notepad-plus-plus-legacy/scintilla/src/Partitioning.h

// Scintilla source code edit control
/** @file Partitioning.h
 ** Data structure used to partition an interval. Used for holding line start/end positions.
 **/
// Copyright 1998-2007 by Neil Hodgson <neilh@scintilla.org>
// The License.txt file describes the conditions under which this software may be distributed.

#ifndef PARTITIONING_H
#define PARTITIONING_H

/// A split vector of integers with a method for adding a value to all elements 
/// in a range.
/// Used by the Partitioning class.

class SplitVectorWithRangeAdd : public SplitVector<int> {
public:
	SplitVectorWithRangeAdd(int growSize_) {
		SetGrowSize(growSize_);
		ReAllocate(growSize_);
	}
	~SplitVectorWithRangeAdd() {
	}
	void RangeAddDelta(int start, int end, int delta) {
		// end is 1 past end, so end-start is number of elements to change
		int i = 0;
		int rangeLength = end - start;
		int range1Length = rangeLength;
		int part1Left = part1Length - start;
		if (range1Length > part1Left)
			range1Length = part1Left;
		while (i < range1Length) {
			body[start++] += delta;
			i++;
		}
		start += gapLength;
		while (i < rangeLength) {
			body[start++] += delta;
			i++;
		}
	}
};

/// Divide an interval into multiple partitions.
/// Useful for breaking a document down into sections such as lines.

class Partitioning {
private:
	// To avoid calculating all the partition positions whenever any text is inserted
	// there may be a step somewhere in the list.
	int stepPartition;
	int stepLength;
	SplitVectorWithRangeAdd *body;

	// Move step forward
	void ApplyStep(int partitionUpTo) {
		if (stepLength != 0) {
			body->RangeAddDelta(stepPartition+1, partitionUpTo + 1, stepLength);
		}
		stepPartition = partitionUpTo;
		if (stepPartition >= body->Length()-1) {
			stepPartition = body->Length()-1;
			stepLength = 0;
		}
	}

	// Move step backward
	void BackStep(int partitionDownTo) {
		if (stepLength != 0) {
			body->RangeAddDelta(partitionDownTo+1, stepPartition+1, -stepLength);
		}
		stepPartition = partitionDownTo;
	}

	void Allocate(int growSize) {
		body = new SplitVectorWithRangeAdd(growSize);
		stepPartition = 0;
		stepLength = 0;
		body->Insert(0, 0);	// This value stays 0 for ever
		body->Insert(1, 0);	// This is the end of the first partition and will be the start of the second
	}

public:
	Partitioning(int growSize) {
		Allocate(growSize);
	}

	~Partitioning() {
		delete body;
		body = NULL;
	}

	int Partitions() {
		return body->Length()-1;
	}

	void InsertPartition(int partition, int pos) {
		if (stepPartition < partition) {
			ApplyStep(partition);
		}
		body->Insert(partition, pos);
		stepPartition++;
	}

	void SetPartitionStartPosition(int partition, int pos) {
		ApplyStep(partition+1);
		if ((partition < 0) || (partition > body->Length())) {
			return;
		}
		body->SetValueAt(partition, pos);
	}

	void InsertText(int partitionInsert, int delta) {
		// Point all the partitions after the insertion point further along in the buffer
		if (stepLength != 0) {
			if (partitionInsert >= stepPartition) {
				// Fill in up to the new insertion point
				ApplyStep(partitionInsert);
				stepLength += delta;
			} else if (partitionInsert >= (stepPartition - body->Length() / 10)) {
				// Close to step but before so move step back
				BackStep(partitionInsert);
				stepLength += delta;
			} else {
				ApplyStep(body->Length()-1);
				stepPartition = partitionInsert;
				stepLength = delta;
			}
		} else {
			stepPartition = partitionInsert;
			stepLength = delta;
		}
	}

	void RemovePartition(int partition) {
		if (partition > stepPartition) {
			ApplyStep(partition);
			stepPartition--;
		} else {
			stepPartition--;
		}
		body->Delete(partition);
	}

	int PositionFromPartition(int partition) {
		PLATFORM_ASSERT(partition >= 0);
		PLATFORM_ASSERT(partition < body->Length());
		if ((partition < 0) || (partition >= body->Length())) {
			return 0;
		}
		int pos = body->ValueAt(partition);
		if (partition > stepPartition)
			pos += stepLength;
		return pos;
	}

	int PartitionFromPosition(int pos) {
		if (body->Length() <= 1)
			return 0;
		if (pos >= (PositionFromPartition(body->Length()-1)))
			return body->Length() - 1 - 1;
		int lower = 0;
		int upper = body->Length()-1;
		do {
			int middle = (upper + lower + 1) / 2; 	// Round high
			int posMiddle = body->ValueAt(middle);
			if (middle > stepPartition)
				posMiddle += stepLength;
			if (pos < posMiddle) {
				upper = middle - 1;
			} else {
				lower = middle;
			}
		} while (lower < upper);
		return lower;
	}

	void DeleteAll() {
		int growSize = body->GetGrowSize();
		delete body;
		Allocate(growSize);
	}
};

#endif
v4.2 ready git-svn-id: svn://svn.tuxfamily.org/svnroot/notepadplus/repository@1 f5eea248-9336-0410-98b8-ebc06183d4e3 2007-08-07 00:55:50 +00:00			`// Scintilla source code edit control`
			`/** @file Partitioning.h`
			`** Data structure used to partition an interval. Used for holding line start/end positions.`
			`**/`
			`// Copyright 1998-2007 by Neil Hodgson <neilh@scintilla.org>`
			`// The License.txt file describes the conditions under which this software may be distributed.`

			`#ifndef PARTITIONING_H`
			`#define PARTITIONING_H`

			`/// A split vector of integers with a method for adding a value to all elements`
			`/// in a range.`
			`/// Used by the Partitioning class.`

			`class SplitVectorWithRangeAdd : public SplitVector<int> {`
			`public:`
			`SplitVectorWithRangeAdd(int growSize_) {`
			`SetGrowSize(growSize_);`
			`ReAllocate(growSize_);`
			`}`
			`~SplitVectorWithRangeAdd() {`
			`}`
			`void RangeAddDelta(int start, int end, int delta) {`
			`// end is 1 past end, so end-start is number of elements to change`
			`int i = 0;`
			`int rangeLength = end - start;`
			`int range1Length = rangeLength;`
			`int part1Left = part1Length - start;`
			`if (range1Length > part1Left)`
			`range1Length = part1Left;`
			`while (i < range1Length) {`
			`body[start++] += delta;`
			`i++;`
			`}`
			`start += gapLength;`
			`while (i < rangeLength) {`
			`body[start++] += delta;`
			`i++;`
			`}`
			`}`
			`};`

			`/// Divide an interval into multiple partitions.`
			`/// Useful for breaking a document down into sections such as lines.`

			`class Partitioning {`
			`private:`
			`// To avoid calculating all the partition positions whenever any text is inserted`
			`// there may be a step somewhere in the list.`
			`int stepPartition;`
			`int stepLength;`
			`SplitVectorWithRangeAdd *body;`

			`// Move step forward`
			`void ApplyStep(int partitionUpTo) {`
			`if (stepLength != 0) {`
			`body->RangeAddDelta(stepPartition+1, partitionUpTo + 1, stepLength);`
			`}`
			`stepPartition = partitionUpTo;`
			`if (stepPartition >= body->Length()-1) {`
			`stepPartition = body->Length()-1;`
			`stepLength = 0;`
			`}`
			`}`

			`// Move step backward`
			`void BackStep(int partitionDownTo) {`
			`if (stepLength != 0) {`
			`body->RangeAddDelta(partitionDownTo+1, stepPartition+1, -stepLength);`
			`}`
			`stepPartition = partitionDownTo;`
			`}`

			`void Allocate(int growSize) {`
			`body = new SplitVectorWithRangeAdd(growSize);`
			`stepPartition = 0;`
			`stepLength = 0;`
			`body->Insert(0, 0); // This value stays 0 for ever`
			`body->Insert(1, 0); // This is the end of the first partition and will be the start of the second`
			`}`

			`public:`
			`Partitioning(int growSize) {`
			`Allocate(growSize);`
			`}`

			`~Partitioning() {`
			`delete body;`
			`body = NULL;`
			`}`

			`int Partitions() {`
			`return body->Length()-1;`
			`}`

			`void InsertPartition(int partition, int pos) {`
			`if (stepPartition < partition) {`
			`ApplyStep(partition);`
			`}`
			`body->Insert(partition, pos);`
			`stepPartition++;`
			`}`

			`void SetPartitionStartPosition(int partition, int pos) {`
			`ApplyStep(partition+1);`
			`if ((partition < 0) \|\| (partition > body->Length())) {`
			`return;`
			`}`
			`body->SetValueAt(partition, pos);`
			`}`

			`void InsertText(int partitionInsert, int delta) {`
			`// Point all the partitions after the insertion point further along in the buffer`
			`if (stepLength != 0) {`
			`if (partitionInsert >= stepPartition) {`
			`// Fill in up to the new insertion point`
			`ApplyStep(partitionInsert);`
			`stepLength += delta;`
			`} else if (partitionInsert >= (stepPartition - body->Length() / 10)) {`
			`// Close to step but before so move step back`
			`BackStep(partitionInsert);`
			`stepLength += delta;`
			`} else {`
			`ApplyStep(body->Length()-1);`
			`stepPartition = partitionInsert;`
			`stepLength = delta;`
			`}`
			`} else {`
			`stepPartition = partitionInsert;`
			`stepLength = delta;`
			`}`
			`}`

			`void RemovePartition(int partition) {`
			`if (partition > stepPartition) {`
			`ApplyStep(partition);`
			`stepPartition--;`
			`} else {`
			`stepPartition--;`
			`}`
			`body->Delete(partition);`
			`}`

			`int PositionFromPartition(int partition) {`
			`PLATFORM_ASSERT(partition >= 0);`
			`PLATFORM_ASSERT(partition < body->Length());`
			`if ((partition < 0) \|\| (partition >= body->Length())) {`
			`return 0;`
			`}`
			`int pos = body->ValueAt(partition);`
			`if (partition > stepPartition)`
			`pos += stepLength;`
			`return pos;`
			`}`

			`int PartitionFromPosition(int pos) {`
			`if (body->Length() <= 1)`
			`return 0;`
			`if (pos >= (PositionFromPartition(body->Length()-1)))`
			`return body->Length() - 1 - 1;`
			`int lower = 0;`
			`int upper = body->Length()-1;`
			`do {`
			`int middle = (upper + lower + 1) / 2; // Round high`
			`int posMiddle = body->ValueAt(middle);`
			`if (middle > stepPartition)`
			`posMiddle += stepLength;`
			`if (pos < posMiddle) {`
			`upper = middle - 1;`
			`} else {`
			`lower = middle;`
			`}`
			`} while (lower < upper);`
			`return lower;`
			`}`

			`void DeleteAll() {`
			`int growSize = body->GetGrowSize();`
			`delete body;`
			`Allocate(growSize);`
			`}`
			`};`

			`#endif`