mirror of
https://github.com/ceph/ceph-csi.git
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560 lines
17 KiB
Go
560 lines
17 KiB
Go
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// Copyright 2023 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 cel
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import (
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"fmt"
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"github.com/google/cel-go/common/ast"
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"github.com/google/cel-go/common/operators"
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"github.com/google/cel-go/common/overloads"
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"github.com/google/cel-go/common/types"
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"github.com/google/cel-go/common/types/ref"
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"github.com/google/cel-go/common/types/traits"
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)
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// ConstantFoldingOption defines a functional option for configuring constant folding.
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type ConstantFoldingOption func(opt *constantFoldingOptimizer) (*constantFoldingOptimizer, error)
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// MaxConstantFoldIterations limits the number of times literals may be folding during optimization.
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//
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// Defaults to 100 if not set.
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func MaxConstantFoldIterations(limit int) ConstantFoldingOption {
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return func(opt *constantFoldingOptimizer) (*constantFoldingOptimizer, error) {
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opt.maxFoldIterations = limit
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return opt, nil
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}
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}
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// NewConstantFoldingOptimizer creates an optimizer which inlines constant scalar an aggregate
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// literal values within function calls and select statements with their evaluated result.
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func NewConstantFoldingOptimizer(opts ...ConstantFoldingOption) (ASTOptimizer, error) {
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folder := &constantFoldingOptimizer{
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maxFoldIterations: defaultMaxConstantFoldIterations,
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}
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var err error
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for _, o := range opts {
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folder, err = o(folder)
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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 folder, nil
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}
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type constantFoldingOptimizer struct {
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maxFoldIterations int
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}
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// Optimize queries the expression graph for scalar and aggregate literal expressions within call and
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// select statements and then evaluates them and replaces the call site with the literal result.
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//
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// Note: only values which can be represented as literals in CEL syntax are supported.
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func (opt *constantFoldingOptimizer) Optimize(ctx *OptimizerContext, a *ast.AST) *ast.AST {
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root := ast.NavigateAST(a)
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// Walk the list of foldable expression and continue to fold until there are no more folds left.
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// All of the fold candidates returned by the constantExprMatcher should succeed unless there's
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// a logic bug with the selection of expressions.
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foldableExprs := ast.MatchDescendants(root, constantExprMatcher)
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foldCount := 0
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for len(foldableExprs) != 0 && foldCount < opt.maxFoldIterations {
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for _, fold := range foldableExprs {
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// If the expression could be folded because it's a non-strict call, and the
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// branches are pruned, continue to the next fold.
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if fold.Kind() == ast.CallKind && maybePruneBranches(ctx, fold) {
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continue
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}
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// Otherwise, assume all context is needed to evaluate the expression.
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err := tryFold(ctx, a, fold)
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if err != nil {
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ctx.ReportErrorAtID(fold.ID(), "constant-folding evaluation failed: %v", err.Error())
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return a
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}
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}
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foldCount++
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foldableExprs = ast.MatchDescendants(root, constantExprMatcher)
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}
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// Once all of the constants have been folded, try to run through the remaining comprehensions
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// one last time. In this case, there's no guarantee they'll run, so we only update the
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// target comprehension node with the literal value if the evaluation succeeds.
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for _, compre := range ast.MatchDescendants(root, ast.KindMatcher(ast.ComprehensionKind)) {
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tryFold(ctx, a, compre)
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}
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// If the output is a list, map, or struct which contains optional entries, then prune it
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// to make sure that the optionals, if resolved, do not surface in the output literal.
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pruneOptionalElements(ctx, root)
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// Ensure that all intermediate values in the folded expression can be represented as valid
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// CEL literals within the AST structure. Use `PostOrderVisit` rather than `MatchDescendents`
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// to avoid extra allocations during this final pass through the AST.
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ast.PostOrderVisit(root, ast.NewExprVisitor(func(e ast.Expr) {
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if e.Kind() != ast.LiteralKind {
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return
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}
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val := e.AsLiteral()
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adapted, err := adaptLiteral(ctx, val)
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if err != nil {
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ctx.ReportErrorAtID(root.ID(), "constant-folding evaluation failed: %v", err.Error())
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return
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}
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ctx.UpdateExpr(e, adapted)
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}))
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return a
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}
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// tryFold attempts to evaluate a sub-expression to a literal.
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//
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// If the evaluation succeeds, the input expr value will be modified to become a literal, otherwise
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// the method will return an error.
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func tryFold(ctx *OptimizerContext, a *ast.AST, expr ast.Expr) error {
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// Assume all context is needed to evaluate the expression.
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subAST := &Ast{
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impl: ast.NewCheckedAST(ast.NewAST(expr, a.SourceInfo()), a.TypeMap(), a.ReferenceMap()),
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}
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prg, err := ctx.Program(subAST)
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if err != nil {
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return err
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}
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out, _, err := prg.Eval(NoVars())
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if err != nil {
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return err
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}
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// Update the fold expression to be a literal.
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ctx.UpdateExpr(expr, ctx.NewLiteral(out))
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return nil
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}
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// maybePruneBranches inspects the non-strict call expression to determine whether
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// a branch can be removed. Evaluation will naturally prune logical and / or calls,
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// but conditional will not be pruned cleanly, so this is one small area where the
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// constant folding step reimplements a portion of the evaluator.
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func maybePruneBranches(ctx *OptimizerContext, expr ast.NavigableExpr) bool {
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call := expr.AsCall()
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args := call.Args()
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switch call.FunctionName() {
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case operators.LogicalAnd, operators.LogicalOr:
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return maybeShortcircuitLogic(ctx, call.FunctionName(), args, expr)
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case operators.Conditional:
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cond := args[0]
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truthy := args[1]
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falsy := args[2]
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if cond.Kind() != ast.LiteralKind {
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return false
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}
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if cond.AsLiteral() == types.True {
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ctx.UpdateExpr(expr, truthy)
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} else {
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ctx.UpdateExpr(expr, falsy)
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}
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return true
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case operators.In:
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haystack := args[1]
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if haystack.Kind() == ast.ListKind && haystack.AsList().Size() == 0 {
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ctx.UpdateExpr(expr, ctx.NewLiteral(types.False))
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return true
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}
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needle := args[0]
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if needle.Kind() == ast.LiteralKind && haystack.Kind() == ast.ListKind {
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needleValue := needle.AsLiteral()
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list := haystack.AsList()
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for _, e := range list.Elements() {
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if e.Kind() == ast.LiteralKind && e.AsLiteral().Equal(needleValue) == types.True {
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ctx.UpdateExpr(expr, ctx.NewLiteral(types.True))
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return true
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}
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}
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}
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}
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return false
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}
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func maybeShortcircuitLogic(ctx *OptimizerContext, function string, args []ast.Expr, expr ast.NavigableExpr) bool {
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shortcircuit := types.False
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skip := types.True
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if function == operators.LogicalOr {
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shortcircuit = types.True
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skip = types.False
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}
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newArgs := []ast.Expr{}
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for _, arg := range args {
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if arg.Kind() != ast.LiteralKind {
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newArgs = append(newArgs, arg)
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continue
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}
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if arg.AsLiteral() == skip {
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continue
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}
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if arg.AsLiteral() == shortcircuit {
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ctx.UpdateExpr(expr, arg)
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return true
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}
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}
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if len(newArgs) == 0 {
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newArgs = append(newArgs, args[0])
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ctx.UpdateExpr(expr, newArgs[0])
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return true
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}
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if len(newArgs) == 1 {
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ctx.UpdateExpr(expr, newArgs[0])
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return true
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}
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ctx.UpdateExpr(expr, ctx.NewCall(function, newArgs...))
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return true
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}
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// pruneOptionalElements works from the bottom up to resolve optional elements within
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// aggregate literals.
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//
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// Note, many aggregate literals will be resolved as arguments to functions or select
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// statements, so this method exists to handle the case where the literal could not be
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// fully resolved or exists outside of a call, select, or comprehension context.
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func pruneOptionalElements(ctx *OptimizerContext, root ast.NavigableExpr) {
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aggregateLiterals := ast.MatchDescendants(root, aggregateLiteralMatcher)
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for _, lit := range aggregateLiterals {
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switch lit.Kind() {
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case ast.ListKind:
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pruneOptionalListElements(ctx, lit)
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case ast.MapKind:
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pruneOptionalMapEntries(ctx, lit)
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case ast.StructKind:
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pruneOptionalStructFields(ctx, lit)
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}
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}
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}
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func pruneOptionalListElements(ctx *OptimizerContext, e ast.Expr) {
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l := e.AsList()
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elems := l.Elements()
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optIndices := l.OptionalIndices()
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if len(optIndices) == 0 {
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return
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}
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updatedElems := []ast.Expr{}
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updatedIndices := []int32{}
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newOptIndex := -1
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for _, e := range elems {
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newOptIndex++
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if !l.IsOptional(int32(newOptIndex)) {
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updatedElems = append(updatedElems, e)
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continue
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}
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if e.Kind() != ast.LiteralKind {
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updatedElems = append(updatedElems, e)
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updatedIndices = append(updatedIndices, int32(newOptIndex))
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continue
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}
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optElemVal, ok := e.AsLiteral().(*types.Optional)
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if !ok {
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updatedElems = append(updatedElems, e)
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updatedIndices = append(updatedIndices, int32(newOptIndex))
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continue
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}
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if !optElemVal.HasValue() {
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newOptIndex-- // Skipping causes the list to get smaller.
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continue
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}
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ctx.UpdateExpr(e, ctx.NewLiteral(optElemVal.GetValue()))
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updatedElems = append(updatedElems, e)
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}
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ctx.UpdateExpr(e, ctx.NewList(updatedElems, updatedIndices))
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}
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func pruneOptionalMapEntries(ctx *OptimizerContext, e ast.Expr) {
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m := e.AsMap()
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entries := m.Entries()
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updatedEntries := []ast.EntryExpr{}
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modified := false
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for _, e := range entries {
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entry := e.AsMapEntry()
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key := entry.Key()
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val := entry.Value()
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// If the entry is not optional, or the value-side of the optional hasn't
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// been resolved to a literal, then preserve the entry as-is.
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if !entry.IsOptional() || val.Kind() != ast.LiteralKind {
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updatedEntries = append(updatedEntries, e)
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continue
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}
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optElemVal, ok := val.AsLiteral().(*types.Optional)
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if !ok {
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updatedEntries = append(updatedEntries, e)
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continue
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}
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// When the key is not a literal, but the value is, then it needs to be
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// restored to an optional value.
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if key.Kind() != ast.LiteralKind {
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undoOptVal, err := adaptLiteral(ctx, optElemVal)
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if err != nil {
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ctx.ReportErrorAtID(val.ID(), "invalid map value literal %v: %v", optElemVal, err)
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}
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ctx.UpdateExpr(val, undoOptVal)
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updatedEntries = append(updatedEntries, e)
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continue
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}
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modified = true
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if !optElemVal.HasValue() {
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continue
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}
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ctx.UpdateExpr(val, ctx.NewLiteral(optElemVal.GetValue()))
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updatedEntry := ctx.NewMapEntry(key, val, false)
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updatedEntries = append(updatedEntries, updatedEntry)
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}
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if modified {
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ctx.UpdateExpr(e, ctx.NewMap(updatedEntries))
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}
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}
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func pruneOptionalStructFields(ctx *OptimizerContext, e ast.Expr) {
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s := e.AsStruct()
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fields := s.Fields()
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updatedFields := []ast.EntryExpr{}
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modified := false
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for _, f := range fields {
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field := f.AsStructField()
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val := field.Value()
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if !field.IsOptional() || val.Kind() != ast.LiteralKind {
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updatedFields = append(updatedFields, f)
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continue
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}
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optElemVal, ok := val.AsLiteral().(*types.Optional)
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if !ok {
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updatedFields = append(updatedFields, f)
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continue
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}
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modified = true
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if !optElemVal.HasValue() {
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continue
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}
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ctx.UpdateExpr(val, ctx.NewLiteral(optElemVal.GetValue()))
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updatedField := ctx.NewStructField(field.Name(), val, false)
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updatedFields = append(updatedFields, updatedField)
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}
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if modified {
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ctx.UpdateExpr(e, ctx.NewStruct(s.TypeName(), updatedFields))
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}
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}
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// adaptLiteral converts a runtime CEL value to its equivalent literal expression.
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//
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// For strongly typed values, the type-provider will be used to reconstruct the fields
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// which are present in the literal and their equivalent initialization values.
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func adaptLiteral(ctx *OptimizerContext, val ref.Val) (ast.Expr, error) {
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switch t := val.Type().(type) {
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case *types.Type:
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switch t {
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case types.BoolType, types.BytesType, types.DoubleType, types.IntType,
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types.NullType, types.StringType, types.UintType:
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return ctx.NewLiteral(val), nil
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case types.DurationType:
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return ctx.NewCall(
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overloads.TypeConvertDuration,
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ctx.NewLiteral(val.ConvertToType(types.StringType)),
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), nil
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case types.TimestampType:
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return ctx.NewCall(
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overloads.TypeConvertTimestamp,
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ctx.NewLiteral(val.ConvertToType(types.StringType)),
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), nil
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case types.OptionalType:
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opt := val.(*types.Optional)
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if !opt.HasValue() {
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return ctx.NewCall("optional.none"), nil
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}
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target, err := adaptLiteral(ctx, opt.GetValue())
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if err != nil {
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return nil, err
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}
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return ctx.NewCall("optional.of", target), nil
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case types.TypeType:
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return ctx.NewIdent(val.(*types.Type).TypeName()), nil
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case types.ListType:
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l, ok := val.(traits.Lister)
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if !ok {
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return nil, fmt.Errorf("failed to adapt %v to literal", val)
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}
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elems := make([]ast.Expr, l.Size().(types.Int))
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idx := 0
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it := l.Iterator()
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for it.HasNext() == types.True {
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elemVal := it.Next()
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elemExpr, err := adaptLiteral(ctx, elemVal)
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if err != nil {
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return nil, err
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}
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elems[idx] = elemExpr
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idx++
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}
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return ctx.NewList(elems, []int32{}), nil
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case types.MapType:
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m, ok := val.(traits.Mapper)
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if !ok {
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return nil, fmt.Errorf("failed to adapt %v to literal", val)
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}
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entries := make([]ast.EntryExpr, m.Size().(types.Int))
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idx := 0
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it := m.Iterator()
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for it.HasNext() == types.True {
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keyVal := it.Next()
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keyExpr, err := adaptLiteral(ctx, keyVal)
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if err != nil {
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return nil, err
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}
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valVal := m.Get(keyVal)
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valExpr, err := adaptLiteral(ctx, valVal)
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if err != nil {
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return nil, err
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}
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|
entries[idx] = ctx.NewMapEntry(keyExpr, valExpr, false)
|
||
|
idx++
|
||
|
}
|
||
|
return ctx.NewMap(entries), nil
|
||
|
default:
|
||
|
provider := ctx.CELTypeProvider()
|
||
|
fields, found := provider.FindStructFieldNames(t.TypeName())
|
||
|
if !found {
|
||
|
return nil, fmt.Errorf("failed to adapt %v to literal", val)
|
||
|
}
|
||
|
tester := val.(traits.FieldTester)
|
||
|
indexer := val.(traits.Indexer)
|
||
|
fieldInits := []ast.EntryExpr{}
|
||
|
for _, f := range fields {
|
||
|
field := types.String(f)
|
||
|
if tester.IsSet(field) != types.True {
|
||
|
continue
|
||
|
}
|
||
|
fieldVal := indexer.Get(field)
|
||
|
fieldExpr, err := adaptLiteral(ctx, fieldVal)
|
||
|
if err != nil {
|
||
|
return nil, err
|
||
|
}
|
||
|
fieldInits = append(fieldInits, ctx.NewStructField(f, fieldExpr, false))
|
||
|
}
|
||
|
return ctx.NewStruct(t.TypeName(), fieldInits), nil
|
||
|
}
|
||
|
}
|
||
|
return nil, fmt.Errorf("failed to adapt %v to literal", val)
|
||
|
}
|
||
|
|
||
|
// constantExprMatcher matches calls, select statements, and comprehensions whose arguments
|
||
|
// are all constant scalar or aggregate literal values.
|
||
|
//
|
||
|
// Only comprehensions which are not nested are included as possible constant folds, and only
|
||
|
// if all variables referenced in the comprehension stack exist are only iteration or
|
||
|
// accumulation variables.
|
||
|
func constantExprMatcher(e ast.NavigableExpr) bool {
|
||
|
switch e.Kind() {
|
||
|
case ast.CallKind:
|
||
|
return constantCallMatcher(e)
|
||
|
case ast.SelectKind:
|
||
|
sel := e.AsSelect() // guaranteed to be a navigable value
|
||
|
return constantMatcher(sel.Operand().(ast.NavigableExpr))
|
||
|
case ast.ComprehensionKind:
|
||
|
if isNestedComprehension(e) {
|
||
|
return false
|
||
|
}
|
||
|
vars := map[string]bool{}
|
||
|
constantExprs := true
|
||
|
visitor := ast.NewExprVisitor(func(e ast.Expr) {
|
||
|
if e.Kind() == ast.ComprehensionKind {
|
||
|
nested := e.AsComprehension()
|
||
|
vars[nested.AccuVar()] = true
|
||
|
vars[nested.IterVar()] = true
|
||
|
}
|
||
|
if e.Kind() == ast.IdentKind && !vars[e.AsIdent()] {
|
||
|
constantExprs = false
|
||
|
}
|
||
|
})
|
||
|
ast.PreOrderVisit(e, visitor)
|
||
|
return constantExprs
|
||
|
default:
|
||
|
return false
|
||
|
}
|
||
|
}
|
||
|
|
||
|
// constantCallMatcher identifies strict and non-strict calls which can be folded.
|
||
|
func constantCallMatcher(e ast.NavigableExpr) bool {
|
||
|
call := e.AsCall()
|
||
|
children := e.Children()
|
||
|
fnName := call.FunctionName()
|
||
|
if fnName == operators.LogicalAnd {
|
||
|
for _, child := range children {
|
||
|
if child.Kind() == ast.LiteralKind {
|
||
|
return true
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
if fnName == operators.LogicalOr {
|
||
|
for _, child := range children {
|
||
|
if child.Kind() == ast.LiteralKind {
|
||
|
return true
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
if fnName == operators.Conditional {
|
||
|
cond := children[0]
|
||
|
if cond.Kind() == ast.LiteralKind && cond.AsLiteral().Type() == types.BoolType {
|
||
|
return true
|
||
|
}
|
||
|
}
|
||
|
if fnName == operators.In {
|
||
|
haystack := children[1]
|
||
|
if haystack.Kind() == ast.ListKind && haystack.AsList().Size() == 0 {
|
||
|
return true
|
||
|
}
|
||
|
needle := children[0]
|
||
|
if needle.Kind() == ast.LiteralKind && haystack.Kind() == ast.ListKind {
|
||
|
needleValue := needle.AsLiteral()
|
||
|
list := haystack.AsList()
|
||
|
for _, e := range list.Elements() {
|
||
|
if e.Kind() == ast.LiteralKind && e.AsLiteral().Equal(needleValue) == types.True {
|
||
|
return true
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
// convert all other calls with constant arguments
|
||
|
for _, child := range children {
|
||
|
if !constantMatcher(child) {
|
||
|
return false
|
||
|
}
|
||
|
}
|
||
|
return true
|
||
|
}
|
||
|
|
||
|
func isNestedComprehension(e ast.NavigableExpr) bool {
|
||
|
parent, found := e.Parent()
|
||
|
for found {
|
||
|
if parent.Kind() == ast.ComprehensionKind {
|
||
|
return true
|
||
|
}
|
||
|
parent, found = parent.Parent()
|
||
|
}
|
||
|
return false
|
||
|
}
|
||
|
|
||
|
func aggregateLiteralMatcher(e ast.NavigableExpr) bool {
|
||
|
return e.Kind() == ast.ListKind || e.Kind() == ast.MapKind || e.Kind() == ast.StructKind
|
||
|
}
|
||
|
|
||
|
var (
|
||
|
constantMatcher = ast.ConstantValueMatcher()
|
||
|
)
|
||
|
|
||
|
const (
|
||
|
defaultMaxConstantFoldIterations = 100
|
||
|
)
|