/* Copyright 2016 Google Inc. All rights reserved. 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 jsonnet import ( "bytes" "fmt" "math" "path" "reflect" "sort" "github.com/google/go-jsonnet/ast" ) // TODO(sbarzowski) use it as a pointer in most places b/c it can sometimes be shared // for example it can be shared between array elements and function arguments type environment struct { sb selfBinding // Bindings introduced in this frame. The way previous bindings are treated // depends on the type of a frame. // If isCall == true then previous bindings are ignored (it's a clean // environment with just the variables we have here). // If isCall == false then if this frame doesn't contain a binding // previous bindings will be used. upValues bindingFrame } func makeEnvironment(upValues bindingFrame, sb selfBinding) environment { return environment{ upValues: upValues, sb: sb, } } func callFrameToTraceFrame(frame *callFrame) TraceFrame { return traceElementToTraceFrame(frame.trace) } func (i *interpreter) getCurrentStackTrace(additional *TraceElement) []TraceFrame { var result []TraceFrame for _, f := range i.stack.stack { if f.isCall { result = append(result, callFrameToTraceFrame(f)) } } if additional != nil { result = append(result, traceElementToTraceFrame(additional)) } return result } type callFrame struct { // True if it switches to a clean environment (function call or array element) // False otherwise, e.g. for local // This makes callFrame a misnomer as it is technically not always a call... isCall bool // Tracing information about the place where it was called from. trace *TraceElement // Whether this frame can be removed from the stack when it doesn't affect // the evaluation result, but in case of an error, it won't appear on the // stack trace. // It's used for tail call optimization. trimmable bool env environment } func dumpCallFrame(c *callFrame) string { var loc ast.LocationRange if c.trace == nil || c.trace.loc == nil { loc = ast.MakeLocationRangeMessage("?") } else { loc = *c.trace.loc } return fmt.Sprintf("", c.isCall, loc, c.trimmable, ) } type callStack struct { calls int limit int stack []*callFrame } func dumpCallStack(c *callStack) string { var buf bytes.Buffer fmt.Fprintf(&buf, "") return buf.String() } func (s *callStack) top() *callFrame { r := s.stack[len(s.stack)-1] return r } // It might've been popped already by tail call optimization. // We check if it was trimmed by comparing the current stack size to the position // of the frame we want to pop. func (s *callStack) popIfExists(whichFrame int) { if len(s.stack) == whichFrame { if s.top().isCall { s.calls-- } s.stack = s.stack[:len(s.stack)-1] } } /** If there is a trimmable frame followed by some locals, pop them all. */ func (s *callStack) tailCallTrimStack() { for i := len(s.stack) - 1; i >= 0; i-- { if s.stack[i].isCall { if !s.stack[i].trimmable { return } // Remove this stack frame and everything above it s.stack = s.stack[:i] s.calls-- return } } } type tailCallStatus int const ( nonTailCall tailCallStatus = iota tailCall ) func (i *interpreter) newCall(trace *TraceElement, env environment, trimmable bool) error { s := &i.stack if s.calls >= s.limit { return makeRuntimeError("Max stack frames exceeded.", i.getCurrentStackTrace(trace)) } s.stack = append(s.stack, &callFrame{ isCall: true, trace: trace, env: env, trimmable: trimmable, }) s.calls++ return nil } func (i *interpreter) newLocal(vars bindingFrame) { s := &i.stack s.stack = append(s.stack, &callFrame{ env: makeEnvironment(vars, selfBinding{}), }) } // getSelfBinding resolves the self construct func (s *callStack) getSelfBinding() selfBinding { for i := len(s.stack) - 1; i >= 0; i-- { if s.stack[i].isCall { return s.stack[i].env.sb } } panic(fmt.Sprintf("malformed stack %v", dumpCallStack(s))) } // lookUpVar finds for the closest variable in scope that matches the given name. func (s *callStack) lookUpVar(id ast.Identifier) potentialValue { for i := len(s.stack) - 1; i >= 0; i-- { bind := s.stack[i].env.upValues[id] if bind != nil { return bind } if s.stack[i].isCall { // Nothing beyond the captured environment of the thunk / closure. break } } return nil } func makeCallStack(limit int) callStack { return callStack{ calls: 0, limit: limit, } } // Keeps current execution context and evaluates things type interpreter struct { // Current stack. It is used for: // 1) Keeping environment (object we're in, variables) // 2) Diagnostic information in case of failure stack callStack // External variables extVars map[string]potentialValue // Native functions nativeFuncs map[string]*NativeFunction // A part of std object common to all files baseStd valueObject // Keeps imports importCache *ImportCache } // Build a binding frame containing specified variables. func (i *interpreter) capture(freeVars ast.Identifiers) bindingFrame { env := make(bindingFrame) for _, fv := range freeVars { env[fv] = i.stack.lookUpVar(fv) if env[fv] == nil { panic(fmt.Sprintf("Variable %v vanished", fv)) } } return env } func addBindings(a, b bindingFrame) bindingFrame { result := make(bindingFrame) for k, v := range a { result[k] = v } for k, v := range b { result[k] = v } return result } func (i *interpreter) getCurrentEnv(ast ast.Node) environment { return makeEnvironment( i.capture(ast.FreeVariables()), i.stack.getSelfBinding(), ) } func (i *interpreter) evaluate(a ast.Node, tc tailCallStatus) (value, error) { e := &evaluator{ trace: &TraceElement{ loc: a.Loc(), context: a.Context(), }, i: i, } switch node := a.(type) { case *ast.Array: sb := i.stack.getSelfBinding() var elements []potentialValue for _, el := range node.Elements { env := makeEnvironment(i.capture(el.FreeVariables()), sb) elThunk := makeThunk(env, el) elements = append(elements, elThunk) } return makeValueArray(elements), nil case *ast.Binary: // Some binary operators are lazy, so thunks are needed in general env := i.getCurrentEnv(node) // TODO(sbarzowski) make sure it displays nicely in stack trace (thunk names etc.) // TODO(sbarzowski) it may make sense not to show a line in stack trace for operators // at all in many cases. 1 + 2 + 3 + 4 + error "x" will show 5 lines // of stack trace now, and it's not that nice. left := makeThunk(env, node.Left) right := makeThunk(env, node.Right) builtin := bopBuiltins[node.Op] result, err := builtin.function(e, left, right) if err != nil { return nil, err } return result, nil case *ast.Unary: env := i.getCurrentEnv(node) arg := makeThunk(env, node.Expr) builtin := uopBuiltins[node.Op] result, err := builtin.function(e, arg) if err != nil { return nil, err } return result, nil case *ast.Conditional: cond, err := e.evalInCurrentContext(node.Cond, nonTailCall) if err != nil { return nil, err } condBool, err := e.getBoolean(cond) if err != nil { return nil, err } if condBool.value { return e.evalInCurrentContext(node.BranchTrue, tc) } return e.evalInCurrentContext(node.BranchFalse, tc) case *ast.DesugaredObject: // Evaluate all the field names. Check for null, dups, etc. fields := make(simpleObjectFieldMap) for _, field := range node.Fields { fieldNameValue, err := e.evalInCurrentContext(field.Name, nonTailCall) if err != nil { return nil, err } var fieldName string switch fieldNameValue := fieldNameValue.(type) { case *valueString: fieldName = fieldNameValue.getString() case *valueNull: // Omitted field. continue default: return nil, e.Error(fmt.Sprintf("Field name must be string, got %v", fieldNameValue.getType().name)) } if _, ok := fields[fieldName]; ok { return nil, e.Error(duplicateFieldNameErrMsg(fieldName)) } var f unboundField = &codeUnboundField{field.Body} if field.PlusSuper { f = &PlusSuperUnboundField{f} } fields[fieldName] = simpleObjectField{field.Hide, f} } var asserts []unboundField for _, assert := range node.Asserts { asserts = append(asserts, &codeUnboundField{assert}) } upValues := i.capture(node.FreeVariables()) return makeValueSimpleObject(upValues, fields, asserts), nil case *ast.Error: msgVal, err := e.evalInCurrentContext(node.Expr, nonTailCall) if err != nil { // error when evaluating error message return nil, err } if msgVal.getType() != stringType { msgVal, err = builtinToString(e, &readyValue{msgVal}) if err != nil { return nil, err } } msg, err := e.getString(msgVal) if err != nil { return nil, err } return nil, e.Error(msg.getString()) case *ast.Index: targetValue, err := e.evalInCurrentContext(node.Target, nonTailCall) if err != nil { return nil, err } index, err := e.evalInCurrentContext(node.Index, nonTailCall) if err != nil { return nil, err } switch target := targetValue.(type) { case valueObject: indexString, err := e.getString(index) if err != nil { return nil, err } return target.index(e, indexString.getString()) case *valueArray: indexInt, err := e.getNumber(index) if err != nil { return nil, err } // TODO(https://github.com/google/jsonnet/issues/377): non-integer indexes should be an error return target.index(e, int(indexInt.value), tc) case *valueString: indexInt, err := e.getNumber(index) if err != nil { return nil, err } // TODO(https://github.com/google/jsonnet/issues/377): non-integer indexes should be an error return target.index(e, int(indexInt.value)) } return nil, e.Error(fmt.Sprintf("Value non indexable: %v", reflect.TypeOf(targetValue))) case *ast.Import: codeDir, _ := path.Split(node.Loc().FileName) return i.importCache.ImportCode(codeDir, node.File.Value, e) case *ast.ImportStr: codeDir, _ := path.Split(node.Loc().FileName) return i.importCache.ImportString(codeDir, node.File.Value, e) case *ast.LiteralBoolean: return makeValueBoolean(node.Value), nil case *ast.LiteralNull: return makeValueNull(), nil case *ast.LiteralNumber: return makeValueNumber(node.Value), nil case *ast.LiteralString: return makeValueString(node.Value), nil case *ast.Local: vars := make(bindingFrame) bindEnv := i.getCurrentEnv(a) for _, bind := range node.Binds { th := makeThunk(bindEnv, bind.Body) // recursive locals vars[bind.Variable] = th bindEnv.upValues[bind.Variable] = th } i.newLocal(vars) sz := len(i.stack.stack) // Add new stack frame, with new thunk for this variable // execute body WRT stack frame. v, err := e.evalInCurrentContext(node.Body, tc) i.stack.popIfExists(sz) return v, err case *ast.Self: sb := i.stack.getSelfBinding() return sb.self, nil case *ast.Var: return e.evaluateTailCall(e.lookUpVar(node.Id), tc) case *ast.SuperIndex: index, err := e.evalInCurrentContext(node.Index, nonTailCall) if err != nil { return nil, err } indexStr, err := e.getString(index) if err != nil { return nil, err } return objectIndex(e, i.stack.getSelfBinding().super(), indexStr.getString()) case *ast.InSuper: index, err := e.evalInCurrentContext(node.Index, nonTailCall) if err != nil { return nil, err } indexStr, err := e.getString(index) if err != nil { return nil, err } field := tryObjectIndex(i.stack.getSelfBinding().super(), indexStr.getString(), withHidden) return makeValueBoolean(field != nil), nil case *ast.Function: return &valueFunction{ ec: makeClosure(i.getCurrentEnv(a), node), }, nil case *ast.Apply: // Eval target target, err := e.evalInCurrentContext(node.Target, nonTailCall) if err != nil { return nil, err } function, err := e.getFunction(target) if err != nil { return nil, err } // environment in which we can evaluate arguments argEnv := i.getCurrentEnv(a) arguments := callArguments{ positional: make([]potentialValue, len(node.Arguments.Positional)), named: make([]namedCallArgument, len(node.Arguments.Named)), tailstrict: node.TailStrict, } for i, arg := range node.Arguments.Positional { arguments.positional[i] = makeThunk(argEnv, arg) } for i, arg := range node.Arguments.Named { arguments.named[i] = namedCallArgument{name: arg.Name, pv: makeThunk(argEnv, arg.Arg)} } return e.evaluateTailCall(function.call(arguments), tc) default: return nil, e.Error(fmt.Sprintf("Executing this AST type not implemented yet: %v", reflect.TypeOf(a))) } } // unparseString Wraps in "" and escapes stuff to make the string JSON-compliant and human-readable. func unparseString(v string) string { var buf bytes.Buffer buf.WriteString("\"") for _, c := range v { switch c { case '"': buf.WriteString("\\\"") case '\\': buf.WriteString("\\\\") case '\b': buf.WriteString("\\b") case '\f': buf.WriteString("\\f") case '\n': buf.WriteString("\\n") case '\r': buf.WriteString("\\r") case '\t': buf.WriteString("\\t") case 0: buf.WriteString("\\u0000") default: if c < 0x20 || (c >= 0x7f && c <= 0x9f) { buf.WriteString(fmt.Sprintf("\\u%04x", int(c))) } else { buf.WriteRune(c) } } } buf.WriteString("\"") return buf.String() } func unparseNumber(v float64) string { if v == math.Floor(v) { return fmt.Sprintf("%.0f", v) } // See "What Every Computer Scientist Should Know About Floating-Point Arithmetic" // Theorem 15 // http://docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html return fmt.Sprintf("%.17g", v) } // manifestJSON converts to standard JSON representation as in "encoding/json" package func (i *interpreter) manifestJSON(trace *TraceElement, v value) (interface{}, error) { e := &evaluator{i: i, trace: trace} switch v := v.(type) { case *valueBoolean: return v.value, nil case *valueFunction: return nil, makeRuntimeError("Couldn't manifest function in JSON output.", i.getCurrentStackTrace(trace)) case *valueNumber: return v.value, nil case *valueString: return v.getString(), nil case *valueNull: return nil, nil case *valueArray: result := make([]interface{}, 0, len(v.elements)) for _, th := range v.elements { elVal, err := e.evaluate(th) if err != nil { return nil, err } elem, err := i.manifestJSON(trace, elVal) if err != nil { return nil, err } result = append(result, elem) } return result, nil case valueObject: fieldNames := objectFields(v, withoutHidden) sort.Strings(fieldNames) err := checkAssertions(e, v) if err != nil { return nil, err } result := make(map[string]interface{}) for _, fieldName := range fieldNames { fieldVal, err := v.index(e, fieldName) if err != nil { return nil, err } field, err := i.manifestJSON(trace, fieldVal) if err != nil { return nil, err } result[fieldName] = field } return result, nil default: return nil, makeRuntimeError( fmt.Sprintf("Manifesting this value not implemented yet: %s", reflect.TypeOf(v)), i.getCurrentStackTrace(trace), ) } } func serializeJSON(v interface{}, multiline bool, indent string, buf *bytes.Buffer) { switch v := v.(type) { case nil: buf.WriteString("null") case []interface{}: if len(v) == 0 { buf.WriteString("[ ]") } else { var prefix string var indent2 string if multiline { prefix = "[\n" indent2 = indent + " " } else { prefix = "[" indent2 = indent } for _, elem := range v { buf.WriteString(prefix) buf.WriteString(indent2) serializeJSON(elem, multiline, indent2, buf) if multiline { prefix = ",\n" } else { prefix = ", " } } if multiline { buf.WriteString("\n") } buf.WriteString(indent) buf.WriteString("]") } case bool: if v { buf.WriteString("true") } else { buf.WriteString("false") } case float64: buf.WriteString(unparseNumber(v)) case map[string]interface{}: fieldNames := make([]string, 0, len(v)) for name := range v { fieldNames = append(fieldNames, name) } sort.Strings(fieldNames) if len(fieldNames) == 0 { buf.WriteString("{ }") } else { var prefix string var indent2 string if multiline { prefix = "{\n" indent2 = indent + " " } else { prefix = "{" indent2 = indent } for _, fieldName := range fieldNames { fieldVal := v[fieldName] buf.WriteString(prefix) buf.WriteString(indent2) buf.WriteString(unparseString(fieldName)) buf.WriteString(": ") serializeJSON(fieldVal, multiline, indent2, buf) if multiline { prefix = ",\n" } else { prefix = ", " } } if multiline { buf.WriteString("\n") } buf.WriteString(indent) buf.WriteString("}") } case string: buf.WriteString(unparseString(v)) default: panic(fmt.Sprintf("Unsupported value for serialization %#+v", v)) } } func (i *interpreter) manifestAndSerializeJSON( buf *bytes.Buffer, trace *TraceElement, v value, multiline bool, indent string) error { manifested, err := i.manifestJSON(trace, v) if err != nil { return err } serializeJSON(manifested, multiline, indent, buf) return nil } // manifestString expects the value to be a string and returns it. func (i *interpreter) manifestString(buf *bytes.Buffer, trace *TraceElement, v value) error { switch v := v.(type) { case *valueString: buf.WriteString(v.getString()) return nil default: return makeRuntimeError(fmt.Sprintf("Expected string result, got: %s", v.getType().name), i.getCurrentStackTrace(trace)) } } func (i *interpreter) manifestAndSerializeMulti(trace *TraceElement, v value) (r map[string]string, err error) { r = make(map[string]string) json, err := i.manifestJSON(trace, v) if err != nil { return r, err } switch json := json.(type) { case map[string]interface{}: for filename, fileJSON := range json { var buf bytes.Buffer serializeJSON(fileJSON, true, "", &buf) buf.WriteString("\n") r[filename] = buf.String() } default: msg := fmt.Sprintf("Multi mode: Top-level object was a %s, "+ "should be an object whose keys are filenames and values hold "+ "the JSON for that file.", v.getType().name) return r, makeRuntimeError(msg, i.getCurrentStackTrace(trace)) } return } func (i *interpreter) manifestAndSerializeYAMLStream(trace *TraceElement, v value) (r []string, err error) { r = make([]string, 0) json, err := i.manifestJSON(trace, v) if err != nil { return r, err } switch json := json.(type) { case []interface{}: for _, doc := range json { var buf bytes.Buffer serializeJSON(doc, true, "", &buf) buf.WriteString("\n") r = append(r, buf.String()) } default: msg := fmt.Sprintf("Stream mode: Top-level object was a %s, "+ "should be an array whose elements hold "+ "the JSON for each document in the stream.", v.getType().name) return r, makeRuntimeError(msg, i.getCurrentStackTrace(trace)) } return } func jsonToValue(e *evaluator, v interface{}) (value, error) { switch v := v.(type) { case nil: return &nullValue, nil case []interface{}: elems := make([]potentialValue, len(v)) for i, elem := range v { val, err := jsonToValue(e, elem) if err != nil { return nil, err } elems[i] = &readyValue{val} } return makeValueArray(elems), nil case bool: return makeValueBoolean(v), nil case float64: return makeValueNumber(v), nil case map[string]interface{}: fieldMap := map[string]value{} for name, f := range v { val, err := jsonToValue(e, f) if err != nil { return nil, err } fieldMap[name] = val } return buildObject(ast.ObjectFieldInherit, fieldMap), nil case string: return makeValueString(v), nil default: return nil, e.Error(fmt.Sprintf("Not a json type: %#+v", v)) } } func (i *interpreter) EvalInCleanEnv(fromWhere *TraceElement, env *environment, ast ast.Node, trimmable bool) (value, error) { err := i.newCall(fromWhere, *env, trimmable) if err != nil { return nil, err } stackSize := len(i.stack.stack) val, err := i.evaluate(ast, tailCall) i.stack.popIfExists(stackSize) return val, err } func buildStdObject(i *interpreter) (valueObject, error) { objVal, err := evaluateStd(i) if err != nil { return nil, err } obj := objVal.(*valueSimpleObject) builtinFields := map[string]unboundField{} for key, ec := range funcBuiltins { function := valueFunction{ec: ec} // TODO(sbarzowski) better way to build function value builtinFields[key] = &readyValue{&function} } for name, value := range builtinFields { obj.fields[name] = simpleObjectField{ast.ObjectFieldHidden, value} } return obj, nil } func evaluateStd(i *interpreter) (value, error) { beforeStdEnv := makeEnvironment( bindingFrame{}, makeUnboundSelfBinding(), ) evalLoc := ast.MakeLocationRangeMessage("During evaluation of std") evalTrace := &TraceElement{loc: &evalLoc} node := ast.StdAst return i.EvalInCleanEnv(evalTrace, &beforeStdEnv, node, false) } func prepareExtVars(i *interpreter, ext vmExtMap, kind string) map[string]potentialValue { result := make(map[string]potentialValue) for name, content := range ext { if content.isCode { varLoc := ast.MakeLocationRangeMessage("During evaluation") varTrace := &TraceElement{ loc: &varLoc, } e := &evaluator{ i: i, trace: varTrace, } result[name] = codeToPV(e, "<"+kind+":"+name+">", content.value) } else { result[name] = &readyValue{makeValueString(content.value)} } } return result } func buildObject(hide ast.ObjectFieldHide, fields map[string]value) valueObject { fieldMap := simpleObjectFieldMap{} for name, v := range fields { fieldMap[name] = simpleObjectField{hide, &readyValue{v}} } return makeValueSimpleObject(bindingFrame{}, fieldMap, nil) } func buildInterpreter(ext vmExtMap, nativeFuncs map[string]*NativeFunction, maxStack int, importer Importer) (*interpreter, error) { i := interpreter{ stack: makeCallStack(maxStack), importCache: MakeImportCache(importer), nativeFuncs: nativeFuncs, } stdObj, err := buildStdObject(&i) if err != nil { return nil, err } i.baseStd = stdObj i.extVars = prepareExtVars(&i, ext, "extvar") return &i, nil } func makeInitialEnv(filename string, baseStd valueObject) environment { fileSpecific := buildObject(ast.ObjectFieldHidden, map[string]value{ "thisFile": makeValueString(filename), }) return makeEnvironment( bindingFrame{ "std": &readyValue{makeValueExtendedObject(baseStd, fileSpecific)}, }, makeUnboundSelfBinding(), ) } func evaluateAux(i *interpreter, node ast.Node, tla vmExtMap) (value, *TraceElement, error) { evalLoc := ast.MakeLocationRangeMessage("During evaluation") evalTrace := &TraceElement{ loc: &evalLoc, } env := makeInitialEnv(node.Loc().FileName, i.baseStd) result, err := i.EvalInCleanEnv(evalTrace, &env, node, false) if err != nil { return nil, nil, err } // If it's not a function, ignore TLA if f, ok := result.(*valueFunction); ok { toplevelArgMap := prepareExtVars(i, tla, "top-level-arg") args := callArguments{} for argName, pv := range toplevelArgMap { args.named = append(args.named, namedCallArgument{name: ast.Identifier(argName), pv: pv}) } funcLoc := ast.MakeLocationRangeMessage("Top-level function") funcTrace := &TraceElement{ loc: &funcLoc, } result, err = f.call(args).getValue(i, funcTrace) if err != nil { return nil, nil, err } } manifestationLoc := ast.MakeLocationRangeMessage("During manifestation") manifestationTrace := &TraceElement{ loc: &manifestationLoc, } return result, manifestationTrace, nil } // TODO(sbarzowski) this function takes far too many arguments - build interpreter in vm instead func evaluate(node ast.Node, ext vmExtMap, tla vmExtMap, nativeFuncs map[string]*NativeFunction, maxStack int, importer Importer, stringOutput bool) (string, error) { i, err := buildInterpreter(ext, nativeFuncs, maxStack, importer) if err != nil { return "", err } result, manifestationTrace, err := evaluateAux(i, node, tla) if err != nil { return "", err } var buf bytes.Buffer if stringOutput { err = i.manifestString(&buf, manifestationTrace, result) } else { err = i.manifestAndSerializeJSON(&buf, manifestationTrace, result, true, "") } if err != nil { return "", err } buf.WriteString("\n") return buf.String(), nil } // TODO(sbarzowski) this function takes far too many arguments - build interpreter in vm instead func evaluateMulti(node ast.Node, ext vmExtMap, tla vmExtMap, nativeFuncs map[string]*NativeFunction, maxStack int, importer Importer, stringOutput bool) (map[string]string, error) { i, err := buildInterpreter(ext, nativeFuncs, maxStack, importer) if err != nil { return nil, err } result, manifestationTrace, err := evaluateAux(i, node, tla) if err != nil { return nil, err } return i.manifestAndSerializeMulti(manifestationTrace, result) } // TODO(sbarzowski) this function takes far too many arguments - build interpreter in vm instead func evaluateStream(node ast.Node, ext vmExtMap, tla vmExtMap, nativeFuncs map[string]*NativeFunction, maxStack int, importer Importer) ([]string, error) { i, err := buildInterpreter(ext, nativeFuncs, maxStack, importer) if err != nil { return nil, err } result, manifestationTrace, err := evaluateAux(i, node, tla) if err != nil { return nil, err } return i.manifestAndSerializeYAMLStream(manifestationTrace, result) }