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bindings.go
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bindings.go
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package sitter
// #include "bindings.h"
import "C"
import (
"context"
"errors"
"fmt"
"math"
"reflect"
"regexp"
"runtime"
"strings"
"sync"
"sync/atomic"
"unsafe"
)
// maintain a map of read functions that can be called from C
var readFuncs = &readFuncsMap{funcs: make(map[int]ReadFunc)}
// Parse is a shortcut for parsing bytes of source code,
// returns root node
//
// Deprecated: use ParseCtx instead
func Parse(content []byte, lang *Language) *Node {
n, _ := ParseCtx(context.Background(), content, lang)
return n
}
// ParseCtx is a shortcut for parsing bytes of source code,
// returns root node
func ParseCtx(ctx context.Context, content []byte, lang *Language) (*Node, error) {
p := NewParser()
p.SetLanguage(lang)
tree, err := p.ParseCtx(ctx, nil, content)
if err != nil {
return nil, err
}
return tree.RootNode(), nil
}
// Parser produces concrete syntax tree based on source code using Language
type Parser struct {
isClosed bool
c *C.TSParser
cancel *uintptr
}
// NewParser creates new Parser
func NewParser() *Parser {
cancel := uintptr(0)
p := &Parser{c: C.ts_parser_new(), cancel: &cancel}
C.ts_parser_set_cancellation_flag(p.c, (*C.size_t)(unsafe.Pointer(p.cancel)))
runtime.SetFinalizer(p, (*Parser).Close)
return p
}
// SetLanguage assignes Language to a parser
func (p *Parser) SetLanguage(lang *Language) {
cLang := (*C.struct_TSLanguage)(lang.ptr)
C.ts_parser_set_language(p.c, cLang)
}
// ReadFunc is a function to retrieve a chunk of text at a given byte offset and (row, column) position
// it should return nil to indicate the end of the document
type ReadFunc func(offset uint32, position Point) []byte
// InputEncoding is a encoding of the text to parse
type InputEncoding int
const (
InputEncodingUTF8 InputEncoding = iota
InputEncodingUTF16
)
// Input defines parameters for parse method
type Input struct {
Read ReadFunc
Encoding InputEncoding
}
var (
ErrOperationLimit = errors.New("operation limit was hit")
ErrNoLanguage = errors.New("cannot parse without language")
)
// Parse produces new Tree from content using old tree
//
// Deprecated: use ParseCtx instead
func (p *Parser) Parse(oldTree *Tree, content []byte) *Tree {
t, _ := p.ParseCtx(context.Background(), oldTree, content)
return t
}
// ParseCtx produces new Tree from content using old tree
func (p *Parser) ParseCtx(ctx context.Context, oldTree *Tree, content []byte) (*Tree, error) {
var BaseTree *C.TSTree
if oldTree != nil {
BaseTree = oldTree.c
}
parseComplete := make(chan struct{})
// run goroutine only if context is cancelable to avoid performance impact
if ctx.Done() != nil {
go func() {
select {
case <-ctx.Done():
atomic.StoreUintptr(p.cancel, 1)
case <-parseComplete:
return
}
}()
}
input := C.CBytes(content)
BaseTree = C.ts_parser_parse_string(p.c, BaseTree, (*C.char)(input), C.uint32_t(len(content)))
close(parseComplete)
C.free(input)
return p.convertTSTree(ctx, BaseTree)
}
// ParseInput produces new Tree by reading from a callback defined in input
// it is useful if your data is stored in specialized data structure
// as it will avoid copying the data into []bytes
// and faster access to edited part of the data
func (p *Parser) ParseInput(oldTree *Tree, input Input) *Tree {
t, _ := p.ParseInputCtx(context.Background(), oldTree, input)
return t
}
// ParseInputCtx produces new Tree by reading from a callback defined in input
// it is useful if your data is stored in specialized data structure
// as it will avoid copying the data into []bytes
// and faster access to edited part of the data
func (p *Parser) ParseInputCtx(ctx context.Context, oldTree *Tree, input Input) (*Tree, error) {
var BaseTree *C.TSTree
if oldTree != nil {
BaseTree = oldTree.c
}
funcID := readFuncs.register(input.Read)
BaseTree = C.call_ts_parser_parse(p.c, BaseTree, C.int(funcID), C.TSInputEncoding(input.Encoding))
readFuncs.unregister(funcID)
return p.convertTSTree(ctx, BaseTree)
}
// convertTSTree converts the tree-sitter response into a *Tree or an error.
//
// tree-sitter can fail for 3 reasons:
// - cancelation
// - operation limit hit
// - no language set
//
// We check for all those conditions if ther return value is nil.
// see: https://github.com/tree-sitter/tree-sitter/blob/7890a29db0b186b7b21a0a95d99fa6c562b8316b/lib/include/tree_sitter/api.h#L209-L246
func (p *Parser) convertTSTree(ctx context.Context, tsTree *C.TSTree) (*Tree, error) {
if tsTree == nil {
if ctx.Err() != nil {
// reset cancellation flag so the parse can be re-used
atomic.StoreUintptr(p.cancel, 0)
// context cancellation caused a timeout, return that error
return nil, ctx.Err()
}
if C.ts_parser_language(p.c) == nil {
return nil, ErrNoLanguage
}
return nil, ErrOperationLimit
}
return p.newTree(tsTree), nil
}
// OperationLimit returns the duration in microseconds that parsing is allowed to take
func (p *Parser) OperationLimit() int {
return int(C.ts_parser_timeout_micros(p.c))
}
// SetOperationLimit limits the maximum duration in microseconds that parsing should be allowed to take before halting
func (p *Parser) SetOperationLimit(limit int) {
C.ts_parser_set_timeout_micros(p.c, C.uint64_t(limit))
}
// Reset causes the parser to parse from scratch on the next call to parse, instead of resuming
// so that it sees the changes to the beginning of the source code.
func (p *Parser) Reset() {
C.ts_parser_reset(p.c)
}
// SetIncludedRanges sets text ranges of a file
func (p *Parser) SetIncludedRanges(ranges []Range) {
cRanges := make([]C.TSRange, len(ranges))
for i, r := range ranges {
cRanges[i] = C.TSRange{
start_point: C.TSPoint{
row: C.uint32_t(r.StartPoint.Row),
column: C.uint32_t(r.StartPoint.Column),
},
end_point: C.TSPoint{
row: C.uint32_t(r.EndPoint.Row),
column: C.uint32_t(r.EndPoint.Column),
},
start_byte: C.uint32_t(r.StartByte),
end_byte: C.uint32_t(r.EndByte),
}
}
C.ts_parser_set_included_ranges(p.c, (*C.TSRange)(unsafe.Pointer(&cRanges[0])), C.uint(len(ranges)))
}
// Debug enables debug output to stderr
func (p *Parser) Debug() {
logger := C.stderr_logger_new(true)
C.ts_parser_set_logger(p.c, logger)
}
// Close should be called to ensure that all the memory used by the parse is freed.
//
// As the constructor in go-tree-sitter would set this func call through runtime.SetFinalizer,
// parser.Close() will be called by Go's garbage collector and users would not have to call this manually.
func (p *Parser) Close() {
if !p.isClosed {
C.ts_parser_delete(p.c)
}
p.isClosed = true
}
type Point struct {
Row uint32
Column uint32
}
type Range struct {
StartPoint Point
EndPoint Point
StartByte uint32
EndByte uint32
}
// we use cache for nodes on normal tree object
// it prevent run of SetFinalizer as it introduces cycle
// we can workaround it using separate object
// for details see: https://github.com/golang/go/issues/7358#issuecomment-66091558
type BaseTree struct {
c *C.TSTree
isClosed bool
}
// newTree creates a new tree object from a C pointer. The function will set a finalizer for the object,
// thus no free is needed for it.
func (p *Parser) newTree(c *C.TSTree) *Tree {
base := &BaseTree{c: c}
runtime.SetFinalizer(base, (*BaseTree).Close)
newTree := &Tree{p: p, BaseTree: base, cache: make(map[C.TSNode]*Node)}
return newTree
}
// Tree represents the syntax tree of an entire source code file
// Note: Tree instances are not thread safe;
// you must copy a tree if you want to use it on multiple threads simultaneously.
type Tree struct {
*BaseTree
// p is a pointer to a Parser that produced the Tree. Only used to keep Parser alive.
// Otherwise Parser may be GC'ed (and deleted by the finalizer) while some Tree objects are still in use.
p *Parser
// most probably better save node.id
cache map[C.TSNode]*Node
}
// Copy returns a new copy of a tree
func (t *Tree) Copy() *Tree {
return t.p.newTree(C.ts_tree_copy(t.c))
}
// RootNode returns root node of a tree
func (t *Tree) RootNode() *Node {
ptr := C.ts_tree_root_node(t.c)
return t.cachedNode(ptr)
}
func (t *Tree) cachedNode(ptr C.TSNode) *Node {
if ptr.id == nil {
return nil
}
if n, ok := t.cache[ptr]; ok {
return n
}
n := &Node{ptr, t}
t.cache[ptr] = n
return n
}
// Close should be called to ensure that all the memory used by the tree is freed.
//
// As the constructor in go-tree-sitter would set this func call through runtime.SetFinalizer,
// parser.Close() will be called by Go's garbage collector and users would not have to call this manually.
func (t *BaseTree) Close() {
if !t.isClosed {
C.ts_tree_delete(t.c)
}
t.isClosed = true
}
type EditInput struct {
StartIndex uint32
OldEndIndex uint32
NewEndIndex uint32
StartPoint Point
OldEndPoint Point
NewEndPoint Point
}
func (i EditInput) c() *C.TSInputEdit {
return &C.TSInputEdit{
start_byte: C.uint32_t(i.StartIndex),
old_end_byte: C.uint32_t(i.OldEndIndex),
new_end_byte: C.uint32_t(i.NewEndIndex),
start_point: C.TSPoint{
row: C.uint32_t(i.StartPoint.Row),
column: C.uint32_t(i.StartPoint.Column),
},
old_end_point: C.TSPoint{
row: C.uint32_t(i.OldEndPoint.Row),
column: C.uint32_t(i.OldEndPoint.Column),
},
new_end_point: C.TSPoint{
row: C.uint32_t(i.OldEndPoint.Row),
column: C.uint32_t(i.OldEndPoint.Column),
},
}
}
// Edit the syntax tree to keep it in sync with source code that has been edited.
func (t *Tree) Edit(i EditInput) {
C.ts_tree_edit(t.c, i.c())
}
// Language defines how to parse a particular programming language
type Language struct {
ptr unsafe.Pointer
}
// NewLanguage creates new Language from c pointer
func NewLanguage(ptr unsafe.Pointer) *Language {
return &Language{ptr}
}
// SymbolName returns a node type string for the given Symbol.
func (l *Language) SymbolName(s Symbol) string {
return C.GoString(C.ts_language_symbol_name((*C.TSLanguage)(l.ptr), s))
}
// SymbolType returns named, anonymous, or a hidden type for a Symbol.
func (l *Language) SymbolType(s Symbol) SymbolType {
return SymbolType(C.ts_language_symbol_type((*C.TSLanguage)(l.ptr), s))
}
// SymbolCount returns the number of distinct field names in the language.
func (l *Language) SymbolCount() uint32 {
return uint32(C.ts_language_symbol_count((*C.TSLanguage)(l.ptr)))
}
func (l *Language) FieldName(idx int) string {
return C.GoString(C.ts_language_field_name_for_id((*C.TSLanguage)(l.ptr), C.ushort(idx)))
}
// Node represents a single node in the syntax tree
// It tracks its start and end positions in the source code,
// as well as its relation to other nodes like its parent, siblings and children.
type Node struct {
c C.TSNode
t *Tree // keep pointer on tree because node is valid only as long as tree is
}
type Symbol = C.TSSymbol
type SymbolType int
const (
SymbolTypeRegular SymbolType = iota
SymbolTypeAnonymous
SymbolTypeAuxiliary
)
var symbolTypeNames = []string{
"Regular",
"Anonymous",
"Auxiliary",
}
func (t SymbolType) String() string {
return symbolTypeNames[t]
}
// StartByte returns the node's start byte.
func (n Node) StartByte() uint32 {
return uint32(C.ts_node_start_byte(n.c))
}
// EndByte returns the node's end byte.
func (n Node) EndByte() uint32 {
return uint32(C.ts_node_end_byte(n.c))
}
// StartPoint returns the node's start position in terms of rows and columns.
func (n Node) StartPoint() Point {
p := C.ts_node_start_point(n.c)
return Point{
Row: uint32(p.row),
Column: uint32(p.column),
}
}
// EndPoint returns the node's end position in terms of rows and columns.
func (n Node) EndPoint() Point {
p := C.ts_node_end_point(n.c)
return Point{
Row: uint32(p.row),
Column: uint32(p.column),
}
}
// Symbol returns the node's type as a Symbol.
func (n Node) Symbol() Symbol {
return C.ts_node_symbol(n.c)
}
// Type returns the node's type as a string.
func (n Node) Type() string {
return C.GoString(C.ts_node_type(n.c))
}
// String returns an S-expression representing the node as a string.
func (n Node) String() string {
ptr := C.ts_node_string(n.c)
defer C.free(unsafe.Pointer(ptr))
return C.GoString(ptr)
}
// Equal checks if two nodes are identical.
func (n Node) Equal(other *Node) bool {
return bool(C.ts_node_eq(n.c, other.c))
}
// IsNull checks if the node is null.
func (n Node) IsNull() bool {
return bool(C.ts_node_is_null(n.c))
}
// IsNamed checks if the node is *named*.
// Named nodes correspond to named rules in the grammar,
// whereas *anonymous* nodes correspond to string literals in the grammar.
func (n Node) IsNamed() bool {
return bool(C.ts_node_is_named(n.c))
}
// IsMissing checks if the node is *missing*.
// Missing nodes are inserted by the parser in order to recover from certain kinds of syntax errors.
func (n Node) IsMissing() bool {
return bool(C.ts_node_is_missing(n.c))
}
// IsExtra checks if the node is *extra*.
// Extra nodes represent things like comments, which are not required the grammar, but can appear anywhere.
func (n Node) IsExtra() bool {
return bool(C.ts_node_is_extra(n.c))
}
// IsError checks if the node is a syntax error.
// Syntax errors represent parts of the code that could not be incorporated into a valid syntax tree.
func (n Node) IsError() bool {
return n.Symbol() == math.MaxUint16
}
// HasChanges checks if a syntax node has been edited.
func (n Node) HasChanges() bool {
return bool(C.ts_node_has_changes(n.c))
}
// HasError check if the node is a syntax error or contains any syntax errors.
func (n Node) HasError() bool {
return bool(C.ts_node_has_error(n.c))
}
// Parent returns the node's immediate parent.
func (n Node) Parent() *Node {
nn := C.ts_node_parent(n.c)
return n.t.cachedNode(nn)
}
// Child returns the node's child at the given index, where zero represents the first child.
func (n Node) Child(idx int) *Node {
nn := C.ts_node_child(n.c, C.uint32_t(idx))
return n.t.cachedNode(nn)
}
// NamedChild returns the node's *named* child at the given index.
func (n Node) NamedChild(idx int) *Node {
nn := C.ts_node_named_child(n.c, C.uint32_t(idx))
return n.t.cachedNode(nn)
}
// ChildCount returns the node's number of children.
func (n Node) ChildCount() uint32 {
return uint32(C.ts_node_child_count(n.c))
}
// NamedChildCount returns the node's number of *named* children.
func (n Node) NamedChildCount() uint32 {
return uint32(C.ts_node_named_child_count(n.c))
}
// ChildByFieldName returns the node's child with the given field name.
func (n Node) ChildByFieldName(name string) *Node {
str := C.CString(name)
defer C.free(unsafe.Pointer(str))
nn := C.ts_node_child_by_field_name(n.c, str, C.uint32_t(len(name)))
return n.t.cachedNode(nn)
}
// FieldNameForChild returns the field name of the child at the given index, or "" if not named.
func (n Node) FieldNameForChild(idx int) string {
return C.GoString(C.ts_node_field_name_for_child(n.c, C.uint32_t(idx)))
}
// NextSibling returns the node's next sibling.
func (n Node) NextSibling() *Node {
nn := C.ts_node_next_sibling(n.c)
return n.t.cachedNode(nn)
}
// NextNamedSibling returns the node's next *named* sibling.
func (n Node) NextNamedSibling() *Node {
nn := C.ts_node_next_named_sibling(n.c)
return n.t.cachedNode(nn)
}
// PrevSibling returns the node's previous sibling.
func (n Node) PrevSibling() *Node {
nn := C.ts_node_prev_sibling(n.c)
return n.t.cachedNode(nn)
}
// PrevNamedSibling returns the node's previous *named* sibling.
func (n Node) PrevNamedSibling() *Node {
nn := C.ts_node_prev_named_sibling(n.c)
return n.t.cachedNode(nn)
}
// Edit the node to keep it in-sync with source code that has been edited.
func (n Node) Edit(i EditInput) {
C.ts_node_edit(&n.c, i.c())
}
// Content returns node's source code from input as a string
func (n Node) Content(input []byte) string {
return string(input[n.StartByte():n.EndByte()])
}
func (n Node) NamedDescendantForPointRange(start Point, end Point) *Node {
cStartPoint := C.TSPoint{
row: C.uint32_t(start.Row),
column: C.uint32_t(start.Column),
}
cEndPoint := C.TSPoint{
row: C.uint32_t(end.Row),
column: C.uint32_t(end.Column),
}
nn := C.ts_node_named_descendant_for_point_range(n.c, cStartPoint, cEndPoint)
return n.t.cachedNode(nn)
}
// TreeCursor allows you to walk a syntax tree more efficiently than is
// possible using the `Node` functions. It is a mutable object that is always
// on a certain syntax node, and can be moved imperatively to different nodes.
type TreeCursor struct {
c *C.TSTreeCursor
t *Tree
isClosed bool
}
// NewTreeCursor creates a new tree cursor starting from the given node.
func NewTreeCursor(n *Node) *TreeCursor {
cc := C.ts_tree_cursor_new(n.c)
c := &TreeCursor{
c: &cc,
t: n.t,
}
runtime.SetFinalizer(c, (*TreeCursor).Close)
return c
}
// Close should be called to ensure that all the memory used by the tree cursor
// is freed.
//
// As the constructor in go-tree-sitter would set this func call through runtime.SetFinalizer,
// parser.Close() will be called by Go's garbage collector and users would not have to call this manually.
func (c *TreeCursor) Close() {
if !c.isClosed {
C.ts_tree_cursor_delete(c.c)
}
c.isClosed = true
}
// Reset re-initializes a tree cursor to start at a different node.
func (c *TreeCursor) Reset(n *Node) {
c.t = n.t
C.ts_tree_cursor_reset(c.c, n.c)
}
// CurrentNode of the tree cursor.
func (c *TreeCursor) CurrentNode() *Node {
n := C.ts_tree_cursor_current_node(c.c)
return c.t.cachedNode(n)
}
// CurrentFieldName gets the field name of the tree cursor's current node.
//
// This returns empty string if the current node doesn't have a field.
func (c *TreeCursor) CurrentFieldName() string {
return C.GoString(C.ts_tree_cursor_current_field_name(c.c))
}
// GoToParent moves the cursor to the parent of its current node.
//
// This returns `true` if the cursor successfully moved, and returns `false`
// if there was no parent node (the cursor was already on the root node).
func (c *TreeCursor) GoToParent() bool {
return bool(C.ts_tree_cursor_goto_parent(c.c))
}
// GoToNextSibling moves the cursor to the next sibling of its current node.
//
// This returns `true` if the cursor successfully moved, and returns `false`
// if there was no next sibling node.
func (c *TreeCursor) GoToNextSibling() bool {
return bool(C.ts_tree_cursor_goto_next_sibling(c.c))
}
// GoToFirstChild moves the cursor to the first child of its current node.
//
// This returns `true` if the cursor successfully moved, and returns `false`
// if there were no children.
func (c *TreeCursor) GoToFirstChild() bool {
return bool(C.ts_tree_cursor_goto_first_child(c.c))
}
// GoToFirstChildForByte moves the cursor to the first child of its current node
// that extends beyond the given byte offset.
//
// This returns the index of the child node if one was found, and returns -1
// if no such child was found.
func (c *TreeCursor) GoToFirstChildForByte(b uint32) int64 {
return int64(C.ts_tree_cursor_goto_first_child_for_byte(c.c, C.uint32_t(b)))
}
// QueryErrorType - value that indicates the type of QueryError.
type QueryErrorType int
const (
QueryErrorNone QueryErrorType = iota
QueryErrorSyntax
QueryErrorNodeType
QueryErrorField
QueryErrorCapture
QueryErrorStructure
QueryErrorLanguage
)
func QueryErrorTypeToString(errorType QueryErrorType) string {
switch errorType {
case QueryErrorNone:
return "none"
case QueryErrorNodeType:
return "node type"
case QueryErrorField:
return "field"
case QueryErrorCapture:
return "capture"
case QueryErrorSyntax:
return "syntax"
default:
return "unknown"
}
}
// QueryError - if there is an error in the query,
// then the Offset argument will be set to the byte offset of the error,
// and the Type argument will be set to a value that indicates the type of error.
type QueryError struct {
Offset uint32
Type QueryErrorType
Message string
}
func (qe *QueryError) Error() string {
return qe.Message
}
// Query API
type Query struct {
c *C.TSQuery
isClosed bool
}
// NewQuery creates a query by specifying a string containing one or more patterns.
// In case of error returns QueryError.
func NewQuery(pattern []byte, lang *Language) (*Query, error) {
var (
erroff C.uint32_t
errtype C.TSQueryError
)
input := C.CBytes(pattern)
c := C.ts_query_new(
(*C.struct_TSLanguage)(lang.ptr),
(*C.char)(input),
C.uint32_t(len(pattern)),
&erroff,
&errtype,
)
C.free(input)
if errtype != C.TSQueryError(QueryErrorNone) {
errorOffset := uint32(erroff)
// search for the line containing the offset
line := 1
line_start := 0
for i, c := range pattern {
line_start = i
if uint32(i) >= errorOffset {
break
}
if c == '\n' {
line++
}
}
column := int(errorOffset) - line_start
errorType := QueryErrorType(errtype)
errorTypeToString := QueryErrorTypeToString(errorType)
var message string
switch errorType {
// errors that apply to a single identifier
case QueryErrorNodeType:
fallthrough
case QueryErrorField:
fallthrough
case QueryErrorCapture:
// find identifier at input[errorOffset]
// and report it in the error message
s := string(pattern[errorOffset:])
identifierRegexp := regexp.MustCompile(`^[a-zA-Z_][a-zA-Z0-9_-]*`)
m := identifierRegexp.FindStringSubmatch(s)
if len(m) > 0 {
message = fmt.Sprintf("invalid %s '%s' at line %d column %d",
errorTypeToString, m[0], line, column)
} else {
message = fmt.Sprintf("invalid %s at line %d column %d",
errorTypeToString, line, column)
}
// errors the report position
case QueryErrorSyntax:
fallthrough
case QueryErrorStructure:
fallthrough
case QueryErrorLanguage:
fallthrough
default:
s := string(pattern[errorOffset:])
lines := strings.Split(s, "\n")
whitespace := strings.Repeat(" ", column)
message = fmt.Sprintf("invalid %s at line %d column %d\n%s\n%s^",
errorTypeToString, line, column,
lines[0], whitespace)
}
return nil, &QueryError{
Offset: errorOffset,
Type: errorType,
Message: message,
}
}
q := &Query{c: c}
// Copied from: https://github.com/klothoplatform/go-tree-sitter/commit/e351b20167b26d515627a4a1a884528ede5fef79
// this is just used for syntax validation - it does not actually filter anything
for i := uint32(0); i < q.PatternCount(); i++ {
predicates := q.PredicatesForPattern(i)
for _, steps := range predicates {
if len(steps) == 0 {
continue
}
if steps[0].Type != QueryPredicateStepTypeString {
return nil, errors.New("predicate must begin with a literal value")
}
operator := q.StringValueForId(steps[0].ValueId)
switch operator {
case "eq?", "not-eq?":
if len(steps) != 4 {
return nil, fmt.Errorf("wrong number of arguments to `#%s` predicate. Expected 2, got %d", operator, len(steps)-2)
}
if steps[1].Type != QueryPredicateStepTypeCapture {
return nil, fmt.Errorf("first argument of `#%s` predicate must be a capture. Got %s", operator, q.StringValueForId(steps[1].ValueId))
}
case "match?", "not-match?":
if len(steps) != 4 {
return nil, fmt.Errorf("wrong number of arguments to `#%s` predicate. Expected 2, got %d", operator, len(steps)-2)
}
if steps[1].Type != QueryPredicateStepTypeCapture {
return nil, fmt.Errorf("first argument of `#%s` predicate must be a capture. Got %s", operator, q.StringValueForId(steps[1].ValueId))
}
if steps[2].Type != QueryPredicateStepTypeString {
return nil, fmt.Errorf("second argument of `#%s` predicate must be a string. Got %s", operator, q.StringValueForId(steps[2].ValueId))
}
case "set!", "is?", "is-not?":
if len(steps) < 3 || len(steps) > 4 {
return nil, fmt.Errorf("wrong number of arguments to `#%s` predicate. Expected 1 or 2, got %d", operator, len(steps)-2)
}
if steps[1].Type != QueryPredicateStepTypeString {
return nil, fmt.Errorf("first argument of `#%s` predicate must be a string. Got %s", operator, q.StringValueForId(steps[1].ValueId))
}
if len(steps) > 2 && steps[2].Type != QueryPredicateStepTypeString {
return nil, fmt.Errorf("second argument of `#%s` predicate must be a string. Got %s", operator, q.StringValueForId(steps[2].ValueId))
}
}
}
}
runtime.SetFinalizer(q, (*Query).Close)
return q, nil
}
// Close should be called to ensure that all the memory used by the query is freed.
//
// As the constructor in go-tree-sitter would set this func call through runtime.SetFinalizer,
// parser.Close() will be called by Go's garbage collector and users would not have to call this manually.
func (q *Query) Close() {
if !q.isClosed {
C.ts_query_delete(q.c)
}
q.isClosed = true
}
func (q *Query) PatternCount() uint32 {
return uint32(C.ts_query_pattern_count(q.c))
}
func (q *Query) CaptureCount() uint32 {
return uint32(C.ts_query_capture_count(q.c))
}
func (q *Query) StringCount() uint32 {
return uint32(C.ts_query_string_count(q.c))
}
type QueryPredicateStepType int
const (
QueryPredicateStepTypeDone QueryPredicateStepType = iota
QueryPredicateStepTypeCapture
QueryPredicateStepTypeString
)
type QueryPredicateStep struct {
Type QueryPredicateStepType
ValueId uint32
}
func (q *Query) PredicatesForPattern(patternIndex uint32) [][]QueryPredicateStep {
var (
length C.uint32_t
cPredicateSteps []C.TSQueryPredicateStep
predicateSteps []QueryPredicateStep
)
cPredicateStep := C.ts_query_predicates_for_pattern(q.c, C.uint32_t(patternIndex), &length)
count := int(length)
slice := (*reflect.SliceHeader)((unsafe.Pointer(&cPredicateSteps)))
slice.Cap = count
slice.Len = count
slice.Data = uintptr(unsafe.Pointer(cPredicateStep))
for _, s := range cPredicateSteps {
stepType := QueryPredicateStepType(s._type)
valueId := uint32(s.value_id)
predicateSteps = append(predicateSteps, QueryPredicateStep{stepType, valueId})
}
return splitPredicates(predicateSteps)
}
func (q *Query) CaptureNameForId(id uint32) string {
var length C.uint32_t
name := C.ts_query_capture_name_for_id(q.c, C.uint32_t(id), &length)
return C.GoStringN(name, C.int(length))
}
func (q *Query) StringValueForId(id uint32) string {
var length C.uint32_t
value := C.ts_query_string_value_for_id(q.c, C.uint32_t(id), &length)
return C.GoStringN(value, C.int(length))
}
type Quantifier int
const (
QuantifierZero = iota
QuantifierZeroOrOne
QuantifierZeroOrMore
QuantifierOne
QuantifierOneOrMore
)
func (q *Query) CaptureQuantifierForId(id uint32, captureId uint32) Quantifier {
return Quantifier(C.ts_query_capture_quantifier_for_id(q.c, C.uint32_t(id), C.uint32_t(captureId)))
}
// QueryCursor carries the state needed for processing the queries.
type QueryCursor struct {
c *C.TSQueryCursor
t *Tree
// keep a pointer to the query to avoid garbage collection
q *Query
isClosed bool
}
// NewQueryCursor creates a query cursor.
func NewQueryCursor() *QueryCursor {
qc := &QueryCursor{c: C.ts_query_cursor_new(), t: nil}
runtime.SetFinalizer(qc, (*QueryCursor).Close)
return qc
}
// Exec executes the query on a given syntax node.
func (qc *QueryCursor) Exec(q *Query, n *Node) {
qc.q = q
qc.t = n.t
C.ts_query_cursor_exec(qc.c, q.c, n.c)
}
func (qc *QueryCursor) SetPointRange(startPoint Point, endPoint Point) {
cStartPoint := C.TSPoint{
row: C.uint32_t(startPoint.Row),
column: C.uint32_t(startPoint.Column),
}
cEndPoint := C.TSPoint{
row: C.uint32_t(endPoint.Row),
column: C.uint32_t(endPoint.Column),
}
C.ts_query_cursor_set_point_range(qc.c, cStartPoint, cEndPoint)
}
// Close should be called to ensure that all the memory used by the query cursor is freed.
//
// As the constructor in go-tree-sitter would set this func call through runtime.SetFinalizer,
// parser.Close() will be called by Go's garbage collector and users would not have to call this manually.
func (qc *QueryCursor) Close() {
if !qc.isClosed {
C.ts_query_cursor_delete(qc.c)
}
qc.isClosed = true
}
// QueryCapture is a captured node by a query with an index
type QueryCapture struct {
Index uint32
Node *Node
}
// QueryMatch - you can then iterate over the matches.
type QueryMatch struct {
ID uint32
PatternIndex uint16
Captures []QueryCapture