| // Copyright 2021 The Go Authors. All rights reserved. |
| // Use of this source code is governed by a BSD-style |
| // license that can be found in the LICENSE file. |
| |
| // This file contains transformation functions on nodes, which are the |
| // transformations that the typecheck package does that are distinct from the |
| // typechecking functionality. These transform functions are pared-down copies of |
| // the original typechecking functions, with all code removed that is related to: |
| // |
| // - Detecting compile-time errors (already done by types2) |
| // - Setting the actual type of existing nodes (already done based on |
| // type info from types2) |
| // - Dealing with untyped constants (which types2 has already resolved) |
| // |
| // Each of the transformation functions requires that node passed in has its type |
| // and typecheck flag set. If the transformation function replaces or adds new |
| // nodes, it will set the type and typecheck flag for those new nodes. |
| |
| package noder |
| |
| import ( |
| "cmd/compile/internal/base" |
| "cmd/compile/internal/ir" |
| "cmd/compile/internal/typecheck" |
| "cmd/compile/internal/types" |
| "fmt" |
| "go/constant" |
| ) |
| |
| // Transformation functions for expressions |
| |
| // transformAdd transforms an addition operation (currently just addition of |
| // strings). Corresponds to the "binary operators" case in typecheck.typecheck1. |
| func transformAdd(n *ir.BinaryExpr) ir.Node { |
| assert(n.Type() != nil && n.Typecheck() == 1) |
| l := n.X |
| if l.Type().IsString() { |
| var add *ir.AddStringExpr |
| if l.Op() == ir.OADDSTR { |
| add = l.(*ir.AddStringExpr) |
| add.SetPos(n.Pos()) |
| } else { |
| add = ir.NewAddStringExpr(n.Pos(), []ir.Node{l}) |
| } |
| r := n.Y |
| if r.Op() == ir.OADDSTR { |
| r := r.(*ir.AddStringExpr) |
| add.List.Append(r.List.Take()...) |
| } else { |
| add.List.Append(r) |
| } |
| typed(l.Type(), add) |
| return add |
| } |
| return n |
| } |
| |
| // Corresponds to typecheck.stringtoruneslit. |
| func stringtoruneslit(n *ir.ConvExpr) ir.Node { |
| if n.X.Op() != ir.OLITERAL || n.X.Val().Kind() != constant.String { |
| base.Fatalf("stringtoarraylit %v", n) |
| } |
| |
| var list []ir.Node |
| i := 0 |
| eltType := n.Type().Elem() |
| for _, r := range ir.StringVal(n.X) { |
| elt := ir.NewKeyExpr(base.Pos, ir.NewInt(int64(i)), ir.NewInt(int64(r))) |
| // Change from untyped int to the actual element type determined |
| // by types2. No need to change elt.Key, since the array indexes |
| // are just used for setting up the element ordering. |
| elt.Value.SetType(eltType) |
| list = append(list, elt) |
| i++ |
| } |
| |
| nn := ir.NewCompLitExpr(base.Pos, ir.OCOMPLIT, ir.TypeNode(n.Type()), nil) |
| nn.List = list |
| typed(n.Type(), nn) |
| // Need to transform the OCOMPLIT. |
| return transformCompLit(nn) |
| } |
| |
| // transformConv transforms an OCONV node as needed, based on the types involved, |
| // etc. Corresponds to typecheck.tcConv. |
| func transformConv(n *ir.ConvExpr) ir.Node { |
| t := n.X.Type() |
| op, _ := typecheck.Convertop(n.X.Op() == ir.OLITERAL, t, n.Type()) |
| n.SetOp(op) |
| switch n.Op() { |
| case ir.OCONVNOP: |
| if t.Kind() == n.Type().Kind() { |
| switch t.Kind() { |
| case types.TFLOAT32, types.TFLOAT64, types.TCOMPLEX64, types.TCOMPLEX128: |
| // Floating point casts imply rounding and |
| // so the conversion must be kept. |
| n.SetOp(ir.OCONV) |
| } |
| } |
| |
| // Do not convert to []byte literal. See CL 125796. |
| // Generated code and compiler memory footprint is better without it. |
| case ir.OSTR2BYTES: |
| // ok |
| |
| case ir.OSTR2RUNES: |
| if n.X.Op() == ir.OLITERAL { |
| return stringtoruneslit(n) |
| } |
| } |
| return n |
| } |
| |
| // transformConvCall transforms a conversion call. Corresponds to the OTYPE part of |
| // typecheck.tcCall. |
| func transformConvCall(n *ir.CallExpr) ir.Node { |
| assert(n.Type() != nil && n.Typecheck() == 1) |
| arg := n.Args[0] |
| n1 := ir.NewConvExpr(n.Pos(), ir.OCONV, nil, arg) |
| typed(n.X.Type(), n1) |
| return transformConv(n1) |
| } |
| |
| // transformCall transforms a normal function/method call. Corresponds to last half |
| // (non-conversion, non-builtin part) of typecheck.tcCall. |
| func transformCall(n *ir.CallExpr) { |
| // n.Type() can be nil for calls with no return value |
| assert(n.Typecheck() == 1) |
| transformArgs(n) |
| l := n.X |
| t := l.Type() |
| |
| switch l.Op() { |
| case ir.ODOTINTER: |
| n.SetOp(ir.OCALLINTER) |
| |
| case ir.ODOTMETH: |
| l := l.(*ir.SelectorExpr) |
| n.SetOp(ir.OCALLMETH) |
| |
| tp := t.Recv().Type |
| |
| if l.X == nil || !types.Identical(l.X.Type(), tp) { |
| base.Fatalf("method receiver") |
| } |
| |
| default: |
| n.SetOp(ir.OCALLFUNC) |
| } |
| |
| typecheckaste(ir.OCALL, n.X, n.IsDDD, t.Params(), n.Args) |
| if t.NumResults() == 1 { |
| n.SetType(l.Type().Results().Field(0).Type) |
| |
| if n.Op() == ir.OCALLFUNC && n.X.Op() == ir.ONAME { |
| if sym := n.X.(*ir.Name).Sym(); types.IsRuntimePkg(sym.Pkg) && sym.Name == "getg" { |
| // Emit code for runtime.getg() directly instead of calling function. |
| // Most such rewrites (for example the similar one for math.Sqrt) should be done in walk, |
| // so that the ordering pass can make sure to preserve the semantics of the original code |
| // (in particular, the exact time of the function call) by introducing temporaries. |
| // In this case, we know getg() always returns the same result within a given function |
| // and we want to avoid the temporaries, so we do the rewrite earlier than is typical. |
| n.SetOp(ir.OGETG) |
| } |
| } |
| return |
| } |
| } |
| |
| // transformCompare transforms a compare operation (currently just equals/not |
| // equals). Corresponds to the "comparison operators" case in |
| // typecheck.typecheck1, including tcArith. |
| func transformCompare(n *ir.BinaryExpr) { |
| assert(n.Type() != nil && n.Typecheck() == 1) |
| if (n.Op() == ir.OEQ || n.Op() == ir.ONE) && !types.Identical(n.X.Type(), n.Y.Type()) { |
| // Comparison is okay as long as one side is assignable to the |
| // other. The only allowed case where the conversion is not CONVNOP is |
| // "concrete == interface". In that case, check comparability of |
| // the concrete type. The conversion allocates, so only do it if |
| // the concrete type is huge. |
| l, r := n.X, n.Y |
| lt, rt := l.Type(), r.Type() |
| converted := false |
| if rt.Kind() != types.TBLANK { |
| aop, _ := typecheck.Assignop(lt, rt) |
| if aop != ir.OXXX { |
| types.CalcSize(lt) |
| if rt.IsInterface() == lt.IsInterface() || lt.Width >= 1<<16 { |
| l = ir.NewConvExpr(base.Pos, aop, rt, l) |
| l.SetTypecheck(1) |
| } |
| |
| converted = true |
| } |
| } |
| |
| if !converted && lt.Kind() != types.TBLANK { |
| aop, _ := typecheck.Assignop(rt, lt) |
| if aop != ir.OXXX { |
| types.CalcSize(rt) |
| if rt.IsInterface() == lt.IsInterface() || rt.Width >= 1<<16 { |
| r = ir.NewConvExpr(base.Pos, aop, lt, r) |
| r.SetTypecheck(1) |
| } |
| } |
| } |
| n.X, n.Y = l, r |
| } |
| } |
| |
| // Corresponds to typecheck.implicitstar. |
| func implicitstar(n ir.Node) ir.Node { |
| // insert implicit * if needed for fixed array |
| t := n.Type() |
| if !t.IsPtr() { |
| return n |
| } |
| t = t.Elem() |
| if !t.IsArray() { |
| return n |
| } |
| star := ir.NewStarExpr(base.Pos, n) |
| star.SetImplicit(true) |
| return typed(t, star) |
| } |
| |
| // transformIndex transforms an index operation. Corresponds to typecheck.tcIndex. |
| func transformIndex(n *ir.IndexExpr) { |
| assert(n.Type() != nil && n.Typecheck() == 1) |
| n.X = implicitstar(n.X) |
| l := n.X |
| t := l.Type() |
| if t.Kind() == types.TMAP { |
| n.Index = assignconvfn(n.Index, t.Key()) |
| n.SetOp(ir.OINDEXMAP) |
| // Set type to just the map value, not (value, bool). This is |
| // different from types2, but fits the later stages of the |
| // compiler better. |
| n.SetType(t.Elem()) |
| n.Assigned = false |
| } |
| } |
| |
| // transformSlice transforms a slice operation. Corresponds to typecheck.tcSlice. |
| func transformSlice(n *ir.SliceExpr) { |
| assert(n.Type() != nil && n.Typecheck() == 1) |
| l := n.X |
| if l.Type().IsArray() { |
| addr := typecheck.NodAddr(n.X) |
| addr.SetImplicit(true) |
| typed(types.NewPtr(n.X.Type()), addr) |
| n.X = addr |
| l = addr |
| } |
| t := l.Type() |
| if t.IsString() { |
| n.SetOp(ir.OSLICESTR) |
| } else if t.IsPtr() && t.Elem().IsArray() { |
| if n.Op().IsSlice3() { |
| n.SetOp(ir.OSLICE3ARR) |
| } else { |
| n.SetOp(ir.OSLICEARR) |
| } |
| } |
| } |
| |
| // Transformation functions for statements |
| |
| // Corresponds to typecheck.checkassign. |
| func transformCheckAssign(stmt ir.Node, n ir.Node) { |
| if n.Op() == ir.OINDEXMAP { |
| n := n.(*ir.IndexExpr) |
| n.Assigned = true |
| return |
| } |
| } |
| |
| // Corresponds to typecheck.assign. |
| func transformAssign(stmt ir.Node, lhs, rhs []ir.Node) { |
| checkLHS := func(i int, typ *types.Type) { |
| transformCheckAssign(stmt, lhs[i]) |
| } |
| |
| cr := len(rhs) |
| if len(rhs) == 1 { |
| if rtyp := rhs[0].Type(); rtyp != nil && rtyp.IsFuncArgStruct() { |
| cr = rtyp.NumFields() |
| } |
| } |
| |
| // x, ok = y |
| assignOK: |
| for len(lhs) == 2 && cr == 1 { |
| stmt := stmt.(*ir.AssignListStmt) |
| r := rhs[0] |
| |
| switch r.Op() { |
| case ir.OINDEXMAP: |
| stmt.SetOp(ir.OAS2MAPR) |
| case ir.ORECV: |
| stmt.SetOp(ir.OAS2RECV) |
| case ir.ODOTTYPE: |
| r := r.(*ir.TypeAssertExpr) |
| stmt.SetOp(ir.OAS2DOTTYPE) |
| r.SetOp(ir.ODOTTYPE2) |
| default: |
| break assignOK |
| } |
| checkLHS(0, r.Type()) |
| checkLHS(1, types.UntypedBool) |
| return |
| } |
| |
| if len(lhs) != cr { |
| for i := range lhs { |
| checkLHS(i, nil) |
| } |
| return |
| } |
| |
| // x,y,z = f() |
| if cr > len(rhs) { |
| stmt := stmt.(*ir.AssignListStmt) |
| stmt.SetOp(ir.OAS2FUNC) |
| r := rhs[0].(*ir.CallExpr) |
| r.Use = ir.CallUseList |
| rtyp := r.Type() |
| |
| for i := range lhs { |
| checkLHS(i, rtyp.Field(i).Type) |
| } |
| return |
| } |
| |
| for i, r := range rhs { |
| checkLHS(i, r.Type()) |
| if lhs[i].Type() != nil { |
| rhs[i] = assignconvfn(r, lhs[i].Type()) |
| } |
| } |
| } |
| |
| // Corresponds to typecheck.typecheckargs. |
| func transformArgs(n ir.InitNode) { |
| var list []ir.Node |
| switch n := n.(type) { |
| default: |
| base.Fatalf("typecheckargs %+v", n.Op()) |
| case *ir.CallExpr: |
| list = n.Args |
| if n.IsDDD { |
| return |
| } |
| case *ir.ReturnStmt: |
| list = n.Results |
| } |
| if len(list) != 1 { |
| return |
| } |
| |
| t := list[0].Type() |
| if t == nil || !t.IsFuncArgStruct() { |
| return |
| } |
| |
| // Rewrite f(g()) into t1, t2, ... = g(); f(t1, t2, ...). |
| |
| // Save n as n.Orig for fmt.go. |
| if ir.Orig(n) == n { |
| n.(ir.OrigNode).SetOrig(ir.SepCopy(n)) |
| } |
| |
| as := ir.NewAssignListStmt(base.Pos, ir.OAS2, nil, nil) |
| as.Rhs.Append(list...) |
| |
| // If we're outside of function context, then this call will |
| // be executed during the generated init function. However, |
| // init.go hasn't yet created it. Instead, associate the |
| // temporary variables with InitTodoFunc for now, and init.go |
| // will reassociate them later when it's appropriate. |
| static := ir.CurFunc == nil |
| if static { |
| ir.CurFunc = typecheck.InitTodoFunc |
| } |
| list = nil |
| for _, f := range t.FieldSlice() { |
| t := typecheck.Temp(f.Type) |
| as.PtrInit().Append(ir.NewDecl(base.Pos, ir.ODCL, t)) |
| as.Lhs.Append(t) |
| list = append(list, t) |
| } |
| if static { |
| ir.CurFunc = nil |
| } |
| |
| switch n := n.(type) { |
| case *ir.CallExpr: |
| n.Args = list |
| case *ir.ReturnStmt: |
| n.Results = list |
| } |
| |
| transformAssign(as, as.Lhs, as.Rhs) |
| as.SetTypecheck(1) |
| n.PtrInit().Append(as) |
| } |
| |
| // assignconvfn converts node n for assignment to type t. Corresponds to |
| // typecheck.assignconvfn. |
| func assignconvfn(n ir.Node, t *types.Type) ir.Node { |
| if t.Kind() == types.TBLANK { |
| return n |
| } |
| |
| if types.Identical(n.Type(), t) { |
| return n |
| } |
| |
| op, _ := typecheck.Assignop(n.Type(), t) |
| |
| r := ir.NewConvExpr(base.Pos, op, t, n) |
| r.SetTypecheck(1) |
| r.SetImplicit(true) |
| return r |
| } |
| |
| // Corresponds to typecheck.typecheckaste. |
| func typecheckaste(op ir.Op, call ir.Node, isddd bool, tstruct *types.Type, nl ir.Nodes) { |
| var t *types.Type |
| var i int |
| |
| lno := base.Pos |
| defer func() { base.Pos = lno }() |
| |
| var n ir.Node |
| if len(nl) == 1 { |
| n = nl[0] |
| } |
| |
| i = 0 |
| for _, tl := range tstruct.Fields().Slice() { |
| t = tl.Type |
| if tl.IsDDD() { |
| if isddd { |
| n = nl[i] |
| ir.SetPos(n) |
| if n.Type() != nil { |
| nl[i] = assignconvfn(n, t) |
| } |
| return |
| } |
| |
| // TODO(mdempsky): Make into ... call with implicit slice. |
| for ; i < len(nl); i++ { |
| n = nl[i] |
| ir.SetPos(n) |
| if n.Type() != nil { |
| nl[i] = assignconvfn(n, t.Elem()) |
| } |
| } |
| return |
| } |
| |
| n = nl[i] |
| ir.SetPos(n) |
| if n.Type() != nil { |
| nl[i] = assignconvfn(n, t) |
| } |
| i++ |
| } |
| } |
| |
| // transformSend transforms a send statement, converting the value to appropriate |
| // type for the channel, as needed. Corresponds of typecheck.tcSend. |
| func transformSend(n *ir.SendStmt) { |
| n.Value = assignconvfn(n.Value, n.Chan.Type().Elem()) |
| } |
| |
| // transformReturn transforms a return node, by doing the needed assignments and |
| // any necessary conversions. Corresponds to typecheck.tcReturn() |
| func transformReturn(rs *ir.ReturnStmt) { |
| transformArgs(rs) |
| nl := rs.Results |
| if ir.HasNamedResults(ir.CurFunc) && len(nl) == 0 { |
| return |
| } |
| |
| typecheckaste(ir.ORETURN, nil, false, ir.CurFunc.Type().Results(), nl) |
| } |
| |
| // transformSelect transforms a select node, creating an assignment list as needed |
| // for each case. Corresponds to typecheck.tcSelect(). |
| func transformSelect(sel *ir.SelectStmt) { |
| for _, ncase := range sel.Cases { |
| if ncase.Comm != nil { |
| n := ncase.Comm |
| oselrecv2 := func(dst, recv ir.Node, def bool) { |
| n := ir.NewAssignListStmt(n.Pos(), ir.OSELRECV2, []ir.Node{dst, ir.BlankNode}, []ir.Node{recv}) |
| n.Def = def |
| n.SetTypecheck(1) |
| ncase.Comm = n |
| } |
| switch n.Op() { |
| case ir.OAS: |
| // convert x = <-c into x, _ = <-c |
| // remove implicit conversions; the eventual assignment |
| // will reintroduce them. |
| n := n.(*ir.AssignStmt) |
| if r := n.Y; r.Op() == ir.OCONVNOP || r.Op() == ir.OCONVIFACE { |
| r := r.(*ir.ConvExpr) |
| if r.Implicit() { |
| n.Y = r.X |
| } |
| } |
| oselrecv2(n.X, n.Y, n.Def) |
| |
| case ir.OAS2RECV: |
| n := n.(*ir.AssignListStmt) |
| n.SetOp(ir.OSELRECV2) |
| |
| case ir.ORECV: |
| // convert <-c into _, _ = <-c |
| n := n.(*ir.UnaryExpr) |
| oselrecv2(ir.BlankNode, n, false) |
| |
| case ir.OSEND: |
| break |
| } |
| } |
| } |
| } |
| |
| // transformAsOp transforms an AssignOp statement. Corresponds to OASOP case in |
| // typecheck1. |
| func transformAsOp(n *ir.AssignOpStmt) { |
| transformCheckAssign(n, n.X) |
| } |
| |
| // transformDot transforms an OXDOT (or ODOT) or ODOT, ODOTPTR, ODOTMETH, |
| // ODOTINTER, or OCALLPART, as appropriate. It adds in extra nodes as needed to |
| // access embedded fields. Corresponds to typecheck.tcDot. |
| func transformDot(n *ir.SelectorExpr, isCall bool) ir.Node { |
| assert(n.Type() != nil && n.Typecheck() == 1) |
| if n.Op() == ir.OXDOT { |
| n = typecheck.AddImplicitDots(n) |
| n.SetOp(ir.ODOT) |
| } |
| |
| t := n.X.Type() |
| |
| if n.X.Op() == ir.OTYPE { |
| return transformMethodExpr(n) |
| } |
| |
| if t.IsPtr() && !t.Elem().IsInterface() { |
| t = t.Elem() |
| n.SetOp(ir.ODOTPTR) |
| } |
| |
| f := typecheck.Lookdot(n, t, 0) |
| assert(f != nil) |
| |
| if (n.Op() == ir.ODOTINTER || n.Op() == ir.ODOTMETH) && !isCall { |
| n.SetOp(ir.OCALLPART) |
| n.SetType(typecheck.MethodValueWrapper(n).Type()) |
| } |
| return n |
| } |
| |
| // Corresponds to typecheck.typecheckMethodExpr. |
| func transformMethodExpr(n *ir.SelectorExpr) (res ir.Node) { |
| t := n.X.Type() |
| |
| // Compute the method set for t. |
| var ms *types.Fields |
| if t.IsInterface() { |
| ms = t.AllMethods() |
| } else { |
| mt := types.ReceiverBaseType(t) |
| typecheck.CalcMethods(mt) |
| ms = mt.AllMethods() |
| |
| // The method expression T.m requires a wrapper when T |
| // is different from m's declared receiver type. We |
| // normally generate these wrappers while writing out |
| // runtime type descriptors, which is always done for |
| // types declared at package scope. However, we need |
| // to make sure to generate wrappers for anonymous |
| // receiver types too. |
| if mt.Sym() == nil { |
| typecheck.NeedRuntimeType(t) |
| } |
| } |
| |
| s := n.Sel |
| m := typecheck.Lookdot1(n, s, t, ms, 0) |
| assert(m != nil) |
| |
| n.SetOp(ir.OMETHEXPR) |
| n.Selection = m |
| n.SetType(typecheck.NewMethodType(m.Type, n.X.Type())) |
| return n |
| } |
| |
| // Corresponds to typecheck.tcAppend. |
| func transformAppend(n *ir.CallExpr) ir.Node { |
| transformArgs(n) |
| args := n.Args |
| t := args[0].Type() |
| assert(t.IsSlice()) |
| |
| if n.IsDDD { |
| if t.Elem().IsKind(types.TUINT8) && args[1].Type().IsString() { |
| return n |
| } |
| |
| args[1] = assignconvfn(args[1], t.Underlying()) |
| return n |
| } |
| |
| as := args[1:] |
| for i, n := range as { |
| assert(n.Type() != nil) |
| as[i] = assignconvfn(n, t.Elem()) |
| } |
| return n |
| } |
| |
| // Corresponds to typecheck.tcComplex. |
| func transformComplex(n *ir.BinaryExpr) ir.Node { |
| l := n.X |
| r := n.Y |
| |
| assert(types.Identical(l.Type(), r.Type())) |
| |
| var t *types.Type |
| switch l.Type().Kind() { |
| case types.TFLOAT32: |
| t = types.Types[types.TCOMPLEX64] |
| case types.TFLOAT64: |
| t = types.Types[types.TCOMPLEX128] |
| default: |
| panic(fmt.Sprintf("transformComplex: unexpected type %v", l.Type())) |
| } |
| |
| // Must set the type here for generics, because this can't be determined |
| // by substitution of the generic types. |
| typed(t, n) |
| return n |
| } |
| |
| // Corresponds to typecheck.tcDelete. |
| func transformDelete(n *ir.CallExpr) ir.Node { |
| transformArgs(n) |
| args := n.Args |
| assert(len(args) == 2) |
| |
| l := args[0] |
| r := args[1] |
| |
| args[1] = assignconvfn(r, l.Type().Key()) |
| return n |
| } |
| |
| // Corresponds to typecheck.tcMake. |
| func transformMake(n *ir.CallExpr) ir.Node { |
| args := n.Args |
| |
| n.Args = nil |
| l := args[0] |
| t := l.Type() |
| assert(t != nil) |
| |
| i := 1 |
| var nn ir.Node |
| switch t.Kind() { |
| case types.TSLICE: |
| l = args[i] |
| i++ |
| var r ir.Node |
| if i < len(args) { |
| r = args[i] |
| i++ |
| } |
| nn = ir.NewMakeExpr(n.Pos(), ir.OMAKESLICE, l, r) |
| |
| case types.TMAP: |
| if i < len(args) { |
| l = args[i] |
| i++ |
| } else { |
| l = ir.NewInt(0) |
| } |
| nn = ir.NewMakeExpr(n.Pos(), ir.OMAKEMAP, l, nil) |
| nn.SetEsc(n.Esc()) |
| |
| case types.TCHAN: |
| l = nil |
| if i < len(args) { |
| l = args[i] |
| i++ |
| } else { |
| l = ir.NewInt(0) |
| } |
| nn = ir.NewMakeExpr(n.Pos(), ir.OMAKECHAN, l, nil) |
| default: |
| panic(fmt.Sprintf("transformMake: unexpected type %v", t)) |
| } |
| |
| assert(i == len(args)) |
| typed(n.Type(), nn) |
| return nn |
| } |
| |
| // Corresponds to typecheck.tcPanic. |
| func transformPanic(n *ir.UnaryExpr) ir.Node { |
| n.X = assignconvfn(n.X, types.Types[types.TINTER]) |
| return n |
| } |
| |
| // Corresponds to typecheck.tcPrint. |
| func transformPrint(n *ir.CallExpr) ir.Node { |
| transformArgs(n) |
| return n |
| } |
| |
| // Corresponds to typecheck.tcRealImag. |
| func transformRealImag(n *ir.UnaryExpr) ir.Node { |
| l := n.X |
| var t *types.Type |
| |
| // Determine result type. |
| switch l.Type().Kind() { |
| case types.TCOMPLEX64: |
| t = types.Types[types.TFLOAT32] |
| case types.TCOMPLEX128: |
| t = types.Types[types.TFLOAT64] |
| default: |
| panic(fmt.Sprintf("transformRealImag: unexpected type %v", l.Type())) |
| } |
| |
| // Must set the type here for generics, because this can't be determined |
| // by substitution of the generic types. |
| typed(t, n) |
| return n |
| } |
| |
| // Corresponds to typecheck.tcLenCap. |
| func transformLenCap(n *ir.UnaryExpr) ir.Node { |
| n.X = implicitstar(n.X) |
| return n |
| } |
| |
| // Corresponds to Builtin part of tcCall. |
| func transformBuiltin(n *ir.CallExpr) ir.Node { |
| // n.Type() can be nil for builtins with no return value |
| assert(n.Typecheck() == 1) |
| fun := n.X.(*ir.Name) |
| op := fun.BuiltinOp |
| |
| switch op { |
| case ir.OAPPEND, ir.ODELETE, ir.OMAKE, ir.OPRINT, ir.OPRINTN, ir.ORECOVER: |
| n.SetOp(op) |
| n.X = nil |
| switch op { |
| case ir.OAPPEND: |
| return transformAppend(n) |
| case ir.ODELETE: |
| return transformDelete(n) |
| case ir.OMAKE: |
| return transformMake(n) |
| case ir.OPRINT, ir.OPRINTN: |
| return transformPrint(n) |
| case ir.ORECOVER: |
| // nothing more to do |
| return n |
| } |
| |
| case ir.OCAP, ir.OCLOSE, ir.OIMAG, ir.OLEN, ir.OPANIC, ir.OREAL: |
| transformArgs(n) |
| fallthrough |
| |
| case ir.ONEW, ir.OALIGNOF, ir.OOFFSETOF, ir.OSIZEOF: |
| u := ir.NewUnaryExpr(n.Pos(), op, n.Args[0]) |
| u1 := typed(n.Type(), ir.InitExpr(n.Init(), u)) // typecheckargs can add to old.Init |
| switch op { |
| case ir.OCAP, ir.OLEN: |
| return transformLenCap(u1.(*ir.UnaryExpr)) |
| case ir.OREAL, ir.OIMAG: |
| return transformRealImag(u1.(*ir.UnaryExpr)) |
| case ir.OPANIC: |
| return transformPanic(u1.(*ir.UnaryExpr)) |
| case ir.OCLOSE, ir.ONEW, ir.OALIGNOF, ir.OOFFSETOF, ir.OSIZEOF: |
| // nothing more to do |
| return u1 |
| } |
| |
| case ir.OCOMPLEX, ir.OCOPY, ir.OUNSAFEADD, ir.OUNSAFESLICE: |
| transformArgs(n) |
| b := ir.NewBinaryExpr(n.Pos(), op, n.Args[0], n.Args[1]) |
| n1 := typed(n.Type(), ir.InitExpr(n.Init(), b)) |
| if op != ir.OCOMPLEX { |
| // nothing more to do |
| return n1 |
| } |
| return transformComplex(n1.(*ir.BinaryExpr)) |
| |
| default: |
| panic(fmt.Sprintf("transformBuiltin: unexpected op %v", op)) |
| } |
| |
| return n |
| } |
| |
| func hasKeys(l ir.Nodes) bool { |
| for _, n := range l { |
| if n.Op() == ir.OKEY || n.Op() == ir.OSTRUCTKEY { |
| return true |
| } |
| } |
| return false |
| } |
| |
| // transformArrayLit runs assignconvfn on each array element and returns the |
| // length of the slice/array that is needed to hold all the array keys/indexes |
| // (one more than the highest index). Corresponds to typecheck.typecheckarraylit. |
| func transformArrayLit(elemType *types.Type, bound int64, elts []ir.Node) int64 { |
| var key, length int64 |
| for i, elt := range elts { |
| ir.SetPos(elt) |
| r := elts[i] |
| var kv *ir.KeyExpr |
| if elt.Op() == ir.OKEY { |
| elt := elt.(*ir.KeyExpr) |
| key = typecheck.IndexConst(elt.Key) |
| assert(key >= 0) |
| kv = elt |
| r = elt.Value |
| } |
| |
| r = assignconvfn(r, elemType) |
| if kv != nil { |
| kv.Value = r |
| } else { |
| elts[i] = r |
| } |
| |
| key++ |
| if key > length { |
| length = key |
| } |
| } |
| |
| return length |
| } |
| |
| // transformCompLit transforms n to an OARRAYLIT, OSLICELIT, OMAPLIT, or |
| // OSTRUCTLIT node, with any needed conversions. Corresponds to |
| // typecheck.tcCompLit. |
| func transformCompLit(n *ir.CompLitExpr) (res ir.Node) { |
| assert(n.Type() != nil && n.Typecheck() == 1) |
| lno := base.Pos |
| defer func() { |
| base.Pos = lno |
| }() |
| |
| // Save original node (including n.Right) |
| n.SetOrig(ir.Copy(n)) |
| |
| ir.SetPos(n) |
| |
| t := n.Type() |
| |
| switch t.Kind() { |
| default: |
| base.Fatalf("transformCompLit %v", t.Kind()) |
| |
| case types.TARRAY: |
| transformArrayLit(t.Elem(), t.NumElem(), n.List) |
| n.SetOp(ir.OARRAYLIT) |
| |
| case types.TSLICE: |
| length := transformArrayLit(t.Elem(), -1, n.List) |
| n.SetOp(ir.OSLICELIT) |
| n.Len = length |
| |
| case types.TMAP: |
| for _, l := range n.List { |
| ir.SetPos(l) |
| assert(l.Op() == ir.OKEY) |
| l := l.(*ir.KeyExpr) |
| |
| r := l.Key |
| l.Key = assignconvfn(r, t.Key()) |
| |
| r = l.Value |
| l.Value = assignconvfn(r, t.Elem()) |
| } |
| |
| n.SetOp(ir.OMAPLIT) |
| |
| case types.TSTRUCT: |
| // Need valid field offsets for Xoffset below. |
| types.CalcSize(t) |
| |
| if len(n.List) != 0 && !hasKeys(n.List) { |
| // simple list of values |
| ls := n.List |
| for i, n1 := range ls { |
| ir.SetPos(n1) |
| |
| f := t.Field(i) |
| n1 = assignconvfn(n1, f.Type) |
| sk := ir.NewStructKeyExpr(base.Pos, f.Sym, n1) |
| sk.Offset = f.Offset |
| ls[i] = sk |
| } |
| assert(len(ls) >= t.NumFields()) |
| } else { |
| // keyed list |
| ls := n.List |
| for i, l := range ls { |
| ir.SetPos(l) |
| |
| if l.Op() == ir.OKEY { |
| kv := l.(*ir.KeyExpr) |
| key := kv.Key |
| |
| // Sym might have resolved to name in other top-level |
| // package, because of import dot. Redirect to correct sym |
| // before we do the lookup. |
| s := key.Sym() |
| if id, ok := key.(*ir.Ident); ok && typecheck.DotImportRefs[id] != nil { |
| s = typecheck.Lookup(s.Name) |
| } |
| |
| // An OXDOT uses the Sym field to hold |
| // the field to the right of the dot, |
| // so s will be non-nil, but an OXDOT |
| // is never a valid struct literal key. |
| assert(!(s == nil || s.Pkg != types.LocalPkg || key.Op() == ir.OXDOT || s.IsBlank())) |
| |
| l = ir.NewStructKeyExpr(l.Pos(), s, kv.Value) |
| ls[i] = l |
| } |
| |
| assert(l.Op() == ir.OSTRUCTKEY) |
| l := l.(*ir.StructKeyExpr) |
| |
| f := typecheck.Lookdot1(nil, l.Field, t, t.Fields(), 0) |
| l.Offset = f.Offset |
| |
| l.Value = assignconvfn(l.Value, f.Type) |
| } |
| } |
| |
| n.SetOp(ir.OSTRUCTLIT) |
| } |
| |
| return n |
| } |