src/cmd/compile/internal/noder/helpers.go - go - Git at Google

 // 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.

 package noder

 import (
 	"go/constant"

 	"cmd/compile/internal/base"
 	"cmd/compile/internal/ir"
 	"cmd/compile/internal/typecheck"
 	"cmd/compile/internal/types"
 	"cmd/internal/src"
 )

 // Helpers for constructing typed IR nodes.
 //
 // TODO(mdempsky): Move into their own package so they can be easily
 // reused by iimport and frontend optimizations.

 type ImplicitNode interface {
 	ir.Node
 	SetImplicit(x bool)
 }

 // Implicit returns n after marking it as Implicit.
 func Implicit(n ImplicitNode) ImplicitNode {
 	n.SetImplicit(true)
 	return n
 }

 // typed returns n after setting its type to typ.
 func typed(typ *types.Type, n ir.Node) ir.Node {
 	n.SetType(typ)
 	n.SetTypecheck(1)
 	return n
 }

 // Values

 func Const(pos src.XPos, typ *types.Type, val constant.Value) ir.Node {
 	return typed(typ, ir.NewBasicLit(pos, val))
 }

 func Nil(pos src.XPos, typ *types.Type) ir.Node {
 	return typed(typ, ir.NewNilExpr(pos))
 }

 // Expressions

 func Addr(pos src.XPos, x ir.Node) *ir.AddrExpr {
 	n := typecheck.NodAddrAt(pos, x)
 	switch x.Op() {
 	case ir.OARRAYLIT, ir.OMAPLIT, ir.OSLICELIT, ir.OSTRUCTLIT:
 		n.SetOp(ir.OPTRLIT)
 	}
 	typed(types.NewPtr(x.Type()), n)
 	return n
 }

 func Assert(pos src.XPos, x ir.Node, typ *types.Type) ir.Node {
 	return typed(typ, ir.NewTypeAssertExpr(pos, x, nil))
 }

 func Binary(pos src.XPos, op ir.Op, typ *types.Type, x, y ir.Node) ir.Node {
 	switch op {
 	case ir.OANDAND, ir.OOROR:
 		return typed(x.Type(), ir.NewLogicalExpr(pos, op, x, y))
 	case ir.OADD:
 		n := ir.NewBinaryExpr(pos, op, x, y)
 		if x.Type().HasTParam() || y.Type().HasTParam() {
 			// Delay transformAdd() if either arg has a type param,
 			// since it needs to know the exact types to decide whether
 			// to transform OADD to OADDSTR.
 			n.SetType(typ)
 			n.SetTypecheck(3)
 			return n
 		}
 		typed(typ, n)
 		return transformAdd(n)
 	default:
 		return typed(x.Type(), ir.NewBinaryExpr(pos, op, x, y))
 	}
 }

 func Call(pos src.XPos, typ *types.Type, fun ir.Node, args []ir.Node, dots bool) ir.Node {
 	n := ir.NewCallExpr(pos, ir.OCALL, fun, args)
 	n.IsDDD = dots
 	// n.Use will be changed to ir.CallUseStmt in g.stmt() if this call is
 	// just a statement (any return values are ignored).
 	n.Use = ir.CallUseExpr

 	if fun.Op() == ir.OTYPE {
 		// Actually a type conversion, not a function call.
 		if fun.Type().HasTParam() || args[0].Type().HasTParam() {
 			// For type params, don't typecheck until we actually know
 			// the type.
 			return typed(typ, n)
 		}
 		typed(typ, n)
 		return transformConvCall(n)
 	}

 	if fun, ok := fun.(*ir.Name); ok && fun.BuiltinOp != 0 {
 		// For Builtin ops, we currently stay with using the old
 		// typechecker to transform the call to a more specific expression
 		// and possibly use more specific ops. However, for a bunch of the
 		// ops, we delay doing the old typechecker if any of the args have
 		// type params, for a variety of reasons:
 		//
 		// OMAKE: hard to choose specific ops OMAKESLICE, etc. until arg type is known
 		// OREAL/OIMAG: can't determine type float32/float64 until arg type know
 		// OLEN/OCAP: old typechecker will complain if arg is not obviously a slice/array.
 		// OAPPEND: old typechecker will complain if arg is not obviously slice, etc.
 		//
 		// We will eventually break out the transforming functionality
 		// needed for builtin's, and call it here or during stenciling, as
 		// appropriate.
 		switch fun.BuiltinOp {
 		case ir.OMAKE, ir.OREAL, ir.OIMAG, ir.OLEN, ir.OCAP, ir.OAPPEND:
 			hasTParam := false
 			for _, arg := range args {
 				if arg.Type().HasTParam() {
 					hasTParam = true
 					break
 				}
 			}
 			if hasTParam {
 				return typed(typ, n)
 			}
 		}

 		typed(typ, n)
 		return transformBuiltin(n)
 	}

 	// Add information, now that we know that fun is actually being called.
 	switch fun := fun.(type) {
 	case *ir.ClosureExpr:
 		fun.Func.SetClosureCalled(true)
 	case *ir.SelectorExpr:
 		if fun.Op() == ir.OCALLPART {
 			op := ir.ODOTMETH
 			if fun.X.Type().IsInterface() {
 				op = ir.ODOTINTER
 			}
 			fun.SetOp(op)
 			// Set the type to include the receiver, since that's what
 			// later parts of the compiler expect
 			fun.SetType(fun.Selection.Type)
 		}
 	}

 	if fun.Type().HasTParam() {
 		// If the fun arg is or has a type param, don't do any extra
 		// transformations, since we may not have needed properties yet
 		// (e.g. number of return values, etc). The type param is probably
 		// described by a structural constraint that requires it to be a
 		// certain function type, etc., but we don't want to analyze that.
 		return typed(typ, n)
 	}

 	if fun.Op() == ir.OXDOT {
 		if !fun.(*ir.SelectorExpr).X.Type().HasTParam() {
 			base.FatalfAt(pos, "Expecting type param receiver in %v", fun)
 		}
 		// For methods called in a generic function, don't do any extra
 		// transformations. We will do those later when we create the
 		// instantiated function and have the correct receiver type.
 		typed(typ, n)
 		return n
 	}
 	if fun.Op() != ir.OFUNCINST {
 		// If no type params, do the normal call transformations. This
 		// will convert OCALL to OCALLFUNC.
 		typed(typ, n)
 		transformCall(n)
 		return n
 	}

 	// Leave the op as OCALL, which indicates the call still needs typechecking.
 	typed(typ, n)
 	return n
 }

 func Compare(pos src.XPos, typ *types.Type, op ir.Op, x, y ir.Node) ir.Node {
 	n := ir.NewBinaryExpr(pos, op, x, y)
 	if x.Type().HasTParam() || y.Type().HasTParam() {
 		// Delay transformCompare() if either arg has a type param, since
 		// it needs to know the exact types to decide on any needed conversions.
 		n.SetType(typ)
 		n.SetTypecheck(3)
 		return n
 	}
 	typed(typ, n)
 	transformCompare(n)
 	return n
 }

 func Deref(pos src.XPos, typ *types.Type, x ir.Node) *ir.StarExpr {
 	n := ir.NewStarExpr(pos, x)
 	typed(typ, n)
 	return n
 }

 func DotField(pos src.XPos, x ir.Node, index int) *ir.SelectorExpr {
 	op, typ := ir.ODOT, x.Type()
 	if typ.IsPtr() {
 		op, typ = ir.ODOTPTR, typ.Elem()
 	}
 	if !typ.IsStruct() {
 		base.FatalfAt(pos, "DotField of non-struct: %L", x)
 	}

 	// TODO(mdempsky): This is the backend's responsibility.
 	types.CalcSize(typ)

 	field := typ.Field(index)
 	return dot(pos, field.Type, op, x, field)
 }

 func DotMethod(pos src.XPos, x ir.Node, index int) *ir.SelectorExpr {
 	method := method(x.Type(), index)

 	// Method value.
 	typ := typecheck.NewMethodType(method.Type, nil)
 	return dot(pos, typ, ir.OCALLPART, x, method)
 }

 // MethodExpr returns a OMETHEXPR node with the indicated index into the methods
 // of typ. The receiver type is set from recv, which is different from typ if the
 // method was accessed via embedded fields. Similarly, the X value of the
 // ir.SelectorExpr is recv, the original OTYPE node before passing through the
 // embedded fields.
 func MethodExpr(pos src.XPos, recv ir.Node, embed *types.Type, index int) *ir.SelectorExpr {
 	method := method(embed, index)
 	typ := typecheck.NewMethodType(method.Type, recv.Type())
 	// 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 recv.Sym() == nil {
 		typecheck.NeedRuntimeType(recv.Type())
 	}
 	return dot(pos, typ, ir.OMETHEXPR, recv, method)
 }

 func dot(pos src.XPos, typ *types.Type, op ir.Op, x ir.Node, selection *types.Field) *ir.SelectorExpr {
 	n := ir.NewSelectorExpr(pos, op, x, selection.Sym)
 	n.Selection = selection
 	typed(typ, n)
 	return n
 }

 // TODO(mdempsky): Move to package types.
 func method(typ *types.Type, index int) *types.Field {
 	if typ.IsInterface() {
 		return typ.AllMethods().Index(index)
 	}
 	return types.ReceiverBaseType(typ).Methods().Index(index)
 }

 func Index(pos src.XPos, typ *types.Type, x, index ir.Node) ir.Node {
 	n := ir.NewIndexExpr(pos, x, index)
 	if x.Type().HasTParam() {
 		// transformIndex needs to know exact type
 		n.SetType(typ)
 		n.SetTypecheck(3)
 		return n
 	}
 	typed(typ, n)
 	// transformIndex will modify n.Type() for OINDEXMAP.
 	transformIndex(n)
 	return n
 }

 func Slice(pos src.XPos, typ *types.Type, x, low, high, max ir.Node) ir.Node {
 	op := ir.OSLICE
 	if max != nil {
 		op = ir.OSLICE3
 	}
 	n := ir.NewSliceExpr(pos, op, x, low, high, max)
 	if x.Type().HasTParam() {
 		// transformSlice needs to know if x.Type() is a string or an array or a slice.
 		n.SetType(typ)
 		n.SetTypecheck(3)
 		return n
 	}
 	typed(typ, n)
 	transformSlice(n)
 	return n
 }

 func Unary(pos src.XPos, typ *types.Type, op ir.Op, x ir.Node) ir.Node {
 	switch op {
 	case ir.OADDR:
 		return Addr(pos, x)
 	case ir.ODEREF:
 		return Deref(pos, typ, x)
 	}

 	if op == ir.ORECV {
 		if typ.IsFuncArgStruct() && typ.NumFields() == 2 {
 			// Remove the second boolean type (if provided by type2),
 			// since that works better with the rest of the compiler
 			// (which will add it back in later).
 			assert(typ.Field(1).Type.Kind() == types.TBOOL)
 			typ = typ.Field(0).Type
 		}
 	}
 	return typed(typ, ir.NewUnaryExpr(pos, op, x))
 }

 // Statements

 var one = constant.MakeInt64(1)

 func IncDec(pos src.XPos, op ir.Op, x ir.Node) *ir.AssignOpStmt {
 	assert(x.Type() != nil)
 	return ir.NewAssignOpStmt(pos, op, x, typecheck.DefaultLit(ir.NewBasicLit(pos, one), x.Type()))
 }
	// 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.

	package noder

	import (
	"go/constant"

	"cmd/compile/internal/base"
	"cmd/compile/internal/ir"
	"cmd/compile/internal/typecheck"
	"cmd/compile/internal/types"
	"cmd/internal/src"
	)

	// Helpers for constructing typed IR nodes.
	//
	// TODO(mdempsky): Move into their own package so they can be easily
	// reused by iimport and frontend optimizations.

	type ImplicitNode interface {
	ir.Node
	SetImplicit(x bool)
	}

	// Implicit returns n after marking it as Implicit.
	func Implicit(n ImplicitNode) ImplicitNode {
	n.SetImplicit(true)
	return n
	}

	// typed returns n after setting its type to typ.
	func typed(typ *types.Type, n ir.Node) ir.Node {
	n.SetType(typ)
	n.SetTypecheck(1)
	return n
	}

	// Values

	func Const(pos src.XPos, typ *types.Type, val constant.Value) ir.Node {
	return typed(typ, ir.NewBasicLit(pos, val))
	}

	func Nil(pos src.XPos, typ *types.Type) ir.Node {
	return typed(typ, ir.NewNilExpr(pos))
	}

	// Expressions

	func Addr(pos src.XPos, x ir.Node) *ir.AddrExpr {
	n := typecheck.NodAddrAt(pos, x)
	switch x.Op() {
	case ir.OARRAYLIT, ir.OMAPLIT, ir.OSLICELIT, ir.OSTRUCTLIT:
	n.SetOp(ir.OPTRLIT)
	}
	typed(types.NewPtr(x.Type()), n)
	return n
	}

	func Assert(pos src.XPos, x ir.Node, typ *types.Type) ir.Node {
	return typed(typ, ir.NewTypeAssertExpr(pos, x, nil))
	}

	func Binary(pos src.XPos, op ir.Op, typ *types.Type, x, y ir.Node) ir.Node {
	switch op {
	case ir.OANDAND, ir.OOROR:
	return typed(x.Type(), ir.NewLogicalExpr(pos, op, x, y))
	case ir.OADD:
	n := ir.NewBinaryExpr(pos, op, x, y)
	if x.Type().HasTParam() \|\| y.Type().HasTParam() {
	// Delay transformAdd() if either arg has a type param,
	// since it needs to know the exact types to decide whether
	// to transform OADD to OADDSTR.
	n.SetType(typ)
	n.SetTypecheck(3)
	return n
	}
	typed(typ, n)
	return transformAdd(n)
	default:
	return typed(x.Type(), ir.NewBinaryExpr(pos, op, x, y))
	}
	}

	func Call(pos src.XPos, typ *types.Type, fun ir.Node, args []ir.Node, dots bool) ir.Node {
	n := ir.NewCallExpr(pos, ir.OCALL, fun, args)
	n.IsDDD = dots
	// n.Use will be changed to ir.CallUseStmt in g.stmt() if this call is
	// just a statement (any return values are ignored).
	n.Use = ir.CallUseExpr

	if fun.Op() == ir.OTYPE {
	// Actually a type conversion, not a function call.
	if fun.Type().HasTParam() \|\| args[0].Type().HasTParam() {
	// For type params, don't typecheck until we actually know
	// the type.
	return typed(typ, n)
	}
	typed(typ, n)
	return transformConvCall(n)
	}

	if fun, ok := fun.(*ir.Name); ok && fun.BuiltinOp != 0 {
	// For Builtin ops, we currently stay with using the old
	// typechecker to transform the call to a more specific expression
	// and possibly use more specific ops. However, for a bunch of the
	// ops, we delay doing the old typechecker if any of the args have
	// type params, for a variety of reasons:
	//
	// OMAKE: hard to choose specific ops OMAKESLICE, etc. until arg type is known
	// OREAL/OIMAG: can't determine type float32/float64 until arg type know
	// OLEN/OCAP: old typechecker will complain if arg is not obviously a slice/array.
	// OAPPEND: old typechecker will complain if arg is not obviously slice, etc.
	//
	// We will eventually break out the transforming functionality
	// needed for builtin's, and call it here or during stenciling, as
	// appropriate.
	switch fun.BuiltinOp {
	case ir.OMAKE, ir.OREAL, ir.OIMAG, ir.OLEN, ir.OCAP, ir.OAPPEND:
	hasTParam := false
	for _, arg := range args {
	if arg.Type().HasTParam() {
	hasTParam = true
	break
	}
	}
	if hasTParam {
	return typed(typ, n)
	}
	}

	typed(typ, n)
	return transformBuiltin(n)
	}

	// Add information, now that we know that fun is actually being called.
	switch fun := fun.(type) {
	case *ir.ClosureExpr:
	fun.Func.SetClosureCalled(true)
	case *ir.SelectorExpr:
	if fun.Op() == ir.OCALLPART {
	op := ir.ODOTMETH
	if fun.X.Type().IsInterface() {
	op = ir.ODOTINTER
	}
	fun.SetOp(op)
	// Set the type to include the receiver, since that's what
	// later parts of the compiler expect
	fun.SetType(fun.Selection.Type)
	}
	}

	if fun.Type().HasTParam() {
	// If the fun arg is or has a type param, don't do any extra
	// transformations, since we may not have needed properties yet
	// (e.g. number of return values, etc). The type param is probably
	// described by a structural constraint that requires it to be a
	// certain function type, etc., but we don't want to analyze that.
	return typed(typ, n)
	}

	if fun.Op() == ir.OXDOT {
	if !fun.(*ir.SelectorExpr).X.Type().HasTParam() {
	base.FatalfAt(pos, "Expecting type param receiver in %v", fun)
	}
	// For methods called in a generic function, don't do any extra
	// transformations. We will do those later when we create the
	// instantiated function and have the correct receiver type.
	typed(typ, n)
	return n
	}
	if fun.Op() != ir.OFUNCINST {
	// If no type params, do the normal call transformations. This
	// will convert OCALL to OCALLFUNC.
	typed(typ, n)
	transformCall(n)
	return n
	}

	// Leave the op as OCALL, which indicates the call still needs typechecking.
	typed(typ, n)
	return n
	}

	func Compare(pos src.XPos, typ *types.Type, op ir.Op, x, y ir.Node) ir.Node {
	n := ir.NewBinaryExpr(pos, op, x, y)
	if x.Type().HasTParam() \|\| y.Type().HasTParam() {
	// Delay transformCompare() if either arg has a type param, since
	// it needs to know the exact types to decide on any needed conversions.
	n.SetType(typ)
	n.SetTypecheck(3)
	return n
	}
	typed(typ, n)
	transformCompare(n)
	return n
	}

	func Deref(pos src.XPos, typ types.Type, x ir.Node) ir.StarExpr {
	n := ir.NewStarExpr(pos, x)
	typed(typ, n)
	return n
	}

	func DotField(pos src.XPos, x ir.Node, index int) *ir.SelectorExpr {
	op, typ := ir.ODOT, x.Type()
	if typ.IsPtr() {
	op, typ = ir.ODOTPTR, typ.Elem()
	}
	if !typ.IsStruct() {
	base.FatalfAt(pos, "DotField of non-struct: %L", x)
	}

	// TODO(mdempsky): This is the backend's responsibility.
	types.CalcSize(typ)

	field := typ.Field(index)
	return dot(pos, field.Type, op, x, field)
	}

	func DotMethod(pos src.XPos, x ir.Node, index int) *ir.SelectorExpr {
	method := method(x.Type(), index)

	// Method value.
	typ := typecheck.NewMethodType(method.Type, nil)
	return dot(pos, typ, ir.OCALLPART, x, method)
	}

	// MethodExpr returns a OMETHEXPR node with the indicated index into the methods
	// of typ. The receiver type is set from recv, which is different from typ if the
	// method was accessed via embedded fields. Similarly, the X value of the
	// ir.SelectorExpr is recv, the original OTYPE node before passing through the
	// embedded fields.
	func MethodExpr(pos src.XPos, recv ir.Node, embed types.Type, index int) ir.SelectorExpr {
	method := method(embed, index)
	typ := typecheck.NewMethodType(method.Type, recv.Type())
	// 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 recv.Sym() == nil {
	typecheck.NeedRuntimeType(recv.Type())
	}
	return dot(pos, typ, ir.OMETHEXPR, recv, method)
	}

	func dot(pos src.XPos, typ types.Type, op ir.Op, x ir.Node, selection types.Field) *ir.SelectorExpr {
	n := ir.NewSelectorExpr(pos, op, x, selection.Sym)
	n.Selection = selection
	typed(typ, n)
	return n
	}

	// TODO(mdempsky): Move to package types.
	func method(typ types.Type, index int) types.Field {
	if typ.IsInterface() {
	return typ.AllMethods().Index(index)
	}
	return types.ReceiverBaseType(typ).Methods().Index(index)
	}

	func Index(pos src.XPos, typ *types.Type, x, index ir.Node) ir.Node {
	n := ir.NewIndexExpr(pos, x, index)
	if x.Type().HasTParam() {
	// transformIndex needs to know exact type
	n.SetType(typ)
	n.SetTypecheck(3)
	return n
	}
	typed(typ, n)
	// transformIndex will modify n.Type() for OINDEXMAP.
	transformIndex(n)
	return n
	}

	func Slice(pos src.XPos, typ *types.Type, x, low, high, max ir.Node) ir.Node {
	op := ir.OSLICE
	if max != nil {
	op = ir.OSLICE3
	}
	n := ir.NewSliceExpr(pos, op, x, low, high, max)
	if x.Type().HasTParam() {
	// transformSlice needs to know if x.Type() is a string or an array or a slice.
	n.SetType(typ)
	n.SetTypecheck(3)
	return n
	}
	typed(typ, n)
	transformSlice(n)
	return n
	}

	func Unary(pos src.XPos, typ *types.Type, op ir.Op, x ir.Node) ir.Node {
	switch op {
	case ir.OADDR:
	return Addr(pos, x)
	case ir.ODEREF:
	return Deref(pos, typ, x)
	}

	if op == ir.ORECV {
	if typ.IsFuncArgStruct() && typ.NumFields() == 2 {
	// Remove the second boolean type (if provided by type2),
	// since that works better with the rest of the compiler
	// (which will add it back in later).
	assert(typ.Field(1).Type.Kind() == types.TBOOL)
	typ = typ.Field(0).Type
	}
	}
	return typed(typ, ir.NewUnaryExpr(pos, op, x))
	}

	// Statements

	var one = constant.MakeInt64(1)

	func IncDec(pos src.XPos, op ir.Op, x ir.Node) *ir.AssignOpStmt {
	assert(x.Type() != nil)
	return ir.NewAssignOpStmt(pos, op, x, typecheck.DefaultLit(ir.NewBasicLit(pos, one), x.Type()))
	}