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package participle
import (
"errors"
"fmt"
"reflect"
"strconv"
"strings"
"github.com/alecthomas/participle/lexer"
)
var (
// MaxIterations limits the number of elements capturable by {}.
MaxIterations = 1000000
positionType = reflect.TypeOf(lexer.Position{})
captureType = reflect.TypeOf((*Capture)(nil)).Elem()
parseableType = reflect.TypeOf((*Parseable)(nil)).Elem()
// NextMatch should be returned by Parseable.Parse() method implementations to indicate
// that the node did not match and that other matches should be attempted, if appropriate.
NextMatch = errors.New("no match") // nolint: golint
)
// A node in the grammar.
type node interface {
// Parse from scanner into value.
//
// Returned slice will be nil if the node does not match.
Parse(ctx *parseContext, parent reflect.Value) ([]reflect.Value, error)
// Return a decent string representation of the Node.
String() string
}
func decorate(err *error, name func() string) {
if *err == nil {
return
}
switch realError := (*err).(type) {
case *lexer.Error:
*err = &lexer.Error{Message: name() + ": " + realError.Message, Pos: realError.Pos}
default:
*err = fmt.Errorf("%s: %s", name(), realError)
}
}
// A node that proxies to an implementation that implements the Parseable interface.
type parseable struct {
t reflect.Type
}
func (p *parseable) String() string { return stringer(p) }
func (p *parseable) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
rv := reflect.New(p.t)
v := rv.Interface().(Parseable)
err = v.Parse(ctx)
if err != nil {
if err == NextMatch {
return nil, nil
}
return nil, err
}
return []reflect.Value{rv.Elem()}, nil
}
type strct struct {
typ reflect.Type
expr node
}
func (s *strct) String() string { return stringer(s) }
func (s *strct) maybeInjectPos(pos lexer.Position, v reflect.Value) {
if f := v.FieldByName("Pos"); f.IsValid() && f.Type() == positionType {
f.Set(reflect.ValueOf(pos))
}
}
func (s *strct) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
sv := reflect.New(s.typ).Elem()
t, err := ctx.Peek(0)
if err != nil {
return nil, err
}
s.maybeInjectPos(t.Pos, sv)
if out, err = s.expr.Parse(ctx, sv); err != nil {
_ = ctx.Apply()
return []reflect.Value{sv}, err
} else if out == nil {
return nil, nil
}
return []reflect.Value{sv}, ctx.Apply()
}
type groupMatchMode int
const (
groupMatchOnce groupMatchMode = iota
groupMatchZeroOrOne = iota
groupMatchZeroOrMore = iota
groupMatchOneOrMore = iota
groupMatchNonEmpty = iota
)
// ( <expr> ) - match once
// ( <expr> )* - match zero or more times
// ( <expr> )+ - match one or more times
// ( <expr> )? - match zero or once
// ( <expr> )! - must be a non-empty match
//
// The additional modifier "!" forces the content of the group to be non-empty if it does match.
type group struct {
expr node
mode groupMatchMode
}
func (g *group) String() string { return stringer(g) }
func (g *group) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
// Configure min/max matches.
min := 1
max := 1
switch g.mode {
case groupMatchNonEmpty:
out, err = g.expr.Parse(ctx, parent)
if err != nil {
return out, err
}
if len(out) == 0 {
t, _ := ctx.Peek(0)
return out, lexer.Errorf(t.Pos, "sub-expression %s cannot be empty", g)
}
return out, nil
case groupMatchOnce:
return g.expr.Parse(ctx, parent)
case groupMatchZeroOrOne:
min = 0
case groupMatchZeroOrMore:
min = 0
max = MaxIterations
case groupMatchOneOrMore:
min = 1
max = MaxIterations
}
matches := 0
for ; matches < max; matches++ {
branch := ctx.Branch()
v, err := g.expr.Parse(branch, parent)
out = append(out, v...)
if err != nil {
// Optional part failed to match.
if ctx.Stop(branch) {
return out, err
}
break
} else {
ctx.Accept(branch)
}
if v == nil {
break
}
}
// fmt.Printf("%d < %d < %d: out == nil? %v\n", min, matches, max, out == nil)
t, _ := ctx.Peek(0)
if matches >= MaxIterations {
panic(lexer.Errorf(t.Pos, "too many iterations of %s (> %d)", g, MaxIterations))
}
if matches < min {
return out, lexer.Errorf(t.Pos, "sub-expression %s must match at least once", g)
}
// The idea here is that something like "a"? is a successful match and that parsing should proceed.
if min == 0 && out == nil {
out = []reflect.Value{}
}
return out, nil
}
// <expr> {"|" <expr>}
type disjunction struct {
nodes []node
}
func (d *disjunction) String() string { return stringer(d) }
func (d *disjunction) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
var (
deepestError = 0
firstError error
firstValues []reflect.Value
)
for _, a := range d.nodes {
branch := ctx.Branch()
if value, err := a.Parse(branch, parent); err != nil {
// If this branch progressed too far and still didn't match, error out.
if ctx.Stop(branch) {
return value, err
}
// Show the closest error returned. The idea here is that the further the parser progresses
// without error, the more difficult it is to trace the error back to its root.
if err != nil && branch.cursor >= deepestError {
firstError = err
firstValues = value
deepestError = branch.cursor
}
} else if value != nil {
ctx.Accept(branch)
return value, nil
}
}
if firstError != nil {
return firstValues, firstError
}
return nil, nil
}
// <node> ...
type sequence struct {
head bool
node node
next *sequence
}
func (s *sequence) String() string { return stringer(s) }
func (s *sequence) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
for n := s; n != nil; n = n.next {
child, err := n.node.Parse(ctx, parent)
out = append(out, child...)
if err != nil {
return out, err
}
if child == nil {
// Early exit if first value doesn't match, otherwise all values must match.
if n == s {
return nil, nil
}
token, err := ctx.Peek(0)
if err != nil {
return nil, err
}
return out, lexer.Errorf(token.Pos, "unexpected %q (expected %s)", token, n)
}
}
return out, nil
}
// @<expr>
type capture struct {
field structLexerField
node node
}
func (c *capture) String() string { return stringer(c) }
func (c *capture) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
token, err := ctx.Peek(0)
if err != nil {
return nil, err
}
pos := token.Pos
v, err := c.node.Parse(ctx, parent)
if err != nil {
if v != nil {
ctx.Defer(pos, parent, c.field, v)
}
return []reflect.Value{parent}, err
}
if v == nil {
return nil, nil
}
ctx.Defer(pos, parent, c.field, v)
return []reflect.Value{parent}, nil
}
// <identifier> - named lexer token reference
type reference struct {
typ rune
identifier string // Used for informational purposes.
}
func (r *reference) String() string { return stringer(r) }
func (r *reference) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
token, err := ctx.Peek(0)
if err != nil {
return nil, err
}
if token.Type != r.typ {
return nil, nil
}
_, _ = ctx.Next()
return []reflect.Value{reflect.ValueOf(token.Value)}, nil
}
// [ <expr> ] <sequence>
type optional struct {
node node
}
func (o *optional) String() string { return stringer(o) }
func (o *optional) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
branch := ctx.Branch()
out, err = o.node.Parse(branch, parent)
if err != nil {
// Optional part failed to match.
if ctx.Stop(branch) {
return out, err
}
} else {
ctx.Accept(branch)
}
if out == nil {
out = []reflect.Value{}
}
return out, nil
}
// { <expr> } <sequence>
type repetition struct {
node node
}
func (r *repetition) String() string { return stringer(r) }
// Parse a repetition. Once a repetition is encountered it will always match, so grammars
// should ensure that branches are differentiated prior to the repetition.
func (r *repetition) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
i := 0
for ; i < MaxIterations; i++ {
branch := ctx.Branch()
v, err := r.node.Parse(branch, parent)
out = append(out, v...)
if err != nil {
// Optional part failed to match.
if ctx.Stop(branch) {
return out, err
}
break
} else {
ctx.Accept(branch)
}
if v == nil {
break
}
}
if i >= MaxIterations {
t, _ := ctx.Peek(0)
panic(lexer.Errorf(t.Pos, "too many iterations of %s (> %d)", r, MaxIterations))
}
if out == nil {
out = []reflect.Value{}
}
return out, nil
}
// Match a token literal exactly "..."[:<type>].
type literal struct {
s string
t rune
tt string // Used for display purposes - symbolic name of t.
}
func (l *literal) String() string { return stringer(l) }
func (l *literal) Parse(ctx *parseContext, parent reflect.Value) (out []reflect.Value, err error) {
token, err := ctx.Peek(0)
if err != nil {
return nil, err
}
equal := false // nolint: ineffassign
if ctx.caseInsensitive[token.Type] {
equal = strings.EqualFold(token.Value, l.s)
} else {
equal = token.Value == l.s
}
if equal && (l.t == -1 || l.t == token.Type) {
next, err := ctx.Next()
if err != nil {
return nil, err
}
return []reflect.Value{reflect.ValueOf(next.Value)}, nil
}
return nil, nil
}
// Attempt to transform values to given type.
//
// This will dereference pointers, and attempt to parse strings into integer values, floats, etc.
func conform(t reflect.Type, values []reflect.Value) (out []reflect.Value, err error) {
for _, v := range values {
for t != v.Type() && t.Kind() == reflect.Ptr && v.Kind() != reflect.Ptr {
// This can occur during partial failure.
if !v.CanAddr() {
return
}
v = v.Addr()
}
// Already of the right kind, don't bother converting.
if v.Kind() == t.Kind() {
out = append(out, v)
continue
}
kind := t.Kind()
switch kind {
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
n, err := strconv.ParseInt(v.String(), 0, sizeOfKind(kind))
if err != nil {
return nil, fmt.Errorf("invalid integer %q: %s", v.String(), err)
}
v = reflect.New(t).Elem()
v.SetInt(n)
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64:
n, err := strconv.ParseUint(v.String(), 0, sizeOfKind(kind))
if err != nil {
return nil, fmt.Errorf("invalid integer %q: %s", v.String(), err)
}
v = reflect.New(t).Elem()
v.SetUint(n)
case reflect.Bool:
v = reflect.ValueOf(true)
case reflect.Float32, reflect.Float64:
n, err := strconv.ParseFloat(v.String(), sizeOfKind(kind))
if err != nil {
return nil, fmt.Errorf("invalid integer %q: %s", v.String(), err)
}
v = reflect.New(t).Elem()
v.SetFloat(n)
}
out = append(out, v)
}
return out, nil
}
func sizeOfKind(kind reflect.Kind) int {
switch kind {
case reflect.Int8, reflect.Uint8:
return 8
case reflect.Int16, reflect.Uint16:
return 16
case reflect.Int32, reflect.Uint32, reflect.Float32:
return 32
case reflect.Int64, reflect.Uint64, reflect.Float64:
return 64
case reflect.Int, reflect.Uint:
return strconv.IntSize
}
panic("unsupported kind " + kind.String())
}
// Set field.
//
// If field is a pointer the pointer will be set to the value. If field is a string, value will be
// appended. If field is a slice, value will be appended to slice.
//
// For all other types, an attempt will be made to convert the string to the corresponding
// type (int, float32, etc.).
func setField(pos lexer.Position, strct reflect.Value, field structLexerField, fieldValue []reflect.Value) (err error) { // nolint: gocyclo
defer decorate(&err, func() string { return pos.String() + ": " + strct.Type().String() + "." + field.Name })
f := strct.FieldByIndex(field.Index)
switch f.Kind() {
case reflect.Slice:
fieldValue, err = conform(f.Type().Elem(), fieldValue)
if err != nil {
return err
}
f.Set(reflect.Append(f, fieldValue...))
return nil
case reflect.Ptr:
if f.IsNil() {
fv := reflect.New(f.Type().Elem()).Elem()
f.Set(fv.Addr())
f = fv
} else {
f = f.Elem()
}
}
if f.Kind() == reflect.Struct {
if pf := f.FieldByName("Pos"); pf.IsValid() && pf.Type() == positionType {
pf.Set(reflect.ValueOf(pos))
}
}
if f.CanAddr() {
if d, ok := f.Addr().Interface().(Capture); ok {
ifv := []string{}
for _, v := range fieldValue {
ifv = append(ifv, v.Interface().(string))
}
err := d.Capture(ifv)
if err != nil {
return err
}
return nil
}
}
// Strings concatenate all captured tokens.
if f.Kind() == reflect.String {
fieldValue, err = conform(f.Type(), fieldValue)
if err != nil {
return err
}
for _, v := range fieldValue {
f.Set(reflect.ValueOf(f.String() + v.String()).Convert(f.Type()))
}
return nil
}
// Coalesce multiple tokens into one. This allows eg. ["-", "10"] to be captured as separate tokens but
// parsed as a single string "-10".
if len(fieldValue) > 1 {
out := []string{}
for _, v := range fieldValue {
out = append(out, v.String())
}
fieldValue = []reflect.Value{reflect.ValueOf(strings.Join(out, ""))}
}
fieldValue, err = conform(f.Type(), fieldValue)
if err != nil {
return err
}
fv := fieldValue[0]
switch f.Kind() {
// Numeric types will increment if the token can not be coerced.
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
if fv.Type() != f.Type() {
f.SetInt(f.Int() + 1)
} else {
f.Set(fv)
}
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64:
if fv.Type() != f.Type() {
f.SetUint(f.Uint() + 1)
} else {
f.Set(fv)
}
case reflect.Float32, reflect.Float64:
if fv.Type() != f.Type() {
f.SetFloat(f.Float() + 1)
} else {
f.Set(fv)
}
case reflect.Bool, reflect.Struct:
if fv.Type() != f.Type() {
return fmt.Errorf("value %q is not correct type %s", fv, f.Type())
}
f.Set(fv)
default:
return fmt.Errorf("unsupported field type %s for field %s", f.Type(), field.Name)
}
return nil
}
// Error is an error returned by the parser internally to differentiate from non-Participle errors.
type Error string
func (e Error) Error() string { return string(e) }