mirror of
https://github.com/ceph/ceph-csi.git
synced 2024-11-30 02:00:19 +00:00
5a66991bb3
updating the kubernetes release to the latest in main go.mod Signed-off-by: Madhu Rajanna <madhupr007@gmail.com>
376 lines
12 KiB
Go
376 lines
12 KiB
Go
// Copyright 2023 Google LLC
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package cel
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import (
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"fmt"
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"reflect"
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"regexp"
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"github.com/google/cel-go/common/ast"
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"github.com/google/cel-go/common/overloads"
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)
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const (
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homogeneousValidatorName = "cel.lib.std.validate.types.homogeneous"
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// HomogeneousAggregateLiteralExemptFunctions is the ValidatorConfig key used to configure
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// the set of function names which are exempt from homogeneous type checks. The expected type
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// is a string list of function names.
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//
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// As an example, the `<string>.format([args])` call expects the input arguments list to be
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// comprised of a variety of types which correspond to the types expected by the format control
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// clauses; however, all other uses of a mixed element type list, would be unexpected.
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HomogeneousAggregateLiteralExemptFunctions = homogeneousValidatorName + ".exempt"
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)
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// ASTValidators configures a set of ASTValidator instances into the target environment.
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//
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// Validators are applied in the order in which the are specified and are treated as singletons.
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// The same ASTValidator with a given name will not be applied more than once.
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func ASTValidators(validators ...ASTValidator) EnvOption {
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return func(e *Env) (*Env, error) {
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for _, v := range validators {
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if !e.HasValidator(v.Name()) {
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e.validators = append(e.validators, v)
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}
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}
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return e, nil
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}
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}
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// ASTValidator defines a singleton interface for validating a type-checked Ast against an environment.
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//
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// Note: the Issues argument is mutable in the sense that it is intended to collect errors which will be
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// reported to the caller.
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type ASTValidator interface {
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// Name returns the name of the validator. Names must be unique.
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Name() string
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// Validate validates a given Ast within an Environment and collects a set of potential issues.
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//
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// The ValidatorConfig is generated from the set of ASTValidatorConfigurer instances prior to
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// the invocation of the Validate call. The expectation is that the validator configuration
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// is created in sequence and immutable once provided to the Validate call.
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//
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// See individual validators for more information on their configuration keys and configuration
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// properties.
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Validate(*Env, ValidatorConfig, *ast.AST, *Issues)
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}
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// ValidatorConfig provides an accessor method for querying validator configuration state.
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type ValidatorConfig interface {
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GetOrDefault(name string, value any) any
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}
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// MutableValidatorConfig provides mutation methods for querying and updating validator configuration
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// settings.
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type MutableValidatorConfig interface {
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ValidatorConfig
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Set(name string, value any) error
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}
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// ASTValidatorConfigurer indicates that this object, currently expected to be an ASTValidator,
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// participates in validator configuration settings.
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//
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// This interface may be split from the expectation of being an ASTValidator instance in the future.
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type ASTValidatorConfigurer interface {
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Configure(MutableValidatorConfig) error
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}
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// validatorConfig implements the ValidatorConfig and MutableValidatorConfig interfaces.
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type validatorConfig struct {
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data map[string]any
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}
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// newValidatorConfig initializes the validator config with default values for core CEL validators.
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func newValidatorConfig() *validatorConfig {
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return &validatorConfig{
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data: map[string]any{
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HomogeneousAggregateLiteralExemptFunctions: []string{},
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},
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}
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}
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// GetOrDefault returns the configured value for the name, if present, else the input default value.
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//
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// Note, the type-agreement between the input default and configured value is not checked on read.
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func (config *validatorConfig) GetOrDefault(name string, value any) any {
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v, found := config.data[name]
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if !found {
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return value
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}
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return v
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}
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// Set configures a validator option with the given name and value.
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//
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// If the value had previously been set, the new value must have the same reflection type as the old one,
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// or the call will error.
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func (config *validatorConfig) Set(name string, value any) error {
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v, found := config.data[name]
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if found && reflect.TypeOf(v) != reflect.TypeOf(value) {
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return fmt.Errorf("incompatible configuration type for %s, got %T, wanted %T", name, value, v)
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}
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config.data[name] = value
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return nil
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}
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// ExtendedValidations collects a set of common AST validations which reduce the likelihood of runtime errors.
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//
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// - Validate duration and timestamp literals
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// - Ensure regex strings are valid
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// - Disable mixed type list and map literals
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func ExtendedValidations() EnvOption {
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return ASTValidators(
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ValidateDurationLiterals(),
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ValidateTimestampLiterals(),
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ValidateRegexLiterals(),
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ValidateHomogeneousAggregateLiterals(),
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)
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}
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// ValidateDurationLiterals ensures that duration literal arguments are valid immediately after type-check.
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func ValidateDurationLiterals() ASTValidator {
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return newFormatValidator(overloads.TypeConvertDuration, 0, evalCall)
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}
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// ValidateTimestampLiterals ensures that timestamp literal arguments are valid immediately after type-check.
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func ValidateTimestampLiterals() ASTValidator {
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return newFormatValidator(overloads.TypeConvertTimestamp, 0, evalCall)
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}
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// ValidateRegexLiterals ensures that regex patterns are validated after type-check.
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func ValidateRegexLiterals() ASTValidator {
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return newFormatValidator(overloads.Matches, 0, compileRegex)
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}
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// ValidateHomogeneousAggregateLiterals checks that all list and map literals entries have the same types, i.e.
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// no mixed list element types or mixed map key or map value types.
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//
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// Note: the string format call relies on a mixed element type list for ease of use, so this check skips all
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// literals which occur within string format calls.
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func ValidateHomogeneousAggregateLiterals() ASTValidator {
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return homogeneousAggregateLiteralValidator{}
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}
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// ValidateComprehensionNestingLimit ensures that comprehension nesting does not exceed the specified limit.
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//
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// This validator can be useful for preventing arbitrarily nested comprehensions which can take high polynomial
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// time to complete.
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//
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// Note, this limit does not apply to comprehensions with an empty iteration range, as these comprehensions have
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// no actual looping cost. The cel.bind() utilizes the comprehension structure to perform local variable
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// assignments and supplies an empty iteration range, so they won't count against the nesting limit either.
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func ValidateComprehensionNestingLimit(limit int) ASTValidator {
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return nestingLimitValidator{limit: limit}
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}
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type argChecker func(env *Env, call, arg ast.Expr) error
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func newFormatValidator(funcName string, argNum int, check argChecker) formatValidator {
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return formatValidator{
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funcName: funcName,
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check: check,
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argNum: argNum,
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}
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}
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type formatValidator struct {
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funcName string
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argNum int
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check argChecker
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}
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// Name returns the unique name of this function format validator.
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func (v formatValidator) Name() string {
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return fmt.Sprintf("cel.lib.std.validate.functions.%s", v.funcName)
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}
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// Validate searches the AST for uses of a given function name with a constant argument and performs a check
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// on whether the argument is a valid literal value.
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func (v formatValidator) Validate(e *Env, _ ValidatorConfig, a *ast.AST, iss *Issues) {
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root := ast.NavigateAST(a)
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funcCalls := ast.MatchDescendants(root, ast.FunctionMatcher(v.funcName))
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for _, call := range funcCalls {
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callArgs := call.AsCall().Args()
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if len(callArgs) <= v.argNum {
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continue
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}
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litArg := callArgs[v.argNum]
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if litArg.Kind() != ast.LiteralKind {
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continue
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}
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if err := v.check(e, call, litArg); err != nil {
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iss.ReportErrorAtID(litArg.ID(), "invalid %s argument", v.funcName)
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}
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}
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}
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func evalCall(env *Env, call, arg ast.Expr) error {
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ast := &Ast{impl: ast.NewAST(call, ast.NewSourceInfo(nil))}
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prg, err := env.Program(ast)
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if err != nil {
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return err
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}
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_, _, err = prg.Eval(NoVars())
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return err
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}
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func compileRegex(_ *Env, _, arg ast.Expr) error {
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pattern := arg.AsLiteral().Value().(string)
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_, err := regexp.Compile(pattern)
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return err
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}
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type homogeneousAggregateLiteralValidator struct{}
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// Name returns the unique name of the homogeneous type validator.
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func (homogeneousAggregateLiteralValidator) Name() string {
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return homogeneousValidatorName
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}
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// Validate validates that all lists and map literals have homogeneous types, i.e. don't contain dyn types.
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//
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// This validator makes an exception for list and map literals which occur at any level of nesting within
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// string format calls.
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func (v homogeneousAggregateLiteralValidator) Validate(_ *Env, c ValidatorConfig, a *ast.AST, iss *Issues) {
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var exemptedFunctions []string
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exemptedFunctions = c.GetOrDefault(HomogeneousAggregateLiteralExemptFunctions, exemptedFunctions).([]string)
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root := ast.NavigateAST(a)
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listExprs := ast.MatchDescendants(root, ast.KindMatcher(ast.ListKind))
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for _, listExpr := range listExprs {
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if inExemptFunction(listExpr, exemptedFunctions) {
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continue
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}
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l := listExpr.AsList()
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elements := l.Elements()
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optIndices := l.OptionalIndices()
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var elemType *Type
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for i, e := range elements {
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et := a.GetType(e.ID())
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if isOptionalIndex(i, optIndices) {
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et = et.Parameters()[0]
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}
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if elemType == nil {
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elemType = et
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continue
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}
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if !elemType.IsEquivalentType(et) {
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v.typeMismatch(iss, e.ID(), elemType, et)
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break
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}
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}
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}
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mapExprs := ast.MatchDescendants(root, ast.KindMatcher(ast.MapKind))
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for _, mapExpr := range mapExprs {
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if inExemptFunction(mapExpr, exemptedFunctions) {
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continue
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}
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m := mapExpr.AsMap()
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entries := m.Entries()
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var keyType, valType *Type
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for _, e := range entries {
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mapEntry := e.AsMapEntry()
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key, val := mapEntry.Key(), mapEntry.Value()
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kt, vt := a.GetType(key.ID()), a.GetType(val.ID())
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if mapEntry.IsOptional() {
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vt = vt.Parameters()[0]
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}
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if keyType == nil && valType == nil {
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keyType, valType = kt, vt
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continue
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}
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if !keyType.IsEquivalentType(kt) {
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v.typeMismatch(iss, key.ID(), keyType, kt)
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}
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if !valType.IsEquivalentType(vt) {
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v.typeMismatch(iss, val.ID(), valType, vt)
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}
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}
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}
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}
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func inExemptFunction(e ast.NavigableExpr, exemptFunctions []string) bool {
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parent, found := e.Parent()
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for found {
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if parent.Kind() == ast.CallKind {
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fnName := parent.AsCall().FunctionName()
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for _, exempt := range exemptFunctions {
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if exempt == fnName {
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return true
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}
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}
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}
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parent, found = parent.Parent()
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}
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return false
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}
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func isOptionalIndex(i int, optIndices []int32) bool {
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for _, optInd := range optIndices {
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if i == int(optInd) {
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return true
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}
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}
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return false
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}
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func (homogeneousAggregateLiteralValidator) typeMismatch(iss *Issues, id int64, expected, actual *Type) {
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iss.ReportErrorAtID(id, "expected type '%s' but found '%s'", FormatCELType(expected), FormatCELType(actual))
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}
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type nestingLimitValidator struct {
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limit int
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}
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func (v nestingLimitValidator) Name() string {
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return "cel.lib.std.validate.comprehension_nesting_limit"
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}
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func (v nestingLimitValidator) Validate(e *Env, _ ValidatorConfig, a *ast.AST, iss *Issues) {
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root := ast.NavigateAST(a)
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comprehensions := ast.MatchDescendants(root, ast.KindMatcher(ast.ComprehensionKind))
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if len(comprehensions) <= v.limit {
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return
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}
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for _, comp := range comprehensions {
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count := 0
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e := comp
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hasParent := true
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for hasParent {
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// When the expression is not a comprehension, continue to the next ancestor.
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if e.Kind() != ast.ComprehensionKind {
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e, hasParent = e.Parent()
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continue
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}
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// When the comprehension has an empty range, continue to the next ancestor
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// as this comprehension does not have any associated cost.
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iterRange := e.AsComprehension().IterRange()
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if iterRange.Kind() == ast.ListKind && iterRange.AsList().Size() == 0 {
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e, hasParent = e.Parent()
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continue
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}
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// Otherwise check the nesting limit.
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count++
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if count > v.limit {
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iss.ReportErrorAtID(comp.ID(), "comprehension exceeds nesting limit")
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break
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}
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e, hasParent = e.Parent()
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}
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}
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}
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