mirror of
https://github.com/ceph/ceph-csi.git
synced 2024-12-20 20:10:22 +00:00
ff3e84ad67
updating kubernetes to 1.28.0 in the main repo. Signed-off-by: Madhu Rajanna <madhupr007@gmail.com>
795 lines
25 KiB
Go
795 lines
25 KiB
Go
// Copyright 2018 Google LLC
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package interpreter
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import (
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"fmt"
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"strings"
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"github.com/google/cel-go/common/containers"
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"github.com/google/cel-go/common/operators"
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"github.com/google/cel-go/common/types/ref"
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"github.com/google/cel-go/interpreter/functions"
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exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
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)
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// interpretablePlanner creates an Interpretable evaluation plan from a proto Expr value.
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type interpretablePlanner interface {
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// Plan generates an Interpretable value (or error) from the input proto Expr.
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Plan(expr *exprpb.Expr) (Interpretable, error)
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}
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// newPlanner creates an interpretablePlanner which references a Dispatcher, TypeProvider,
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// TypeAdapter, Container, and CheckedExpr value. These pieces of data are used to resolve
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// functions, types, and namespaced identifiers at plan time rather than at runtime since
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// it only needs to be done once and may be semi-expensive to compute.
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func newPlanner(disp Dispatcher,
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provider ref.TypeProvider,
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adapter ref.TypeAdapter,
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attrFactory AttributeFactory,
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cont *containers.Container,
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checked *exprpb.CheckedExpr,
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decorators ...InterpretableDecorator) interpretablePlanner {
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return &planner{
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disp: disp,
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provider: provider,
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adapter: adapter,
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attrFactory: attrFactory,
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container: cont,
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refMap: checked.GetReferenceMap(),
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typeMap: checked.GetTypeMap(),
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decorators: decorators,
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}
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}
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// newUncheckedPlanner creates an interpretablePlanner which references a Dispatcher, TypeProvider,
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// TypeAdapter, and Container to resolve functions and types at plan time. Namespaces present in
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// Select expressions are resolved lazily at evaluation time.
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func newUncheckedPlanner(disp Dispatcher,
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provider ref.TypeProvider,
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adapter ref.TypeAdapter,
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attrFactory AttributeFactory,
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cont *containers.Container,
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decorators ...InterpretableDecorator) interpretablePlanner {
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return &planner{
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disp: disp,
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provider: provider,
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adapter: adapter,
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attrFactory: attrFactory,
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container: cont,
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refMap: make(map[int64]*exprpb.Reference),
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typeMap: make(map[int64]*exprpb.Type),
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decorators: decorators,
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}
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}
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// planner is an implementation of the interpretablePlanner interface.
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type planner struct {
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disp Dispatcher
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provider ref.TypeProvider
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adapter ref.TypeAdapter
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attrFactory AttributeFactory
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container *containers.Container
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refMap map[int64]*exprpb.Reference
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typeMap map[int64]*exprpb.Type
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decorators []InterpretableDecorator
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}
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// Plan implements the interpretablePlanner interface. This implementation of the Plan method also
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// applies decorators to each Interpretable generated as part of the overall plan. Decorators are
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// useful for layering functionality into the evaluation that is not natively understood by CEL,
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// such as state-tracking, expression re-write, and possibly efficient thread-safe memoization of
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// repeated expressions.
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func (p *planner) Plan(expr *exprpb.Expr) (Interpretable, error) {
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switch expr.GetExprKind().(type) {
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case *exprpb.Expr_CallExpr:
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return p.decorate(p.planCall(expr))
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case *exprpb.Expr_IdentExpr:
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return p.decorate(p.planIdent(expr))
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case *exprpb.Expr_SelectExpr:
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return p.decorate(p.planSelect(expr))
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case *exprpb.Expr_ListExpr:
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return p.decorate(p.planCreateList(expr))
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case *exprpb.Expr_StructExpr:
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return p.decorate(p.planCreateStruct(expr))
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case *exprpb.Expr_ComprehensionExpr:
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return p.decorate(p.planComprehension(expr))
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case *exprpb.Expr_ConstExpr:
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return p.decorate(p.planConst(expr))
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}
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return nil, fmt.Errorf("unsupported expr: %v", expr)
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}
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// decorate applies the InterpretableDecorator functions to the given Interpretable.
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// Both the Interpretable and error generated by a Plan step are accepted as arguments
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// for convenience.
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func (p *planner) decorate(i Interpretable, err error) (Interpretable, error) {
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if err != nil {
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return nil, err
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}
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for _, dec := range p.decorators {
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i, err = dec(i)
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if err != nil {
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return nil, err
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}
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}
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return i, nil
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}
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// planIdent creates an Interpretable that resolves an identifier from an Activation.
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func (p *planner) planIdent(expr *exprpb.Expr) (Interpretable, error) {
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// Establish whether the identifier is in the reference map.
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if identRef, found := p.refMap[expr.GetId()]; found {
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return p.planCheckedIdent(expr.GetId(), identRef)
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}
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// Create the possible attribute list for the unresolved reference.
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ident := expr.GetIdentExpr()
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return &evalAttr{
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adapter: p.adapter,
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attr: p.attrFactory.MaybeAttribute(expr.GetId(), ident.Name),
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}, nil
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}
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func (p *planner) planCheckedIdent(id int64, identRef *exprpb.Reference) (Interpretable, error) {
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// Plan a constant reference if this is the case for this simple identifier.
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if identRef.GetValue() != nil {
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return p.Plan(&exprpb.Expr{Id: id,
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ExprKind: &exprpb.Expr_ConstExpr{
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ConstExpr: identRef.GetValue(),
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}})
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}
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// Check to see whether the type map indicates this is a type name. All types should be
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// registered with the provider.
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cType := p.typeMap[id]
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if cType.GetType() != nil {
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cVal, found := p.provider.FindIdent(identRef.GetName())
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if !found {
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return nil, fmt.Errorf("reference to undefined type: %s", identRef.GetName())
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}
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return NewConstValue(id, cVal), nil
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}
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// Otherwise, return the attribute for the resolved identifier name.
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return &evalAttr{
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adapter: p.adapter,
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attr: p.attrFactory.AbsoluteAttribute(id, identRef.GetName()),
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}, nil
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}
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// planSelect creates an Interpretable with either:
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//
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// a) selects a field from a map or proto.
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// b) creates a field presence test for a select within a has() macro.
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// c) resolves the select expression to a namespaced identifier.
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func (p *planner) planSelect(expr *exprpb.Expr) (Interpretable, error) {
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// If the Select id appears in the reference map from the CheckedExpr proto then it is either
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// a namespaced identifier or enum value.
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if identRef, found := p.refMap[expr.GetId()]; found {
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return p.planCheckedIdent(expr.GetId(), identRef)
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}
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sel := expr.GetSelectExpr()
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// Plan the operand evaluation.
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op, err := p.Plan(sel.GetOperand())
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if err != nil {
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return nil, err
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}
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opType := p.typeMap[sel.GetOperand().GetId()]
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// If the Select was marked TestOnly, this is a presence test.
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//
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// Note: presence tests are defined for structured (e.g. proto) and dynamic values (map, json)
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// as follows:
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// - True if the object field has a non-default value, e.g. obj.str != ""
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// - True if the dynamic value has the field defined, e.g. key in map
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//
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// However, presence tests are not defined for qualified identifier names with primitive types.
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// If a string named 'a.b.c' is declared in the environment and referenced within `has(a.b.c)`,
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// it is not clear whether has should error or follow the convention defined for structured
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// values.
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// Establish the attribute reference.
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attr, isAttr := op.(InterpretableAttribute)
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if !isAttr {
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attr, err = p.relativeAttr(op.ID(), op, false)
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if err != nil {
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return nil, err
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}
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}
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// Build a qualifier for the attribute.
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qual, err := p.attrFactory.NewQualifier(opType, expr.GetId(), sel.GetField(), false)
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if err != nil {
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return nil, err
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}
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// Modify the attribute to be test-only.
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if sel.GetTestOnly() {
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attr = &evalTestOnly{
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id: expr.GetId(),
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InterpretableAttribute: attr,
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}
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}
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// Append the qualifier on the attribute.
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_, err = attr.AddQualifier(qual)
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return attr, err
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}
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// planCall creates a callable Interpretable while specializing for common functions and invocation
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// patterns. Specifically, conditional operators &&, ||, ?:, and (in)equality functions result in
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// optimized Interpretable values.
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func (p *planner) planCall(expr *exprpb.Expr) (Interpretable, error) {
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call := expr.GetCallExpr()
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target, fnName, oName := p.resolveFunction(expr)
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argCount := len(call.GetArgs())
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var offset int
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if target != nil {
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argCount++
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offset++
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}
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args := make([]Interpretable, argCount)
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if target != nil {
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arg, err := p.Plan(target)
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if err != nil {
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return nil, err
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}
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args[0] = arg
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}
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for i, argExpr := range call.GetArgs() {
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arg, err := p.Plan(argExpr)
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if err != nil {
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return nil, err
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}
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args[i+offset] = arg
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}
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// Generate specialized Interpretable operators by function name if possible.
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switch fnName {
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case operators.LogicalAnd:
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return p.planCallLogicalAnd(expr, args)
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case operators.LogicalOr:
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return p.planCallLogicalOr(expr, args)
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case operators.Conditional:
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return p.planCallConditional(expr, args)
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case operators.Equals:
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return p.planCallEqual(expr, args)
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case operators.NotEquals:
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return p.planCallNotEqual(expr, args)
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case operators.Index:
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return p.planCallIndex(expr, args, false)
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case operators.OptSelect, operators.OptIndex:
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return p.planCallIndex(expr, args, true)
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}
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// Otherwise, generate Interpretable calls specialized by argument count.
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// Try to find the specific function by overload id.
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var fnDef *functions.Overload
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if oName != "" {
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fnDef, _ = p.disp.FindOverload(oName)
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}
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// If the overload id couldn't resolve the function, try the simple function name.
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if fnDef == nil {
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fnDef, _ = p.disp.FindOverload(fnName)
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}
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switch argCount {
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case 0:
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return p.planCallZero(expr, fnName, oName, fnDef)
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case 1:
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// If the FunctionOp has been used, then use it as it may exist for the purposes
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// of dynamic dispatch within a singleton function implementation.
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if fnDef != nil && fnDef.Unary == nil && fnDef.Function != nil {
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return p.planCallVarArgs(expr, fnName, oName, fnDef, args)
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}
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return p.planCallUnary(expr, fnName, oName, fnDef, args)
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case 2:
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// If the FunctionOp has been used, then use it as it may exist for the purposes
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// of dynamic dispatch within a singleton function implementation.
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if fnDef != nil && fnDef.Binary == nil && fnDef.Function != nil {
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return p.planCallVarArgs(expr, fnName, oName, fnDef, args)
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}
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return p.planCallBinary(expr, fnName, oName, fnDef, args)
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default:
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return p.planCallVarArgs(expr, fnName, oName, fnDef, args)
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}
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}
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// planCallZero generates a zero-arity callable Interpretable.
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func (p *planner) planCallZero(expr *exprpb.Expr,
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function string,
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overload string,
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impl *functions.Overload) (Interpretable, error) {
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if impl == nil || impl.Function == nil {
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return nil, fmt.Errorf("no such overload: %s()", function)
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}
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return &evalZeroArity{
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id: expr.GetId(),
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function: function,
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overload: overload,
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impl: impl.Function,
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}, nil
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}
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// planCallUnary generates a unary callable Interpretable.
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func (p *planner) planCallUnary(expr *exprpb.Expr,
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function string,
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overload string,
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impl *functions.Overload,
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args []Interpretable) (Interpretable, error) {
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var fn functions.UnaryOp
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var trait int
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var nonStrict bool
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if impl != nil {
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if impl.Unary == nil {
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return nil, fmt.Errorf("no such overload: %s(arg)", function)
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}
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fn = impl.Unary
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trait = impl.OperandTrait
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nonStrict = impl.NonStrict
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}
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return &evalUnary{
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id: expr.GetId(),
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function: function,
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overload: overload,
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arg: args[0],
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trait: trait,
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impl: fn,
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nonStrict: nonStrict,
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}, nil
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}
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// planCallBinary generates a binary callable Interpretable.
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func (p *planner) planCallBinary(expr *exprpb.Expr,
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function string,
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overload string,
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impl *functions.Overload,
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args []Interpretable) (Interpretable, error) {
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var fn functions.BinaryOp
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var trait int
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var nonStrict bool
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if impl != nil {
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if impl.Binary == nil {
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return nil, fmt.Errorf("no such overload: %s(lhs, rhs)", function)
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}
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fn = impl.Binary
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trait = impl.OperandTrait
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nonStrict = impl.NonStrict
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}
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return &evalBinary{
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id: expr.GetId(),
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function: function,
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overload: overload,
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lhs: args[0],
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rhs: args[1],
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trait: trait,
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impl: fn,
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nonStrict: nonStrict,
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}, nil
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}
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// planCallVarArgs generates a variable argument callable Interpretable.
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func (p *planner) planCallVarArgs(expr *exprpb.Expr,
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function string,
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overload string,
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impl *functions.Overload,
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args []Interpretable) (Interpretable, error) {
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var fn functions.FunctionOp
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var trait int
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var nonStrict bool
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if impl != nil {
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if impl.Function == nil {
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return nil, fmt.Errorf("no such overload: %s(...)", function)
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}
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fn = impl.Function
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trait = impl.OperandTrait
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nonStrict = impl.NonStrict
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}
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return &evalVarArgs{
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id: expr.GetId(),
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function: function,
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overload: overload,
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args: args,
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trait: trait,
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impl: fn,
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nonStrict: nonStrict,
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}, nil
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}
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// planCallEqual generates an equals (==) Interpretable.
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func (p *planner) planCallEqual(expr *exprpb.Expr, args []Interpretable) (Interpretable, error) {
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return &evalEq{
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id: expr.GetId(),
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lhs: args[0],
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rhs: args[1],
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}, nil
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}
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// planCallNotEqual generates a not equals (!=) Interpretable.
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func (p *planner) planCallNotEqual(expr *exprpb.Expr, args []Interpretable) (Interpretable, error) {
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return &evalNe{
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id: expr.GetId(),
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lhs: args[0],
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rhs: args[1],
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}, nil
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}
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// planCallLogicalAnd generates a logical and (&&) Interpretable.
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func (p *planner) planCallLogicalAnd(expr *exprpb.Expr, args []Interpretable) (Interpretable, error) {
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return &evalAnd{
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id: expr.GetId(),
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lhs: args[0],
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rhs: args[1],
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}, nil
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}
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// planCallLogicalOr generates a logical or (||) Interpretable.
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func (p *planner) planCallLogicalOr(expr *exprpb.Expr, args []Interpretable) (Interpretable, error) {
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return &evalOr{
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id: expr.GetId(),
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lhs: args[0],
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rhs: args[1],
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}, nil
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}
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// planCallConditional generates a conditional / ternary (c ? t : f) Interpretable.
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func (p *planner) planCallConditional(expr *exprpb.Expr, args []Interpretable) (Interpretable, error) {
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cond := args[0]
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t := args[1]
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var tAttr Attribute
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truthyAttr, isTruthyAttr := t.(InterpretableAttribute)
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if isTruthyAttr {
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tAttr = truthyAttr.Attr()
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} else {
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tAttr = p.attrFactory.RelativeAttribute(t.ID(), t)
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}
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f := args[2]
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var fAttr Attribute
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falsyAttr, isFalsyAttr := f.(InterpretableAttribute)
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if isFalsyAttr {
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fAttr = falsyAttr.Attr()
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} else {
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fAttr = p.attrFactory.RelativeAttribute(f.ID(), f)
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}
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return &evalAttr{
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adapter: p.adapter,
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attr: p.attrFactory.ConditionalAttribute(expr.GetId(), cond, tAttr, fAttr),
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}, nil
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}
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// planCallIndex either extends an attribute with the argument to the index operation, or creates
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// a relative attribute based on the return of a function call or operation.
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func (p *planner) planCallIndex(expr *exprpb.Expr, args []Interpretable, optional bool) (Interpretable, error) {
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op := args[0]
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ind := args[1]
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opType := p.typeMap[expr.GetCallExpr().GetTarget().GetId()]
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// Establish the attribute reference.
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var err error
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attr, isAttr := op.(InterpretableAttribute)
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if !isAttr {
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attr, err = p.relativeAttr(op.ID(), op, false)
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if err != nil {
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return nil, err
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}
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}
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// Construct the qualifier type.
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var qual Qualifier
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switch ind := ind.(type) {
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case InterpretableConst:
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qual, err = p.attrFactory.NewQualifier(opType, expr.GetId(), ind.Value(), optional)
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case InterpretableAttribute:
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qual, err = p.attrFactory.NewQualifier(opType, expr.GetId(), ind, optional)
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default:
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qual, err = p.relativeAttr(expr.GetId(), ind, optional)
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}
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// Add the qualifier to the attribute
|
|
_, err = attr.AddQualifier(qual)
|
|
return attr, err
|
|
}
|
|
|
|
// planCreateList generates a list construction Interpretable.
|
|
func (p *planner) planCreateList(expr *exprpb.Expr) (Interpretable, error) {
|
|
list := expr.GetListExpr()
|
|
optionalIndices := list.GetOptionalIndices()
|
|
elements := list.GetElements()
|
|
optionals := make([]bool, len(elements))
|
|
for _, index := range optionalIndices {
|
|
if index < 0 || index >= int32(len(elements)) {
|
|
return nil, fmt.Errorf("optional index %d out of element bounds [0, %d]", index, len(elements))
|
|
}
|
|
optionals[index] = true
|
|
}
|
|
elems := make([]Interpretable, len(elements))
|
|
for i, elem := range elements {
|
|
elemVal, err := p.Plan(elem)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
elems[i] = elemVal
|
|
}
|
|
return &evalList{
|
|
id: expr.GetId(),
|
|
elems: elems,
|
|
optionals: optionals,
|
|
hasOptionals: len(optionals) != 0,
|
|
adapter: p.adapter,
|
|
}, nil
|
|
}
|
|
|
|
// planCreateStruct generates a map or object construction Interpretable.
|
|
func (p *planner) planCreateStruct(expr *exprpb.Expr) (Interpretable, error) {
|
|
str := expr.GetStructExpr()
|
|
if len(str.MessageName) != 0 {
|
|
return p.planCreateObj(expr)
|
|
}
|
|
entries := str.GetEntries()
|
|
optionals := make([]bool, len(entries))
|
|
keys := make([]Interpretable, len(entries))
|
|
vals := make([]Interpretable, len(entries))
|
|
for i, entry := range entries {
|
|
keyVal, err := p.Plan(entry.GetMapKey())
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
keys[i] = keyVal
|
|
|
|
valVal, err := p.Plan(entry.GetValue())
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
vals[i] = valVal
|
|
optionals[i] = entry.GetOptionalEntry()
|
|
}
|
|
return &evalMap{
|
|
id: expr.GetId(),
|
|
keys: keys,
|
|
vals: vals,
|
|
optionals: optionals,
|
|
hasOptionals: len(optionals) != 0,
|
|
adapter: p.adapter,
|
|
}, nil
|
|
}
|
|
|
|
// planCreateObj generates an object construction Interpretable.
|
|
func (p *planner) planCreateObj(expr *exprpb.Expr) (Interpretable, error) {
|
|
obj := expr.GetStructExpr()
|
|
typeName, defined := p.resolveTypeName(obj.GetMessageName())
|
|
if !defined {
|
|
return nil, fmt.Errorf("unknown type: %s", obj.GetMessageName())
|
|
}
|
|
entries := obj.GetEntries()
|
|
optionals := make([]bool, len(entries))
|
|
fields := make([]string, len(entries))
|
|
vals := make([]Interpretable, len(entries))
|
|
for i, entry := range entries {
|
|
fields[i] = entry.GetFieldKey()
|
|
val, err := p.Plan(entry.GetValue())
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
vals[i] = val
|
|
optionals[i] = entry.GetOptionalEntry()
|
|
}
|
|
return &evalObj{
|
|
id: expr.GetId(),
|
|
typeName: typeName,
|
|
fields: fields,
|
|
vals: vals,
|
|
optionals: optionals,
|
|
hasOptionals: len(optionals) != 0,
|
|
provider: p.provider,
|
|
}, nil
|
|
}
|
|
|
|
// planComprehension generates an Interpretable fold operation.
|
|
func (p *planner) planComprehension(expr *exprpb.Expr) (Interpretable, error) {
|
|
fold := expr.GetComprehensionExpr()
|
|
accu, err := p.Plan(fold.GetAccuInit())
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
iterRange, err := p.Plan(fold.GetIterRange())
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
cond, err := p.Plan(fold.GetLoopCondition())
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
step, err := p.Plan(fold.GetLoopStep())
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
result, err := p.Plan(fold.GetResult())
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
return &evalFold{
|
|
id: expr.GetId(),
|
|
accuVar: fold.AccuVar,
|
|
accu: accu,
|
|
iterVar: fold.IterVar,
|
|
iterRange: iterRange,
|
|
cond: cond,
|
|
step: step,
|
|
result: result,
|
|
adapter: p.adapter,
|
|
}, nil
|
|
}
|
|
|
|
// planConst generates a constant valued Interpretable.
|
|
func (p *planner) planConst(expr *exprpb.Expr) (Interpretable, error) {
|
|
val, err := p.constValue(expr.GetConstExpr())
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
return NewConstValue(expr.GetId(), val), nil
|
|
}
|
|
|
|
// constValue converts a proto Constant value to a ref.Val.
|
|
func (p *planner) constValue(c *exprpb.Constant) (ref.Val, error) {
|
|
switch c.GetConstantKind().(type) {
|
|
case *exprpb.Constant_BoolValue:
|
|
return p.adapter.NativeToValue(c.GetBoolValue()), nil
|
|
case *exprpb.Constant_BytesValue:
|
|
return p.adapter.NativeToValue(c.GetBytesValue()), nil
|
|
case *exprpb.Constant_DoubleValue:
|
|
return p.adapter.NativeToValue(c.GetDoubleValue()), nil
|
|
case *exprpb.Constant_DurationValue:
|
|
return p.adapter.NativeToValue(c.GetDurationValue().AsDuration()), nil
|
|
case *exprpb.Constant_Int64Value:
|
|
return p.adapter.NativeToValue(c.GetInt64Value()), nil
|
|
case *exprpb.Constant_NullValue:
|
|
return p.adapter.NativeToValue(c.GetNullValue()), nil
|
|
case *exprpb.Constant_StringValue:
|
|
return p.adapter.NativeToValue(c.GetStringValue()), nil
|
|
case *exprpb.Constant_TimestampValue:
|
|
return p.adapter.NativeToValue(c.GetTimestampValue().AsTime()), nil
|
|
case *exprpb.Constant_Uint64Value:
|
|
return p.adapter.NativeToValue(c.GetUint64Value()), nil
|
|
}
|
|
return nil, fmt.Errorf("unknown constant type: %v", c)
|
|
}
|
|
|
|
// resolveTypeName takes a qualified string constructed at parse time, applies the proto
|
|
// namespace resolution rules to it in a scan over possible matching types in the TypeProvider.
|
|
func (p *planner) resolveTypeName(typeName string) (string, bool) {
|
|
for _, qualifiedTypeName := range p.container.ResolveCandidateNames(typeName) {
|
|
if _, found := p.provider.FindType(qualifiedTypeName); found {
|
|
return qualifiedTypeName, true
|
|
}
|
|
}
|
|
return "", false
|
|
}
|
|
|
|
// resolveFunction determines the call target, function name, and overload name from a given Expr
|
|
// value.
|
|
//
|
|
// The resolveFunction resolves ambiguities where a function may either be a receiver-style
|
|
// invocation or a qualified global function name.
|
|
// - The target expression may only consist of ident and select expressions.
|
|
// - The function is declared in the environment using its fully-qualified name.
|
|
// - The fully-qualified function name matches the string serialized target value.
|
|
func (p *planner) resolveFunction(expr *exprpb.Expr) (*exprpb.Expr, string, string) {
|
|
// Note: similar logic exists within the `checker/checker.go`. If making changes here
|
|
// please consider the impact on checker.go and consolidate implementations or mirror code
|
|
// as appropriate.
|
|
call := expr.GetCallExpr()
|
|
target := call.GetTarget()
|
|
fnName := call.GetFunction()
|
|
|
|
// Checked expressions always have a reference map entry, and _should_ have the fully qualified
|
|
// function name as the fnName value.
|
|
oRef, hasOverload := p.refMap[expr.GetId()]
|
|
if hasOverload {
|
|
if len(oRef.GetOverloadId()) == 1 {
|
|
return target, fnName, oRef.GetOverloadId()[0]
|
|
}
|
|
// Note, this namespaced function name will not appear as a fully qualified name in ASTs
|
|
// built and stored before cel-go v0.5.0; however, this functionality did not work at all
|
|
// before the v0.5.0 release.
|
|
return target, fnName, ""
|
|
}
|
|
|
|
// Parse-only expressions need to handle the same logic as is normally performed at check time,
|
|
// but with potentially much less information. The only reliable source of information about
|
|
// which functions are configured is the dispatcher.
|
|
if target == nil {
|
|
// If the user has a parse-only expression, then it should have been configured as such in
|
|
// the interpreter dispatcher as it may have been omitted from the checker environment.
|
|
for _, qualifiedName := range p.container.ResolveCandidateNames(fnName) {
|
|
_, found := p.disp.FindOverload(qualifiedName)
|
|
if found {
|
|
return nil, qualifiedName, ""
|
|
}
|
|
}
|
|
// It's possible that the overload was not found, but this situation is accounted for in
|
|
// the planCall phase; however, the leading dot used for denoting fully-qualified
|
|
// namespaced identifiers must be stripped, as all declarations already use fully-qualified
|
|
// names. This stripping behavior is handled automatically by the ResolveCandidateNames
|
|
// call.
|
|
return target, stripLeadingDot(fnName), ""
|
|
}
|
|
|
|
// Handle the situation where the function target actually indicates a qualified function name.
|
|
qualifiedPrefix, maybeQualified := p.toQualifiedName(target)
|
|
if maybeQualified {
|
|
maybeQualifiedName := qualifiedPrefix + "." + fnName
|
|
for _, qualifiedName := range p.container.ResolveCandidateNames(maybeQualifiedName) {
|
|
_, found := p.disp.FindOverload(qualifiedName)
|
|
if found {
|
|
// Clear the target to ensure the proper arity is used for finding the
|
|
// implementation.
|
|
return nil, qualifiedName, ""
|
|
}
|
|
}
|
|
}
|
|
// In the default case, the function is exactly as it was advertised: a receiver call on with
|
|
// an expression-based target with the given simple function name.
|
|
return target, fnName, ""
|
|
}
|
|
|
|
// relativeAttr indicates that the attribute in this case acts as a qualifier and as such needs to
|
|
// be observed to ensure that it's evaluation value is properly recorded for state tracking.
|
|
func (p *planner) relativeAttr(id int64, eval Interpretable, opt bool) (InterpretableAttribute, error) {
|
|
eAttr, ok := eval.(InterpretableAttribute)
|
|
if !ok {
|
|
eAttr = &evalAttr{
|
|
adapter: p.adapter,
|
|
attr: p.attrFactory.RelativeAttribute(id, eval),
|
|
optional: opt,
|
|
}
|
|
}
|
|
// This looks like it should either decorate the new evalAttr node, or early return the InterpretableAttribute
|
|
decAttr, err := p.decorate(eAttr, nil)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
eAttr, ok = decAttr.(InterpretableAttribute)
|
|
if !ok {
|
|
return nil, fmt.Errorf("invalid attribute decoration: %v(%T)", decAttr, decAttr)
|
|
}
|
|
return eAttr, nil
|
|
}
|
|
|
|
// toQualifiedName converts an expression AST into a qualified name if possible, with a boolean
|
|
// 'found' value that indicates if the conversion is successful.
|
|
func (p *planner) toQualifiedName(operand *exprpb.Expr) (string, bool) {
|
|
// If the checker identified the expression as an attribute by the type-checker, then it can't
|
|
// possibly be part of qualified name in a namespace.
|
|
_, isAttr := p.refMap[operand.GetId()]
|
|
if isAttr {
|
|
return "", false
|
|
}
|
|
// Since functions cannot be both namespaced and receiver functions, if the operand is not an
|
|
// qualified variable name, return the (possibly) qualified name given the expressions.
|
|
return containers.ToQualifiedName(operand)
|
|
}
|
|
|
|
func stripLeadingDot(name string) string {
|
|
if strings.HasPrefix(name, ".") {
|
|
return name[1:]
|
|
}
|
|
return name
|
|
}
|