mirror of
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418 lines
15 KiB
Go
418 lines
15 KiB
Go
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// 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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"fmt"
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"github.com/google/cel-go/common"
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"github.com/google/cel-go/common/operators"
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exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
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)
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// NewGlobalMacro creates a Macro for a global function with the specified arg count.
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func NewGlobalMacro(function string, argCount int, expander MacroExpander) Macro {
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return ¯o{
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function: function,
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argCount: argCount,
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expander: expander}
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}
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// NewReceiverMacro creates a Macro for a receiver function matching the specified arg count.
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func NewReceiverMacro(function string, argCount int, expander MacroExpander) Macro {
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return ¯o{
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function: function,
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argCount: argCount,
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expander: expander,
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receiverStyle: true}
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}
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// NewGlobalVarArgMacro creates a Macro for a global function with a variable arg count.
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func NewGlobalVarArgMacro(function string, expander MacroExpander) Macro {
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return ¯o{
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function: function,
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expander: expander,
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varArgStyle: true}
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}
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// NewReceiverVarArgMacro creates a Macro for a receiver function matching a variable arg count.
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func NewReceiverVarArgMacro(function string, expander MacroExpander) Macro {
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return ¯o{
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function: function,
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expander: expander,
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receiverStyle: true,
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varArgStyle: true}
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}
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// Macro interface for describing the function signature to match and the MacroExpander to apply.
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//
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// Note: when a Macro should apply to multiple overloads (based on arg count) of a given function,
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// a Macro should be created per arg-count.
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type Macro interface {
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// Function name to match.
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Function() string
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// ArgCount for the function call.
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//
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// When the macro is a var-arg style macro, the return value will be zero, but the MacroKey
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// will contain a `*` where the arg count would have been.
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ArgCount() int
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// IsReceiverStyle returns true if the macro matches a receiver style call.
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IsReceiverStyle() bool
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// MacroKey returns the macro signatures accepted by this macro.
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//
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// Format: `<function>:<arg-count>:<is-receiver>`.
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//
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// When the macros is a var-arg style macro, the `arg-count` value is represented as a `*`.
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MacroKey() string
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// Expander returns the MacroExpander to apply when the macro key matches the parsed call
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// signature.
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Expander() MacroExpander
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}
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// Macro type which declares the function name and arg count expected for the
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// macro, as well as a macro expansion function.
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type macro struct {
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function string
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receiverStyle bool
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varArgStyle bool
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argCount int
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expander MacroExpander
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}
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// Function returns the macro's function name (i.e. the function whose syntax it mimics).
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func (m *macro) Function() string {
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return m.function
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}
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// ArgCount returns the number of arguments the macro expects.
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func (m *macro) ArgCount() int {
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return m.argCount
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}
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// IsReceiverStyle returns whether the macro is receiver style.
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func (m *macro) IsReceiverStyle() bool {
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return m.receiverStyle
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}
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// Expander implements the Macro interface method.
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func (m *macro) Expander() MacroExpander {
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return m.expander
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}
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// MacroKey implements the Macro interface method.
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func (m *macro) MacroKey() string {
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if m.varArgStyle {
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return makeVarArgMacroKey(m.function, m.receiverStyle)
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}
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return makeMacroKey(m.function, m.argCount, m.receiverStyle)
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}
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func makeMacroKey(name string, args int, receiverStyle bool) string {
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return fmt.Sprintf("%s:%d:%v", name, args, receiverStyle)
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}
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func makeVarArgMacroKey(name string, receiverStyle bool) string {
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return fmt.Sprintf("%s:*:%v", name, receiverStyle)
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}
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// MacroExpander converts a call and its associated arguments into a new CEL abstract syntax tree, or an error
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// if the input arguments are not suitable for the expansion requirements for the macro in question.
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//
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// The MacroExpander accepts as arguments a MacroExprHelper as well as the arguments used in the function call
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// and produces as output an Expr ast node.
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//
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// Note: when the Macro.IsReceiverStyle() method returns true, the target argument will be nil.
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type MacroExpander func(eh ExprHelper,
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target *exprpb.Expr,
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args []*exprpb.Expr) (*exprpb.Expr, *common.Error)
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// ExprHelper assists with the manipulation of proto-based Expr values in a manner which is
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// consistent with the source position and expression id generation code leveraged by both
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// the parser and type-checker.
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type ExprHelper interface {
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// LiteralBool creates an Expr value for a bool literal.
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LiteralBool(value bool) *exprpb.Expr
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// LiteralBytes creates an Expr value for a byte literal.
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LiteralBytes(value []byte) *exprpb.Expr
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// LiteralDouble creates an Expr value for double literal.
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LiteralDouble(value float64) *exprpb.Expr
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// LiteralInt creates an Expr value for an int literal.
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LiteralInt(value int64) *exprpb.Expr
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// LiteralString creates am Expr value for a string literal.
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LiteralString(value string) *exprpb.Expr
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// LiteralUint creates an Expr value for a uint literal.
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LiteralUint(value uint64) *exprpb.Expr
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// NewList creates a CreateList instruction where the list is comprised of the optional set
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// of elements provided as arguments.
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NewList(elems ...*exprpb.Expr) *exprpb.Expr
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// NewMap creates a CreateStruct instruction for a map where the map is comprised of the
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// optional set of key, value entries.
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NewMap(entries ...*exprpb.Expr_CreateStruct_Entry) *exprpb.Expr
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// NewMapEntry creates a Map Entry for the key, value pair.
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NewMapEntry(key *exprpb.Expr, val *exprpb.Expr) *exprpb.Expr_CreateStruct_Entry
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// NewObject creates a CreateStruct instruction for an object with a given type name and
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// optional set of field initializers.
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NewObject(typeName string, fieldInits ...*exprpb.Expr_CreateStruct_Entry) *exprpb.Expr
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// NewObjectFieldInit creates a new Object field initializer from the field name and value.
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NewObjectFieldInit(field string, init *exprpb.Expr) *exprpb.Expr_CreateStruct_Entry
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// Fold creates a fold comprehension instruction.
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//
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// - iterVar is the iteration variable name.
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// - iterRange represents the expression that resolves to a list or map where the elements or
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// keys (respectively) will be iterated over.
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// - accuVar is the accumulation variable name, typically parser.AccumulatorName.
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// - accuInit is the initial expression whose value will be set for the accuVar prior to
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// folding.
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// - condition is the expression to test to determine whether to continue folding.
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// - step is the expression to evaluation at the conclusion of a single fold iteration.
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// - result is the computation to evaluate at the conclusion of the fold.
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//
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// The accuVar should not shadow variable names that you would like to reference within the
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// environment in the step and condition expressions. Presently, the name __result__ is commonly
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// used by built-in macros but this may change in the future.
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Fold(iterVar string,
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iterRange *exprpb.Expr,
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accuVar string,
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accuInit *exprpb.Expr,
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condition *exprpb.Expr,
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step *exprpb.Expr,
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result *exprpb.Expr) *exprpb.Expr
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// Ident creates an identifier Expr value.
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Ident(name string) *exprpb.Expr
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// AccuIdent returns an accumulator identifier for use with comprehension results.
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AccuIdent() *exprpb.Expr
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// GlobalCall creates a function call Expr value for a global (free) function.
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GlobalCall(function string, args ...*exprpb.Expr) *exprpb.Expr
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// ReceiverCall creates a function call Expr value for a receiver-style function.
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ReceiverCall(function string, target *exprpb.Expr, args ...*exprpb.Expr) *exprpb.Expr
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// PresenceTest creates a Select TestOnly Expr value for modelling has() semantics.
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PresenceTest(operand *exprpb.Expr, field string) *exprpb.Expr
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// Select create a field traversal Expr value.
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Select(operand *exprpb.Expr, field string) *exprpb.Expr
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// OffsetLocation returns the Location of the expression identifier.
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OffsetLocation(exprID int64) common.Location
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}
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var (
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// HasMacro expands "has(m.f)" which tests the presence of a field, avoiding the need to
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// specify the field as a string.
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HasMacro = NewGlobalMacro(operators.Has, 1, MakeHas)
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// AllMacro expands "range.all(var, predicate)" into a comprehension which ensures that all
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// elements in the range satisfy the predicate.
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AllMacro = NewReceiverMacro(operators.All, 2, MakeAll)
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// ExistsMacro expands "range.exists(var, predicate)" into a comprehension which ensures that
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// some element in the range satisfies the predicate.
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ExistsMacro = NewReceiverMacro(operators.Exists, 2, MakeExists)
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// ExistsOneMacro expands "range.exists_one(var, predicate)", which is true if for exactly one
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// element in range the predicate holds.
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ExistsOneMacro = NewReceiverMacro(operators.ExistsOne, 2, MakeExistsOne)
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// MapMacro expands "range.map(var, function)" into a comprehension which applies the function
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// to each element in the range to produce a new list.
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MapMacro = NewReceiverMacro(operators.Map, 2, MakeMap)
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// MapFilterMacro expands "range.map(var, predicate, function)" into a comprehension which
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// first filters the elements in the range by the predicate, then applies the transform function
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// to produce a new list.
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MapFilterMacro = NewReceiverMacro(operators.Map, 3, MakeMap)
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// FilterMacro expands "range.filter(var, predicate)" into a comprehension which filters
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// elements in the range, producing a new list from the elements that satisfy the predicate.
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FilterMacro = NewReceiverMacro(operators.Filter, 2, MakeFilter)
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// AllMacros includes the list of all spec-supported macros.
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AllMacros = []Macro{
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HasMacro,
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AllMacro,
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ExistsMacro,
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ExistsOneMacro,
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MapMacro,
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MapFilterMacro,
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FilterMacro,
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}
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// NoMacros list.
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NoMacros = []Macro{}
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)
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// AccumulatorName is the traditional variable name assigned to the fold accumulator variable.
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const AccumulatorName = "__result__"
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type quantifierKind int
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const (
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quantifierAll quantifierKind = iota
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quantifierExists
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quantifierExistsOne
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)
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// MakeAll expands the input call arguments into a comprehension that returns true if all of the
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// elements in the range match the predicate expressions:
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// <iterRange>.all(<iterVar>, <predicate>)
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func MakeAll(eh ExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *common.Error) {
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return makeQuantifier(quantifierAll, eh, target, args)
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}
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// MakeExists expands the input call arguments into a comprehension that returns true if any of the
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// elements in the range match the predicate expressions:
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// <iterRange>.exists(<iterVar>, <predicate>)
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func MakeExists(eh ExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *common.Error) {
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return makeQuantifier(quantifierExists, eh, target, args)
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}
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// MakeExistsOne expands the input call arguments into a comprehension that returns true if exactly
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// one of the elements in the range match the predicate expressions:
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// <iterRange>.exists_one(<iterVar>, <predicate>)
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func MakeExistsOne(eh ExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *common.Error) {
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return makeQuantifier(quantifierExistsOne, eh, target, args)
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}
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// MakeMap expands the input call arguments into a comprehension that transforms each element in the
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// input to produce an output list.
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//
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// There are two call patterns supported by map:
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// <iterRange>.map(<iterVar>, <transform>)
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// <iterRange>.map(<iterVar>, <predicate>, <transform>)
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// In the second form only iterVar values which return true when provided to the predicate expression
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// are transformed.
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func MakeMap(eh ExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *common.Error) {
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v, found := extractIdent(args[0])
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if !found {
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return nil, &common.Error{Message: "argument is not an identifier"}
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}
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var fn *exprpb.Expr
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var filter *exprpb.Expr
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if len(args) == 3 {
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filter = args[1]
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fn = args[2]
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} else {
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filter = nil
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fn = args[1]
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}
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accuExpr := eh.Ident(AccumulatorName)
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init := eh.NewList()
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condition := eh.LiteralBool(true)
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step := eh.GlobalCall(operators.Add, accuExpr, eh.NewList(fn))
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if filter != nil {
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step = eh.GlobalCall(operators.Conditional, filter, step, accuExpr)
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}
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return eh.Fold(v, target, AccumulatorName, init, condition, step, accuExpr), nil
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}
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// MakeFilter expands the input call arguments into a comprehension which produces a list which contains
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// only elements which match the provided predicate expression:
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// <iterRange>.filter(<iterVar>, <predicate>)
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func MakeFilter(eh ExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *common.Error) {
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v, found := extractIdent(args[0])
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if !found {
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return nil, &common.Error{Message: "argument is not an identifier"}
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}
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filter := args[1]
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accuExpr := eh.Ident(AccumulatorName)
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init := eh.NewList()
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condition := eh.LiteralBool(true)
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step := eh.GlobalCall(operators.Add, accuExpr, eh.NewList(args[0]))
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step = eh.GlobalCall(operators.Conditional, filter, step, accuExpr)
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return eh.Fold(v, target, AccumulatorName, init, condition, step, accuExpr), nil
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}
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// MakeHas expands the input call arguments into a presence test, e.g. has(<operand>.field)
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func MakeHas(eh ExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *common.Error) {
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if s, ok := args[0].ExprKind.(*exprpb.Expr_SelectExpr); ok {
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return eh.PresenceTest(s.SelectExpr.GetOperand(), s.SelectExpr.GetField()), nil
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}
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return nil, &common.Error{Message: "invalid argument to has() macro"}
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}
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func makeQuantifier(kind quantifierKind, eh ExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *common.Error) {
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v, found := extractIdent(args[0])
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if !found {
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location := eh.OffsetLocation(args[0].GetId())
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return nil, &common.Error{
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Message: "argument must be a simple name",
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Location: location,
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}
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}
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var init *exprpb.Expr
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var condition *exprpb.Expr
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var step *exprpb.Expr
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var result *exprpb.Expr
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switch kind {
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case quantifierAll:
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init = eh.LiteralBool(true)
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condition = eh.GlobalCall(operators.NotStrictlyFalse, eh.AccuIdent())
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step = eh.GlobalCall(operators.LogicalAnd, eh.AccuIdent(), args[1])
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result = eh.AccuIdent()
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case quantifierExists:
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init = eh.LiteralBool(false)
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condition = eh.GlobalCall(
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operators.NotStrictlyFalse,
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eh.GlobalCall(operators.LogicalNot, eh.AccuIdent()))
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step = eh.GlobalCall(operators.LogicalOr, eh.AccuIdent(), args[1])
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result = eh.AccuIdent()
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case quantifierExistsOne:
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zeroExpr := eh.LiteralInt(0)
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oneExpr := eh.LiteralInt(1)
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init = zeroExpr
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condition = eh.LiteralBool(true)
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step = eh.GlobalCall(operators.Conditional, args[1],
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||
|
eh.GlobalCall(operators.Add, eh.AccuIdent(), oneExpr), eh.AccuIdent())
|
||
|
result = eh.GlobalCall(operators.Equals, eh.AccuIdent(), oneExpr)
|
||
|
default:
|
||
|
return nil, &common.Error{Message: fmt.Sprintf("unrecognized quantifier '%v'", kind)}
|
||
|
}
|
||
|
return eh.Fold(v, target, AccumulatorName, init, condition, step, result), nil
|
||
|
}
|
||
|
|
||
|
func extractIdent(e *exprpb.Expr) (string, bool) {
|
||
|
switch e.ExprKind.(type) {
|
||
|
case *exprpb.Expr_IdentExpr:
|
||
|
return e.GetIdentExpr().GetName(), true
|
||
|
}
|
||
|
return "", false
|
||
|
}
|