// Use the top level Evaluator or StreamEvaluator to evaluate expressions and return matches. package yqlib import ( "container/list" "fmt" "math" "strconv" "strings" logging "gopkg.in/op/go-logging.v1" ) var ExpressionParser ExpressionParserInterface func InitExpressionParser() { if ExpressionParser == nil { ExpressionParser = newExpressionParser() } } var log = logging.MustGetLogger("yq-lib") var PrettyPrintExp = `(... | (select(tag != "!!str"), select(tag == "!!str") | select(test("(?i)^(y|yes|n|no|on|off)$") | not)) ) style=""` // GetLogger returns the yq logger instance. func GetLogger() *logging.Logger { return log } func recurseNodeArrayEqual(lhs *CandidateNode, rhs *CandidateNode) bool { if len(lhs.Content) != len(rhs.Content) { return false } for index := 0; index < len(lhs.Content); index = index + 1 { if !recursiveNodeEqual(lhs.Content[index], rhs.Content[index]) { return false } } return true } func findInArray(array *CandidateNode, item *CandidateNode) int { for index := 0; index < len(array.Content); index = index + 1 { if recursiveNodeEqual(array.Content[index], item) { return index } } return -1 } func findKeyInMap(dataMap *CandidateNode, item *CandidateNode) int { for index := 0; index < len(dataMap.Content); index = index + 2 { if recursiveNodeEqual(dataMap.Content[index], item) { return index } } return -1 } func recurseNodeObjectEqual(lhs *CandidateNode, rhs *CandidateNode) bool { if len(lhs.Content) != len(rhs.Content) { return false } for index := 0; index < len(lhs.Content); index = index + 2 { key := lhs.Content[index] value := lhs.Content[index+1] indexInRHS := findInArray(rhs, key) if indexInRHS == -1 || !recursiveNodeEqual(value, rhs.Content[indexInRHS+1]) { return false } } return true } func parseSnippet(value string) (*CandidateNode, error) { if value == "" { return &CandidateNode{ Kind: ScalarNode, Tag: "!!null", }, nil } decoder := NewYamlDecoder(ConfiguredYamlPreferences) err := decoder.Init(strings.NewReader(value)) if err != nil { return nil, err } result, err := decoder.Decode() if err != nil { return nil, err } if result.Tag == "!!str" { // use the original string value, as // decoding drops new lines return CreateScalarNode(value, value), nil } result.Line = 0 result.Column = 0 return result, err } func recursiveNodeEqual(lhs *CandidateNode, rhs *CandidateNode) bool { if lhs.Kind != rhs.Kind { return false } if lhs.Kind == ScalarNode { //process custom tags of scalar nodes. //dont worry about matching tags of maps or arrays. lhsTag := lhs.GuessTagFromCustomType() rhsTag := rhs.GuessTagFromCustomType() if lhsTag != rhsTag { return false } } if lhs.Tag == "!!null" { return true } else if lhs.Kind == ScalarNode { return lhs.Value == rhs.Value } else if lhs.Kind == SequenceNode { return recurseNodeArrayEqual(lhs, rhs) } else if lhs.Kind == MappingNode { return recurseNodeObjectEqual(lhs, rhs) } return false } // yaml numbers can be hex and octal encoded... func parseInt64(numberString string) (string, int64, error) { if strings.HasPrefix(numberString, "0x") || strings.HasPrefix(numberString, "0X") { num, err := strconv.ParseInt(numberString[2:], 16, 64) return "0x%X", num, err } else if strings.HasPrefix(numberString, "0o") { num, err := strconv.ParseInt(numberString[2:], 8, 64) return "0o%o", num, err } num, err := strconv.ParseInt(numberString, 10, 64) return "%v", num, err } func parseInt(numberString string) (int, error) { _, parsed, err := parseInt64(numberString) if err != nil { return 0, err } else if parsed > math.MaxInt || parsed < math.MinInt { return 0, fmt.Errorf("%v is not within [%v, %v]", parsed, math.MinInt, math.MaxInt) } return int(parsed), err } // use for debugging only func NodesToString(collection *list.List) string { if !log.IsEnabledFor(logging.DEBUG) { return "" } result := fmt.Sprintf("%v results\n", collection.Len()) for el := collection.Front(); el != nil; el = el.Next() { result = result + "\n" + NodeToString(el.Value.(*CandidateNode)) } return result } func NodeToString(node *CandidateNode) string { if !log.IsEnabledFor(logging.DEBUG) { return "" } if node == nil { return "-- nil --" } tag := node.Tag if node.Kind == AliasNode { tag = "alias" } valueToUse := node.Value if valueToUse == "" { valueToUse = fmt.Sprintf("%v kids", len(node.Content)) } return fmt.Sprintf(`D%v, P%v, %v (%v)::%v`, node.GetDocument(), node.GetNicePath(), KindString(node.Kind), tag, valueToUse) } func NodeContentToString(node *CandidateNode, depth int) string { if !log.IsEnabledFor(logging.DEBUG) { return "" } var sb strings.Builder for _, child := range node.Content { for i := 0; i < depth; i++ { sb.WriteString(" ") } sb.WriteString("- ") sb.WriteString(NodeToString(child)) sb.WriteString("\n") sb.WriteString(NodeContentToString(child, depth+1)) } return sb.String() } func KindString(kind Kind) string { switch kind { case ScalarNode: return "ScalarNode" case SequenceNode: return "SequenceNode" case MappingNode: return "MappingNode" case AliasNode: return "AliasNode" default: return "unknown!" } }