third_party/gotools/go/types/operand.go - llvm-project/llgo - Git at Google

 // Copyright 2012 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 defines operands and associated operations.

 package types

 import (
 	"bytes"
 	"go/ast"
 	"go/token"

 	"llvm.org/llgo/third_party/gotools/go/exact"
 )

 // An operandMode specifies the (addressing) mode of an operand.
 type operandMode byte

 const (
 	invalid  operandMode = iota // operand is invalid
 	novalue                     // operand represents no value (result of a function call w/o result)
 	builtin                     // operand is a built-in function
 	typexpr                     // operand is a type
 	constant                    // operand is a constant; the operand's typ is a Basic type
 	variable                    // operand is an addressable variable
 	mapindex                    // operand is a map index expression (acts like a variable on lhs, commaok on rhs of an assignment)
 	value                       // operand is a computed value
 	commaok                     // like value, but operand may be used in a comma,ok expression
 )

 var operandModeString = [...]string{
 	invalid:  "invalid operand",
 	novalue:  "no value",
 	builtin:  "built-in",
 	typexpr:  "type",
 	constant: "constant",
 	variable: "variable",
 	mapindex: "map index expression",
 	value:    "value",
 	commaok:  "comma, ok expression",
 }

 // An operand represents an intermediate value during type checking.
 // Operands have an (addressing) mode, the expression evaluating to
 // the operand, the operand's type, a value for constants, and an id
 // for built-in functions.
 // The zero value of operand is a ready to use invalid operand.
 //
 type operand struct {
 	mode operandMode
 	expr ast.Expr
 	typ  Type
 	val  exact.Value
 	id   builtinId
 }

 // pos returns the position of the expression corresponding to x.
 // If x is invalid the position is token.NoPos.
 //
 func (x *operand) pos() token.Pos {
 	// x.expr may not be set if x is invalid
 	if x.expr == nil {
 		return token.NoPos
 	}
 	return x.expr.Pos()
 }

 // Operand string formats
 // (not all "untyped" cases can appear due to the type system,
 // but they fall out naturally here)
 //
 // mode       format
 //
 // invalid    <expr> (               <mode>                    )
 // novalue    <expr> (               <mode>                    )
 // builtin    <expr> (               <mode>                    )
 // typexpr    <expr> (               <mode>                    )
 //
 // constant   <expr> (<untyped kind> <mode>                    )
 // constant   <expr> (               <mode>       of type <typ>)
 // constant   <expr> (<untyped kind> <mode> <val>              )
 // constant   <expr> (               <mode> <val> of type <typ>)
 //
 // variable   <expr> (<untyped kind> <mode>                    )
 // variable   <expr> (               <mode>       of type <typ>)
 //
 // mapindex   <expr> (<untyped kind> <mode>                    )
 // mapindex   <expr> (               <mode>       of type <typ>)
 //
 // value      <expr> (<untyped kind> <mode>                    )
 // value      <expr> (               <mode>       of type <typ>)
 //
 // commaok    <expr> (<untyped kind> <mode>                    )
 // commaok    <expr> (               <mode>       of type <typ>)
 //
 func operandString(this *Package, x *operand) string {
 	var buf bytes.Buffer

 	var expr string
 	if x.expr != nil {
 		expr = ExprString(x.expr)
 	} else {
 		switch x.mode {
 		case builtin:
 			expr = predeclaredFuncs[x.id].name
 		case typexpr:
 			expr = TypeString(this, x.typ)
 		case constant:
 			expr = x.val.String()
 		}
 	}

 	// <expr> (
 	if expr != "" {
 		buf.WriteString(expr)
 		buf.WriteString(" (")
 	}

 	// <untyped kind>
 	hasType := false
 	switch x.mode {
 	case invalid, novalue, builtin, typexpr:
 		// no type
 	default:
 		// has type
 		if isUntyped(x.typ) {
 			buf.WriteString(x.typ.(*Basic).name)
 			buf.WriteByte(' ')
 			break
 		}
 		hasType = true
 	}

 	// <mode>
 	buf.WriteString(operandModeString[x.mode])

 	// <val>
 	if x.mode == constant {
 		if s := x.val.String(); s != expr {
 			buf.WriteByte(' ')
 			buf.WriteString(s)
 		}
 	}

 	// <typ>
 	if hasType {
 		if x.typ != Typ[Invalid] {
 			buf.WriteString(" of type ")
 			WriteType(&buf, this, x.typ)
 		} else {
 			buf.WriteString(" with invalid type")
 		}
 	}

 	// )
 	if expr != "" {
 		buf.WriteByte(')')
 	}

 	return buf.String()
 }

 func (x *operand) String() string {
 	return operandString(nil, x)
 }

 // setConst sets x to the untyped constant for literal lit.
 func (x *operand) setConst(tok token.Token, lit string) {
 	val := exact.MakeFromLiteral(lit, tok)
 	if val == nil {
 		// TODO(gri) Should we make it an unknown constant instead?
 		x.mode = invalid
 		return
 	}

 	var kind BasicKind
 	switch tok {
 	case token.INT:
 		kind = UntypedInt
 	case token.FLOAT:
 		kind = UntypedFloat
 	case token.IMAG:
 		kind = UntypedComplex
 	case token.CHAR:
 		kind = UntypedRune
 	case token.STRING:
 		kind = UntypedString
 	}

 	x.mode = constant
 	x.typ = Typ[kind]
 	x.val = val
 }

 // isNil reports whether x is the nil value.
 func (x *operand) isNil() bool {
 	return x.mode == value && x.typ == Typ[UntypedNil]
 }

 // TODO(gri) The functions operand.assignableTo, checker.convertUntyped,
 //           checker.representable, and checker.assignment are
 //           overlapping in functionality. Need to simplify and clean up.

 // assignableTo reports whether x is assignable to a variable of type T.
 func (x *operand) assignableTo(conf *Config, T Type) bool {
 	if x.mode == invalid || T == Typ[Invalid] {
 		return true // avoid spurious errors
 	}

 	V := x.typ

 	// x's type is identical to T
 	if Identical(V, T) {
 		return true
 	}

 	Vu := V.Underlying()
 	Tu := T.Underlying()

 	// T is an interface type and x implements T
 	// (Do this check first as it might succeed early.)
 	if Ti, ok := Tu.(*Interface); ok {
 		if Implements(x.typ, Ti) {
 			return true
 		}
 	}

 	// x's type V and T have identical underlying types
 	// and at least one of V or T is not a named type
 	if Identical(Vu, Tu) && (!isNamed(V) || !isNamed(T)) {
 		return true
 	}

 	// x is a bidirectional channel value, T is a channel
 	// type, x's type V and T have identical element types,
 	// and at least one of V or T is not a named type
 	if Vc, ok := Vu.(*Chan); ok && Vc.dir == SendRecv {
 		if Tc, ok := Tu.(*Chan); ok && Identical(Vc.elem, Tc.elem) {
 			return !isNamed(V) || !isNamed(T)
 		}
 	}

 	// x is the predeclared identifier nil and T is a pointer,
 	// function, slice, map, channel, or interface type
 	if x.isNil() {
 		switch t := Tu.(type) {
 		case *Basic:
 			if t.kind == UnsafePointer {
 				return true
 			}
 		case *Pointer, *Signature, *Slice, *Map, *Chan, *Interface:
 			return true
 		}
 		return false
 	}

 	// x is an untyped constant representable by a value of type T
 	// TODO(gri) This is borrowing from checker.convertUntyped and
 	//           checker.representable. Need to clean up.
 	if isUntyped(Vu) {
 		switch t := Tu.(type) {
 		case *Basic:
 			if x.mode == constant {
 				return representableConst(x.val, conf, t.kind, nil)
 			}
 			// The result of a comparison is an untyped boolean,
 			// but may not be a constant.
 			if Vb, _ := Vu.(*Basic); Vb != nil {
 				return Vb.kind == UntypedBool && isBoolean(Tu)
 			}
 		case *Interface:
 			return x.isNil() || t.Empty()
 		case *Pointer, *Signature, *Slice, *Map, *Chan:
 			return x.isNil()
 		}
 	}

 	return false
 }

 // isInteger reports whether x is a (typed or untyped) integer value.
 func (x *operand) isInteger() bool {
 	return x.mode == invalid ||
 		isInteger(x.typ) ||
 		x.mode == constant && representableConst(x.val, nil, UntypedInt, nil) // no *Config required for UntypedInt
 }
	// Copyright 2012 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 defines operands and associated operations.

	package types

	import (
	"bytes"
	"go/ast"
	"go/token"

	"llvm.org/llgo/third_party/gotools/go/exact"
	)

	// An operandMode specifies the (addressing) mode of an operand.
	type operandMode byte

	const (
	invalid operandMode = iota // operand is invalid
	novalue // operand represents no value (result of a function call w/o result)
	builtin // operand is a built-in function
	typexpr // operand is a type
	constant // operand is a constant; the operand's typ is a Basic type
	variable // operand is an addressable variable
	mapindex // operand is a map index expression (acts like a variable on lhs, commaok on rhs of an assignment)
	value // operand is a computed value
	commaok // like value, but operand may be used in a comma,ok expression
	)

	var operandModeString = [...]string{
	invalid: "invalid operand",
	novalue: "no value",
	builtin: "built-in",
	typexpr: "type",
	constant: "constant",
	variable: "variable",
	mapindex: "map index expression",
	value: "value",
	commaok: "comma, ok expression",
	}

	// An operand represents an intermediate value during type checking.
	// Operands have an (addressing) mode, the expression evaluating to
	// the operand, the operand's type, a value for constants, and an id
	// for built-in functions.
	// The zero value of operand is a ready to use invalid operand.
	//
	type operand struct {
	mode operandMode
	expr ast.Expr
	typ Type
	val exact.Value
	id builtinId
	}

	// pos returns the position of the expression corresponding to x.
	// If x is invalid the position is token.NoPos.
	//
	func (x *operand) pos() token.Pos {
	// x.expr may not be set if x is invalid
	if x.expr == nil {
	return token.NoPos
	}
	return x.expr.Pos()
	}

	// Operand string formats
	// (not all "untyped" cases can appear due to the type system,
	// but they fall out naturally here)
	//
	// mode format
	//
	// invalid <expr> ( <mode> )
	// novalue <expr> ( <mode> )
	// builtin <expr> ( <mode> )
	// typexpr <expr> ( <mode> )
	//
	// constant <expr> (<untyped kind> <mode> )
	// constant <expr> ( <mode> of type <typ>)
	// constant <expr> (<untyped kind> <mode> <val> )
	// constant <expr> ( <mode> <val> of type <typ>)
	//
	// variable <expr> (<untyped kind> <mode> )
	// variable <expr> ( <mode> of type <typ>)
	//
	// mapindex <expr> (<untyped kind> <mode> )
	// mapindex <expr> ( <mode> of type <typ>)
	//
	// value <expr> (<untyped kind> <mode> )
	// value <expr> ( <mode> of type <typ>)
	//
	// commaok <expr> (<untyped kind> <mode> )
	// commaok <expr> ( <mode> of type <typ>)
	//
	func operandString(this Package, x operand) string {
	var buf bytes.Buffer

	var expr string
	if x.expr != nil {
	expr = ExprString(x.expr)
	} else {
	switch x.mode {
	case builtin:
	expr = predeclaredFuncs[x.id].name
	case typexpr:
	expr = TypeString(this, x.typ)
	case constant:
	expr = x.val.String()
	}
	}

	// <expr> (
	if expr != "" {
	buf.WriteString(expr)
	buf.WriteString(" (")
	}

	// <untyped kind>
	hasType := false
	switch x.mode {
	case invalid, novalue, builtin, typexpr:
	// no type
	default:
	// has type
	if isUntyped(x.typ) {
	buf.WriteString(x.typ.(*Basic).name)
	buf.WriteByte(' ')
	break
	}
	hasType = true
	}

	// <mode>
	buf.WriteString(operandModeString[x.mode])

	// <val>
	if x.mode == constant {
	if s := x.val.String(); s != expr {
	buf.WriteByte(' ')
	buf.WriteString(s)
	}
	}

	// <typ>
	if hasType {
	if x.typ != Typ[Invalid] {
	buf.WriteString(" of type ")
	WriteType(&buf, this, x.typ)
	} else {
	buf.WriteString(" with invalid type")
	}
	}

	// )
	if expr != "" {
	buf.WriteByte(')')
	}

	return buf.String()
	}

	func (x *operand) String() string {
	return operandString(nil, x)
	}

	// setConst sets x to the untyped constant for literal lit.
	func (x *operand) setConst(tok token.Token, lit string) {
	val := exact.MakeFromLiteral(lit, tok)
	if val == nil {
	// TODO(gri) Should we make it an unknown constant instead?
	x.mode = invalid
	return
	}

	var kind BasicKind
	switch tok {
	case token.INT:
	kind = UntypedInt
	case token.FLOAT:
	kind = UntypedFloat
	case token.IMAG:
	kind = UntypedComplex
	case token.CHAR:
	kind = UntypedRune
	case token.STRING:
	kind = UntypedString
	}

	x.mode = constant
	x.typ = Typ[kind]
	x.val = val
	}

	// isNil reports whether x is the nil value.
	func (x *operand) isNil() bool {
	return x.mode == value && x.typ == Typ[UntypedNil]
	}

	// TODO(gri) The functions operand.assignableTo, checker.convertUntyped,
	// checker.representable, and checker.assignment are
	// overlapping in functionality. Need to simplify and clean up.

	// assignableTo reports whether x is assignable to a variable of type T.
	func (x operand) assignableTo(conf Config, T Type) bool {
	if x.mode == invalid \|\| T == Typ[Invalid] {
	return true // avoid spurious errors
	}

	V := x.typ

	// x's type is identical to T
	if Identical(V, T) {
	return true
	}

	Vu := V.Underlying()
	Tu := T.Underlying()

	// T is an interface type and x implements T
	// (Do this check first as it might succeed early.)
	if Ti, ok := Tu.(*Interface); ok {
	if Implements(x.typ, Ti) {
	return true
	}
	}

	// x's type V and T have identical underlying types
	// and at least one of V or T is not a named type
	if Identical(Vu, Tu) && (!isNamed(V) \|\| !isNamed(T)) {
	return true
	}

	// x is a bidirectional channel value, T is a channel
	// type, x's type V and T have identical element types,
	// and at least one of V or T is not a named type
	if Vc, ok := Vu.(*Chan); ok && Vc.dir == SendRecv {
	if Tc, ok := Tu.(*Chan); ok && Identical(Vc.elem, Tc.elem) {
	return !isNamed(V) \|\| !isNamed(T)
	}
	}

	// x is the predeclared identifier nil and T is a pointer,
	// function, slice, map, channel, or interface type
	if x.isNil() {
	switch t := Tu.(type) {
	case *Basic:
	if t.kind == UnsafePointer {
	return true
	}
	case Pointer, Signature, Slice, Map, Chan, Interface:
	return true
	}
	return false
	}

	// x is an untyped constant representable by a value of type T
	// TODO(gri) This is borrowing from checker.convertUntyped and
	// checker.representable. Need to clean up.
	if isUntyped(Vu) {
	switch t := Tu.(type) {
	case *Basic:
	if x.mode == constant {
	return representableConst(x.val, conf, t.kind, nil)
	}
	// The result of a comparison is an untyped boolean,
	// but may not be a constant.
	if Vb, _ := Vu.(*Basic); Vb != nil {
	return Vb.kind == UntypedBool && isBoolean(Tu)
	}
	case *Interface:
	return x.isNil() \|\| t.Empty()
	case Pointer, Signature, Slice, Map, *Chan:
	return x.isNil()
	}
	}

	return false
	}

	// isInteger reports whether x is a (typed or untyped) integer value.
	func (x *operand) isInteger() bool {
	return x.mode == invalid \|\|
	isInteger(x.typ) \|\|
	x.mode == constant && representableConst(x.val, nil, UntypedInt, nil) // no *Config required for UntypedInt
	}