mirror of
https://github.com/ceph/ceph-csi.git
synced 2024-12-20 12:00:24 +00:00
5a66991bb3
updating the kubernetes release to the latest in main go.mod Signed-off-by: Madhu Rajanna <madhupr007@gmail.com>
475 lines
16 KiB
Go
475 lines
16 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 parser
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import (
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"sync"
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antlr "github.com/antlr4-go/antlr/v4"
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"github.com/google/cel-go/common"
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"github.com/google/cel-go/common/ast"
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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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)
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type parserHelper struct {
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exprFactory ast.ExprFactory
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source common.Source
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sourceInfo *ast.SourceInfo
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nextID int64
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}
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func newParserHelper(source common.Source, fac ast.ExprFactory) *parserHelper {
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return &parserHelper{
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exprFactory: fac,
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source: source,
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sourceInfo: ast.NewSourceInfo(source),
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nextID: 1,
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}
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}
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func (p *parserHelper) getSourceInfo() *ast.SourceInfo {
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return p.sourceInfo
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}
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func (p *parserHelper) newLiteral(ctx any, value ref.Val) ast.Expr {
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return p.exprFactory.NewLiteral(p.newID(ctx), value)
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}
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func (p *parserHelper) newLiteralBool(ctx any, value bool) ast.Expr {
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return p.newLiteral(ctx, types.Bool(value))
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}
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func (p *parserHelper) newLiteralString(ctx any, value string) ast.Expr {
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return p.newLiteral(ctx, types.String(value))
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}
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func (p *parserHelper) newLiteralBytes(ctx any, value []byte) ast.Expr {
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return p.newLiteral(ctx, types.Bytes(value))
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}
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func (p *parserHelper) newLiteralInt(ctx any, value int64) ast.Expr {
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return p.newLiteral(ctx, types.Int(value))
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}
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func (p *parserHelper) newLiteralUint(ctx any, value uint64) ast.Expr {
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return p.newLiteral(ctx, types.Uint(value))
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}
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func (p *parserHelper) newLiteralDouble(ctx any, value float64) ast.Expr {
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return p.newLiteral(ctx, types.Double(value))
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}
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func (p *parserHelper) newIdent(ctx any, name string) ast.Expr {
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return p.exprFactory.NewIdent(p.newID(ctx), name)
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}
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func (p *parserHelper) newSelect(ctx any, operand ast.Expr, field string) ast.Expr {
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return p.exprFactory.NewSelect(p.newID(ctx), operand, field)
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}
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func (p *parserHelper) newPresenceTest(ctx any, operand ast.Expr, field string) ast.Expr {
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return p.exprFactory.NewPresenceTest(p.newID(ctx), operand, field)
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}
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func (p *parserHelper) newGlobalCall(ctx any, function string, args ...ast.Expr) ast.Expr {
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return p.exprFactory.NewCall(p.newID(ctx), function, args...)
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}
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func (p *parserHelper) newReceiverCall(ctx any, function string, target ast.Expr, args ...ast.Expr) ast.Expr {
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return p.exprFactory.NewMemberCall(p.newID(ctx), function, target, args...)
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}
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func (p *parserHelper) newList(ctx any, elements []ast.Expr, optionals ...int32) ast.Expr {
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return p.exprFactory.NewList(p.newID(ctx), elements, optionals)
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}
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func (p *parserHelper) newMap(ctx any, entries ...ast.EntryExpr) ast.Expr {
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return p.exprFactory.NewMap(p.newID(ctx), entries)
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}
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func (p *parserHelper) newMapEntry(entryID int64, key ast.Expr, value ast.Expr, optional bool) ast.EntryExpr {
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return p.exprFactory.NewMapEntry(entryID, key, value, optional)
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}
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func (p *parserHelper) newObject(ctx any, typeName string, fields ...ast.EntryExpr) ast.Expr {
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return p.exprFactory.NewStruct(p.newID(ctx), typeName, fields)
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}
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func (p *parserHelper) newObjectField(fieldID int64, field string, value ast.Expr, optional bool) ast.EntryExpr {
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return p.exprFactory.NewStructField(fieldID, field, value, optional)
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}
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func (p *parserHelper) newComprehension(ctx any,
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iterRange ast.Expr,
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iterVar string,
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accuVar string,
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accuInit ast.Expr,
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condition ast.Expr,
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step ast.Expr,
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result ast.Expr) ast.Expr {
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return p.exprFactory.NewComprehension(
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p.newID(ctx), iterRange, iterVar, accuVar, accuInit, condition, step, result)
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}
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func (p *parserHelper) newID(ctx any) int64 {
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if id, isID := ctx.(int64); isID {
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return id
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}
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return p.id(ctx)
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}
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func (p *parserHelper) newExpr(ctx any) ast.Expr {
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return p.exprFactory.NewUnspecifiedExpr(p.newID(ctx))
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}
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func (p *parserHelper) id(ctx any) int64 {
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var offset ast.OffsetRange
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switch c := ctx.(type) {
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case antlr.ParserRuleContext:
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start, stop := c.GetStart(), c.GetStop()
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if stop == nil {
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stop = start
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}
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offset.Start = p.sourceInfo.ComputeOffset(int32(start.GetLine()), int32(start.GetColumn()))
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offset.Stop = p.sourceInfo.ComputeOffset(int32(stop.GetLine()), int32(stop.GetColumn()))
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case antlr.Token:
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offset.Start = p.sourceInfo.ComputeOffset(int32(c.GetLine()), int32(c.GetColumn()))
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offset.Stop = offset.Start
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case common.Location:
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offset.Start = p.sourceInfo.ComputeOffset(int32(c.Line()), int32(c.Column()))
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offset.Stop = offset.Start
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case ast.OffsetRange:
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offset = c
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default:
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// This should only happen if the ctx is nil
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return -1
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}
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id := p.nextID
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p.sourceInfo.SetOffsetRange(id, offset)
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p.nextID++
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return id
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}
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func (p *parserHelper) getLocation(id int64) common.Location {
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return p.sourceInfo.GetStartLocation(id)
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}
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// buildMacroCallArg iterates the expression and returns a new expression
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// where all macros have been replaced by their IDs in MacroCalls
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func (p *parserHelper) buildMacroCallArg(expr ast.Expr) ast.Expr {
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if _, found := p.sourceInfo.GetMacroCall(expr.ID()); found {
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return p.exprFactory.NewUnspecifiedExpr(expr.ID())
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}
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switch expr.Kind() {
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case ast.CallKind:
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// Iterate the AST from `expr` recursively looking for macros. Because we are at most
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// starting from the top level macro, this recursion is bounded by the size of the AST. This
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// means that the depth check on the AST during parsing will catch recursion overflows
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// before we get to here.
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call := expr.AsCall()
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macroArgs := make([]ast.Expr, len(call.Args()))
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for index, arg := range call.Args() {
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macroArgs[index] = p.buildMacroCallArg(arg)
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}
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if !call.IsMemberFunction() {
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return p.exprFactory.NewCall(expr.ID(), call.FunctionName(), macroArgs...)
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}
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macroTarget := p.buildMacroCallArg(call.Target())
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return p.exprFactory.NewMemberCall(expr.ID(), call.FunctionName(), macroTarget, macroArgs...)
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case ast.ListKind:
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list := expr.AsList()
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macroListArgs := make([]ast.Expr, list.Size())
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for i, elem := range list.Elements() {
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macroListArgs[i] = p.buildMacroCallArg(elem)
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}
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return p.exprFactory.NewList(expr.ID(), macroListArgs, list.OptionalIndices())
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}
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return expr
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}
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// addMacroCall adds the macro the the MacroCalls map in source info. If a macro has args/subargs/target
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// that are macros, their ID will be stored instead for later self-lookups.
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func (p *parserHelper) addMacroCall(exprID int64, function string, target ast.Expr, args ...ast.Expr) {
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macroArgs := make([]ast.Expr, len(args))
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for index, arg := range args {
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macroArgs[index] = p.buildMacroCallArg(arg)
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}
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if target == nil {
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p.sourceInfo.SetMacroCall(exprID, p.exprFactory.NewCall(0, function, macroArgs...))
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return
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}
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macroTarget := target
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if _, found := p.sourceInfo.GetMacroCall(target.ID()); found {
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macroTarget = p.exprFactory.NewUnspecifiedExpr(target.ID())
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} else {
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macroTarget = p.buildMacroCallArg(target)
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}
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p.sourceInfo.SetMacroCall(exprID, p.exprFactory.NewMemberCall(0, function, macroTarget, macroArgs...))
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}
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// logicManager compacts logical trees into a more efficient structure which is semantically
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// equivalent with how the logic graph is constructed by the ANTLR parser.
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//
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// The purpose of the logicManager is to ensure a compact serialization format for the logical &&, ||
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// operators which have a tendency to create long DAGs which are skewed in one direction. Since the
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// operators are commutative re-ordering the terms *must not* affect the evaluation result.
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//
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// The logic manager will either render the terms to N-chained && / || operators as a single logical
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// call with N-terms, or will rebalance the tree. Rebalancing the terms is a safe, if somewhat
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// controversial choice as it alters the traditional order of execution assumptions present in most
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// expressions.
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type logicManager struct {
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exprFactory ast.ExprFactory
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function string
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terms []ast.Expr
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ops []int64
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variadicASTs bool
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}
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// newVariadicLogicManager creates a logic manager instance bound to a specific function and its first term.
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func newVariadicLogicManager(fac ast.ExprFactory, function string, term ast.Expr) *logicManager {
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return &logicManager{
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exprFactory: fac,
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function: function,
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terms: []ast.Expr{term},
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ops: []int64{},
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variadicASTs: true,
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}
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}
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// newBalancingLogicManager creates a logic manager instance bound to a specific function and its first term.
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func newBalancingLogicManager(fac ast.ExprFactory, function string, term ast.Expr) *logicManager {
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return &logicManager{
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exprFactory: fac,
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function: function,
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terms: []ast.Expr{term},
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ops: []int64{},
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variadicASTs: false,
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}
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}
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// addTerm adds an operation identifier and term to the set of terms to be balanced.
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func (l *logicManager) addTerm(op int64, term ast.Expr) {
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l.terms = append(l.terms, term)
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l.ops = append(l.ops, op)
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}
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// toExpr renders the logic graph into an Expr value, either balancing a tree of logical
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// operations or creating a variadic representation of the logical operator.
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func (l *logicManager) toExpr() ast.Expr {
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if len(l.terms) == 1 {
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return l.terms[0]
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}
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if l.variadicASTs {
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return l.exprFactory.NewCall(l.ops[0], l.function, l.terms...)
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}
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return l.balancedTree(0, len(l.ops)-1)
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}
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// balancedTree recursively balances the terms provided to a commutative operator.
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func (l *logicManager) balancedTree(lo, hi int) ast.Expr {
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mid := (lo + hi + 1) / 2
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var left ast.Expr
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if mid == lo {
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left = l.terms[mid]
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} else {
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left = l.balancedTree(lo, mid-1)
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}
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var right ast.Expr
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if mid == hi {
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right = l.terms[mid+1]
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} else {
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right = l.balancedTree(mid+1, hi)
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}
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return l.exprFactory.NewCall(l.ops[mid], l.function, left, right)
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}
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type exprHelper struct {
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*parserHelper
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id int64
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}
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func (e *exprHelper) nextMacroID() int64 {
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return e.parserHelper.id(e.parserHelper.getLocation(e.id))
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}
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// Copy implements the ExprHelper interface method by producing a copy of the input Expr value
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// with a fresh set of numeric identifiers the Expr and all its descendants.
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func (e *exprHelper) Copy(expr ast.Expr) ast.Expr {
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offsetRange, _ := e.parserHelper.sourceInfo.GetOffsetRange(expr.ID())
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copyID := e.parserHelper.newID(offsetRange)
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switch expr.Kind() {
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case ast.LiteralKind:
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return e.exprFactory.NewLiteral(copyID, expr.AsLiteral())
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case ast.IdentKind:
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return e.exprFactory.NewIdent(copyID, expr.AsIdent())
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case ast.SelectKind:
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sel := expr.AsSelect()
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op := e.Copy(sel.Operand())
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if sel.IsTestOnly() {
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return e.exprFactory.NewPresenceTest(copyID, op, sel.FieldName())
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}
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return e.exprFactory.NewSelect(copyID, op, sel.FieldName())
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case ast.CallKind:
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call := expr.AsCall()
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args := call.Args()
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argsCopy := make([]ast.Expr, len(args))
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for i, arg := range args {
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argsCopy[i] = e.Copy(arg)
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}
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if !call.IsMemberFunction() {
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return e.exprFactory.NewCall(copyID, call.FunctionName(), argsCopy...)
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}
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return e.exprFactory.NewMemberCall(copyID, call.FunctionName(), e.Copy(call.Target()), argsCopy...)
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case ast.ListKind:
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list := expr.AsList()
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elems := list.Elements()
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elemsCopy := make([]ast.Expr, len(elems))
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for i, elem := range elems {
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elemsCopy[i] = e.Copy(elem)
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}
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return e.exprFactory.NewList(copyID, elemsCopy, list.OptionalIndices())
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case ast.MapKind:
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m := expr.AsMap()
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entries := m.Entries()
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entriesCopy := make([]ast.EntryExpr, len(entries))
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for i, en := range entries {
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entry := en.AsMapEntry()
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entryID := e.nextMacroID()
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entriesCopy[i] = e.exprFactory.NewMapEntry(entryID,
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e.Copy(entry.Key()), e.Copy(entry.Value()), entry.IsOptional())
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}
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return e.exprFactory.NewMap(copyID, entriesCopy)
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case ast.StructKind:
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s := expr.AsStruct()
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fields := s.Fields()
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fieldsCopy := make([]ast.EntryExpr, len(fields))
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for i, f := range fields {
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field := f.AsStructField()
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fieldID := e.nextMacroID()
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fieldsCopy[i] = e.exprFactory.NewStructField(fieldID,
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field.Name(), e.Copy(field.Value()), field.IsOptional())
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}
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return e.exprFactory.NewStruct(copyID, s.TypeName(), fieldsCopy)
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case ast.ComprehensionKind:
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compre := expr.AsComprehension()
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iterRange := e.Copy(compre.IterRange())
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accuInit := e.Copy(compre.AccuInit())
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cond := e.Copy(compre.LoopCondition())
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step := e.Copy(compre.LoopStep())
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result := e.Copy(compre.Result())
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return e.exprFactory.NewComprehension(copyID,
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iterRange, compre.IterVar(), compre.AccuVar(), accuInit, cond, step, result)
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}
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return e.exprFactory.NewUnspecifiedExpr(copyID)
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}
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// NewLiteral implements the ExprHelper interface method.
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func (e *exprHelper) NewLiteral(value ref.Val) ast.Expr {
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return e.exprFactory.NewLiteral(e.nextMacroID(), value)
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}
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// NewList implements the ExprHelper interface method.
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func (e *exprHelper) NewList(elems ...ast.Expr) ast.Expr {
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return e.exprFactory.NewList(e.nextMacroID(), elems, []int32{})
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}
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// NewMap implements the ExprHelper interface method.
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func (e *exprHelper) NewMap(entries ...ast.EntryExpr) ast.Expr {
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return e.exprFactory.NewMap(e.nextMacroID(), entries)
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}
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// NewMapEntry implements the ExprHelper interface method.
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func (e *exprHelper) NewMapEntry(key ast.Expr, val ast.Expr, optional bool) ast.EntryExpr {
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return e.exprFactory.NewMapEntry(e.nextMacroID(), key, val, optional)
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}
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// NewStruct implements the ExprHelper interface method.
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func (e *exprHelper) NewStruct(typeName string, fieldInits ...ast.EntryExpr) ast.Expr {
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return e.exprFactory.NewStruct(e.nextMacroID(), typeName, fieldInits)
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}
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// NewStructField implements the ExprHelper interface method.
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func (e *exprHelper) NewStructField(field string, init ast.Expr, optional bool) ast.EntryExpr {
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return e.exprFactory.NewStructField(e.nextMacroID(), field, init, optional)
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}
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// NewComprehension implements the ExprHelper interface method.
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func (e *exprHelper) NewComprehension(
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iterRange ast.Expr,
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iterVar string,
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accuVar string,
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accuInit ast.Expr,
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condition ast.Expr,
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step ast.Expr,
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result ast.Expr) ast.Expr {
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return e.exprFactory.NewComprehension(
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e.nextMacroID(), iterRange, iterVar, accuVar, accuInit, condition, step, result)
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}
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// NewIdent implements the ExprHelper interface method.
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func (e *exprHelper) NewIdent(name string) ast.Expr {
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return e.exprFactory.NewIdent(e.nextMacroID(), name)
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}
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// NewAccuIdent implements the ExprHelper interface method.
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func (e *exprHelper) NewAccuIdent() ast.Expr {
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return e.exprFactory.NewAccuIdent(e.nextMacroID())
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}
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// NewGlobalCall implements the ExprHelper interface method.
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func (e *exprHelper) NewCall(function string, args ...ast.Expr) ast.Expr {
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return e.exprFactory.NewCall(e.nextMacroID(), function, args...)
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}
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// NewMemberCall implements the ExprHelper interface method.
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func (e *exprHelper) NewMemberCall(function string, target ast.Expr, args ...ast.Expr) ast.Expr {
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return e.exprFactory.NewMemberCall(e.nextMacroID(), function, target, args...)
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}
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// NewPresenceTest implements the ExprHelper interface method.
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func (e *exprHelper) NewPresenceTest(operand ast.Expr, field string) ast.Expr {
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return e.exprFactory.NewPresenceTest(e.nextMacroID(), operand, field)
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}
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// NewSelect implements the ExprHelper interface method.
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func (e *exprHelper) NewSelect(operand ast.Expr, field string) ast.Expr {
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return e.exprFactory.NewSelect(e.nextMacroID(), operand, field)
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}
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// OffsetLocation implements the ExprHelper interface method.
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func (e *exprHelper) OffsetLocation(exprID int64) common.Location {
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return e.parserHelper.sourceInfo.GetStartLocation(exprID)
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}
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// NewError associates an error message with a given expression id, populating the source offset location of the error if possible.
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func (e *exprHelper) NewError(exprID int64, message string) *common.Error {
|
|
return common.NewError(exprID, message, e.OffsetLocation(exprID))
|
|
}
|
|
|
|
var (
|
|
// Thread-safe pool of ExprHelper values to minimize alloc overhead of ExprHelper creations.
|
|
exprHelperPool = &sync.Pool{
|
|
New: func() any {
|
|
return &exprHelper{}
|
|
},
|
|
}
|
|
)
|