AssertedType: t}
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a.setPos(pos)
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a.setType(t)
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return f.emit(a)
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}
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// emitTypeTest emits to f a type test value,ok := x.(t) and returns
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// a (value, ok) tuple. x.Type() must be an interface.
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//
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func emitTypeTest(f *Function, x Value, t types.Type, pos token.Pos) Value {
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a := &TypeAssert{
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X: x,
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AssertedType: t,
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CommaOk: true,
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}
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a.setPos(pos)
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a.setType(types.NewTuple(
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types.NewVar(token.NoPos, nil, "value", t),
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varOk,
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))
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return f.emit(a)
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}
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// emitTailCall emits to f a function call in tail position. The
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// caller is responsible for all fields of 'call' except its type.
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// Intended for wrapper methods.
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// Precondition: f does/will not use deferred procedure calls.
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// Postcondition: f.currentBlock is nil.
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//
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func emitTailCall(f *Function, call *Call) {
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tresults := f.Signature.Results()
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nr := tresults.Len()
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if nr == 1 {
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call.typ = tresults.At(0).Type()
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} else {
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call.typ = tresults
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}
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tuple := f.emit(call)
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var ret Ret
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switch nr {
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case 0:
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// no-op
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case 1:
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ret.Results = []Value{tuple}
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default:
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for i := 0; i < nr; i++ {
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v := emitExtract(f, tuple, i, tresults.At(i).Type())
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// TODO(adonovan): in principle, this is required:
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// v = emitConv(f, o.Type, f.Signature.Results[i].Type)
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// but in practice emitTailCall is only used when
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// the types exactly match.
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ret.Results = append(ret.Results, v)
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}
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}
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f.emit(&ret)
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f.currentBlock = nil
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}
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// emitImplicitSelections emits to f code to apply the sequence of
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// implicit field selections specified by indices to base value v, and
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// returns the selected value.
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//
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// If v is the address of a struct, the result will be the address of
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// a field; if it is the value of a struct, the result will be the
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// value of a field.
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//
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func emitImplicitSelections(f *Function, v Value, indices []int) Value {
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for _, index := range indices {
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fld := deref(v.Type()).Underlying().(*types.Struct).Field(index)
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if isPointer(v.Type()) {
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instr := &FieldAddr{
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X: v,
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Field: index,
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}
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instr.setType(types.NewPointer(fld.Type()))
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v = f.emit(instr)
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// Load the field's value iff indirectly embedded.
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if isPointer(fld.Type()) {
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v = emitLoad(f, v)
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}
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} else {
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instr := &Field{
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X: v,
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Field: index,
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}
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instr.setType(fld.Type())
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v = f.emit(instr)
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}
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}
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return v
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}
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// emitFieldSelection emits to f code to select the index'th field of v.
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//
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// If wantAddr, the input must be a pointer-to-struct and the result
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// will be the field's address; otherwise the result will be the
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// field's value.
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//
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func emitFieldSelection(f *Function, v Value, index int, wantAddr bool, pos token.Pos) Value {
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fld := deref(v.Type()).Underlying().(*types.Struct).Field(index)
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if isPointer(v.Type()) {
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instr := &FieldAddr{
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X: v,
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Field: index,
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}
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instr.setPos(pos)
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instr.setType(types.NewPointer(fld.Type()))
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v = f.emit(instr)
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// Load the field's value iff we don't want its address.
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if !wantAddr {
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v = emitLoad(f, v)
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}
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} else {
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instr := &Field{
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X: v,
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Field: index,
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}
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instr.setPos(pos)
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instr.setType(fld.Type())
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v = f.emit(instr)
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}
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return v
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}
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