internal/core/compile/builtin.go - cue - Git at Google

 // Copyright 2020 CUE Authors
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 package compile

 import (
 	"cuelang.org/go/cue/errors"
 	"cuelang.org/go/internal/core/adt"
 )

 // This file contains predeclared builtins.

 const supportedByLen = adt.StructKind | adt.BytesKind | adt.StringKind | adt.ListKind

 var (
 	stringParam = adt.Param{Value: &adt.BasicType{K: adt.StringKind}}
 	structParam = adt.Param{Value: &adt.BasicType{K: adt.StructKind}}
 	listParam   = adt.Param{Value: &adt.BasicType{K: adt.ListKind}}
 	intParam    = adt.Param{Value: &adt.BasicType{K: adt.IntKind}}
 )

 var lenBuiltin = &adt.Builtin{
 	Name:   "len",
 	Params: []adt.Param{{Value: &adt.BasicType{K: supportedByLen}}},
 	Result: adt.IntKind,
 	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
 		v := args[0]
 		if x, ok := v.(*adt.Vertex); ok {
 			switch x.BaseValue.(type) {
 			case nil:
 				// This should not happen, but be defensive.
 				return c.NewErrf("unevaluated vertex")
 			case *adt.ListMarker:
 				return c.NewInt64(int64(len(x.Elems())), v)

 			case *adt.StructMarker:
 				n := 0
 				v, _ := v.(*adt.Vertex)
 				for _, a := range v.Arcs {
 					if a.Label.IsRegular() {
 						n++
 					}
 				}
 				return c.NewInt64(int64(n), v)

 			default:
 				v = x.Value()
 			}
 		}

 		switch x := v.(type) {
 		case *adt.Bytes:
 			return c.NewInt64(int64(len(x.B)), v)
 		case *adt.String:
 			return c.NewInt64(int64(len(x.Str)), v)
 		default:
 			k := x.Kind()
 			if k&supportedByLen == adt.BottomKind {
 				return c.NewErrf("invalid argument type %v", k)
 			}
 			b := c.NewErrf("incomplete argument %s (type %v)", v, k)
 			b.Code = adt.IncompleteError
 			return b
 		}
 	},
 }

 var closeBuiltin = &adt.Builtin{
 	Name:   "close",
 	Params: []adt.Param{structParam},
 	Result: adt.StructKind,
 	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
 		s, ok := args[0].(*adt.Vertex)
 		if !ok {
 			return c.NewErrf("struct argument must be concrete")
 		}
 		if s.IsClosedStruct() {
 			return s
 		}
 		v := *s
 		// TODO(perf): do not copy the arc, but rather find a way to mark the
 		// calling nodeContext.
 		v.BaseValue = &adt.StructMarker{NeedClose: true}
 		return &v
 	},
 }

 var andBuiltin = &adt.Builtin{
 	Name:   "and",
 	Params: []adt.Param{listParam},
 	Result: adt.IntKind,
 	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
 		list := c.Elems(args[0])
 		if len(list) == 0 {
 			return &adt.Top{}
 		}
 		a := []adt.Value{}
 		for _, c := range list {
 			a = append(a, c)
 		}
 		return &adt.Conjunction{Values: a}
 	},
 }

 var orBuiltin = &adt.Builtin{
 	Name:   "or",
 	Params: []adt.Param{listParam},
 	Result: adt.IntKind,
 	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
 		d := []adt.Disjunct{}
 		for _, c := range c.Elems(args[0]) {
 			d = append(d, adt.Disjunct{Val: c, Default: false})
 		}
 		if len(d) == 0 {
 			// TODO(manifest): This should not be unconditionally incomplete,
 			// but it requires results from comprehensions and all to have
 			// some special status. Maybe this can be solved by having results
 			// of list comprehensions be open if they result from iterating over
 			// an open list or struct. This would actually be exactly what
 			// that means. The error here could then only add an incomplete
 			// status if the source is open.
 			return &adt.Bottom{
 				Code: adt.IncompleteError,
 				Err:  errors.Newf(c.Pos(), "empty list in call to or"),
 			}
 		}
 		v := &adt.Vertex{}
 		// TODO: make a Disjunction.
 		v.AddConjunct(adt.MakeRootConjunct(nil,
 			&adt.DisjunctionExpr{Values: d, HasDefaults: false},
 		))
 		c.Unify(v, adt.Finalized)
 		return v
 	},
 }

 var divBuiltin = &adt.Builtin{
 	Name:   "div",
 	Params: []adt.Param{intParam, intParam},
 	Result: adt.IntKind,
 	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
 		const name = "argument to div builtin"

 		return intDivOp(c, (*adt.OpContext).IntDiv, name, args)
 	},
 }

 var modBuiltin = &adt.Builtin{
 	Name:   "mod",
 	Params: []adt.Param{intParam, intParam},
 	Result: adt.IntKind,
 	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
 		const name = "argument to mod builtin"

 		return intDivOp(c, (*adt.OpContext).IntMod, name, args)
 	},
 }

 var quoBuiltin = &adt.Builtin{
 	Name:   "quo",
 	Params: []adt.Param{intParam, intParam},
 	Result: adt.IntKind,
 	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
 		const name = "argument to quo builtin"

 		return intDivOp(c, (*adt.OpContext).IntQuo, name, args)
 	},
 }

 var remBuiltin = &adt.Builtin{
 	Name:   "rem",
 	Params: []adt.Param{intParam, intParam},
 	Result: adt.IntKind,
 	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
 		const name = "argument to rem builtin"

 		return intDivOp(c, (*adt.OpContext).IntRem, name, args)
 	},
 }

 type intFunc func(c *adt.OpContext, x, y *adt.Num) adt.Value

 func intDivOp(c *adt.OpContext, fn intFunc, name string, args []adt.Value) adt.Value {
 	a := c.Num(args[0], name)
 	b := c.Num(args[1], name)

 	if c.HasErr() {
 		return nil
 	}

 	return fn(c, a, b)
 }
	// Copyright 2020 CUE Authors
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	package compile

	import (
	"cuelang.org/go/cue/errors"
	"cuelang.org/go/internal/core/adt"
	)

	// This file contains predeclared builtins.

	const supportedByLen = adt.StructKind \| adt.BytesKind \| adt.StringKind \| adt.ListKind

	var (
	stringParam = adt.Param{Value: &adt.BasicType{K: adt.StringKind}}
	structParam = adt.Param{Value: &adt.BasicType{K: adt.StructKind}}
	listParam = adt.Param{Value: &adt.BasicType{K: adt.ListKind}}
	intParam = adt.Param{Value: &adt.BasicType{K: adt.IntKind}}
	)

	var lenBuiltin = &adt.Builtin{
	Name: "len",
	Params: []adt.Param{{Value: &adt.BasicType{K: supportedByLen}}},
	Result: adt.IntKind,
	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
	v := args[0]
	if x, ok := v.(*adt.Vertex); ok {
	switch x.BaseValue.(type) {
	case nil:
	// This should not happen, but be defensive.
	return c.NewErrf("unevaluated vertex")
	case *adt.ListMarker:
	return c.NewInt64(int64(len(x.Elems())), v)

	case *adt.StructMarker:
	n := 0
	v, _ := v.(*adt.Vertex)
	for _, a := range v.Arcs {
	if a.Label.IsRegular() {
	n++
	}
	}
	return c.NewInt64(int64(n), v)

	default:
	v = x.Value()
	}
	}

	switch x := v.(type) {
	case *adt.Bytes:
	return c.NewInt64(int64(len(x.B)), v)
	case *adt.String:
	return c.NewInt64(int64(len(x.Str)), v)
	default:
	k := x.Kind()
	if k&supportedByLen == adt.BottomKind {
	return c.NewErrf("invalid argument type %v", k)
	}
	b := c.NewErrf("incomplete argument %s (type %v)", v, k)
	b.Code = adt.IncompleteError
	return b
	}
	},
	}

	var closeBuiltin = &adt.Builtin{
	Name: "close",
	Params: []adt.Param{structParam},
	Result: adt.StructKind,
	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
	s, ok := args[0].(*adt.Vertex)
	if !ok {
	return c.NewErrf("struct argument must be concrete")
	}
	if s.IsClosedStruct() {
	return s
	}
	v := *s
	// TODO(perf): do not copy the arc, but rather find a way to mark the
	// calling nodeContext.
	v.BaseValue = &adt.StructMarker{NeedClose: true}
	return &v
	},
	}

	var andBuiltin = &adt.Builtin{
	Name: "and",
	Params: []adt.Param{listParam},
	Result: adt.IntKind,
	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
	list := c.Elems(args[0])
	if len(list) == 0 {
	return &adt.Top{}
	}
	a := []adt.Value{}
	for _, c := range list {
	a = append(a, c)
	}
	return &adt.Conjunction{Values: a}
	},
	}

	var orBuiltin = &adt.Builtin{
	Name: "or",
	Params: []adt.Param{listParam},
	Result: adt.IntKind,
	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
	d := []adt.Disjunct{}
	for _, c := range c.Elems(args[0]) {
	d = append(d, adt.Disjunct{Val: c, Default: false})
	}
	if len(d) == 0 {
	// TODO(manifest): This should not be unconditionally incomplete,
	// but it requires results from comprehensions and all to have
	// some special status. Maybe this can be solved by having results
	// of list comprehensions be open if they result from iterating over
	// an open list or struct. This would actually be exactly what
	// that means. The error here could then only add an incomplete
	// status if the source is open.
	return &adt.Bottom{
	Code: adt.IncompleteError,
	Err: errors.Newf(c.Pos(), "empty list in call to or"),
	}
	}
	v := &adt.Vertex{}
	// TODO: make a Disjunction.
	v.AddConjunct(adt.MakeRootConjunct(nil,
	&adt.DisjunctionExpr{Values: d, HasDefaults: false},
	))
	c.Unify(v, adt.Finalized)
	return v
	},
	}

	var divBuiltin = &adt.Builtin{
	Name: "div",
	Params: []adt.Param{intParam, intParam},
	Result: adt.IntKind,
	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
	const name = "argument to div builtin"

	return intDivOp(c, (*adt.OpContext).IntDiv, name, args)
	},
	}

	var modBuiltin = &adt.Builtin{
	Name: "mod",
	Params: []adt.Param{intParam, intParam},
	Result: adt.IntKind,
	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
	const name = "argument to mod builtin"

	return intDivOp(c, (*adt.OpContext).IntMod, name, args)
	},
	}

	var quoBuiltin = &adt.Builtin{
	Name: "quo",
	Params: []adt.Param{intParam, intParam},
	Result: adt.IntKind,
	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
	const name = "argument to quo builtin"

	return intDivOp(c, (*adt.OpContext).IntQuo, name, args)
	},
	}

	var remBuiltin = &adt.Builtin{
	Name: "rem",
	Params: []adt.Param{intParam, intParam},
	Result: adt.IntKind,
	Func: func(c *adt.OpContext, args []adt.Value) adt.Expr {
	const name = "argument to rem builtin"

	return intDivOp(c, (*adt.OpContext).IntRem, name, args)
	},
	}

	type intFunc func(c adt.OpContext, x, y adt.Num) adt.Value

	func intDivOp(c *adt.OpContext, fn intFunc, name string, args []adt.Value) adt.Value {
	a := c.Num(args[0], name)
	b := c.Num(args[1], name)

	if c.HasErr() {
	return nil
	}

	return fn(c, a, b)
	}