mirror of
https://github.com/ceph/ceph-csi.git
synced 2024-12-18 19:10:21 +00:00
5a66991bb3
updating the kubernetes release to the latest in main go.mod Signed-off-by: Madhu Rajanna <madhupr007@gmail.com>
356 lines
14 KiB
Go
356 lines
14 KiB
Go
// Copyright 2022 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/decls"
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"github.com/google/cel-go/common/functions"
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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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exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
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)
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// Kind indicates a CEL type's kind which is used to differentiate quickly between simple and complex types.
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type Kind = types.Kind
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const (
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// DynKind represents a dynamic type. This kind only exists at type-check time.
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DynKind Kind = types.DynKind
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// AnyKind represents a google.protobuf.Any type. This kind only exists at type-check time.
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AnyKind = types.AnyKind
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// BoolKind represents a boolean type.
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BoolKind = types.BoolKind
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// BytesKind represents a bytes type.
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BytesKind = types.BytesKind
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// DoubleKind represents a double type.
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DoubleKind = types.DoubleKind
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// DurationKind represents a CEL duration type.
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DurationKind = types.DurationKind
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// IntKind represents an integer type.
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IntKind = types.IntKind
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// ListKind represents a list type.
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ListKind = types.ListKind
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// MapKind represents a map type.
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MapKind = types.MapKind
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// NullTypeKind represents a null type.
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NullTypeKind = types.NullTypeKind
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// OpaqueKind represents an abstract type which has no accessible fields.
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OpaqueKind = types.OpaqueKind
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// StringKind represents a string type.
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StringKind = types.StringKind
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// StructKind represents a structured object with typed fields.
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StructKind = types.StructKind
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// TimestampKind represents a a CEL time type.
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TimestampKind = types.TimestampKind
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// TypeKind represents the CEL type.
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TypeKind = types.TypeKind
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// TypeParamKind represents a parameterized type whose type name will be resolved at type-check time, if possible.
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TypeParamKind = types.TypeParamKind
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// UintKind represents a uint type.
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UintKind = types.UintKind
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)
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var (
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// AnyType represents the google.protobuf.Any type.
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AnyType = types.AnyType
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// BoolType represents the bool type.
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BoolType = types.BoolType
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// BytesType represents the bytes type.
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BytesType = types.BytesType
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// DoubleType represents the double type.
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DoubleType = types.DoubleType
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// DurationType represents the CEL duration type.
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DurationType = types.DurationType
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// DynType represents a dynamic CEL type whose type will be determined at runtime from context.
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DynType = types.DynType
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// IntType represents the int type.
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IntType = types.IntType
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// NullType represents the type of a null value.
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NullType = types.NullType
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// StringType represents the string type.
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StringType = types.StringType
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// TimestampType represents the time type.
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TimestampType = types.TimestampType
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// TypeType represents a CEL type
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TypeType = types.TypeType
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// UintType represents a uint type.
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UintType = types.UintType
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// function references for instantiating new types.
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// ListType creates an instances of a list type value with the provided element type.
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ListType = types.NewListType
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// MapType creates an instance of a map type value with the provided key and value types.
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MapType = types.NewMapType
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// NullableType creates an instance of a nullable type with the provided wrapped type.
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//
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// Note: only primitive types are supported as wrapped types.
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NullableType = types.NewNullableType
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// OptionalType creates an abstract parameterized type instance corresponding to CEL's notion of optional.
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OptionalType = types.NewOptionalType
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// OpaqueType creates an abstract parameterized type with a given name.
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OpaqueType = types.NewOpaqueType
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// ObjectType creates a type references to an externally defined type, e.g. a protobuf message type.
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ObjectType = types.NewObjectType
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// TypeParamType creates a parameterized type instance.
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TypeParamType = types.NewTypeParamType
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)
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// Type holds a reference to a runtime type with an optional type-checked set of type parameters.
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type Type = types.Type
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// Constant creates an instances of an identifier declaration with a variable name, type, and value.
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func Constant(name string, t *Type, v ref.Val) EnvOption {
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return func(e *Env) (*Env, error) {
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e.variables = append(e.variables, decls.NewConstant(name, t, v))
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return e, nil
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}
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}
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// Variable creates an instance of a variable declaration with a variable name and type.
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func Variable(name string, t *Type) EnvOption {
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return func(e *Env) (*Env, error) {
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e.variables = append(e.variables, decls.NewVariable(name, t))
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return e, nil
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}
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}
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// Function defines a function and overloads with optional singleton or per-overload bindings.
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//
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// Using Function is roughly equivalent to calling Declarations() to declare the function signatures
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// and Functions() to define the function bindings, if they have been defined. Specifying the
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// same function name more than once will result in the aggregation of the function overloads. If any
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// signatures conflict between the existing and new function definition an error will be raised.
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// However, if the signatures are identical and the overload ids are the same, the redefinition will
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// be considered a no-op.
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//
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// One key difference with using Function() is that each FunctionDecl provided will handle dynamic
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// dispatch based on the type-signatures of the overloads provided which means overload resolution at
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// runtime is handled out of the box rather than via a custom binding for overload resolution via
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// Functions():
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//
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// - Overloads are searched in the order they are declared
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// - Dynamic dispatch for lists and maps is limited by inspection of the list and map contents
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//
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// at runtime. Empty lists and maps will result in a 'default dispatch'
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//
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// - In the event that a default dispatch occurs, the first overload provided is the one invoked
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//
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// If you intend to use overloads which differentiate based on the key or element type of a list or
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// map, consider using a generic function instead: e.g. func(list(T)) or func(map(K, V)) as this
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// will allow your implementation to determine how best to handle dispatch and the default behavior
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// for empty lists and maps whose contents cannot be inspected.
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//
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// For functions which use parameterized opaque types (abstract types), consider using a singleton
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// function which is capable of inspecting the contents of the type and resolving the appropriate
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// overload as CEL can only make inferences by type-name regarding such types.
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func Function(name string, opts ...FunctionOpt) EnvOption {
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return func(e *Env) (*Env, error) {
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fn, err := decls.NewFunction(name, opts...)
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if err != nil {
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return nil, err
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}
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if existing, found := e.functions[fn.Name()]; found {
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fn, err = existing.Merge(fn)
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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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e.functions[fn.Name()] = fn
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return e, nil
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}
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}
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// FunctionOpt defines a functional option for configuring a function declaration.
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type FunctionOpt = decls.FunctionOpt
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// SingletonUnaryBinding creates a singleton function definition to be used for all function overloads.
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//
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// Note, this approach works well if operand is expected to have a specific trait which it implements,
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// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
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func SingletonUnaryBinding(fn functions.UnaryOp, traits ...int) FunctionOpt {
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return decls.SingletonUnaryBinding(fn, traits...)
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}
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// SingletonBinaryImpl creates a singleton function definition to be used with all function overloads.
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//
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// Note, this approach works well if operand is expected to have a specific trait which it implements,
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// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
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//
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// Deprecated: use SingletonBinaryBinding
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func SingletonBinaryImpl(fn functions.BinaryOp, traits ...int) FunctionOpt {
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return decls.SingletonBinaryBinding(fn, traits...)
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}
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// SingletonBinaryBinding creates a singleton function definition to be used with all function overloads.
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//
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// Note, this approach works well if operand is expected to have a specific trait which it implements,
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// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
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func SingletonBinaryBinding(fn functions.BinaryOp, traits ...int) FunctionOpt {
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return decls.SingletonBinaryBinding(fn, traits...)
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}
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// SingletonFunctionImpl creates a singleton function definition to be used with all function overloads.
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//
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// Note, this approach works well if operand is expected to have a specific trait which it implements,
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// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
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//
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// Deprecated: use SingletonFunctionBinding
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func SingletonFunctionImpl(fn functions.FunctionOp, traits ...int) FunctionOpt {
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return decls.SingletonFunctionBinding(fn, traits...)
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}
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// SingletonFunctionBinding creates a singleton function definition to be used with all function overloads.
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//
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// Note, this approach works well if operand is expected to have a specific trait which it implements,
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// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
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func SingletonFunctionBinding(fn functions.FunctionOp, traits ...int) FunctionOpt {
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return decls.SingletonFunctionBinding(fn, traits...)
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}
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// DisableDeclaration disables the function signatures, effectively removing them from the type-check
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// environment while preserving the runtime bindings.
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func DisableDeclaration(value bool) FunctionOpt {
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return decls.DisableDeclaration(value)
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}
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// Overload defines a new global overload with an overload id, argument types, and result type. Through the
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// use of OverloadOpt options, the overload may also be configured with a binding, an operand trait, and to
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// be non-strict.
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//
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// Note: function bindings should be commonly configured with Overload instances whereas operand traits and
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// strict-ness should be rare occurrences.
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func Overload(overloadID string, args []*Type, resultType *Type, opts ...OverloadOpt) FunctionOpt {
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return decls.Overload(overloadID, args, resultType, opts...)
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}
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// MemberOverload defines a new receiver-style overload (or member function) with an overload id, argument types,
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// and result type. Through the use of OverloadOpt options, the overload may also be configured with a binding,
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// an operand trait, and to be non-strict.
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//
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// Note: function bindings should be commonly configured with Overload instances whereas operand traits and
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// strict-ness should be rare occurrences.
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func MemberOverload(overloadID string, args []*Type, resultType *Type, opts ...OverloadOpt) FunctionOpt {
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return decls.MemberOverload(overloadID, args, resultType, opts...)
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}
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// OverloadOpt is a functional option for configuring a function overload.
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type OverloadOpt = decls.OverloadOpt
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// UnaryBinding provides the implementation of a unary overload. The provided function is protected by a runtime
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// type-guard which ensures runtime type agreement between the overload signature and runtime argument types.
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func UnaryBinding(binding functions.UnaryOp) OverloadOpt {
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return decls.UnaryBinding(binding)
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}
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// BinaryBinding provides the implementation of a binary overload. The provided function is protected by a runtime
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// type-guard which ensures runtime type agreement between the overload signature and runtime argument types.
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func BinaryBinding(binding functions.BinaryOp) OverloadOpt {
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return decls.BinaryBinding(binding)
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}
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// FunctionBinding provides the implementation of a variadic overload. The provided function is protected by a runtime
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// type-guard which ensures runtime type agreement between the overload signature and runtime argument types.
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func FunctionBinding(binding functions.FunctionOp) OverloadOpt {
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return decls.FunctionBinding(binding)
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}
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// OverloadIsNonStrict enables the function to be called with error and unknown argument values.
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//
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// Note: do not use this option unless absoluately necessary as it should be an uncommon feature.
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func OverloadIsNonStrict() OverloadOpt {
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return decls.OverloadIsNonStrict()
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}
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// OverloadOperandTrait configures a set of traits which the first argument to the overload must implement in order to be
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// successfully invoked.
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func OverloadOperandTrait(trait int) OverloadOpt {
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return decls.OverloadOperandTrait(trait)
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}
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// TypeToExprType converts a CEL-native type representation to a protobuf CEL Type representation.
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func TypeToExprType(t *Type) (*exprpb.Type, error) {
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return types.TypeToExprType(t)
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}
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// ExprTypeToType converts a protobuf CEL type representation to a CEL-native type representation.
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func ExprTypeToType(t *exprpb.Type) (*Type, error) {
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return types.ExprTypeToType(t)
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}
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// ExprDeclToDeclaration converts a protobuf CEL declaration to a CEL-native declaration, either a Variable or Function.
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func ExprDeclToDeclaration(d *exprpb.Decl) (EnvOption, error) {
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switch d.GetDeclKind().(type) {
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case *exprpb.Decl_Function:
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overloads := d.GetFunction().GetOverloads()
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opts := make([]FunctionOpt, len(overloads))
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for i, o := range overloads {
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args := make([]*Type, len(o.GetParams()))
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for j, p := range o.GetParams() {
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a, err := types.ExprTypeToType(p)
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if err != nil {
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return nil, err
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}
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args[j] = a
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}
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res, err := types.ExprTypeToType(o.GetResultType())
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if err != nil {
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return nil, err
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}
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if o.IsInstanceFunction {
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opts[i] = decls.MemberOverload(o.GetOverloadId(), args, res)
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} else {
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opts[i] = decls.Overload(o.GetOverloadId(), args, res)
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}
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}
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return Function(d.GetName(), opts...), nil
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case *exprpb.Decl_Ident:
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t, err := types.ExprTypeToType(d.GetIdent().GetType())
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if err != nil {
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return nil, err
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}
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if d.GetIdent().GetValue() == nil {
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return Variable(d.GetName(), t), nil
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}
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val, err := ast.ConstantToVal(d.GetIdent().GetValue())
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if err != nil {
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return nil, err
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}
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return Constant(d.GetName(), t, val), nil
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default:
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return nil, fmt.Errorf("unsupported decl: %v", d)
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}
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}
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