// Copyright 2019 Google LLC // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package cel import ( "context" "fmt" "sync" "github.com/google/cel-go/common/types" "github.com/google/cel-go/common/types/ref" "github.com/google/cel-go/interpreter" ) // Program is an evaluable view of an Ast. type Program interface { // Eval returns the result of an evaluation of the Ast and environment against the input vars. // // The vars value may either be an `interpreter.Activation` or a `map[string]any`. // // If the `OptTrackState`, `OptTrackCost` or `OptExhaustiveEval` flags are used, the `details` response will // be non-nil. Given this caveat on `details`, the return state from evaluation will be: // // * `val`, `details`, `nil` - Successful evaluation of a non-error result. // * `val`, `details`, `err` - Successful evaluation to an error result. // * `nil`, `details`, `err` - Unsuccessful evaluation. // // An unsuccessful evaluation is typically the result of a series of incompatible `EnvOption` // or `ProgramOption` values used in the creation of the evaluation environment or executable // program. Eval(any) (ref.Val, *EvalDetails, error) // ContextEval evaluates the program with a set of input variables and a context object in order // to support cancellation and timeouts. This method must be used in conjunction with the // InterruptCheckFrequency() option for cancellation interrupts to be impact evaluation. // // The vars value may either be an `interpreter.Activation` or `map[string]any`. // // The output contract for `ContextEval` is otherwise identical to the `Eval` method. ContextEval(context.Context, any) (ref.Val, *EvalDetails, error) } // NoVars returns an empty Activation. func NoVars() interpreter.Activation { return interpreter.EmptyActivation() } // PartialVars returns a PartialActivation which contains variables and a set of AttributePattern // values that indicate variables or parts of variables whose value are not yet known. // // This method relies on manually configured sets of missing attribute patterns. For a method which // infers the missing variables from the input and the configured environment, use Env.PartialVars(). // // The `vars` value may either be an interpreter.Activation or any valid input to the // interpreter.NewActivation call. func PartialVars(vars any, unknowns ...*interpreter.AttributePattern) (interpreter.PartialActivation, error) { return interpreter.NewPartialActivation(vars, unknowns...) } // AttributePattern returns an AttributePattern that matches a top-level variable. The pattern is // mutable, and its methods support the specification of one or more qualifier patterns. // // For example, the AttributePattern(`a`).QualString(`b`) represents a variable access `a` with a // string field or index qualification `b`. This pattern will match Attributes `a`, and `a.b`, // but not `a.c`. // // When using a CEL expression within a container, e.g. a package or namespace, the variable name // in the pattern must match the qualified name produced during the variable namespace resolution. // For example, when variable `a` is declared within an expression whose container is `ns.app`, the // fully qualified variable name may be `ns.app.a`, `ns.a`, or `a` per the CEL namespace resolution // rules. Pick the fully qualified variable name that makes sense within the container as the // AttributePattern `varName` argument. // // See the interpreter.AttributePattern and interpreter.AttributeQualifierPattern for more info // about how to create and manipulate AttributePattern values. func AttributePattern(varName string) *interpreter.AttributePattern { return interpreter.NewAttributePattern(varName) } // EvalDetails holds additional information observed during the Eval() call. type EvalDetails struct { state interpreter.EvalState costTracker *interpreter.CostTracker } // State of the evaluation, non-nil if the OptTrackState or OptExhaustiveEval is specified // within EvalOptions. func (ed *EvalDetails) State() interpreter.EvalState { return ed.state } // ActualCost returns the tracked cost through the course of execution when `CostTracking` is enabled. // Otherwise, returns nil if the cost was not enabled. func (ed *EvalDetails) ActualCost() *uint64 { if ed == nil || ed.costTracker == nil { return nil } cost := ed.costTracker.ActualCost() return &cost } // prog is the internal implementation of the Program interface. type prog struct { *Env evalOpts EvalOption defaultVars interpreter.Activation dispatcher interpreter.Dispatcher interpreter interpreter.Interpreter interruptCheckFrequency uint // Intermediate state used to configure the InterpretableDecorator set provided // to the initInterpretable call. decorators []interpreter.InterpretableDecorator regexOptimizations []*interpreter.RegexOptimization // Interpretable configured from an Ast and aggregate decorator set based on program options. interpretable interpreter.Interpretable callCostEstimator interpreter.ActualCostEstimator costOptions []interpreter.CostTrackerOption costLimit *uint64 } func (p *prog) clone() *prog { costOptsCopy := make([]interpreter.CostTrackerOption, len(p.costOptions)) copy(costOptsCopy, p.costOptions) return &prog{ Env: p.Env, evalOpts: p.evalOpts, defaultVars: p.defaultVars, dispatcher: p.dispatcher, interpreter: p.interpreter, interruptCheckFrequency: p.interruptCheckFrequency, } } // newProgram creates a program instance with an environment, an ast, and an optional list of // ProgramOption values. // // If the program cannot be configured the prog will be nil, with a non-nil error response. func newProgram(e *Env, a *Ast, opts []ProgramOption) (Program, error) { // Build the dispatcher, interpreter, and default program value. disp := interpreter.NewDispatcher() // Ensure the default attribute factory is set after the adapter and provider are // configured. p := &prog{ Env: e, decorators: []interpreter.InterpretableDecorator{}, dispatcher: disp, costOptions: []interpreter.CostTrackerOption{}, } // Configure the program via the ProgramOption values. var err error for _, opt := range opts { p, err = opt(p) if err != nil { return nil, err } } // Add the function bindings created via Function() options. for _, fn := range e.functions { bindings, err := fn.Bindings() if err != nil { return nil, err } err = disp.Add(bindings...) if err != nil { return nil, err } } // Set the attribute factory after the options have been set. var attrFactory interpreter.AttributeFactory if p.evalOpts&OptPartialEval == OptPartialEval { attrFactory = interpreter.NewPartialAttributeFactory(e.Container, e.adapter, e.provider) } else { attrFactory = interpreter.NewAttributeFactory(e.Container, e.adapter, e.provider) } interp := interpreter.NewInterpreter(disp, e.Container, e.provider, e.adapter, attrFactory) p.interpreter = interp // Translate the EvalOption flags into InterpretableDecorator instances. decorators := make([]interpreter.InterpretableDecorator, len(p.decorators)) copy(decorators, p.decorators) // Enable interrupt checking if there's a non-zero check frequency if p.interruptCheckFrequency > 0 { decorators = append(decorators, interpreter.InterruptableEval()) } // Enable constant folding first. if p.evalOpts&OptOptimize == OptOptimize { decorators = append(decorators, interpreter.Optimize()) p.regexOptimizations = append(p.regexOptimizations, interpreter.MatchesRegexOptimization) } // Enable regex compilation of constants immediately after folding constants. if len(p.regexOptimizations) > 0 { decorators = append(decorators, interpreter.CompileRegexConstants(p.regexOptimizations...)) } // Enable exhaustive eval, state tracking and cost tracking last since they require a factory. if p.evalOpts&(OptExhaustiveEval|OptTrackState|OptTrackCost) != 0 { factory := func(state interpreter.EvalState, costTracker *interpreter.CostTracker) (Program, error) { costTracker.Estimator = p.callCostEstimator costTracker.Limit = p.costLimit for _, costOpt := range p.costOptions { err := costOpt(costTracker) if err != nil { return nil, err } } // Limit capacity to guarantee a reallocation when calling 'append(decs, ...)' below. This // prevents the underlying memory from being shared between factory function calls causing // undesired mutations. decs := decorators[:len(decorators):len(decorators)] var observers []interpreter.EvalObserver if p.evalOpts&(OptExhaustiveEval|OptTrackState) != 0 { // EvalStateObserver is required for OptExhaustiveEval. observers = append(observers, interpreter.EvalStateObserver(state)) } if p.evalOpts&OptTrackCost == OptTrackCost { observers = append(observers, interpreter.CostObserver(costTracker)) } // Enable exhaustive eval over a basic observer since it offers a superset of features. if p.evalOpts&OptExhaustiveEval == OptExhaustiveEval { decs = append(decs, interpreter.ExhaustiveEval(), interpreter.Observe(observers...)) } else if len(observers) > 0 { decs = append(decs, interpreter.Observe(observers...)) } return p.clone().initInterpretable(a, decs) } return newProgGen(factory) } return p.initInterpretable(a, decorators) } func (p *prog) initInterpretable(a *Ast, decs []interpreter.InterpretableDecorator) (*prog, error) { // When the AST has been exprAST it contains metadata that can be used to speed up program execution. interpretable, err := p.interpreter.NewInterpretable(a.impl, decs...) if err != nil { return nil, err } p.interpretable = interpretable return p, nil } // Eval implements the Program interface method. func (p *prog) Eval(input any) (v ref.Val, det *EvalDetails, err error) { // Configure error recovery for unexpected panics during evaluation. Note, the use of named // return values makes it possible to modify the error response during the recovery // function. defer func() { if r := recover(); r != nil { switch t := r.(type) { case interpreter.EvalCancelledError: err = t default: err = fmt.Errorf("internal error: %v", r) } } }() // Build a hierarchical activation if there are default vars set. var vars interpreter.Activation switch v := input.(type) { case interpreter.Activation: vars = v case map[string]any: vars = activationPool.Setup(v) defer activationPool.Put(vars) default: return nil, nil, fmt.Errorf("invalid input, wanted Activation or map[string]any, got: (%T)%v", input, input) } if p.defaultVars != nil { vars = interpreter.NewHierarchicalActivation(p.defaultVars, vars) } v = p.interpretable.Eval(vars) // The output of an internal Eval may have a value (`v`) that is a types.Err. This step // translates the CEL value to a Go error response. This interface does not quite match the // RPC signature which allows for multiple errors to be returned, but should be sufficient. if types.IsError(v) { err = v.(*types.Err) } return } // ContextEval implements the Program interface. func (p *prog) ContextEval(ctx context.Context, input any) (ref.Val, *EvalDetails, error) { if ctx == nil { return nil, nil, fmt.Errorf("context can not be nil") } // Configure the input, making sure to wrap Activation inputs in the special ctxActivation which // exposes the #interrupted variable and manages rate-limited checks of the ctx.Done() state. var vars interpreter.Activation switch v := input.(type) { case interpreter.Activation: vars = ctxActivationPool.Setup(v, ctx.Done(), p.interruptCheckFrequency) defer ctxActivationPool.Put(vars) case map[string]any: rawVars := activationPool.Setup(v) defer activationPool.Put(rawVars) vars = ctxActivationPool.Setup(rawVars, ctx.Done(), p.interruptCheckFrequency) defer ctxActivationPool.Put(vars) default: return nil, nil, fmt.Errorf("invalid input, wanted Activation or map[string]any, got: (%T)%v", input, input) } return p.Eval(vars) } // progFactory is a helper alias for marking a program creation factory function. type progFactory func(interpreter.EvalState, *interpreter.CostTracker) (Program, error) // progGen holds a reference to a progFactory instance and implements the Program interface. type progGen struct { factory progFactory } // newProgGen tests the factory object by calling it once and returns a factory-based Program if // the test is successful. func newProgGen(factory progFactory) (Program, error) { // Test the factory to make sure that configuration errors are spotted at config tracker, err := interpreter.NewCostTracker(nil) if err != nil { return nil, err } _, err = factory(interpreter.NewEvalState(), tracker) if err != nil { return nil, err } return &progGen{factory: factory}, nil } // Eval implements the Program interface method. func (gen *progGen) Eval(input any) (ref.Val, *EvalDetails, error) { // The factory based Eval() differs from the standard evaluation model in that it generates a // new EvalState instance for each call to ensure that unique evaluations yield unique stateful // results. state := interpreter.NewEvalState() costTracker, err := interpreter.NewCostTracker(nil) if err != nil { return nil, nil, err } det := &EvalDetails{state: state, costTracker: costTracker} // Generate a new instance of the interpretable using the factory configured during the call to // newProgram(). It is incredibly unlikely that the factory call will generate an error given // the factory test performed within the Program() call. p, err := gen.factory(state, costTracker) if err != nil { return nil, det, err } // Evaluate the input, returning the result and the 'state' within EvalDetails. v, _, err := p.Eval(input) if err != nil { return v, det, err } return v, det, nil } // ContextEval implements the Program interface method. func (gen *progGen) ContextEval(ctx context.Context, input any) (ref.Val, *EvalDetails, error) { if ctx == nil { return nil, nil, fmt.Errorf("context can not be nil") } // The factory based Eval() differs from the standard evaluation model in that it generates a // new EvalState instance for each call to ensure that unique evaluations yield unique stateful // results. state := interpreter.NewEvalState() costTracker, err := interpreter.NewCostTracker(nil) if err != nil { return nil, nil, err } det := &EvalDetails{state: state, costTracker: costTracker} // Generate a new instance of the interpretable using the factory configured during the call to // newProgram(). It is incredibly unlikely that the factory call will generate an error given // the factory test performed within the Program() call. p, err := gen.factory(state, costTracker) if err != nil { return nil, det, err } // Evaluate the input, returning the result and the 'state' within EvalDetails. v, _, err := p.ContextEval(ctx, input) if err != nil { return v, det, err } return v, det, nil } type ctxEvalActivation struct { parent interpreter.Activation interrupt <-chan struct{} interruptCheckCount uint interruptCheckFrequency uint } // ResolveName implements the Activation interface method, but adds a special #interrupted variable // which is capable of testing whether a 'done' signal is provided from a context.Context channel. func (a *ctxEvalActivation) ResolveName(name string) (any, bool) { if name == "#interrupted" { a.interruptCheckCount++ if a.interruptCheckCount%a.interruptCheckFrequency == 0 { select { case <-a.interrupt: return true, true default: return nil, false } } return nil, false } return a.parent.ResolveName(name) } func (a *ctxEvalActivation) Parent() interpreter.Activation { return a.parent } func newCtxEvalActivationPool() *ctxEvalActivationPool { return &ctxEvalActivationPool{ Pool: sync.Pool{ New: func() any { return &ctxEvalActivation{} }, }, } } type ctxEvalActivationPool struct { sync.Pool } // Setup initializes a pooled Activation with the ability check for context.Context cancellation func (p *ctxEvalActivationPool) Setup(vars interpreter.Activation, done <-chan struct{}, interruptCheckRate uint) *ctxEvalActivation { a := p.Pool.Get().(*ctxEvalActivation) a.parent = vars a.interrupt = done a.interruptCheckCount = 0 a.interruptCheckFrequency = interruptCheckRate return a } type evalActivation struct { vars map[string]any lazyVars map[string]any } // ResolveName looks up the value of the input variable name, if found. // // Lazy bindings may be supplied within the map-based input in either of the following forms: // - func() any // - func() ref.Val // // The lazy binding will only be invoked once per evaluation. // // Values which are not represented as ref.Val types on input may be adapted to a ref.Val using // the types.Adapter configured in the environment. func (a *evalActivation) ResolveName(name string) (any, bool) { v, found := a.vars[name] if !found { return nil, false } switch obj := v.(type) { case func() ref.Val: if resolved, found := a.lazyVars[name]; found { return resolved, true } lazy := obj() a.lazyVars[name] = lazy return lazy, true case func() any: if resolved, found := a.lazyVars[name]; found { return resolved, true } lazy := obj() a.lazyVars[name] = lazy return lazy, true default: return obj, true } } // Parent implements the interpreter.Activation interface func (a *evalActivation) Parent() interpreter.Activation { return nil } func newEvalActivationPool() *evalActivationPool { return &evalActivationPool{ Pool: sync.Pool{ New: func() any { return &evalActivation{lazyVars: make(map[string]any)} }, }, } } type evalActivationPool struct { sync.Pool } // Setup initializes a pooled Activation object with the map input. func (p *evalActivationPool) Setup(vars map[string]any) *evalActivation { a := p.Pool.Get().(*evalActivation) a.vars = vars return a } func (p *evalActivationPool) Put(value any) { a := value.(*evalActivation) for k := range a.lazyVars { delete(a.lazyVars, k) } p.Pool.Put(a) } var ( // activationPool is an internally managed pool of Activation values that wrap map[string]any inputs activationPool = newEvalActivationPool() // ctxActivationPool is an internally managed pool of Activation values that expose a special #interrupted variable ctxActivationPool = newCtxEvalActivationPool() )