internal/colltab/iter.go - text - Git at Google

 // Copyright 2015 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package colltab

 // An Iter incrementally converts chunks of the input text to collation
 // elements, while ensuring that the collation elements are in normalized order
 // (that is, they are in the order as if the input text were normalized first).
 type Iter struct {
 	Weighter Weighter
 	Elems    []Elem
 	// N is the number of elements in Elems that will not be reordered on
 	// subsequent iterations, N <= len(Elems).
 	N int

 	bytes []byte
 	str   string
 	// Because the Elems buffer may contain collation elements that are needed
 	// for look-ahead, we need two positions in the text (bytes or str): one for
 	// the end position in the text for the current iteration and one for the
 	// start of the next call to appendNext.
 	pEnd  int // end position in text corresponding to N.
 	pNext int // pEnd <= pNext.
 }

 // Reset sets the position in the current input text to p and discards any
 // results obtained so far.
 func (i *Iter) Reset(p int) {
 	i.Elems = i.Elems[:0]
 	i.N = 0
 	i.pEnd = p
 	i.pNext = p
 }

 // Len returns the length of the input text.
 func (i *Iter) Len() int {
 	if i.bytes != nil {
 		return len(i.bytes)
 	}
 	return len(i.str)
 }

 // Discard removes the collation elements up to N.
 func (i *Iter) Discard() {
 	// TODO: change this such that only modifiers following starters will have
 	// to be copied.
 	i.Elems = i.Elems[:copy(i.Elems, i.Elems[i.N:])]
 	i.N = 0
 }

 // End returns the end position of the input text for which Next has returned
 // results.
 func (i *Iter) End() int {
 	return i.pEnd
 }

 // SetInput resets i to input s.
 func (i *Iter) SetInput(s []byte) {
 	i.bytes = s
 	i.str = ""
 	i.Reset(0)
 }

 // SetInputString resets i to input s.
 func (i *Iter) SetInputString(s string) {
 	i.str = s
 	i.bytes = nil
 	i.Reset(0)
 }

 func (i *Iter) done() bool {
 	return i.pNext >= len(i.str) && i.pNext >= len(i.bytes)
 }

 func (i *Iter) appendNext() bool {
 	if i.done() {
 		return false
 	}
 	var sz int
 	if i.bytes == nil {
 		i.Elems, sz = i.Weighter.AppendNextString(i.Elems, i.str[i.pNext:])
 	} else {
 		i.Elems, sz = i.Weighter.AppendNext(i.Elems, i.bytes[i.pNext:])
 	}
 	if sz == 0 {
 		sz = 1
 	}
 	i.pNext += sz
 	return true
 }

 // Next appends Elems to the internal array. On each iteration, it will either
 // add starters or modifiers. In the majority of cases, an Elem with a primary
 // value > 0 will have a CCC of 0. The CCC values of collation elements are also
 // used to detect if the input string was not normalized and to adjust the
 // result accordingly.
 func (i *Iter) Next() bool {
 	if i.N == len(i.Elems) && !i.appendNext() {
 		return false
 	}

 	// Check if the current segment starts with a starter.
 	prevCCC := i.Elems[len(i.Elems)-1].CCC()
 	if prevCCC == 0 {
 		i.N = len(i.Elems)
 		i.pEnd = i.pNext
 		return true
 	} else if i.Elems[i.N].CCC() == 0 {
 		// set i.N to only cover part of i.Elems for which prevCCC == 0 and
 		// use rest for the next call to next.
 		for i.N++; i.N < len(i.Elems) && i.Elems[i.N].CCC() == 0; i.N++ {
 		}
 		i.pEnd = i.pNext
 		return true
 	}

 	// The current (partial) segment starts with modifiers. We need to collect
 	// all successive modifiers to ensure that they are normalized.
 	for {
 		p := len(i.Elems)
 		i.pEnd = i.pNext
 		if !i.appendNext() {
 			break
 		}

 		if ccc := i.Elems[p].CCC(); ccc == 0 || len(i.Elems)-i.N > maxCombiningCharacters {
 			// Leave the starter for the next iteration. This ensures that we
 			// do not return sequences of collation elements that cross two
 			// segments.
 			//
 			// TODO: handle large number of combining characters by fully
 			// normalizing the input segment before iteration. This ensures
 			// results are consistent across the text repo.
 			i.N = p
 			return true
 		} else if ccc < prevCCC {
 			i.doNorm(p, ccc) // should be rare, never occurs for NFD and FCC.
 		} else {
 			prevCCC = ccc
 		}
 	}

 	done := len(i.Elems) != i.N
 	i.N = len(i.Elems)
 	return done
 }

 // nextNoNorm is the same as next, but does not "normalize" the collation
 // elements.
 func (i *Iter) nextNoNorm() bool {
 	// TODO: remove this function. Using this instead of next does not seem
 	// to improve performance in any significant way. We retain this until
 	// later for evaluation purposes.
 	if i.done() {
 		return false
 	}
 	i.appendNext()
 	i.N = len(i.Elems)
 	return true
 }

 const maxCombiningCharacters = 30

 // doNorm reorders the collation elements in i.Elems.
 // It assumes that blocks of collation elements added with appendNext
 // either start and end with the same CCC or start with CCC == 0.
 // This allows for a single insertion point for the entire block.
 // The correctness of this assumption is verified in builder.go.
 func (i *Iter) doNorm(p int, ccc uint8) {
 	n := len(i.Elems)
 	k := p
 	for p--; p > i.N && ccc < i.Elems[p-1].CCC(); p-- {
 	}
 	i.Elems = append(i.Elems, i.Elems[p:k]...)
 	copy(i.Elems[p:], i.Elems[k:])
 	i.Elems = i.Elems[:n]
 }
	// Copyright 2015 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package colltab

	// An Iter incrementally converts chunks of the input text to collation
	// elements, while ensuring that the collation elements are in normalized order
	// (that is, they are in the order as if the input text were normalized first).
	type Iter struct {
	Weighter Weighter
	Elems []Elem
	// N is the number of elements in Elems that will not be reordered on
	// subsequent iterations, N <= len(Elems).
	N int

	bytes []byte
	str string
	// Because the Elems buffer may contain collation elements that are needed
	// for look-ahead, we need two positions in the text (bytes or str): one for
	// the end position in the text for the current iteration and one for the
	// start of the next call to appendNext.
	pEnd int // end position in text corresponding to N.
	pNext int // pEnd <= pNext.
	}

	// Reset sets the position in the current input text to p and discards any
	// results obtained so far.
	func (i *Iter) Reset(p int) {
	i.Elems = i.Elems[:0]
	i.N = 0
	i.pEnd = p
	i.pNext = p
	}

	// Len returns the length of the input text.
	func (i *Iter) Len() int {
	if i.bytes != nil {
	return len(i.bytes)
	}
	return len(i.str)
	}

	// Discard removes the collation elements up to N.
	func (i *Iter) Discard() {
	// TODO: change this such that only modifiers following starters will have
	// to be copied.
	i.Elems = i.Elems[:copy(i.Elems, i.Elems[i.N:])]
	i.N = 0
	}

	// End returns the end position of the input text for which Next has returned
	// results.
	func (i *Iter) End() int {
	return i.pEnd
	}

	// SetInput resets i to input s.
	func (i *Iter) SetInput(s []byte) {
	i.bytes = s
	i.str = ""
	i.Reset(0)
	}

	// SetInputString resets i to input s.
	func (i *Iter) SetInputString(s string) {
	i.str = s
	i.bytes = nil
	i.Reset(0)
	}

	func (i *Iter) done() bool {
	return i.pNext >= len(i.str) && i.pNext >= len(i.bytes)
	}

	func (i *Iter) appendNext() bool {
	if i.done() {
	return false
	}
	var sz int
	if i.bytes == nil {
	i.Elems, sz = i.Weighter.AppendNextString(i.Elems, i.str[i.pNext:])
	} else {
	i.Elems, sz = i.Weighter.AppendNext(i.Elems, i.bytes[i.pNext:])
	}
	if sz == 0 {
	sz = 1
	}
	i.pNext += sz
	return true
	}

	// Next appends Elems to the internal array. On each iteration, it will either
	// add starters or modifiers. In the majority of cases, an Elem with a primary
	// value > 0 will have a CCC of 0. The CCC values of collation elements are also
	// used to detect if the input string was not normalized and to adjust the
	// result accordingly.
	func (i *Iter) Next() bool {
	if i.N == len(i.Elems) && !i.appendNext() {
	return false
	}

	// Check if the current segment starts with a starter.
	prevCCC := i.Elems[len(i.Elems)-1].CCC()
	if prevCCC == 0 {
	i.N = len(i.Elems)
	i.pEnd = i.pNext
	return true
	} else if i.Elems[i.N].CCC() == 0 {
	// set i.N to only cover part of i.Elems for which prevCCC == 0 and
	// use rest for the next call to next.
	for i.N++; i.N < len(i.Elems) && i.Elems[i.N].CCC() == 0; i.N++ {
	}
	i.pEnd = i.pNext
	return true
	}

	// The current (partial) segment starts with modifiers. We need to collect
	// all successive modifiers to ensure that they are normalized.
	for {
	p := len(i.Elems)
	i.pEnd = i.pNext
	if !i.appendNext() {
	break
	}

	if ccc := i.Elems[p].CCC(); ccc == 0 \|\| len(i.Elems)-i.N > maxCombiningCharacters {
	// Leave the starter for the next iteration. This ensures that we
	// do not return sequences of collation elements that cross two
	// segments.
	//
	// TODO: handle large number of combining characters by fully
	// normalizing the input segment before iteration. This ensures
	// results are consistent across the text repo.
	i.N = p
	return true
	} else if ccc < prevCCC {
	i.doNorm(p, ccc) // should be rare, never occurs for NFD and FCC.
	} else {
	prevCCC = ccc
	}
	}

	done := len(i.Elems) != i.N
	i.N = len(i.Elems)
	return done
	}

	// nextNoNorm is the same as next, but does not "normalize" the collation
	// elements.
	func (i *Iter) nextNoNorm() bool {
	// TODO: remove this function. Using this instead of next does not seem
	// to improve performance in any significant way. We retain this until
	// later for evaluation purposes.
	if i.done() {
	return false
	}
	i.appendNext()
	i.N = len(i.Elems)
	return true
	}

	const maxCombiningCharacters = 30

	// doNorm reorders the collation elements in i.Elems.
	// It assumes that blocks of collation elements added with appendNext
	// either start and end with the same CCC or start with CCC == 0.
	// This allows for a single insertion point for the entire block.
	// The correctness of this assumption is verified in builder.go.
	func (i *Iter) doNorm(p int, ccc uint8) {
	n := len(i.Elems)
	k := p
	for p--; p > i.N && ccc < i.Elems[p-1].CCC(); p-- {
	}
	i.Elems = append(i.Elems, i.Elems[p:k]...)
	copy(i.Elems[p:], i.Elems[k:])
	i.Elems = i.Elems[:n]
	}