VMProtect/third-party/scintilla/PositionCache.cxx

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2023-05-14 16:21:09 +03:00
// Scintilla source code edit control
/** @file PositionCache.cxx
** Classes for caching layout information.
**/
// Copyright 1998-2007 by Neil Hodgson <neilh@scintilla.org>
// The License.txt file describes the conditions under which this software may be distributed.
#include "Platform.h"
#include "Scintilla.h"
#include "SplitVector.h"
#include "Partitioning.h"
#include "RunStyles.h"
#include "ContractionState.h"
#include "CellBuffer.h"
#include "KeyMap.h"
#include "Indicator.h"
#include "XPM.h"
#include "LineMarker.h"
#include "Style.h"
#include "ViewStyle.h"
#include "CharClassify.h"
#include "Decoration.h"
#include "ILexer.h"
#include "CaseFolder.h"
#include "Document.h"
#include "UniConversion.h"
#include "Selection.h"
#include "PositionCache.h"
#ifdef SCI_NAMESPACE
using namespace Scintilla;
#endif
LineLayout::LineLayout(int maxLineLength_) :
lineStarts(0),
lenLineStarts(0),
lineNumber(-1),
inCache(false),
maxLineLength(-1),
numCharsInLine(0),
numCharsBeforeEOL(0),
validity(llInvalid),
xHighlightGuide(0),
highlightColumn(0),
psel(NULL),
containsCaret(false),
edgeColumn(0),
chars(0),
styles(0),
styleBitsSet(0),
indicators(0),
positions(0),
hsStart(0),
hsEnd(0),
widthLine(wrapWidthInfinite),
lines(1),
wrapIndent(0) {
bracePreviousStyles[0] = 0;
bracePreviousStyles[1] = 0;
Resize(maxLineLength_);
}
LineLayout::~LineLayout() {
Free();
}
void LineLayout::Resize(int maxLineLength_) {
if (maxLineLength_ > maxLineLength) {
Free();
chars = new char[maxLineLength_ + 1];
styles = new unsigned char[maxLineLength_ + 1];
indicators = new char[maxLineLength_ + 1];
// Extra position allocated as sometimes the Windows
// GetTextExtentExPoint API writes an extra element.
positions = new XYPOSITION[maxLineLength_ + 1 + 1];
maxLineLength = maxLineLength_;
}
}
void LineLayout::Free() {
delete []chars;
chars = 0;
delete []styles;
styles = 0;
delete []indicators;
indicators = 0;
delete []positions;
positions = 0;
delete []lineStarts;
lineStarts = 0;
}
void LineLayout::Invalidate(validLevel validity_) {
if (validity > validity_)
validity = validity_;
}
int LineLayout::LineStart(int line) const {
if (line <= 0) {
return 0;
} else if ((line >= lines) || !lineStarts) {
return numCharsInLine;
} else {
return lineStarts[line];
}
}
int LineLayout::LineLastVisible(int line) const {
if (line < 0) {
return 0;
} else if ((line >= lines-1) || !lineStarts) {
return numCharsBeforeEOL;
} else {
return lineStarts[line+1];
}
}
Range LineLayout::SubLineRange(int subLine) const {
return Range(LineStart(subLine), LineLastVisible(subLine));
}
bool LineLayout::InLine(int offset, int line) const {
return ((offset >= LineStart(line)) && (offset < LineStart(line + 1))) ||
((offset == numCharsInLine) && (line == (lines-1)));
}
void LineLayout::SetLineStart(int line, int start) {
if ((line >= lenLineStarts) && (line != 0)) {
int newMaxLines = line + 20;
int *newLineStarts = new int[newMaxLines];
for (int i = 0; i < newMaxLines; i++) {
if (i < lenLineStarts)
newLineStarts[i] = lineStarts[i];
else
newLineStarts[i] = 0;
}
delete []lineStarts;
lineStarts = newLineStarts;
lenLineStarts = newMaxLines;
}
lineStarts[line] = start;
}
void LineLayout::SetBracesHighlight(Range rangeLine, Position braces[],
char bracesMatchStyle, int xHighlight, bool ignoreStyle) {
if (!ignoreStyle && rangeLine.ContainsCharacter(braces[0])) {
int braceOffset = braces[0] - rangeLine.start;
if (braceOffset < numCharsInLine) {
bracePreviousStyles[0] = styles[braceOffset];
styles[braceOffset] = bracesMatchStyle;
}
}
if (!ignoreStyle && rangeLine.ContainsCharacter(braces[1])) {
int braceOffset = braces[1] - rangeLine.start;
if (braceOffset < numCharsInLine) {
bracePreviousStyles[1] = styles[braceOffset];
styles[braceOffset] = bracesMatchStyle;
}
}
if ((braces[0] >= rangeLine.start && braces[1] <= rangeLine.end) ||
(braces[1] >= rangeLine.start && braces[0] <= rangeLine.end)) {
xHighlightGuide = xHighlight;
}
}
void LineLayout::RestoreBracesHighlight(Range rangeLine, Position braces[], bool ignoreStyle) {
if (!ignoreStyle && rangeLine.ContainsCharacter(braces[0])) {
int braceOffset = braces[0] - rangeLine.start;
if (braceOffset < numCharsInLine) {
styles[braceOffset] = bracePreviousStyles[0];
}
}
if (!ignoreStyle && rangeLine.ContainsCharacter(braces[1])) {
int braceOffset = braces[1] - rangeLine.start;
if (braceOffset < numCharsInLine) {
styles[braceOffset] = bracePreviousStyles[1];
}
}
xHighlightGuide = 0;
}
int LineLayout::FindBefore(XYPOSITION x, int lower, int upper) const {
do {
int middle = (upper + lower + 1) / 2; // Round high
XYPOSITION posMiddle = positions[middle];
if (x < posMiddle) {
upper = middle - 1;
} else {
lower = middle;
}
} while (lower < upper);
return lower;
}
int LineLayout::FindPositionFromX(XYPOSITION x, Range range, bool charPosition) const {
int pos = FindBefore(x, range.start, range.end);
while (pos < range.end) {
if (charPosition) {
if (x < (positions[pos + 1])) {
return pos;
}
} else {
if (x < ((positions[pos] + positions[pos + 1]) / 2)) {
return pos;
}
}
pos++;
}
return range.end;
}
Point LineLayout::PointFromPosition(int posInLine, int lineHeight) const {
Point pt;
// In case of very long line put x at arbitrary large position
if (posInLine > maxLineLength) {
pt.x = positions[maxLineLength] - positions[LineStart(lines)];
}
for (int subLine = 0; subLine < lines; subLine++) {
const Range rangeSubLine = SubLineRange(subLine);
if (posInLine >= rangeSubLine.start) {
pt.y = static_cast<XYPOSITION>(subLine*lineHeight);
if (posInLine <= rangeSubLine.end) {
pt.x = positions[posInLine] - positions[rangeSubLine.start];
if (rangeSubLine.start != 0) // Wrapped lines may be indented
pt.x += wrapIndent;
}
} else {
break;
}
}
return pt;
}
int LineLayout::EndLineStyle() const {
return styles[numCharsBeforeEOL > 0 ? numCharsBeforeEOL-1 : 0];
}
LineLayoutCache::LineLayoutCache() :
level(0),
allInvalidated(false), styleClock(-1), useCount(0) {
Allocate(0);
}
LineLayoutCache::~LineLayoutCache() {
Deallocate();
}
void LineLayoutCache::Allocate(size_t length_) {
PLATFORM_ASSERT(cache.empty());
allInvalidated = false;
cache.resize(length_);
}
void LineLayoutCache::AllocateForLevel(int linesOnScreen, int linesInDoc) {
PLATFORM_ASSERT(useCount == 0);
size_t lengthForLevel = 0;
if (level == llcCaret) {
lengthForLevel = 1;
} else if (level == llcPage) {
lengthForLevel = linesOnScreen + 1;
} else if (level == llcDocument) {
lengthForLevel = linesInDoc;
}
if (lengthForLevel > cache.size()) {
Deallocate();
Allocate(lengthForLevel);
} else {
if (lengthForLevel < cache.size()) {
for (size_t i = lengthForLevel; i < cache.size(); i++) {
delete cache[i];
cache[i] = 0;
}
}
cache.resize(lengthForLevel);
}
PLATFORM_ASSERT(cache.size() == lengthForLevel);
}
void LineLayoutCache::Deallocate() {
PLATFORM_ASSERT(useCount == 0);
for (size_t i = 0; i < cache.size(); i++)
delete cache[i];
cache.clear();
}
void LineLayoutCache::Invalidate(LineLayout::validLevel validity_) {
if (!cache.empty() && !allInvalidated) {
for (size_t i = 0; i < cache.size(); i++) {
if (cache[i]) {
cache[i]->Invalidate(validity_);
}
}
if (validity_ == LineLayout::llInvalid) {
allInvalidated = true;
}
}
}
void LineLayoutCache::SetLevel(int level_) {
allInvalidated = false;
if ((level_ != -1) && (level != level_)) {
level = level_;
Deallocate();
}
}
LineLayout *LineLayoutCache::Retrieve(int lineNumber, int lineCaret, int maxChars, int styleClock_,
int linesOnScreen, int linesInDoc) {
AllocateForLevel(linesOnScreen, linesInDoc);
if (styleClock != styleClock_) {
Invalidate(LineLayout::llCheckTextAndStyle);
styleClock = styleClock_;
}
allInvalidated = false;
int pos = -1;
LineLayout *ret = 0;
if (level == llcCaret) {
pos = 0;
} else if (level == llcPage) {
if (lineNumber == lineCaret) {
pos = 0;
} else if (cache.size() > 1) {
pos = 1 + (lineNumber % (cache.size() - 1));
}
} else if (level == llcDocument) {
pos = lineNumber;
}
if (pos >= 0) {
PLATFORM_ASSERT(useCount == 0);
if (!cache.empty() && (pos < static_cast<int>(cache.size()))) {
if (cache[pos]) {
if ((cache[pos]->lineNumber != lineNumber) ||
(cache[pos]->maxLineLength < maxChars)) {
delete cache[pos];
cache[pos] = 0;
}
}
if (!cache[pos]) {
cache[pos] = new LineLayout(maxChars);
}
cache[pos]->lineNumber = lineNumber;
cache[pos]->inCache = true;
ret = cache[pos];
useCount++;
}
}
if (!ret) {
ret = new LineLayout(maxChars);
ret->lineNumber = lineNumber;
}
return ret;
}
void LineLayoutCache::Dispose(LineLayout *ll) {
allInvalidated = false;
if (ll) {
if (!ll->inCache) {
delete ll;
} else {
useCount--;
}
}
}
// Simply pack the (maximum 4) character bytes into an int
static inline int KeyFromString(const char *charBytes, size_t len) {
PLATFORM_ASSERT(len <= 4);
int k=0;
for (size_t i=0; i<len && charBytes[i]; i++) {
k = k * 0x100;
k += static_cast<unsigned char>(charBytes[i]);
}
return k;
}
SpecialRepresentations::SpecialRepresentations() {
std::fill(startByteHasReprs, startByteHasReprs+0x100, 0);
}
void SpecialRepresentations::SetRepresentation(const char *charBytes, const char *value) {
MapRepresentation::iterator it = mapReprs.find(KeyFromString(charBytes, UTF8MaxBytes));
if (it == mapReprs.end()) {
// New entry so increment for first byte
startByteHasReprs[static_cast<unsigned char>(charBytes[0])]++;
}
mapReprs[KeyFromString(charBytes, UTF8MaxBytes)] = Representation(value);
}
void SpecialRepresentations::ClearRepresentation(const char *charBytes) {
MapRepresentation::iterator it = mapReprs.find(KeyFromString(charBytes, UTF8MaxBytes));
if (it != mapReprs.end()) {
mapReprs.erase(it);
startByteHasReprs[static_cast<unsigned char>(charBytes[0])]--;
}
}
Representation *SpecialRepresentations::RepresentationFromCharacter(const char *charBytes, size_t len) {
PLATFORM_ASSERT(len <= 4);
if (!startByteHasReprs[static_cast<unsigned char>(charBytes[0])])
return 0;
MapRepresentation::iterator it = mapReprs.find(KeyFromString(charBytes, len));
if (it != mapReprs.end()) {
return &(it->second);
}
return 0;
}
bool SpecialRepresentations::Contains(const char *charBytes, size_t len) const {
PLATFORM_ASSERT(len <= 4);
if (!startByteHasReprs[static_cast<unsigned char>(charBytes[0])])
return false;
MapRepresentation::const_iterator it = mapReprs.find(KeyFromString(charBytes, len));
return it != mapReprs.end();
}
void SpecialRepresentations::Clear() {
mapReprs.clear();
std::fill(startByteHasReprs, startByteHasReprs+0x100, 0);
}
void BreakFinder::Insert(int val) {
if (val > nextBreak) {
const std::vector<int>::iterator it = std::lower_bound(selAndEdge.begin(), selAndEdge.end(), val);
if (it == selAndEdge.end()) {
selAndEdge.push_back(val);
} else if (*it != val) {
selAndEdge.insert(it, 1, val);
}
}
}
BreakFinder::BreakFinder(LineLayout *ll_, int lineStart_, int lineEnd_, int posLineStart_,
int xStart, bool breakForSelection, Document *pdoc_, SpecialRepresentations *preprs_) :
ll(ll_),
lineStart(lineStart_),
lineEnd(lineEnd_),
posLineStart(posLineStart_),
nextBreak(lineStart_),
saeCurrentPos(0),
saeNext(0),
subBreak(-1),
pdoc(pdoc_),
encodingFamily(pdoc_->CodePageFamily()),
preprs(preprs_) {
// Search for first visible break
// First find the first visible character
if (xStart > 0.0f)
nextBreak = ll->FindBefore(static_cast<XYPOSITION>(xStart), lineStart, lineEnd);
// Now back to a style break
while ((nextBreak > lineStart) && (ll->styles[nextBreak] == ll->styles[nextBreak - 1])) {
nextBreak--;
}
if (breakForSelection) {
SelectionPosition posStart(posLineStart);
SelectionPosition posEnd(posLineStart + lineEnd);
SelectionSegment segmentLine(posStart, posEnd);
for (size_t r=0; r<ll->psel->Count(); r++) {
SelectionSegment portion = ll->psel->Range(r).Intersect(segmentLine);
if (!(portion.start == portion.end)) {
if (portion.start.IsValid())
Insert(portion.start.Position() - posLineStart);
if (portion.end.IsValid())
Insert(portion.end.Position() - posLineStart);
}
}
}
Insert(ll->edgeColumn);
Insert(lineEnd);
saeNext = (!selAndEdge.empty()) ? selAndEdge[0] : -1;
}
BreakFinder::~BreakFinder() {
}
TextSegment BreakFinder::Next() {
if (subBreak == -1) {
int prev = nextBreak;
while (nextBreak < lineEnd) {
int charWidth = 1;
if (encodingFamily == efUnicode)
charWidth = UTF8DrawBytes(reinterpret_cast<unsigned char *>(ll->chars) + nextBreak, lineEnd - nextBreak);
else if (encodingFamily == efDBCS)
charWidth = pdoc->IsDBCSLeadByte(ll->chars[nextBreak]) ? 2 : 1;
Representation *repr = preprs->RepresentationFromCharacter(ll->chars + nextBreak, charWidth);
if (((nextBreak > 0) && (ll->styles[nextBreak] != ll->styles[nextBreak - 1])) ||
repr ||
(nextBreak == saeNext)) {
while ((nextBreak >= saeNext) && (saeNext < lineEnd)) {
saeCurrentPos++;
saeNext = (saeCurrentPos < selAndEdge.size()) ? selAndEdge[saeCurrentPos] : lineEnd;
}
if ((nextBreak > prev) || repr) {
// Have a segment to report
if (nextBreak == prev) {
nextBreak += charWidth;
} else {
repr = 0; // Optimize -> should remember repr
}
if ((nextBreak - prev) < lengthStartSubdivision) {
return TextSegment(prev, nextBreak - prev, repr);
} else {
break;
}
}
}
nextBreak += charWidth;
}
if ((nextBreak - prev) < lengthStartSubdivision) {
return TextSegment(prev, nextBreak - prev);
}
subBreak = prev;
}
// Splitting up a long run from prev to nextBreak in lots of approximately lengthEachSubdivision.
// For very long runs add extra breaks after spaces or if no spaces before low punctuation.
int startSegment = subBreak;
if ((nextBreak - subBreak) <= lengthEachSubdivision) {
subBreak = -1;
return TextSegment(startSegment, nextBreak - startSegment);
} else {
subBreak += pdoc->SafeSegment(ll->chars + subBreak, nextBreak-subBreak, lengthEachSubdivision);
if (subBreak >= nextBreak) {
subBreak = -1;
return TextSegment(startSegment, nextBreak - startSegment);
} else {
return TextSegment(startSegment, subBreak - startSegment);
}
}
}
bool BreakFinder::More() const {
return (subBreak >= 0) || (nextBreak < lineEnd);
}
PositionCacheEntry::PositionCacheEntry() :
styleNumber(0), len(0), clock(0), positions(0) {
}
void PositionCacheEntry::Set(unsigned int styleNumber_, const char *s_,
unsigned int len_, XYPOSITION *positions_, unsigned int clock_) {
Clear();
styleNumber = styleNumber_;
len = len_;
clock = clock_;
if (s_ && positions_) {
positions = new XYPOSITION[len + (len / 4) + 1];
for (unsigned int i=0; i<len; i++) {
positions[i] = positions_[i];
}
memcpy(reinterpret_cast<char *>(positions + len), s_, len);
}
}
PositionCacheEntry::~PositionCacheEntry() {
Clear();
}
void PositionCacheEntry::Clear() {
delete []positions;
positions = 0;
styleNumber = 0;
len = 0;
clock = 0;
}
bool PositionCacheEntry::Retrieve(unsigned int styleNumber_, const char *s_,
unsigned int len_, XYPOSITION *positions_) const {
if ((styleNumber == styleNumber_) && (len == len_) &&
(memcmp(reinterpret_cast<char *>(positions + len), s_, len)== 0)) {
for (unsigned int i=0; i<len; i++) {
positions_[i] = positions[i];
}
return true;
} else {
return false;
}
}
unsigned int PositionCacheEntry::Hash(unsigned int styleNumber_, const char *s, unsigned int len_) {
unsigned int ret = s[0] << 7;
for (unsigned int i=0; i<len_; i++) {
ret *= 1000003;
ret ^= s[i];
}
ret *= 1000003;
ret ^= len_;
ret *= 1000003;
ret ^= styleNumber_;
return ret;
}
bool PositionCacheEntry::NewerThan(const PositionCacheEntry &other) const {
return clock > other.clock;
}
void PositionCacheEntry::ResetClock() {
if (clock > 0) {
clock = 1;
}
}
PositionCache::PositionCache() {
clock = 1;
pces.resize(0x400);
allClear = true;
}
PositionCache::~PositionCache() {
Clear();
}
void PositionCache::Clear() {
if (!allClear) {
for (size_t i=0; i<pces.size(); i++) {
pces[i].Clear();
}
}
clock = 1;
allClear = true;
}
void PositionCache::SetSize(size_t size_) {
Clear();
pces.resize(size_);
}
void PositionCache::MeasureWidths(Surface *surface, ViewStyle &vstyle, unsigned int styleNumber,
const char *s, unsigned int len, XYPOSITION *positions, Document *pdoc) {
allClear = false;
size_t probe = pces.size(); // Out of bounds
if ((!pces.empty()) && (len < 30)) {
// Only store short strings in the cache so it doesn't churn with
// long comments with only a single comment.
// Two way associative: try two probe positions.
unsigned int hashValue = PositionCacheEntry::Hash(styleNumber, s, len);
probe = hashValue % pces.size();
if (pces[probe].Retrieve(styleNumber, s, len, positions)) {
return;
}
unsigned int probe2 = (hashValue * 37) % pces.size();
if (pces[probe2].Retrieve(styleNumber, s, len, positions)) {
return;
}
// Not found. Choose the oldest of the two slots to replace
if (pces[probe].NewerThan(pces[probe2])) {
probe = probe2;
}
}
if (len > BreakFinder::lengthStartSubdivision) {
// Break up into segments
unsigned int startSegment = 0;
XYPOSITION xStartSegment = 0;
while (startSegment < len) {
unsigned int lenSegment = pdoc->SafeSegment(s + startSegment, len - startSegment, BreakFinder::lengthEachSubdivision);
surface->MeasureWidths(vstyle.styles[styleNumber].font, s + startSegment, lenSegment, positions + startSegment);
for (unsigned int inSeg = 0; inSeg < lenSegment; inSeg++) {
positions[startSegment + inSeg] += xStartSegment;
}
xStartSegment = positions[startSegment + lenSegment - 1];
startSegment += lenSegment;
}
} else {
surface->MeasureWidths(vstyle.styles[styleNumber].font, s, len, positions);
}
if (probe < pces.size()) {
// Store into cache
clock++;
if (clock > 60000) {
// Since there are only 16 bits for the clock, wrap it round and
// reset all cache entries so none get stuck with a high clock.
for (size_t i=0; i<pces.size(); i++) {
pces[i].ResetClock();
}
clock = 2;
}
pces[probe].Set(styleNumber, s, len, positions, clock);
}
}