mirror of
https://github.com/cheat/cheat.git
synced 2024-11-27 08:21:36 +01:00
348 lines
8.6 KiB
Go
348 lines
8.6 KiB
Go
package regexp2
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import (
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"bytes"
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"fmt"
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)
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// Match is a single regex result match that contains groups and repeated captures
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// -Groups
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// -Capture
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type Match struct {
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Group //embeded group 0
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regex *Regexp
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otherGroups []Group
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// input to the match
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textpos int
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textstart int
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capcount int
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caps []int
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sparseCaps map[int]int
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// output from the match
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matches [][]int
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matchcount []int
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// whether we've done any balancing with this match. If we
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// have done balancing, we'll need to do extra work in Tidy().
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balancing bool
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}
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// Group is an explicit or implit (group 0) matched group within the pattern
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type Group struct {
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Capture // the last capture of this group is embeded for ease of use
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Name string // group name
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Captures []Capture // captures of this group
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}
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// Capture is a single capture of text within the larger original string
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type Capture struct {
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// the original string
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text []rune
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// the position in the original string where the first character of
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// captured substring was found.
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Index int
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// the length of the captured substring.
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Length int
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}
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// String returns the captured text as a String
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func (c *Capture) String() string {
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return string(c.text[c.Index : c.Index+c.Length])
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}
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// Runes returns the captured text as a rune slice
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func (c *Capture) Runes() []rune {
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return c.text[c.Index : c.Index+c.Length]
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}
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func newMatch(regex *Regexp, capcount int, text []rune, startpos int) *Match {
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m := Match{
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regex: regex,
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matchcount: make([]int, capcount),
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matches: make([][]int, capcount),
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textstart: startpos,
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balancing: false,
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}
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m.Name = "0"
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m.text = text
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m.matches[0] = make([]int, 2)
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return &m
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}
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func newMatchSparse(regex *Regexp, caps map[int]int, capcount int, text []rune, startpos int) *Match {
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m := newMatch(regex, capcount, text, startpos)
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m.sparseCaps = caps
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return m
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}
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func (m *Match) reset(text []rune, textstart int) {
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m.text = text
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m.textstart = textstart
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for i := 0; i < len(m.matchcount); i++ {
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m.matchcount[i] = 0
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}
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m.balancing = false
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}
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func (m *Match) tidy(textpos int) {
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interval := m.matches[0]
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m.Index = interval[0]
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m.Length = interval[1]
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m.textpos = textpos
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m.capcount = m.matchcount[0]
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//copy our root capture to the list
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m.Group.Captures = []Capture{m.Group.Capture}
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if m.balancing {
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// The idea here is that we want to compact all of our unbalanced captures. To do that we
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// use j basically as a count of how many unbalanced captures we have at any given time
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// (really j is an index, but j/2 is the count). First we skip past all of the real captures
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// until we find a balance captures. Then we check each subsequent entry. If it's a balance
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// capture (it's negative), we decrement j. If it's a real capture, we increment j and copy
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// it down to the last free position.
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for cap := 0; cap < len(m.matchcount); cap++ {
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limit := m.matchcount[cap] * 2
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matcharray := m.matches[cap]
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var i, j int
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for i = 0; i < limit; i++ {
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if matcharray[i] < 0 {
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break
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}
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}
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for j = i; i < limit; i++ {
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if matcharray[i] < 0 {
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// skip negative values
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j--
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} else {
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// but if we find something positive (an actual capture), copy it back to the last
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// unbalanced position.
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if i != j {
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matcharray[j] = matcharray[i]
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}
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j++
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}
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}
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m.matchcount[cap] = j / 2
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}
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m.balancing = false
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}
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}
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// isMatched tells if a group was matched by capnum
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func (m *Match) isMatched(cap int) bool {
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return cap < len(m.matchcount) && m.matchcount[cap] > 0 && m.matches[cap][m.matchcount[cap]*2-1] != (-3+1)
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}
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// matchIndex returns the index of the last specified matched group by capnum
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func (m *Match) matchIndex(cap int) int {
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i := m.matches[cap][m.matchcount[cap]*2-2]
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if i >= 0 {
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return i
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}
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return m.matches[cap][-3-i]
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}
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// matchLength returns the length of the last specified matched group by capnum
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func (m *Match) matchLength(cap int) int {
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i := m.matches[cap][m.matchcount[cap]*2-1]
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if i >= 0 {
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return i
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}
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return m.matches[cap][-3-i]
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}
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// Nonpublic builder: add a capture to the group specified by "c"
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func (m *Match) addMatch(c, start, l int) {
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if m.matches[c] == nil {
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m.matches[c] = make([]int, 2)
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}
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capcount := m.matchcount[c]
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if capcount*2+2 > len(m.matches[c]) {
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oldmatches := m.matches[c]
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newmatches := make([]int, capcount*8)
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copy(newmatches, oldmatches[:capcount*2])
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m.matches[c] = newmatches
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}
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m.matches[c][capcount*2] = start
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m.matches[c][capcount*2+1] = l
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m.matchcount[c] = capcount + 1
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//log.Printf("addMatch: c=%v, i=%v, l=%v ... matches: %v", c, start, l, m.matches)
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}
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// Nonpublic builder: Add a capture to balance the specified group. This is used by the
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// balanced match construct. (?<foo-foo2>...)
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//
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// If there were no such thing as backtracking, this would be as simple as calling RemoveMatch(c).
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// However, since we have backtracking, we need to keep track of everything.
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func (m *Match) balanceMatch(c int) {
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m.balancing = true
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// we'll look at the last capture first
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capcount := m.matchcount[c]
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target := capcount*2 - 2
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// first see if it is negative, and therefore is a reference to the next available
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// capture group for balancing. If it is, we'll reset target to point to that capture.
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if m.matches[c][target] < 0 {
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target = -3 - m.matches[c][target]
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}
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// move back to the previous capture
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target -= 2
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// if the previous capture is a reference, just copy that reference to the end. Otherwise, point to it.
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if target >= 0 && m.matches[c][target] < 0 {
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m.addMatch(c, m.matches[c][target], m.matches[c][target+1])
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} else {
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m.addMatch(c, -3-target, -4-target /* == -3 - (target + 1) */)
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}
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}
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// Nonpublic builder: removes a group match by capnum
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func (m *Match) removeMatch(c int) {
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m.matchcount[c]--
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}
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// GroupCount returns the number of groups this match has matched
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func (m *Match) GroupCount() int {
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return len(m.matchcount)
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}
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// GroupByName returns a group based on the name of the group, or nil if the group name does not exist
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func (m *Match) GroupByName(name string) *Group {
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num := m.regex.GroupNumberFromName(name)
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if num < 0 {
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return nil
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}
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return m.GroupByNumber(num)
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}
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// GroupByNumber returns a group based on the number of the group, or nil if the group number does not exist
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func (m *Match) GroupByNumber(num int) *Group {
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// check our sparse map
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if m.sparseCaps != nil {
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if newNum, ok := m.sparseCaps[num]; ok {
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num = newNum
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}
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}
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if num >= len(m.matchcount) || num < 0 {
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return nil
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}
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if num == 0 {
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return &m.Group
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}
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m.populateOtherGroups()
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return &m.otherGroups[num-1]
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}
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// Groups returns all the capture groups, starting with group 0 (the full match)
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func (m *Match) Groups() []Group {
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m.populateOtherGroups()
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g := make([]Group, len(m.otherGroups)+1)
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g[0] = m.Group
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copy(g[1:], m.otherGroups)
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return g
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}
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func (m *Match) populateOtherGroups() {
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// Construct all the Group objects first time called
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if m.otherGroups == nil {
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m.otherGroups = make([]Group, len(m.matchcount)-1)
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for i := 0; i < len(m.otherGroups); i++ {
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m.otherGroups[i] = newGroup(m.regex.GroupNameFromNumber(i+1), m.text, m.matches[i+1], m.matchcount[i+1])
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}
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}
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}
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func (m *Match) groupValueAppendToBuf(groupnum int, buf *bytes.Buffer) {
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c := m.matchcount[groupnum]
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if c == 0 {
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return
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}
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matches := m.matches[groupnum]
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index := matches[(c-1)*2]
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last := index + matches[(c*2)-1]
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for ; index < last; index++ {
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buf.WriteRune(m.text[index])
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}
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}
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func newGroup(name string, text []rune, caps []int, capcount int) Group {
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g := Group{}
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g.text = text
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if capcount > 0 {
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g.Index = caps[(capcount-1)*2]
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g.Length = caps[(capcount*2)-1]
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}
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g.Name = name
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g.Captures = make([]Capture, capcount)
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for i := 0; i < capcount; i++ {
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g.Captures[i] = Capture{
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text: text,
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Index: caps[i*2],
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Length: caps[i*2+1],
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}
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}
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//log.Printf("newGroup! capcount %v, %+v", capcount, g)
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return g
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}
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func (m *Match) dump() string {
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buf := &bytes.Buffer{}
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buf.WriteRune('\n')
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if len(m.sparseCaps) > 0 {
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for k, v := range m.sparseCaps {
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fmt.Fprintf(buf, "Slot %v -> %v\n", k, v)
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}
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}
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for i, g := range m.Groups() {
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fmt.Fprintf(buf, "Group %v (%v), %v caps:\n", i, g.Name, len(g.Captures))
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for _, c := range g.Captures {
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fmt.Fprintf(buf, " (%v, %v) %v\n", c.Index, c.Length, c.String())
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}
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}
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/*
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for i := 0; i < len(m.matchcount); i++ {
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fmt.Fprintf(buf, "\nGroup %v (%v):\n", i, m.regex.GroupNameFromNumber(i))
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for j := 0; j < m.matchcount[i]; j++ {
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text := ""
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if m.matches[i][j*2] >= 0 {
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start := m.matches[i][j*2]
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text = m.text[start : start+m.matches[i][j*2+1]]
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}
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fmt.Fprintf(buf, " (%v, %v) %v\n", m.matches[i][j*2], m.matches[i][j*2+1], text)
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}
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}
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*/
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return buf.String()
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}
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