gecko-dev/gfx/thebes/gfxFont.cpp
Ehsan Akhgari e368dc9c85 Bug 579517 - Part 1: Automated conversion of NSPR numeric types to stdint types in Gecko; r=bsmedberg
This patch was generated by a script.  Here's the source of the script for
future reference:

function convert() {
echo "Converting $1 to $2..."
find . ! -wholename "*nsprpub*" \
       ! -wholename "*security/nss*" \
       ! -wholename "*/.hg*" \
       ! -wholename "obj-ff-dbg*" \
       ! -name nsXPCOMCID.h \
       ! -name prtypes.h \
         -type f \
      \( -iname "*.cpp" \
         -o -iname "*.h" \
         -o -iname "*.c" \
         -o -iname "*.cc" \
         -o -iname "*.idl" \
         -o -iname "*.ipdl" \
         -o -iname "*.ipdlh" \
         -o -iname "*.mm" \) | \
    xargs -n 1 sed -i -e "s/\b$1\b/$2/g"
}

convert PRInt8 int8_t
convert PRUint8 uint8_t
convert PRInt16 int16_t
convert PRUint16 uint16_t
convert PRInt32 int32_t
convert PRUint32 uint32_t
convert PRInt64 int64_t
convert PRUint64 uint64_t

convert PRIntn int
convert PRUintn unsigned

convert PRSize size_t

convert PROffset32 int32_t
convert PROffset64 int64_t

convert PRPtrdiff ptrdiff_t

convert PRFloat64 double
2012-08-22 11:56:38 -04:00

5646 lines
198 KiB
C++

/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#ifdef MOZ_LOGGING
#define FORCE_PR_LOG /* Allow logging in the release build */
#endif
#include "prlog.h"
#include "nsServiceManagerUtils.h"
#include "nsReadableUtils.h"
#include "nsExpirationTracker.h"
#include "nsILanguageAtomService.h"
#include "nsITimer.h"
#include "gfxFont.h"
#include "gfxPlatform.h"
#include "nsGkAtoms.h"
#include "prtypes.h"
#include "gfxTypes.h"
#include "nsAlgorithm.h"
#include "gfxContext.h"
#include "gfxFontMissingGlyphs.h"
#include "gfxUserFontSet.h"
#include "gfxPlatformFontList.h"
#include "gfxScriptItemizer.h"
#include "nsUnicodeProperties.h"
#include "nsMathUtils.h"
#include "nsBidiUtils.h"
#include "nsUnicodeRange.h"
#include "nsStyleConsts.h"
#include "mozilla/Preferences.h"
#include "mozilla/Services.h"
#include "mozilla/Telemetry.h"
#include "cairo.h"
#include "gfxFontTest.h"
#include "harfbuzz/hb.h"
#include "nsCRT.h"
#include "sampler.h"
#include <algorithm>
using namespace mozilla;
using namespace mozilla::gfx;
using namespace mozilla::unicode;
using mozilla::services::GetObserverService;
gfxFontCache *gfxFontCache::gGlobalCache = nullptr;
#ifdef DEBUG_roc
#define DEBUG_TEXT_RUN_STORAGE_METRICS
#endif
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
static uint32_t gTextRunStorageHighWaterMark = 0;
static uint32_t gTextRunStorage = 0;
static uint32_t gFontCount = 0;
static uint32_t gGlyphExtentsCount = 0;
static uint32_t gGlyphExtentsWidthsTotalSize = 0;
static uint32_t gGlyphExtentsSetupEagerSimple = 0;
static uint32_t gGlyphExtentsSetupEagerTight = 0;
static uint32_t gGlyphExtentsSetupLazyTight = 0;
static uint32_t gGlyphExtentsSetupFallBackToTight = 0;
#endif
void
gfxCharacterMap::NotifyReleased()
{
gfxPlatformFontList *fontlist = gfxPlatformFontList::PlatformFontList();
if (mShared) {
fontlist->RemoveCmap(this);
}
delete this;
}
gfxFontEntry::~gfxFontEntry()
{
delete mUserFontData;
}
bool gfxFontEntry::IsSymbolFont()
{
return mSymbolFont;
}
bool gfxFontEntry::TestCharacterMap(uint32_t aCh)
{
if (!mCharacterMap) {
ReadCMAP();
NS_ASSERTION(mCharacterMap, "failed to initialize character map");
}
return mCharacterMap->test(aCh);
}
nsresult gfxFontEntry::InitializeUVSMap()
{
// mUVSOffset will not be initialized
// until cmap is initialized.
if (!mCharacterMap) {
ReadCMAP();
NS_ASSERTION(mCharacterMap, "failed to initialize character map");
}
if (!mUVSOffset) {
return NS_ERROR_FAILURE;
}
if (!mUVSData) {
const uint32_t kCmapTag = TRUETYPE_TAG('c','m','a','p');
AutoFallibleTArray<uint8_t,16384> buffer;
if (GetFontTable(kCmapTag, buffer) != NS_OK) {
mUVSOffset = 0; // don't bother to read the table again
return NS_ERROR_FAILURE;
}
uint8_t* uvsData;
nsresult rv = gfxFontUtils::ReadCMAPTableFormat14(
buffer.Elements() + mUVSOffset,
buffer.Length() - mUVSOffset,
uvsData);
if (NS_FAILED(rv)) {
mUVSOffset = 0; // don't bother to read the table again
return rv;
}
mUVSData = uvsData;
}
return NS_OK;
}
uint16_t gfxFontEntry::GetUVSGlyph(uint32_t aCh, uint32_t aVS)
{
InitializeUVSMap();
if (mUVSData) {
return gfxFontUtils::MapUVSToGlyphFormat14(mUVSData, aCh, aVS);
}
return 0;
}
nsresult gfxFontEntry::ReadCMAP()
{
NS_ASSERTION(false, "using default no-op implementation of ReadCMAP");
mCharacterMap = new gfxCharacterMap();
return NS_OK;
}
nsString gfxFontEntry::FamilyName() const
{
NS_ASSERTION(mFamily, "orphaned font entry");
if (mFamily) {
return mFamily->Name();
} else {
return nsString();
}
}
nsString
gfxFontEntry::RealFaceName()
{
FallibleTArray<uint8_t> nameTable;
nsresult rv = GetFontTable(TRUETYPE_TAG('n','a','m','e'), nameTable);
if (NS_SUCCEEDED(rv)) {
nsAutoString name;
rv = gfxFontUtils::GetFullNameFromTable(nameTable, name);
if (NS_SUCCEEDED(rv)) {
return name;
}
}
return Name();
}
already_AddRefed<gfxFont>
gfxFontEntry::FindOrMakeFont(const gfxFontStyle *aStyle, bool aNeedsBold)
{
// the font entry name is the psname, not the family name
nsRefPtr<gfxFont> font = gfxFontCache::GetCache()->Lookup(this, aStyle);
if (!font) {
gfxFont *newFont = CreateFontInstance(aStyle, aNeedsBold);
if (!newFont)
return nullptr;
if (!newFont->Valid()) {
delete newFont;
return nullptr;
}
font = newFont;
gfxFontCache::GetCache()->AddNew(font);
}
gfxFont *f = nullptr;
font.swap(f);
return f;
}
/**
* FontTableBlobData
*
* See FontTableHashEntry for the general strategy.
*/
class gfxFontEntry::FontTableBlobData {
public:
// Adopts the content of aBuffer.
// Pass a non-null aHashEntry only if it should be cleared if/when this
// FontTableBlobData is deleted.
FontTableBlobData(FallibleTArray<uint8_t>& aBuffer,
FontTableHashEntry *aHashEntry)
: mHashEntry(aHashEntry), mHashtable()
{
MOZ_COUNT_CTOR(FontTableBlobData);
mTableData.SwapElements(aBuffer);
}
~FontTableBlobData() {
MOZ_COUNT_DTOR(FontTableBlobData);
if (mHashEntry) {
if (mHashtable) {
mHashtable->RemoveEntry(mHashEntry->GetKey());
} else {
mHashEntry->Clear();
}
}
}
// Useful for creating blobs
const char *GetTable() const
{
return reinterpret_cast<const char*>(mTableData.Elements());
}
uint32_t GetTableLength() const { return mTableData.Length(); }
// Tell this FontTableBlobData to remove the HashEntry when this is
// destroyed.
void ManageHashEntry(nsTHashtable<FontTableHashEntry> *aHashtable)
{
mHashtable = aHashtable;
}
// Disconnect from the HashEntry (because the blob has already been
// removed from the hashtable).
void ForgetHashEntry()
{
mHashEntry = nullptr;
}
size_t SizeOfExcludingThis(nsMallocSizeOfFun aMallocSizeOf) const {
return mTableData.SizeOfExcludingThis(aMallocSizeOf);
}
size_t SizeOfIncludingThis(nsMallocSizeOfFun aMallocSizeOf) const {
return aMallocSizeOf(this) + SizeOfExcludingThis(aMallocSizeOf);
}
private:
// The font table data block, owned (via adoption)
FallibleTArray<uint8_t> mTableData;
// The blob destroy function needs to know the hashtable entry,
FontTableHashEntry *mHashEntry;
// and the owning hashtable, so that it can remove the entry.
nsTHashtable<FontTableHashEntry> *mHashtable;
// not implemented
FontTableBlobData(const FontTableBlobData&);
};
void
gfxFontEntry::FontTableHashEntry::SaveTable(FallibleTArray<uint8_t>& aTable)
{
Clear();
// adopts elements of aTable
FontTableBlobData *data = new FontTableBlobData(aTable, nullptr);
mBlob = hb_blob_create(data->GetTable(), data->GetTableLength(),
HB_MEMORY_MODE_READONLY,
data, DeleteFontTableBlobData);
}
hb_blob_t *
gfxFontEntry::FontTableHashEntry::
ShareTableAndGetBlob(FallibleTArray<uint8_t>& aTable,
nsTHashtable<FontTableHashEntry> *aHashtable)
{
Clear();
// adopts elements of aTable
mSharedBlobData = new FontTableBlobData(aTable, this);
mBlob = hb_blob_create(mSharedBlobData->GetTable(),
mSharedBlobData->GetTableLength(),
HB_MEMORY_MODE_READONLY,
mSharedBlobData, DeleteFontTableBlobData);
if (!mSharedBlobData) {
// The FontTableBlobData was destroyed during hb_blob_create().
// The (empty) blob is still be held in the hashtable with a strong
// reference.
return hb_blob_reference(mBlob);
}
// Tell the FontTableBlobData to remove this hash entry when destroyed.
// The hashtable does not keep a strong reference.
mSharedBlobData->ManageHashEntry(aHashtable);
return mBlob;
}
void
gfxFontEntry::FontTableHashEntry::Clear()
{
// If the FontTableBlobData is managing the hash entry, then the blob is
// not owned by this HashEntry; otherwise there is strong reference to the
// blob that must be removed.
if (mSharedBlobData) {
mSharedBlobData->ForgetHashEntry();
mSharedBlobData = nullptr;
} else if (mBlob) {
hb_blob_destroy(mBlob);
}
mBlob = nullptr;
}
// a hb_destroy_func for hb_blob_create
/* static */ void
gfxFontEntry::FontTableHashEntry::DeleteFontTableBlobData(void *aBlobData)
{
delete static_cast<FontTableBlobData*>(aBlobData);
}
hb_blob_t *
gfxFontEntry::FontTableHashEntry::GetBlob() const
{
return hb_blob_reference(mBlob);
}
bool
gfxFontEntry::GetExistingFontTable(uint32_t aTag, hb_blob_t **aBlob)
{
if (!mFontTableCache.IsInitialized()) {
// we do this here rather than on fontEntry construction
// because not all shapers will access the table cache at all
mFontTableCache.Init(10);
}
FontTableHashEntry *entry = mFontTableCache.GetEntry(aTag);
if (!entry) {
return false;
}
*aBlob = entry->GetBlob();
return true;
}
hb_blob_t *
gfxFontEntry::ShareFontTableAndGetBlob(uint32_t aTag,
FallibleTArray<uint8_t>* aBuffer)
{
if (NS_UNLIKELY(!mFontTableCache.IsInitialized())) {
// we do this here rather than on fontEntry construction
// because not all shapers will access the table cache at all
mFontTableCache.Init(10);
}
FontTableHashEntry *entry = mFontTableCache.PutEntry(aTag);
if (NS_UNLIKELY(!entry)) { // OOM
return nullptr;
}
if (!aBuffer) {
// ensure the entry is null
entry->Clear();
return nullptr;
}
return entry->ShareTableAndGetBlob(*aBuffer, &mFontTableCache);
}
#ifdef MOZ_GRAPHITE
void
gfxFontEntry::CheckForGraphiteTables()
{
AutoFallibleTArray<uint8_t,16384> buffer;
mHasGraphiteTables =
NS_SUCCEEDED(GetFontTable(TRUETYPE_TAG('S','i','l','f'), buffer));
}
#endif
/* static */ size_t
gfxFontEntry::FontTableHashEntry::SizeOfEntryExcludingThis
(FontTableHashEntry *aEntry,
nsMallocSizeOfFun aMallocSizeOf,
void* aUserArg)
{
FontListSizes *sizes = static_cast<FontListSizes*>(aUserArg);
if (aEntry->mBlob) {
sizes->mFontTableCacheSize += aMallocSizeOf(aEntry->mBlob);
}
if (aEntry->mSharedBlobData) {
sizes->mFontTableCacheSize +=
aEntry->mSharedBlobData->SizeOfIncludingThis(aMallocSizeOf);
}
// the size of the table is recorded in the FontListSizes record,
// so we return 0 here for the function result
return 0;
}
void
gfxFontEntry::SizeOfExcludingThis(nsMallocSizeOfFun aMallocSizeOf,
FontListSizes* aSizes) const
{
aSizes->mFontListSize += mName.SizeOfExcludingThisIfUnshared(aMallocSizeOf);
// cmaps are shared so only non-shared cmaps are included here
if (mCharacterMap && mCharacterMap->mBuildOnTheFly) {
aSizes->mCharMapsSize +=
mCharacterMap->SizeOfIncludingThis(aMallocSizeOf);
}
aSizes->mFontTableCacheSize +=
mFontTableCache.SizeOfExcludingThis(
FontTableHashEntry::SizeOfEntryExcludingThis,
aMallocSizeOf, aSizes);
}
void
gfxFontEntry::SizeOfIncludingThis(nsMallocSizeOfFun aMallocSizeOf,
FontListSizes* aSizes) const
{
aSizes->mFontListSize += aMallocSizeOf(this);
SizeOfExcludingThis(aMallocSizeOf, aSizes);
}
//////////////////////////////////////////////////////////////////////////////
//
// class gfxFontFamily
//
//////////////////////////////////////////////////////////////////////////////
// we consider faces with mStandardFace == true to be "greater than" those with false,
// because during style matching, later entries will replace earlier ones
class FontEntryStandardFaceComparator {
public:
bool Equals(const nsRefPtr<gfxFontEntry>& a, const nsRefPtr<gfxFontEntry>& b) const {
return a->mStandardFace == b->mStandardFace;
}
bool LessThan(const nsRefPtr<gfxFontEntry>& a, const nsRefPtr<gfxFontEntry>& b) const {
return (a->mStandardFace == false && b->mStandardFace == true);
}
};
void
gfxFontFamily::SortAvailableFonts()
{
mAvailableFonts.Sort(FontEntryStandardFaceComparator());
}
bool
gfxFontFamily::HasOtherFamilyNames()
{
// need to read in other family names to determine this
if (!mOtherFamilyNamesInitialized) {
ReadOtherFamilyNames(gfxPlatformFontList::PlatformFontList()); // sets mHasOtherFamilyNames
}
return mHasOtherFamilyNames;
}
gfxFontEntry*
gfxFontFamily::FindFontForStyle(const gfxFontStyle& aFontStyle,
bool& aNeedsSyntheticBold)
{
if (!mHasStyles)
FindStyleVariations(); // collect faces for the family, if not already done
NS_ASSERTION(mAvailableFonts.Length() > 0, "font family with no faces!");
aNeedsSyntheticBold = false;
int8_t baseWeight = aFontStyle.ComputeWeight();
bool wantBold = baseWeight >= 6;
// If the family has only one face, we simply return it; no further checking needed
if (mAvailableFonts.Length() == 1) {
gfxFontEntry *fe = mAvailableFonts[0];
aNeedsSyntheticBold = wantBold && !fe->IsBold();
return fe;
}
bool wantItalic = (aFontStyle.style &
(NS_FONT_STYLE_ITALIC | NS_FONT_STYLE_OBLIQUE)) != 0;
// Most families are "simple", having just Regular/Bold/Italic/BoldItalic,
// or some subset of these. In this case, we have exactly 4 entries in mAvailableFonts,
// stored in the above order; note that some of the entries may be NULL.
// We can then pick the required entry based on whether the request is for
// bold or non-bold, italic or non-italic, without running the more complex
// matching algorithm used for larger families with many weights and/or widths.
if (mIsSimpleFamily) {
// Family has no more than the "standard" 4 faces, at fixed indexes;
// calculate which one we want.
// Note that we cannot simply return it as not all 4 faces are necessarily present.
uint8_t faceIndex = (wantItalic ? kItalicMask : 0) |
(wantBold ? kBoldMask : 0);
// if the desired style is available, return it directly
gfxFontEntry *fe = mAvailableFonts[faceIndex];
if (fe) {
// no need to set aNeedsSyntheticBold here as we matched the boldness request
return fe;
}
// order to check fallback faces in a simple family, depending on requested style
static const uint8_t simpleFallbacks[4][3] = {
{ kBoldFaceIndex, kItalicFaceIndex, kBoldItalicFaceIndex }, // fallbacks for Regular
{ kRegularFaceIndex, kBoldItalicFaceIndex, kItalicFaceIndex },// Bold
{ kBoldItalicFaceIndex, kRegularFaceIndex, kBoldFaceIndex }, // Italic
{ kItalicFaceIndex, kBoldFaceIndex, kRegularFaceIndex } // BoldItalic
};
const uint8_t *order = simpleFallbacks[faceIndex];
for (uint8_t trial = 0; trial < 3; ++trial) {
// check remaining faces in order of preference to find the first that actually exists
fe = mAvailableFonts[order[trial]];
if (fe) {
aNeedsSyntheticBold = wantBold && !fe->IsBold();
return fe;
}
}
// this can't happen unless we have totally broken the font-list manager!
NS_NOTREACHED("no face found in simple font family!");
return nullptr;
}
// This is a large/rich font family, so we do full style- and weight-matching:
// first collect a list of weights that are the best match for the requested
// font-stretch and font-style, then pick the best weight match among those
// available.
gfxFontEntry *weightList[10] = { 0 };
bool foundWeights = FindWeightsForStyle(weightList, wantItalic, aFontStyle.stretch);
if (!foundWeights) {
return nullptr;
}
// First find a match for the best weight
int8_t matchBaseWeight = 0;
int8_t i = baseWeight;
// Need to special case when normal face doesn't exist but medium does.
// In that case, use medium otherwise weights < 400
if (baseWeight == 4 && !weightList[4]) {
i = 5; // medium
}
// Loop through weights, since one exists loop will terminate
int8_t direction = (baseWeight > 5) ? 1 : -1;
for (; ; i += direction) {
if (weightList[i]) {
matchBaseWeight = i;
break;
}
// If we've reached one side without finding a font,
// start over and go the other direction until we find a match
if (i == 1 || i == 9) {
i = baseWeight;
direction = -direction;
}
}
NS_ASSERTION(matchBaseWeight != 0,
"weight mapping should always find at least one font in a family");
gfxFontEntry *matchFE = weightList[matchBaseWeight];
NS_ASSERTION(matchFE,
"weight mapping should always find at least one font in a family");
if (!matchFE->IsBold() && baseWeight >= 6)
{
aNeedsSyntheticBold = true;
}
return matchFE;
}
void
gfxFontFamily::CheckForSimpleFamily()
{
uint32_t count = mAvailableFonts.Length();
if (count > 4 || count == 0) {
return; // can't be "simple" if there are >4 faces;
// if none then the family is unusable anyway
}
if (count == 1) {
mIsSimpleFamily = true;
return;
}
int16_t firstStretch = mAvailableFonts[0]->Stretch();
gfxFontEntry *faces[4] = { 0 };
for (uint8_t i = 0; i < count; ++i) {
gfxFontEntry *fe = mAvailableFonts[i];
if (fe->Stretch() != firstStretch) {
return; // font-stretch doesn't match, don't treat as simple family
}
uint8_t faceIndex = (fe->IsItalic() ? kItalicMask : 0) |
(fe->Weight() >= 600 ? kBoldMask : 0);
if (faces[faceIndex]) {
return; // two faces resolve to the same slot; family isn't "simple"
}
faces[faceIndex] = fe;
}
// we have successfully slotted the available faces into the standard
// 4-face framework
mAvailableFonts.SetLength(4);
for (uint8_t i = 0; i < 4; ++i) {
if (mAvailableFonts[i].get() != faces[i]) {
mAvailableFonts[i].swap(faces[i]);
}
}
mIsSimpleFamily = true;
}
static inline uint32_t
StyleDistance(gfxFontEntry *aFontEntry,
bool anItalic, int16_t aStretch)
{
// Compute a measure of the "distance" between the requested style
// and the given fontEntry,
// considering italicness and font-stretch but not weight.
int32_t distance = 0;
if (aStretch != aFontEntry->mStretch) {
// stretch values are in the range -4 .. +4
// if aStretch is positive, we prefer more-positive values;
// if zero or negative, prefer more-negative
if (aStretch > 0) {
distance = (aFontEntry->mStretch - aStretch) * 2;
} else {
distance = (aStretch - aFontEntry->mStretch) * 2;
}
// if the computed "distance" here is negative, it means that
// aFontEntry lies in the "non-preferred" direction from aStretch,
// so we treat that as larger than any preferred-direction distance
// (max possible is 8) by adding an extra 10 to the absolute value
if (distance < 0) {
distance = -distance + 10;
}
}
if (aFontEntry->IsItalic() != anItalic) {
distance += 1;
}
return uint32_t(distance);
}
bool
gfxFontFamily::FindWeightsForStyle(gfxFontEntry* aFontsForWeights[],
bool anItalic, int16_t aStretch)
{
uint32_t foundWeights = 0;
uint32_t bestMatchDistance = 0xffffffff;
uint32_t count = mAvailableFonts.Length();
for (uint32_t i = 0; i < count; i++) {
// this is not called for "simple" families, and therefore it does not
// need to check the mAvailableFonts entries for NULL
gfxFontEntry *fe = mAvailableFonts[i];
uint32_t distance = StyleDistance(fe, anItalic, aStretch);
if (distance <= bestMatchDistance) {
int8_t wt = fe->mWeight / 100;
NS_ASSERTION(wt >= 1 && wt < 10, "invalid weight in fontEntry");
if (!aFontsForWeights[wt]) {
// record this as a possible candidate for weight matching
aFontsForWeights[wt] = fe;
++foundWeights;
} else {
uint32_t prevDistance =
StyleDistance(aFontsForWeights[wt], anItalic, aStretch);
if (prevDistance >= distance) {
// replacing a weight we already found,
// so don't increment foundWeights
aFontsForWeights[wt] = fe;
}
}
bestMatchDistance = distance;
}
}
NS_ASSERTION(foundWeights > 0, "Font family containing no faces?");
if (foundWeights == 1) {
// no need to cull entries if we only found one weight
return true;
}
// we might have recorded some faces that were a partial style match, but later found
// others that were closer; in this case, we need to cull the poorer matches from the
// weight list we'll return
for (uint32_t i = 0; i < 10; ++i) {
if (aFontsForWeights[i] &&
StyleDistance(aFontsForWeights[i], anItalic, aStretch) > bestMatchDistance)
{
aFontsForWeights[i] = 0;
}
}
return (foundWeights > 0);
}
void gfxFontFamily::LocalizedName(nsAString& aLocalizedName)
{
// just return the primary name; subclasses should override
aLocalizedName = mName;
}
// metric for how close a given font matches a style
static int32_t
CalcStyleMatch(gfxFontEntry *aFontEntry, const gfxFontStyle *aStyle)
{
int32_t rank = 0;
if (aStyle) {
// italics
bool wantItalic =
(aStyle->style & (NS_FONT_STYLE_ITALIC | NS_FONT_STYLE_OBLIQUE)) != 0;
if (aFontEntry->IsItalic() == wantItalic) {
rank += 10;
}
// measure of closeness of weight to the desired value
rank += 9 - abs(aFontEntry->Weight() / 100 - aStyle->ComputeWeight());
} else {
// if no font to match, prefer non-bold, non-italic fonts
if (!aFontEntry->IsItalic()) {
rank += 3;
}
if (!aFontEntry->IsBold()) {
rank += 2;
}
}
return rank;
}
#define RANK_MATCHED_CMAP 20
void
gfxFontFamily::FindFontForChar(GlobalFontMatch *aMatchData)
{
if (mFamilyCharacterMapInitialized && !TestCharacterMap(aMatchData->mCh)) {
// none of the faces in the family support the required char,
// so bail out immediately
return;
}
bool needsBold;
gfxFontStyle normal;
gfxFontEntry *fe = FindFontForStyle(
(aMatchData->mStyle == nullptr) ? *aMatchData->mStyle : normal,
needsBold);
if (fe && !fe->SkipDuringSystemFallback()) {
int32_t rank = 0;
if (fe->TestCharacterMap(aMatchData->mCh)) {
rank += RANK_MATCHED_CMAP;
aMatchData->mCount++;
#ifdef PR_LOGGING
PRLogModuleInfo *log = gfxPlatform::GetLog(eGfxLog_textrun);
if (NS_UNLIKELY(log)) {
uint32_t charRange = gfxFontUtils::CharRangeBit(aMatchData->mCh);
uint32_t unicodeRange = FindCharUnicodeRange(aMatchData->mCh);
uint32_t script = GetScriptCode(aMatchData->mCh);
PR_LOG(log, PR_LOG_DEBUG,\
("(textrun-systemfallback-fonts) char: u+%6.6x "
"char-range: %d unicode-range: %d script: %d match: [%s]\n",
aMatchData->mCh,
charRange, unicodeRange, script,
NS_ConvertUTF16toUTF8(fe->Name()).get()));
}
#endif
}
aMatchData->mCmapsTested++;
if (rank == 0) {
return;
}
// omitting from original windows code -- family name, lang group, pitch
// not available in current FontEntry implementation
rank += CalcStyleMatch(fe, aMatchData->mStyle);
// xxx - add whether AAT font with morphing info for specific lang groups
if (rank > aMatchData->mMatchRank
|| (rank == aMatchData->mMatchRank &&
Compare(fe->Name(), aMatchData->mBestMatch->Name()) > 0))
{
aMatchData->mBestMatch = fe;
aMatchData->mMatchRank = rank;
}
}
}
void
gfxFontFamily::SearchAllFontsForChar(GlobalFontMatch *aMatchData)
{
uint32_t i, numFonts = mAvailableFonts.Length();
for (i = 0; i < numFonts; i++) {
gfxFontEntry *fe = mAvailableFonts[i];
if (fe && fe->TestCharacterMap(aMatchData->mCh)) {
int32_t rank = RANK_MATCHED_CMAP;
rank += CalcStyleMatch(fe, aMatchData->mStyle);
if (rank > aMatchData->mMatchRank
|| (rank == aMatchData->mMatchRank &&
Compare(fe->Name(), aMatchData->mBestMatch->Name()) > 0))
{
aMatchData->mBestMatch = fe;
aMatchData->mMatchRank = rank;
}
}
}
}
// returns true if other names were found, false otherwise
bool
gfxFontFamily::ReadOtherFamilyNamesForFace(gfxPlatformFontList *aPlatformFontList,
FallibleTArray<uint8_t>& aNameTable,
bool useFullName)
{
const uint8_t *nameData = aNameTable.Elements();
uint32_t dataLength = aNameTable.Length();
const gfxFontUtils::NameHeader *nameHeader =
reinterpret_cast<const gfxFontUtils::NameHeader*>(nameData);
uint32_t nameCount = nameHeader->count;
if (nameCount * sizeof(gfxFontUtils::NameRecord) > dataLength) {
NS_WARNING("invalid font (name records)");
return false;
}
const gfxFontUtils::NameRecord *nameRecord =
reinterpret_cast<const gfxFontUtils::NameRecord*>(nameData + sizeof(gfxFontUtils::NameHeader));
uint32_t stringsBase = uint32_t(nameHeader->stringOffset);
bool foundNames = false;
for (uint32_t i = 0; i < nameCount; i++, nameRecord++) {
uint32_t nameLen = nameRecord->length;
uint32_t nameOff = nameRecord->offset; // offset from base of string storage
if (stringsBase + nameOff + nameLen > dataLength) {
NS_WARNING("invalid font (name table strings)");
return false;
}
uint16_t nameID = nameRecord->nameID;
if ((useFullName && nameID == gfxFontUtils::NAME_ID_FULL) ||
(!useFullName && (nameID == gfxFontUtils::NAME_ID_FAMILY ||
nameID == gfxFontUtils::NAME_ID_PREFERRED_FAMILY))) {
nsAutoString otherFamilyName;
bool ok = gfxFontUtils::DecodeFontName(nameData + stringsBase + nameOff,
nameLen,
uint32_t(nameRecord->platformID),
uint32_t(nameRecord->encodingID),
uint32_t(nameRecord->languageID),
otherFamilyName);
// add if not same as canonical family name
if (ok && otherFamilyName != mName) {
aPlatformFontList->AddOtherFamilyName(this, otherFamilyName);
foundNames = true;
}
}
}
return foundNames;
}
void
gfxFontFamily::ReadOtherFamilyNames(gfxPlatformFontList *aPlatformFontList)
{
if (mOtherFamilyNamesInitialized)
return;
mOtherFamilyNamesInitialized = true;
FindStyleVariations();
// read in other family names for the first face in the list
uint32_t i, numFonts = mAvailableFonts.Length();
const uint32_t kNAME = TRUETYPE_TAG('n','a','m','e');
AutoFallibleTArray<uint8_t,8192> buffer;
for (i = 0; i < numFonts; ++i) {
gfxFontEntry *fe = mAvailableFonts[i];
if (!fe)
continue;
if (fe->GetFontTable(kNAME, buffer) != NS_OK)
continue;
mHasOtherFamilyNames = ReadOtherFamilyNamesForFace(aPlatformFontList,
buffer);
break;
}
// read in other names for the first face in the list with the assumption
// that if extra names don't exist in that face then they don't exist in
// other faces for the same font
if (!mHasOtherFamilyNames)
return;
// read in names for all faces, needed to catch cases where fonts have
// family names for individual weights (e.g. Hiragino Kaku Gothic Pro W6)
for ( ; i < numFonts; i++) {
gfxFontEntry *fe = mAvailableFonts[i];
if (!fe)
continue;
if (fe->GetFontTable(kNAME, buffer) != NS_OK)
continue;
ReadOtherFamilyNamesForFace(aPlatformFontList, buffer);
}
}
void
gfxFontFamily::ReadFaceNames(gfxPlatformFontList *aPlatformFontList,
bool aNeedFullnamePostscriptNames)
{
// if all needed names have already been read, skip
if (mOtherFamilyNamesInitialized &&
(mFaceNamesInitialized || !aNeedFullnamePostscriptNames))
return;
FindStyleVariations();
uint32_t i, numFonts = mAvailableFonts.Length();
const uint32_t kNAME = TRUETYPE_TAG('n','a','m','e');
AutoFallibleTArray<uint8_t,8192> buffer;
nsAutoString fullname, psname;
bool firstTime = true, readAllFaces = false;
for (i = 0; i < numFonts; ++i) {
gfxFontEntry *fe = mAvailableFonts[i];
if (!fe)
continue;
if (fe->GetFontTable(kNAME, buffer) != NS_OK)
continue;
if (aNeedFullnamePostscriptNames) {
if (gfxFontUtils::ReadCanonicalName(
buffer, gfxFontUtils::NAME_ID_FULL, fullname) == NS_OK)
{
aPlatformFontList->AddFullname(fe, fullname);
}
if (gfxFontUtils::ReadCanonicalName(
buffer, gfxFontUtils::NAME_ID_POSTSCRIPT, psname) == NS_OK)
{
aPlatformFontList->AddPostscriptName(fe, psname);
}
}
if (!mOtherFamilyNamesInitialized && (firstTime || readAllFaces)) {
bool foundOtherName = ReadOtherFamilyNamesForFace(aPlatformFontList,
buffer);
// if the first face has a different name, scan all faces, otherwise
// assume the family doesn't have other names
if (firstTime && foundOtherName) {
mHasOtherFamilyNames = true;
readAllFaces = true;
}
firstTime = false;
}
// if not reading in any more names, skip other faces
if (!readAllFaces && !aNeedFullnamePostscriptNames)
break;
}
mFaceNamesInitialized = true;
mOtherFamilyNamesInitialized = true;
}
gfxFontEntry*
gfxFontFamily::FindFont(const nsAString& aPostscriptName)
{
// find the font using a simple linear search
uint32_t numFonts = mAvailableFonts.Length();
for (uint32_t i = 0; i < numFonts; i++) {
gfxFontEntry *fe = mAvailableFonts[i].get();
if (fe && fe->Name() == aPostscriptName)
return fe;
}
return nullptr;
}
void
gfxFontFamily::SizeOfExcludingThis(nsMallocSizeOfFun aMallocSizeOf,
FontListSizes* aSizes) const
{
aSizes->mFontListSize +=
mName.SizeOfExcludingThisIfUnshared(aMallocSizeOf);
aSizes->mCharMapsSize +=
mFamilyCharacterMap.SizeOfExcludingThis(aMallocSizeOf);
aSizes->mFontListSize +=
mAvailableFonts.SizeOfExcludingThis(aMallocSizeOf);
for (uint32_t i = 0; i < mAvailableFonts.Length(); ++i) {
gfxFontEntry *fe = mAvailableFonts[i];
if (fe) {
fe->SizeOfIncludingThis(aMallocSizeOf, aSizes);
}
}
}
void
gfxFontFamily::SizeOfIncludingThis(nsMallocSizeOfFun aMallocSizeOf,
FontListSizes* aSizes) const
{
aSizes->mFontListSize += aMallocSizeOf(this);
SizeOfExcludingThis(aMallocSizeOf, aSizes);
}
/*
* gfxFontCache - global cache of gfxFont instances.
* Expires unused fonts after a short interval;
* notifies fonts to age their cached shaped-word records;
* observes memory-pressure notification and tells fonts to clear their
* shaped-word caches to free up memory.
*/
NS_IMPL_ISUPPORTS1(gfxFontCache::MemoryReporter, nsIMemoryMultiReporter)
NS_MEMORY_REPORTER_MALLOC_SIZEOF_FUN(FontCacheMallocSizeOf, "font-cache")
NS_IMETHODIMP
gfxFontCache::MemoryReporter::GetName(nsACString &aName)
{
aName.AssignLiteral("font-cache");
return NS_OK;
}
NS_IMETHODIMP
gfxFontCache::MemoryReporter::CollectReports
(nsIMemoryMultiReporterCallback* aCb,
nsISupports* aClosure)
{
FontCacheSizes sizes;
gfxFontCache::GetCache()->SizeOfIncludingThis(&FontCacheMallocSizeOf,
&sizes);
aCb->Callback(EmptyCString(),
NS_LITERAL_CSTRING("explicit/gfx/font-cache"),
nsIMemoryReporter::KIND_HEAP, nsIMemoryReporter::UNITS_BYTES,
sizes.mFontInstances,
NS_LITERAL_CSTRING("Memory used for active font instances."),
aClosure);
aCb->Callback(EmptyCString(),
NS_LITERAL_CSTRING("explicit/gfx/font-shaped-words"),
nsIMemoryReporter::KIND_HEAP, nsIMemoryReporter::UNITS_BYTES,
sizes.mShapedWords,
NS_LITERAL_CSTRING("Memory used to cache shaped glyph data."),
aClosure);
return NS_OK;
}
NS_IMETHODIMP
gfxFontCache::MemoryReporter::GetExplicitNonHeap(int64_t* aAmount)
{
// This reporter only measures heap memory.
*aAmount = 0;
return NS_OK;
}
// Observer for the memory-pressure notification, to trigger
// flushing of the shaped-word caches
class MemoryPressureObserver MOZ_FINAL : public nsIObserver,
public nsSupportsWeakReference
{
public:
NS_DECL_ISUPPORTS
NS_DECL_NSIOBSERVER
};
NS_IMPL_ISUPPORTS2(MemoryPressureObserver, nsIObserver, nsISupportsWeakReference)
NS_IMETHODIMP
MemoryPressureObserver::Observe(nsISupports *aSubject,
const char *aTopic,
const PRUnichar *someData)
{
if (!nsCRT::strcmp(aTopic, "memory-pressure")) {
gfxFontCache *fontCache = gfxFontCache::GetCache();
if (fontCache) {
fontCache->FlushShapedWordCaches();
}
}
return NS_OK;
}
nsresult
gfxFontCache::Init()
{
NS_ASSERTION(!gGlobalCache, "Where did this come from?");
gGlobalCache = new gfxFontCache();
if (!gGlobalCache) {
return NS_ERROR_OUT_OF_MEMORY;
}
NS_RegisterMemoryMultiReporter(new MemoryReporter);
return NS_OK;
}
void
gfxFontCache::Shutdown()
{
delete gGlobalCache;
gGlobalCache = nullptr;
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
printf("Textrun storage high water mark=%d\n", gTextRunStorageHighWaterMark);
printf("Total number of fonts=%d\n", gFontCount);
printf("Total glyph extents allocated=%d (size %d)\n", gGlyphExtentsCount,
int(gGlyphExtentsCount*sizeof(gfxGlyphExtents)));
printf("Total glyph extents width-storage size allocated=%d\n", gGlyphExtentsWidthsTotalSize);
printf("Number of simple glyph extents eagerly requested=%d\n", gGlyphExtentsSetupEagerSimple);
printf("Number of tight glyph extents eagerly requested=%d\n", gGlyphExtentsSetupEagerTight);
printf("Number of tight glyph extents lazily requested=%d\n", gGlyphExtentsSetupLazyTight);
printf("Number of simple glyph extent setups that fell back to tight=%d\n", gGlyphExtentsSetupFallBackToTight);
#endif
}
gfxFontCache::gfxFontCache()
: nsExpirationTracker<gfxFont,3>(FONT_TIMEOUT_SECONDS * 1000)
{
mFonts.Init();
nsCOMPtr<nsIObserverService> obs = GetObserverService();
if (obs) {
obs->AddObserver(new MemoryPressureObserver, "memory-pressure", false);
}
#if 0 // disabled due to crashiness, see bug 717175
mWordCacheExpirationTimer = do_CreateInstance("@mozilla.org/timer;1");
if (mWordCacheExpirationTimer) {
mWordCacheExpirationTimer->
InitWithFuncCallback(WordCacheExpirationTimerCallback, this,
SHAPED_WORD_TIMEOUT_SECONDS * 1000,
nsITimer::TYPE_REPEATING_SLACK);
}
#endif
}
gfxFontCache::~gfxFontCache()
{
if (mWordCacheExpirationTimer) {
mWordCacheExpirationTimer->Cancel();
mWordCacheExpirationTimer = nullptr;
}
// Expire everything that has a zero refcount, so we don't leak them.
AgeAllGenerations();
// All fonts should be gone.
NS_WARN_IF_FALSE(mFonts.Count() == 0,
"Fonts still alive while shutting down gfxFontCache");
// Note that we have to delete everything through the expiration
// tracker, since there might be fonts not in the hashtable but in
// the tracker.
}
bool
gfxFontCache::HashEntry::KeyEquals(const KeyTypePointer aKey) const
{
return aKey->mFontEntry == mFont->GetFontEntry() &&
aKey->mStyle->Equals(*mFont->GetStyle());
}
already_AddRefed<gfxFont>
gfxFontCache::Lookup(const gfxFontEntry *aFontEntry,
const gfxFontStyle *aStyle)
{
Key key(aFontEntry, aStyle);
HashEntry *entry = mFonts.GetEntry(key);
Telemetry::Accumulate(Telemetry::FONT_CACHE_HIT, entry != nullptr);
if (!entry)
return nullptr;
gfxFont *font = entry->mFont;
NS_ADDREF(font);
return font;
}
void
gfxFontCache::AddNew(gfxFont *aFont)
{
Key key(aFont->GetFontEntry(), aFont->GetStyle());
HashEntry *entry = mFonts.PutEntry(key);
if (!entry)
return;
gfxFont *oldFont = entry->mFont;
entry->mFont = aFont;
// If someone's asked us to replace an existing font entry, then that's a
// bit weird, but let it happen, and expire the old font if it's not used.
if (oldFont && oldFont->GetExpirationState()->IsTracked()) {
// if oldFont == aFont, recount should be > 0,
// so we shouldn't be here.
NS_ASSERTION(aFont != oldFont, "new font is tracked for expiry!");
NotifyExpired(oldFont);
}
}
void
gfxFontCache::NotifyReleased(gfxFont *aFont)
{
nsresult rv = AddObject(aFont);
if (NS_FAILED(rv)) {
// We couldn't track it for some reason. Kill it now.
DestroyFont(aFont);
}
// Note that we might have fonts that aren't in the hashtable, perhaps because
// of OOM adding to the hashtable or because someone did an AddNew where
// we already had a font. These fonts are added to the expiration tracker
// anyway, even though Lookup can't resurrect them. Eventually they will
// expire and be deleted.
}
void
gfxFontCache::NotifyExpired(gfxFont *aFont)
{
aFont->ClearCachedWords();
RemoveObject(aFont);
DestroyFont(aFont);
}
void
gfxFontCache::DestroyFont(gfxFont *aFont)
{
Key key(aFont->GetFontEntry(), aFont->GetStyle());
HashEntry *entry = mFonts.GetEntry(key);
if (entry && entry->mFont == aFont)
mFonts.RemoveEntry(key);
NS_ASSERTION(aFont->GetRefCount() == 0,
"Destroying with non-zero ref count!");
delete aFont;
}
/*static*/
PLDHashOperator
gfxFontCache::AgeCachedWordsForFont(HashEntry* aHashEntry, void* aUserData)
{
aHashEntry->mFont->AgeCachedWords();
return PL_DHASH_NEXT;
}
/*static*/
void
gfxFontCache::WordCacheExpirationTimerCallback(nsITimer* aTimer, void* aCache)
{
gfxFontCache* cache = static_cast<gfxFontCache*>(aCache);
cache->mFonts.EnumerateEntries(AgeCachedWordsForFont, nullptr);
}
/*static*/
PLDHashOperator
gfxFontCache::ClearCachedWordsForFont(HashEntry* aHashEntry, void* aUserData)
{
aHashEntry->mFont->ClearCachedWords();
return PL_DHASH_NEXT;
}
/*static*/
size_t
gfxFontCache::SizeOfFontEntryExcludingThis(HashEntry* aHashEntry,
nsMallocSizeOfFun aMallocSizeOf,
void* aUserArg)
{
HashEntry *entry = static_cast<HashEntry*>(aHashEntry);
FontCacheSizes *sizes = static_cast<FontCacheSizes*>(aUserArg);
entry->mFont->SizeOfExcludingThis(aMallocSizeOf, sizes);
// The font records its size in the |sizes| parameter, so we return zero
// here to the hashtable enumerator.
return 0;
}
void
gfxFontCache::SizeOfExcludingThis(nsMallocSizeOfFun aMallocSizeOf,
FontCacheSizes* aSizes) const
{
// TODO: add the overhead of the expiration tracker (generation arrays)
mFonts.SizeOfExcludingThis(SizeOfFontEntryExcludingThis,
aMallocSizeOf, aSizes);
}
void
gfxFontCache::SizeOfIncludingThis(nsMallocSizeOfFun aMallocSizeOf,
FontCacheSizes* aSizes) const
{
aSizes->mFontInstances += aMallocSizeOf(this);
SizeOfExcludingThis(aMallocSizeOf, aSizes);
}
/* static */ bool
gfxFontShaper::MergeFontFeatures(
const nsTArray<gfxFontFeature>& aStyleRuleFeatures,
const nsTArray<gfxFontFeature>& aFontFeatures,
bool aDisableLigatures,
nsDataHashtable<nsUint32HashKey,uint32_t>& aMergedFeatures)
{
// bail immediately if nothing to do
if (aStyleRuleFeatures.IsEmpty() &&
aFontFeatures.IsEmpty() &&
!aDisableLigatures) {
return false;
}
aMergedFeatures.Init();
// Ligature features are enabled by default in the generic shaper,
// so we explicitly turn them off if necessary (for letter-spacing)
if (aDisableLigatures) {
aMergedFeatures.Put(HB_TAG('l','i','g','a'), 0);
aMergedFeatures.Put(HB_TAG('c','l','i','g'), 0);
}
// add feature values from font
uint32_t i, count;
count = aFontFeatures.Length();
for (i = 0; i < count; i++) {
const gfxFontFeature& feature = aFontFeatures.ElementAt(i);
aMergedFeatures.Put(feature.mTag, feature.mValue);
}
// add feature values from style rules
count = aStyleRuleFeatures.Length();
for (i = 0; i < count; i++) {
const gfxFontFeature& feature = aStyleRuleFeatures.ElementAt(i);
aMergedFeatures.Put(feature.mTag, feature.mValue);
}
return aMergedFeatures.Count() != 0;
}
void
gfxFont::RunMetrics::CombineWith(const RunMetrics& aOther, bool aOtherIsOnLeft)
{
mAscent = NS_MAX(mAscent, aOther.mAscent);
mDescent = NS_MAX(mDescent, aOther.mDescent);
if (aOtherIsOnLeft) {
mBoundingBox =
(mBoundingBox + gfxPoint(aOther.mAdvanceWidth, 0)).Union(aOther.mBoundingBox);
} else {
mBoundingBox =
mBoundingBox.Union(aOther.mBoundingBox + gfxPoint(mAdvanceWidth, 0));
}
mAdvanceWidth += aOther.mAdvanceWidth;
}
gfxFont::gfxFont(gfxFontEntry *aFontEntry, const gfxFontStyle *aFontStyle,
AntialiasOption anAAOption, cairo_scaled_font_t *aScaledFont) :
mScaledFont(aScaledFont),
mFontEntry(aFontEntry), mIsValid(true),
mApplySyntheticBold(false),
mStyle(*aFontStyle),
mAdjustedSize(0.0),
mFUnitsConvFactor(0.0f),
mAntialiasOption(anAAOption)
{
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
++gFontCount;
#endif
}
gfxFont::~gfxFont()
{
uint32_t i, count = mGlyphExtentsArray.Length();
// We destroy the contents of mGlyphExtentsArray explicitly instead of
// using nsAutoPtr because VC++ can't deal with nsTArrays of nsAutoPtrs
// of classes that lack a proper copy constructor
for (i = 0; i < count; ++i) {
delete mGlyphExtentsArray[i];
}
}
/*static*/
PLDHashOperator
gfxFont::AgeCacheEntry(CacheHashEntry *aEntry, void *aUserData)
{
if (!aEntry->mShapedWord) {
NS_ASSERTION(aEntry->mShapedWord, "cache entry has no gfxShapedWord!");
return PL_DHASH_REMOVE;
}
if (aEntry->mShapedWord->IncrementAge() == kShapedWordCacheMaxAge) {
return PL_DHASH_REMOVE;
}
return PL_DHASH_NEXT;
}
hb_blob_t *
gfxFont::GetFontTable(uint32_t aTag) {
hb_blob_t *blob;
if (mFontEntry->GetExistingFontTable(aTag, &blob))
return blob;
FallibleTArray<uint8_t> buffer;
bool haveTable = NS_SUCCEEDED(mFontEntry->GetFontTable(aTag, buffer));
return mFontEntry->ShareFontTableAndGetBlob(aTag,
haveTable ? &buffer : nullptr);
}
/**
* A helper function in case we need to do any rounding or other
* processing here.
*/
#define ToDeviceUnits(aAppUnits, aDevUnitsPerAppUnit) \
(double(aAppUnits)*double(aDevUnitsPerAppUnit))
struct GlyphBuffer {
#define GLYPH_BUFFER_SIZE (2048/sizeof(cairo_glyph_t))
cairo_glyph_t mGlyphBuffer[GLYPH_BUFFER_SIZE];
unsigned int mNumGlyphs;
GlyphBuffer()
: mNumGlyphs(0) { }
cairo_glyph_t *AppendGlyph() {
return &mGlyphBuffer[mNumGlyphs++];
}
void Flush(cairo_t *aCR, cairo_pattern_t *aStrokePattern,
gfxFont::DrawMode aDrawMode, bool aReverse,
bool aFinish = false) {
// Ensure there's enough room for a glyph to be added to the buffer
if (!aFinish && mNumGlyphs < GLYPH_BUFFER_SIZE) {
return;
}
if (aReverse) {
for (uint32_t i = 0; i < mNumGlyphs/2; ++i) {
cairo_glyph_t tmp = mGlyphBuffer[i];
mGlyphBuffer[i] = mGlyphBuffer[mNumGlyphs - 1 - i];
mGlyphBuffer[mNumGlyphs - 1 - i] = tmp;
}
}
if (aDrawMode == gfxFont::GLYPH_PATH) {
cairo_glyph_path(aCR, mGlyphBuffer, mNumGlyphs);
} else {
if (aDrawMode & gfxFont::GLYPH_FILL) {
SAMPLE_LABEL("GlyphBuffer", "cairo_show_glyphs");
cairo_show_glyphs(aCR, mGlyphBuffer, mNumGlyphs);
}
if (aDrawMode & gfxFont::GLYPH_STROKE) {
if (aStrokePattern) {
cairo_save(aCR);
cairo_set_source(aCR, aStrokePattern);
}
cairo_new_path(aCR);
cairo_glyph_path(aCR, mGlyphBuffer, mNumGlyphs);
cairo_stroke(aCR);
if (aStrokePattern) {
cairo_restore(aCR);
}
}
}
mNumGlyphs = 0;
}
#undef GLYPH_BUFFER_SIZE
};
struct GlyphBufferAzure {
#define GLYPH_BUFFER_SIZE (2048/sizeof(Glyph))
Glyph mGlyphBuffer[GLYPH_BUFFER_SIZE];
unsigned int mNumGlyphs;
GlyphBufferAzure()
: mNumGlyphs(0) { }
Glyph *AppendGlyph() {
return &mGlyphBuffer[mNumGlyphs++];
}
void Flush(DrawTarget *aDT, gfxPattern *aStrokePattern, ScaledFont *aFont,
gfxFont::DrawMode aDrawMode, bool aReverse, const GlyphRenderingOptions *aOptions,
gfxContext *aThebesContext, const Matrix *invFontMatrix, bool aFinish = false)
{
// Ensure there's enough room for a glyph to be added to the buffer
if (!aFinish && mNumGlyphs < GLYPH_BUFFER_SIZE || !mNumGlyphs) {
return;
}
if (aReverse) {
Glyph *begin = &mGlyphBuffer[0];
Glyph *end = &mGlyphBuffer[mNumGlyphs];
std::reverse(begin, end);
}
gfx::GlyphBuffer buf;
buf.mGlyphs = mGlyphBuffer;
buf.mNumGlyphs = mNumGlyphs;
gfxContext::AzureState state = aThebesContext->CurrentState();
if (aDrawMode & gfxFont::GLYPH_FILL) {
if (state.pattern) {
Pattern *pat = state.pattern->GetPattern(aDT, state.patternTransformChanged ? &state.patternTransform : nullptr);
if (invFontMatrix) {
// The brush matrix needs to be multiplied with the inverted matrix
// as well, to move the brush into the space of the glyphs. Before
// the render target transformation
// This relies on the returned Pattern not to be reused by
// others, but regenerated on GetPattern calls. This is true!
Matrix *mat = nullptr;
if (pat->GetType() == PATTERN_LINEAR_GRADIENT) {
mat = &static_cast<LinearGradientPattern*>(pat)->mMatrix;
} else if (pat->GetType() == PATTERN_RADIAL_GRADIENT) {
mat = &static_cast<RadialGradientPattern*>(pat)->mMatrix;
} else if (pat->GetType() == PATTERN_SURFACE) {
mat = &static_cast<SurfacePattern*>(pat)->mMatrix;
}
if (mat) {
*mat = (*mat) * (*invFontMatrix);
}
}
aDT->FillGlyphs(aFont, buf, *pat,
DrawOptions(), aOptions);
} else if (state.sourceSurface) {
aDT->FillGlyphs(aFont, buf, SurfacePattern(state.sourceSurface,
EXTEND_CLAMP,
state.surfTransform),
DrawOptions(), aOptions);
} else {
aDT->FillGlyphs(aFont, buf, ColorPattern(state.color),
DrawOptions(), aOptions);
}
}
if (aDrawMode & gfxFont::GLYPH_PATH) {
aThebesContext->EnsurePathBuilder();
aFont->CopyGlyphsToBuilder(buf, aThebesContext->mPathBuilder);
}
if (aDrawMode & gfxFont::GLYPH_STROKE) {
RefPtr<Path> path = aFont->GetPathForGlyphs(buf, aDT);
if (aStrokePattern) {
aDT->Stroke(path, *aStrokePattern->GetPattern(aDT), state.strokeOptions);
}
}
mNumGlyphs = 0;
}
#undef GLYPH_BUFFER_SIZE
};
// Bug 674909. When synthetic bolding text by drawing twice, need to
// render using a pixel offset in device pixels, otherwise text
// doesn't appear bolded, it appears as if a bad text shadow exists
// when a non-identity transform exists. Use an offset factor so that
// the second draw occurs at a constant offset in device pixels.
double
gfxFont::CalcXScale(gfxContext *aContext)
{
// determine magnitude of a 1px x offset in device space
gfxSize t = aContext->UserToDevice(gfxSize(1.0, 0.0));
if (t.width == 1.0 && t.height == 0.0) {
// short-circuit the most common case to avoid sqrt() and division
return 1.0;
}
double m = sqrt(t.width * t.width + t.height * t.height);
NS_ASSERTION(m != 0.0, "degenerate transform while synthetic bolding");
if (m == 0.0) {
return 0.0; // effectively disables offset
}
// scale factor so that offsets are 1px in device pixels
return 1.0 / m;
}
void
gfxFont::Draw(gfxTextRun *aTextRun, uint32_t aStart, uint32_t aEnd,
gfxContext *aContext, DrawMode aDrawMode, gfxPoint *aPt,
Spacing *aSpacing, gfxPattern *aStrokePattern)
{
NS_ASSERTION(aDrawMode <= gfxFont::GLYPH_PATH, "GLYPH_PATH cannot be used with GLYPH_FILL or GLYPH_STROKE");
// We have to multiply the stroke matrix by the context matrix as cairo
// multiplies by the inverse of the context matrix when the pattern is set
gfxMatrix strokeMatrix;
if (aStrokePattern) {
strokeMatrix = aStrokePattern->GetMatrix();
aStrokePattern->SetMatrix(aContext->CurrentMatrix().Multiply(strokeMatrix));
}
if (aStart >= aEnd)
return;
const gfxTextRun::CompressedGlyph *charGlyphs = aTextRun->GetCharacterGlyphs();
const uint32_t appUnitsPerDevUnit = aTextRun->GetAppUnitsPerDevUnit();
const double devUnitsPerAppUnit = 1.0/double(appUnitsPerDevUnit);
bool isRTL = aTextRun->IsRightToLeft();
double direction = aTextRun->GetDirection();
// synthetic-bold strikes are each offset one device pixel in run direction
// (these values are only needed if IsSyntheticBold() is true)
double synBoldOnePixelOffset = 0;
int32_t strikes = 0;
if (IsSyntheticBold()) {
double xscale = CalcXScale(aContext);
synBoldOnePixelOffset = direction * xscale;
// use as many strikes as needed for the the increased advance
strikes = NS_lroundf(GetSyntheticBoldOffset() / xscale);
}
uint32_t i;
// Current position in appunits
double x = aPt->x;
double y = aPt->y;
cairo_t *cr = aContext->GetCairo();
RefPtr<DrawTarget> dt = aContext->GetDrawTarget();
if (aContext->IsCairo()) {
cairo_pattern_t *strokePattern = nullptr;
if (aStrokePattern) {
strokePattern = aStrokePattern->CairoPattern();
}
bool success = SetupCairoFont(aContext);
if (NS_UNLIKELY(!success))
return;
::GlyphBuffer glyphs;
cairo_glyph_t *glyph;
if (aSpacing) {
x += direction*aSpacing[0].mBefore;
}
for (i = aStart; i < aEnd; ++i) {
const gfxTextRun::CompressedGlyph *glyphData = &charGlyphs[i];
if (glyphData->IsSimpleGlyph()) {
glyph = glyphs.AppendGlyph();
glyph->index = glyphData->GetSimpleGlyph();
double advance = glyphData->GetSimpleAdvance();
// Perhaps we should put a scale in the cairo context instead of
// doing this scaling here...
// Multiplying by the reciprocal may introduce tiny error here,
// but we assume cairo is going to round coordinates at some stage
// and this is faster
double glyphX;
if (isRTL) {
x -= advance;
glyphX = x;
} else {
glyphX = x;
x += advance;
}
glyph->x = ToDeviceUnits(glyphX, devUnitsPerAppUnit);
glyph->y = ToDeviceUnits(y, devUnitsPerAppUnit);
glyphs.Flush(cr, strokePattern, aDrawMode, isRTL);
// synthetic bolding by multi-striking with 1-pixel offsets
// at least once, more if there's room (large font sizes)
if (IsSyntheticBold()) {
double strikeOffset = synBoldOnePixelOffset;
int32_t strikeCount = strikes;
do {
cairo_glyph_t *doubleglyph;
doubleglyph = glyphs.AppendGlyph();
doubleglyph->index = glyph->index;
doubleglyph->x =
ToDeviceUnits(glyphX + strikeOffset * appUnitsPerDevUnit,
devUnitsPerAppUnit);
doubleglyph->y = glyph->y;
strikeOffset += synBoldOnePixelOffset;
glyphs.Flush(cr, strokePattern, aDrawMode, isRTL);
} while (--strikeCount > 0);
}
} else {
uint32_t glyphCount = glyphData->GetGlyphCount();
if (glyphCount > 0) {
const gfxTextRun::DetailedGlyph *details =
aTextRun->GetDetailedGlyphs(i);
NS_ASSERTION(details, "detailedGlyph should not be missing!");
for (uint32_t j = 0; j < glyphCount; ++j, ++details) {
double advance = details->mAdvance;
if (glyphData->IsMissing()) {
// default ignorable characters will have zero advance width.
// we don't have to draw the hexbox for them
if (aDrawMode != gfxFont::GLYPH_PATH && advance > 0) {
double glyphX = x;
if (isRTL) {
glyphX -= advance;
}
gfxPoint pt(ToDeviceUnits(glyphX, devUnitsPerAppUnit),
ToDeviceUnits(y, devUnitsPerAppUnit));
gfxFloat advanceDevUnits = ToDeviceUnits(advance, devUnitsPerAppUnit);
gfxFloat height = GetMetrics().maxAscent;
gfxRect glyphRect(pt.x, pt.y - height, advanceDevUnits, height);
gfxFontMissingGlyphs::DrawMissingGlyph(aContext,
glyphRect,
details->mGlyphID);
}
} else {
glyph = glyphs.AppendGlyph();
glyph->index = details->mGlyphID;
double glyphX = x + details->mXOffset;
if (isRTL) {
glyphX -= advance;
}
glyph->x = ToDeviceUnits(glyphX, devUnitsPerAppUnit);
glyph->y = ToDeviceUnits(y + details->mYOffset, devUnitsPerAppUnit);
glyphs.Flush(cr, strokePattern, aDrawMode, isRTL);
if (IsSyntheticBold()) {
double strikeOffset = synBoldOnePixelOffset;
int32_t strikeCount = strikes;
do {
cairo_glyph_t *doubleglyph;
doubleglyph = glyphs.AppendGlyph();
doubleglyph->index = glyph->index;
doubleglyph->x =
ToDeviceUnits(glyphX + strikeOffset *
appUnitsPerDevUnit,
devUnitsPerAppUnit);
doubleglyph->y = glyph->y;
strikeOffset += synBoldOnePixelOffset;
glyphs.Flush(cr, strokePattern, aDrawMode, isRTL);
} while (--strikeCount > 0);
}
}
x += direction*advance;
}
}
}
if (aSpacing) {
double space = aSpacing[i - aStart].mAfter;
if (i + 1 < aEnd) {
space += aSpacing[i + 1 - aStart].mBefore;
}
x += direction*space;
}
}
if (gfxFontTestStore::CurrentStore()) {
/* This assumes that the tests won't have anything that results
* in more than GLYPH_BUFFER_SIZE glyphs. Do this before we
* flush, since that'll blow away the num_glyphs.
*/
gfxFontTestStore::CurrentStore()->AddItem(GetName(),
glyphs.mGlyphBuffer,
glyphs.mNumGlyphs);
}
// draw any remaining glyphs
glyphs.Flush(cr, strokePattern, aDrawMode, isRTL, true);
} else {
RefPtr<ScaledFont> scaledFont =
gfxPlatform::GetPlatform()->GetScaledFontForFont(dt, this);
if (!scaledFont) {
return;
}
bool oldSubpixelAA = dt->GetPermitSubpixelAA();
if (!AllowSubpixelAA()) {
dt->SetPermitSubpixelAA(false);
}
GlyphBufferAzure glyphs;
Glyph *glyph;
Matrix mat, matInv;
Matrix oldMat = dt->GetTransform();
// This is NULL when we have inverse-transformed glyphs and we need to
// transform the Brush inside flush.
Matrix *passedInvMatrix = nullptr;
RefPtr<GlyphRenderingOptions> renderingOptions =
GetGlyphRenderingOptions();
if (mScaledFont) {
cairo_matrix_t matrix;
cairo_scaled_font_get_font_matrix(mScaledFont, &matrix);
if (matrix.xy != 0) {
// If this matrix applies a skew, which can happen when drawing
// oblique fonts, we will set the DrawTarget matrix to apply the
// skew. We'll need to move the glyphs by the inverse of the skew to
// get the glyphs positioned correctly in the new device space
// though, since the font matrix should only be applied to drawing
// the glyphs, and not to their position.
mat = ToMatrix(*reinterpret_cast<gfxMatrix*>(&matrix));
mat._11 = mat._22 = 1.0;
mat._21 /= mAdjustedSize;
dt->SetTransform(mat * oldMat);
matInv = mat;
matInv.Invert();
passedInvMatrix = &matInv;
}
}
if (aSpacing) {
x += direction*aSpacing[0].mBefore;
}
for (i = aStart; i < aEnd; ++i) {
const gfxTextRun::CompressedGlyph *glyphData = &charGlyphs[i];
if (glyphData->IsSimpleGlyph()) {
glyph = glyphs.AppendGlyph();
glyph->mIndex = glyphData->GetSimpleGlyph();
double advance = glyphData->GetSimpleAdvance();
// Perhaps we should put a scale in the cairo context instead of
// doing this scaling here...
// Multiplying by the reciprocal may introduce tiny error here,
// but we assume cairo is going to round coordinates at some stage
// and this is faster
double glyphX;
if (isRTL) {
x -= advance;
glyphX = x;
} else {
glyphX = x;
x += advance;
}
glyph->mPosition.x = ToDeviceUnits(glyphX, devUnitsPerAppUnit);
glyph->mPosition.y = ToDeviceUnits(y, devUnitsPerAppUnit);
glyph->mPosition = matInv * glyph->mPosition;
glyphs.Flush(dt, aStrokePattern, scaledFont,
aDrawMode, isRTL, renderingOptions,
aContext, passedInvMatrix);
// synthetic bolding by multi-striking with 1-pixel offsets
// at least once, more if there's room (large font sizes)
if (IsSyntheticBold()) {
double strikeOffset = synBoldOnePixelOffset;
int32_t strikeCount = strikes;
do {
Glyph *doubleglyph;
doubleglyph = glyphs.AppendGlyph();
doubleglyph->mIndex = glyph->mIndex;
doubleglyph->mPosition.x =
ToDeviceUnits(glyphX + strikeOffset * appUnitsPerDevUnit,
devUnitsPerAppUnit);
doubleglyph->mPosition.y = glyph->mPosition.y;
doubleglyph->mPosition = matInv * doubleglyph->mPosition;
strikeOffset += synBoldOnePixelOffset;
glyphs.Flush(dt, aStrokePattern, scaledFont,
aDrawMode, isRTL, renderingOptions,
aContext, passedInvMatrix);
} while (--strikeCount > 0);
}
} else {
uint32_t glyphCount = glyphData->GetGlyphCount();
if (glyphCount > 0) {
const gfxTextRun::DetailedGlyph *details =
aTextRun->GetDetailedGlyphs(i);
NS_ASSERTION(details, "detailedGlyph should not be missing!");
for (uint32_t j = 0; j < glyphCount; ++j, ++details) {
double advance = details->mAdvance;
if (glyphData->IsMissing()) {
// default ignorable characters will have zero advance width.
// we don't have to draw the hexbox for them
if (aDrawMode != gfxFont::GLYPH_PATH && advance > 0) {
double glyphX = x;
if (isRTL) {
glyphX -= advance;
}
gfxPoint pt(ToDeviceUnits(glyphX, devUnitsPerAppUnit),
ToDeviceUnits(y, devUnitsPerAppUnit));
gfxFloat advanceDevUnits = ToDeviceUnits(advance, devUnitsPerAppUnit);
gfxFloat height = GetMetrics().maxAscent;
gfxRect glyphRect(pt.x, pt.y - height, advanceDevUnits, height);
gfxFontMissingGlyphs::DrawMissingGlyph(aContext,
glyphRect,
details->mGlyphID);
}
} else {
glyph = glyphs.AppendGlyph();
glyph->mIndex = details->mGlyphID;
double glyphX = x + details->mXOffset;
if (isRTL) {
glyphX -= advance;
}
glyph->mPosition.x = ToDeviceUnits(glyphX, devUnitsPerAppUnit);
glyph->mPosition.y = ToDeviceUnits(y + details->mYOffset, devUnitsPerAppUnit);
glyph->mPosition = matInv * glyph->mPosition;
glyphs.Flush(dt, aStrokePattern, scaledFont, aDrawMode,
isRTL, renderingOptions, aContext, passedInvMatrix);
if (IsSyntheticBold()) {
double strikeOffset = synBoldOnePixelOffset;
int32_t strikeCount = strikes;
do {
Glyph *doubleglyph;
doubleglyph = glyphs.AppendGlyph();
doubleglyph->mIndex = glyph->mIndex;
doubleglyph->mPosition.x =
ToDeviceUnits(glyphX + strikeOffset *
appUnitsPerDevUnit,
devUnitsPerAppUnit);
doubleglyph->mPosition.y = glyph->mPosition.y;
strikeOffset += synBoldOnePixelOffset;
doubleglyph->mPosition = matInv * doubleglyph->mPosition;
glyphs.Flush(dt, aStrokePattern, scaledFont,
aDrawMode, isRTL, renderingOptions,
aContext, passedInvMatrix);
} while (--strikeCount > 0);
}
}
x += direction*advance;
}
}
}
if (aSpacing) {
double space = aSpacing[i - aStart].mAfter;
if (i + 1 < aEnd) {
space += aSpacing[i + 1 - aStart].mBefore;
}
x += direction*space;
}
}
glyphs.Flush(dt, aStrokePattern, scaledFont, aDrawMode, isRTL,
renderingOptions, aContext, passedInvMatrix, true);
dt->SetTransform(oldMat);
dt->SetPermitSubpixelAA(oldSubpixelAA);
}
// Restore matrix for stroke pattern
if (aStrokePattern) {
aStrokePattern->SetMatrix(strokeMatrix);
}
*aPt = gfxPoint(x, y);
}
static void
UnionRange(gfxFloat aX, gfxFloat* aDestMin, gfxFloat* aDestMax)
{
*aDestMin = NS_MIN(*aDestMin, aX);
*aDestMax = NS_MAX(*aDestMax, aX);
}
// We get precise glyph extents if the textrun creator requested them, or
// if the font is a user font --- in which case the author may be relying
// on overflowing glyphs.
static bool
NeedsGlyphExtents(gfxFont *aFont, gfxTextRun *aTextRun)
{
return (aTextRun->GetFlags() & gfxTextRunFactory::TEXT_NEED_BOUNDING_BOX) ||
aFont->GetFontEntry()->IsUserFont();
}
static bool
NeedsGlyphExtents(gfxTextRun *aTextRun)
{
if (aTextRun->GetFlags() & gfxTextRunFactory::TEXT_NEED_BOUNDING_BOX)
return true;
uint32_t numRuns;
const gfxTextRun::GlyphRun *glyphRuns = aTextRun->GetGlyphRuns(&numRuns);
for (uint32_t i = 0; i < numRuns; ++i) {
if (glyphRuns[i].mFont->GetFontEntry()->IsUserFont())
return true;
}
return false;
}
gfxFont::RunMetrics
gfxFont::Measure(gfxTextRun *aTextRun,
uint32_t aStart, uint32_t aEnd,
BoundingBoxType aBoundingBoxType,
gfxContext *aRefContext,
Spacing *aSpacing)
{
// If aBoundingBoxType is TIGHT_HINTED_OUTLINE_EXTENTS
// and the underlying cairo font may be antialiased,
// we need to create a copy in order to avoid getting cached extents.
// This is only used by MathML layout at present.
if (aBoundingBoxType == TIGHT_HINTED_OUTLINE_EXTENTS &&
mAntialiasOption != kAntialiasNone) {
if (!mNonAAFont) {
mNonAAFont = CopyWithAntialiasOption(kAntialiasNone);
}
// if font subclass doesn't implement CopyWithAntialiasOption(),
// it will return null and we'll proceed to use the existing font
if (mNonAAFont) {
return mNonAAFont->Measure(aTextRun, aStart, aEnd,
TIGHT_HINTED_OUTLINE_EXTENTS,
aRefContext, aSpacing);
}
}
const uint32_t appUnitsPerDevUnit = aTextRun->GetAppUnitsPerDevUnit();
// Current position in appunits
const gfxFont::Metrics& fontMetrics = GetMetrics();
RunMetrics metrics;
metrics.mAscent = fontMetrics.maxAscent*appUnitsPerDevUnit;
metrics.mDescent = fontMetrics.maxDescent*appUnitsPerDevUnit;
if (aStart == aEnd) {
// exit now before we look at aSpacing[0], which is undefined
metrics.mBoundingBox = gfxRect(0, -metrics.mAscent, 0, metrics.mAscent + metrics.mDescent);
return metrics;
}
gfxFloat advanceMin = 0, advanceMax = 0;
const gfxTextRun::CompressedGlyph *charGlyphs = aTextRun->GetCharacterGlyphs();
bool isRTL = aTextRun->IsRightToLeft();
double direction = aTextRun->GetDirection();
bool needsGlyphExtents = NeedsGlyphExtents(this, aTextRun);
gfxGlyphExtents *extents =
(aBoundingBoxType == LOOSE_INK_EXTENTS &&
!needsGlyphExtents &&
!aTextRun->HasDetailedGlyphs()) ? nullptr
: GetOrCreateGlyphExtents(aTextRun->GetAppUnitsPerDevUnit());
double x = 0;
if (aSpacing) {
x += direction*aSpacing[0].mBefore;
}
uint32_t i;
for (i = aStart; i < aEnd; ++i) {
const gfxTextRun::CompressedGlyph *glyphData = &charGlyphs[i];
if (glyphData->IsSimpleGlyph()) {
double advance = glyphData->GetSimpleAdvance();
// Only get the real glyph horizontal extent if we were asked
// for the tight bounding box or we're in quality mode
if ((aBoundingBoxType != LOOSE_INK_EXTENTS || needsGlyphExtents) &&
extents) {
uint32_t glyphIndex = glyphData->GetSimpleGlyph();
uint16_t extentsWidth = extents->GetContainedGlyphWidthAppUnits(glyphIndex);
if (extentsWidth != gfxGlyphExtents::INVALID_WIDTH &&
aBoundingBoxType == LOOSE_INK_EXTENTS) {
UnionRange(x, &advanceMin, &advanceMax);
UnionRange(x + direction*extentsWidth, &advanceMin, &advanceMax);
} else {
gfxRect glyphRect;
if (!extents->GetTightGlyphExtentsAppUnits(this,
aRefContext, glyphIndex, &glyphRect)) {
glyphRect = gfxRect(0, metrics.mBoundingBox.Y(),
advance, metrics.mBoundingBox.Height());
}
if (isRTL) {
glyphRect -= gfxPoint(advance, 0);
}
glyphRect += gfxPoint(x, 0);
metrics.mBoundingBox = metrics.mBoundingBox.Union(glyphRect);
}
}
x += direction*advance;
} else {
uint32_t glyphCount = glyphData->GetGlyphCount();
if (glyphCount > 0) {
const gfxTextRun::DetailedGlyph *details =
aTextRun->GetDetailedGlyphs(i);
NS_ASSERTION(details != nullptr,
"detaiedGlyph record should not be missing!");
uint32_t j;
for (j = 0; j < glyphCount; ++j, ++details) {
uint32_t glyphIndex = details->mGlyphID;
gfxPoint glyphPt(x + details->mXOffset, details->mYOffset);
double advance = details->mAdvance;
gfxRect glyphRect;
if (glyphData->IsMissing() || !extents ||
!extents->GetTightGlyphExtentsAppUnits(this,
aRefContext, glyphIndex, &glyphRect)) {
// We might have failed to get glyph extents due to
// OOM or something
glyphRect = gfxRect(0, -metrics.mAscent,
advance, metrics.mAscent + metrics.mDescent);
}
if (isRTL) {
glyphRect -= gfxPoint(advance, 0);
}
glyphRect += gfxPoint(x, 0);
metrics.mBoundingBox = metrics.mBoundingBox.Union(glyphRect);
x += direction*advance;
}
}
}
// Every other glyph type is ignored
if (aSpacing) {
double space = aSpacing[i - aStart].mAfter;
if (i + 1 < aEnd) {
space += aSpacing[i + 1 - aStart].mBefore;
}
x += direction*space;
}
}
if (aBoundingBoxType == LOOSE_INK_EXTENTS) {
UnionRange(x, &advanceMin, &advanceMax);
gfxRect fontBox(advanceMin, -metrics.mAscent,
advanceMax - advanceMin, metrics.mAscent + metrics.mDescent);
metrics.mBoundingBox = metrics.mBoundingBox.Union(fontBox);
}
if (isRTL) {
metrics.mBoundingBox -= gfxPoint(x, 0);
}
metrics.mAdvanceWidth = x*direction;
return metrics;
}
#define MAX_SHAPING_LENGTH 32760 // slightly less than 32K, trying to avoid
// over-stressing platform shapers
#define BACKTRACK_LIMIT 1024 // If we can't find a space or a cluster start
// within 1K chars, just chop arbitrarily.
// Limiting backtrack here avoids pathological
// behavior on long runs with no whitespace.
static bool
IsBoundarySpace(PRUnichar aChar, PRUnichar aNextChar)
{
return (aChar == ' ' || aChar == 0x00A0) && !IsClusterExtender(aNextChar);
}
static inline uint32_t
HashMix(uint32_t aHash, PRUnichar aCh)
{
return (aHash >> 28) ^ (aHash << 4) ^ aCh;
}
template<typename T>
gfxShapedWord*
gfxFont::GetShapedWord(gfxContext *aContext,
const T *aText,
uint32_t aLength,
uint32_t aHash,
int32_t aRunScript,
int32_t aAppUnitsPerDevUnit,
uint32_t aFlags)
{
// if the cache is getting too big, flush it and start over
if (mWordCache.Count() > 10000) {
NS_WARNING("flushing shaped-word cache");
ClearCachedWords();
}
// if there's a cached entry for this word, just return it
CacheHashKey key(aText, aLength, aHash,
aRunScript,
aAppUnitsPerDevUnit,
aFlags);
CacheHashEntry *entry = mWordCache.PutEntry(key);
if (!entry) {
NS_WARNING("failed to create word cache entry - expect missing text");
return nullptr;
}
gfxShapedWord *sw = entry->mShapedWord;
if (sw) {
sw->ResetAge();
Telemetry::Accumulate(Telemetry::WORD_CACHE_HITS, aLength);
return sw;
}
Telemetry::Accumulate(Telemetry::WORD_CACHE_MISSES, aLength);
sw = entry->mShapedWord = gfxShapedWord::Create(aText, aLength,
aRunScript,
aAppUnitsPerDevUnit,
aFlags);
if (!sw) {
NS_WARNING("failed to create gfxShapedWord - expect missing text");
return nullptr;
}
DebugOnly<bool> ok = false;
if (sizeof(T) == sizeof(PRUnichar)) {
ok = ShapeWord(aContext, sw, (const PRUnichar*)aText);
} else {
nsAutoString utf16;
AppendASCIItoUTF16(nsDependentCSubstring((const char*)aText, aLength),
utf16);
if (utf16.Length() == aLength) {
ok = ShapeWord(aContext, sw, utf16.BeginReading());
}
}
NS_WARN_IF_FALSE(ok, "failed to shape word - expect garbled text");
for (uint32_t i = 0; i < aLength; ++i) {
if (aText[i] == ' ') {
sw->SetIsSpace(i);
} else if (i > 0 &&
NS_IS_HIGH_SURROGATE(aText[i - 1]) &&
NS_IS_LOW_SURROGATE(aText[i])) {
sw->SetIsLowSurrogate(i);
}
}
return sw;
}
bool
gfxFont::CacheHashEntry::KeyEquals(const KeyTypePointer aKey) const
{
const gfxShapedWord *sw = mShapedWord;
if (!sw) {
return false;
}
if (sw->Length() != aKey->mLength ||
sw->Flags() != aKey->mFlags ||
sw->AppUnitsPerDevUnit() != aKey->mAppUnitsPerDevUnit ||
sw->Script() != aKey->mScript) {
return false;
}
if (sw->TextIs8Bit()) {
if (aKey->mTextIs8Bit) {
return (0 == memcmp(sw->Text8Bit(), aKey->mText.mSingle,
aKey->mLength * sizeof(uint8_t)));
}
// The key has 16-bit text, even though all the characters are < 256,
// so the TEXT_IS_8BIT flag was set and the cached ShapedWord we're
// comparing with will have 8-bit text.
const uint8_t *s1 = sw->Text8Bit();
const PRUnichar *s2 = aKey->mText.mDouble;
const PRUnichar *s2end = s2 + aKey->mLength;
while (s2 < s2end) {
if (*s1++ != *s2++) {
return false;
}
}
return true;
}
NS_ASSERTION((aKey->mFlags & gfxTextRunFactory::TEXT_IS_8BIT) == 0 &&
!aKey->mTextIs8Bit, "didn't expect 8-bit text here");
return (0 == memcmp(sw->TextUnicode(), aKey->mText.mDouble,
aKey->mLength * sizeof(PRUnichar)));
}
bool
gfxFont::ShapeWord(gfxContext *aContext,
gfxShapedWord *aShapedWord,
const PRUnichar *aText,
bool aPreferPlatformShaping)
{
bool ok = false;
#ifdef MOZ_GRAPHITE
if (mGraphiteShaper && gfxPlatform::GetPlatform()->UseGraphiteShaping()) {
ok = mGraphiteShaper->ShapeWord(aContext, aShapedWord, aText);
}
#endif
if (!ok && mHarfBuzzShaper && !aPreferPlatformShaping) {
if (gfxPlatform::GetPlatform()->UseHarfBuzzForScript(aShapedWord->Script())) {
ok = mHarfBuzzShaper->ShapeWord(aContext, aShapedWord, aText);
}
}
if (!ok) {
if (!mPlatformShaper) {
CreatePlatformShaper();
NS_ASSERTION(mPlatformShaper, "no platform shaper available!");
}
if (mPlatformShaper) {
ok = mPlatformShaper->ShapeWord(aContext, aShapedWord, aText);
}
}
if (ok && IsSyntheticBold()) {
float synBoldOffset =
GetSyntheticBoldOffset() * CalcXScale(aContext);
aShapedWord->AdjustAdvancesForSyntheticBold(synBoldOffset);
}
return ok;
}
inline static bool IsChar8Bit(uint8_t /*aCh*/) { return true; }
inline static bool IsChar8Bit(PRUnichar aCh) { return aCh < 0x100; }
template<typename T>
bool
gfxFont::SplitAndInitTextRun(gfxContext *aContext,
gfxTextRun *aTextRun,
const T *aString,
uint32_t aRunStart,
uint32_t aRunLength,
int32_t aRunScript)
{
if (aRunLength == 0) {
return true;
}
InitWordCache();
// the only flags we care about for ShapedWord construction/caching
uint32_t flags = aTextRun->GetFlags() &
(gfxTextRunFactory::TEXT_IS_RTL |
gfxTextRunFactory::TEXT_DISABLE_OPTIONAL_LIGATURES);
if (sizeof(T) == sizeof(uint8_t)) {
flags |= gfxTextRunFactory::TEXT_IS_8BIT;
}
const T *text = aString + aRunStart;
uint32_t wordStart = 0;
uint32_t hash = 0;
bool wordIs8Bit = true;
int32_t appUnitsPerDevUnit = aTextRun->GetAppUnitsPerDevUnit();
T nextCh = text[0];
for (uint32_t i = 0; i <= aRunLength; ++i) {
T ch = nextCh;
nextCh = (i < aRunLength - 1) ? text[i + 1] : '\n';
bool boundary = IsBoundarySpace(ch, nextCh);
bool invalid = !boundary && gfxFontGroup::IsInvalidChar(ch);
uint32_t length = i - wordStart;
// break into separate ShapedWords when we hit an invalid char,
// or a boundary space (always handled individually),
// or the first non-space after a space
bool breakHere = boundary || invalid;
if (!breakHere) {
// if we're approaching the max ShapedWord length, break anyway...
if (sizeof(T) == sizeof(uint8_t)) {
// in 8-bit text, no clusters or surrogates to worry about
if (length >= gfxShapedWord::kMaxLength) {
breakHere = true;
}
} else {
// try to avoid breaking before combining mark or low surrogate
if (length >= gfxShapedWord::kMaxLength - 15) {
if (!NS_IS_LOW_SURROGATE(ch)) {
if (!IsClusterExtender(ch)) {
breakHere = true;
}
}
if (!breakHere && length >= gfxShapedWord::kMaxLength - 3) {
if (!NS_IS_LOW_SURROGATE(ch)) {
breakHere = true;
}
}
if (!breakHere && length >= gfxShapedWord::kMaxLength) {
breakHere = true;
}
}
}
}
if (!breakHere) {
if (!IsChar8Bit(ch)) {
wordIs8Bit = false;
}
// include this character in the hash, and move on to next
hash = HashMix(hash, ch);
continue;
}
// We've decided to break here (i.e. we're at the end of a "word",
// or the word is becoming excessively long): shape the word and
// add it to the textrun
if (length > 0) {
uint32_t wordFlags = flags;
// in the 8-bit version of this method, TEXT_IS_8BIT was
// already set as part of |flags|, so no need for a per-word
// adjustment here
if (sizeof(T) == sizeof(PRUnichar)) {
if (wordIs8Bit) {
wordFlags |= gfxTextRunFactory::TEXT_IS_8BIT;
}
}
gfxShapedWord *sw = GetShapedWord(aContext,
text + wordStart, length,
hash, aRunScript,
appUnitsPerDevUnit,
wordFlags);
if (sw) {
aTextRun->CopyGlyphDataFrom(sw, aRunStart + wordStart);
} else {
return false; // failed, presumably out of memory?
}
}
if (boundary) {
// word was terminated by a space: add that to the textrun
if (!aTextRun->SetSpaceGlyphIfSimple(this, aContext,
aRunStart + i, ch))
{
static const uint8_t space = ' ';
gfxShapedWord *sw =
GetShapedWord(aContext,
&space, 1,
HashMix(0, ' '), aRunScript,
appUnitsPerDevUnit,
flags | gfxTextRunFactory::TEXT_IS_8BIT);
if (sw) {
aTextRun->CopyGlyphDataFrom(sw, aRunStart + i);
} else {
return false;
}
}
hash = 0;
wordStart = i + 1;
wordIs8Bit = true;
continue;
}
if (i == aRunLength) {
break;
}
if (invalid) {
// word was terminated by an invalid char: skip it,
// but record where TAB or NEWLINE occur
if (ch == '\t') {
aTextRun->SetIsTab(aRunStart + i);
} else if (ch == '\n') {
aTextRun->SetIsNewline(aRunStart + i);
}
hash = 0;
wordStart = i + 1;
wordIs8Bit = true;
continue;
}
// word was forcibly broken, so current char will begin next word
hash = HashMix(0, ch);
wordStart = i;
wordIs8Bit = IsChar8Bit(ch);
}
return true;
}
gfxGlyphExtents *
gfxFont::GetOrCreateGlyphExtents(uint32_t aAppUnitsPerDevUnit) {
uint32_t i, count = mGlyphExtentsArray.Length();
for (i = 0; i < count; ++i) {
if (mGlyphExtentsArray[i]->GetAppUnitsPerDevUnit() == aAppUnitsPerDevUnit)
return mGlyphExtentsArray[i];
}
gfxGlyphExtents *glyphExtents = new gfxGlyphExtents(aAppUnitsPerDevUnit);
if (glyphExtents) {
mGlyphExtentsArray.AppendElement(glyphExtents);
// Initialize the extents of a space glyph, assuming that spaces don't
// render anything!
glyphExtents->SetContainedGlyphWidthAppUnits(GetSpaceGlyph(), 0);
}
return glyphExtents;
}
void
gfxFont::SetupGlyphExtents(gfxContext *aContext, uint32_t aGlyphID, bool aNeedTight,
gfxGlyphExtents *aExtents)
{
gfxMatrix matrix = aContext->CurrentMatrix();
aContext->IdentityMatrix();
cairo_glyph_t glyph;
glyph.index = aGlyphID;
glyph.x = 0;
glyph.y = 0;
cairo_text_extents_t extents;
cairo_glyph_extents(aContext->GetCairo(), &glyph, 1, &extents);
aContext->SetMatrix(matrix);
const Metrics& fontMetrics = GetMetrics();
uint32_t appUnitsPerDevUnit = aExtents->GetAppUnitsPerDevUnit();
if (!aNeedTight && extents.x_bearing >= 0 &&
extents.y_bearing >= -fontMetrics.maxAscent &&
extents.height + extents.y_bearing <= fontMetrics.maxDescent) {
uint32_t appUnitsWidth =
uint32_t(ceil((extents.x_bearing + extents.width)*appUnitsPerDevUnit));
if (appUnitsWidth < gfxGlyphExtents::INVALID_WIDTH) {
aExtents->SetContainedGlyphWidthAppUnits(aGlyphID, uint16_t(appUnitsWidth));
return;
}
}
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
if (!aNeedTight) {
++gGlyphExtentsSetupFallBackToTight;
}
#endif
double d2a = appUnitsPerDevUnit;
gfxRect bounds(extents.x_bearing*d2a, extents.y_bearing*d2a,
extents.width*d2a, extents.height*d2a);
aExtents->SetTightGlyphExtents(aGlyphID, bounds);
}
// Try to initialize font metrics by reading sfnt tables directly;
// set mIsValid=TRUE and return TRUE on success.
// Return FALSE if the gfxFontEntry subclass does not
// implement GetFontTable(), or for non-sfnt fonts where tables are
// not available.
bool
gfxFont::InitMetricsFromSfntTables(Metrics& aMetrics)
{
mIsValid = false; // font is NOT valid in case of early return
const uint32_t kHeadTableTag = TRUETYPE_TAG('h','e','a','d');
const uint32_t kHheaTableTag = TRUETYPE_TAG('h','h','e','a');
const uint32_t kPostTableTag = TRUETYPE_TAG('p','o','s','t');
const uint32_t kOS_2TableTag = TRUETYPE_TAG('O','S','/','2');
if (mFUnitsConvFactor == 0.0) {
// If the conversion factor from FUnits is not yet set,
// 'head' table is required; otherwise we cannot read any metrics
// because we don't know unitsPerEm
AutoFallibleTArray<uint8_t,sizeof(HeadTable)> headData;
if (NS_FAILED(mFontEntry->GetFontTable(kHeadTableTag, headData)) ||
headData.Length() < sizeof(HeadTable)) {
return false; // no 'head' table -> not an sfnt
}
HeadTable *head = reinterpret_cast<HeadTable*>(headData.Elements());
uint32_t unitsPerEm = head->unitsPerEm;
if (!unitsPerEm) {
return true; // is an sfnt, but not valid
}
mFUnitsConvFactor = mAdjustedSize / unitsPerEm;
}
// 'hhea' table is required to get vertical extents
AutoFallibleTArray<uint8_t,sizeof(HheaTable)> hheaData;
if (NS_FAILED(mFontEntry->GetFontTable(kHheaTableTag, hheaData)) ||
hheaData.Length() < sizeof(HheaTable)) {
return false; // no 'hhea' table -> not an sfnt
}
HheaTable *hhea = reinterpret_cast<HheaTable*>(hheaData.Elements());
#define SET_UNSIGNED(field,src) aMetrics.field = uint16_t(src) * mFUnitsConvFactor
#define SET_SIGNED(field,src) aMetrics.field = int16_t(src) * mFUnitsConvFactor
SET_UNSIGNED(maxAdvance, hhea->advanceWidthMax);
SET_SIGNED(maxAscent, hhea->ascender);
SET_SIGNED(maxDescent, -int16_t(hhea->descender));
SET_SIGNED(externalLeading, hhea->lineGap);
// 'post' table is required for underline metrics
AutoFallibleTArray<uint8_t,sizeof(PostTable)> postData;
if (NS_FAILED(mFontEntry->GetFontTable(kPostTableTag, postData))) {
return true; // no 'post' table -> sfnt is not valid
}
if (postData.Length() <
offsetof(PostTable, underlineThickness) + sizeof(uint16_t)) {
return true; // bad post table -> sfnt is not valid
}
PostTable *post = reinterpret_cast<PostTable*>(postData.Elements());
SET_SIGNED(underlineOffset, post->underlinePosition);
SET_UNSIGNED(underlineSize, post->underlineThickness);
// 'OS/2' table is optional, if not found we'll estimate xHeight
// and aveCharWidth by measuring glyphs
AutoFallibleTArray<uint8_t,sizeof(OS2Table)> os2data;
if (NS_SUCCEEDED(mFontEntry->GetFontTable(kOS_2TableTag, os2data))) {
OS2Table *os2 = reinterpret_cast<OS2Table*>(os2data.Elements());
if (os2data.Length() >= offsetof(OS2Table, sxHeight) +
sizeof(int16_t) &&
uint16_t(os2->version) >= 2) {
// version 2 and later includes the x-height field
SET_SIGNED(xHeight, os2->sxHeight);
// NS_ABS because of negative xHeight seen in Kokonor (Tibetan) font
aMetrics.xHeight = NS_ABS(aMetrics.xHeight);
}
// this should always be present
if (os2data.Length() >= offsetof(OS2Table, yStrikeoutPosition) +
sizeof(int16_t)) {
SET_SIGNED(aveCharWidth, os2->xAvgCharWidth);
SET_SIGNED(subscriptOffset, os2->ySubscriptYOffset);
SET_SIGNED(superscriptOffset, os2->ySuperscriptYOffset);
SET_SIGNED(strikeoutSize, os2->yStrikeoutSize);
SET_SIGNED(strikeoutOffset, os2->yStrikeoutPosition);
}
}
mIsValid = true;
return true;
}
static double
RoundToNearestMultiple(double aValue, double aFraction)
{
return floor(aValue/aFraction + 0.5) * aFraction;
}
void gfxFont::CalculateDerivedMetrics(Metrics& aMetrics)
{
aMetrics.maxAscent =
ceil(RoundToNearestMultiple(aMetrics.maxAscent, 1/1024.0));
aMetrics.maxDescent =
ceil(RoundToNearestMultiple(aMetrics.maxDescent, 1/1024.0));
if (aMetrics.xHeight <= 0) {
// only happens if we couldn't find either font metrics
// or a char to measure;
// pick an arbitrary value that's better than zero
aMetrics.xHeight = aMetrics.maxAscent * DEFAULT_XHEIGHT_FACTOR;
}
aMetrics.maxHeight = aMetrics.maxAscent + aMetrics.maxDescent;
if (aMetrics.maxHeight - aMetrics.emHeight > 0.0) {
aMetrics.internalLeading = aMetrics.maxHeight - aMetrics.emHeight;
} else {
aMetrics.internalLeading = 0.0;
}
aMetrics.emAscent = aMetrics.maxAscent * aMetrics.emHeight
/ aMetrics.maxHeight;
aMetrics.emDescent = aMetrics.emHeight - aMetrics.emAscent;
if (GetFontEntry()->IsFixedPitch()) {
// Some Quartz fonts are fixed pitch, but there's some glyph with a bigger
// advance than the average character width... this forces
// those fonts to be recognized like fixed pitch fonts by layout.
aMetrics.maxAdvance = aMetrics.aveCharWidth;
}
if (!aMetrics.subscriptOffset) {
aMetrics.subscriptOffset = aMetrics.xHeight;
}
if (!aMetrics.superscriptOffset) {
aMetrics.superscriptOffset = aMetrics.xHeight;
}
if (!aMetrics.strikeoutOffset) {
aMetrics.strikeoutOffset = aMetrics.xHeight * 0.5;
}
if (!aMetrics.strikeoutSize) {
aMetrics.strikeoutSize = aMetrics.underlineSize;
}
}
void
gfxFont::SanitizeMetrics(gfxFont::Metrics *aMetrics, bool aIsBadUnderlineFont)
{
// Even if this font size is zero, this font is created with non-zero size.
// However, for layout and others, we should return the metrics of zero size font.
if (mStyle.size == 0.0) {
memset(aMetrics, 0, sizeof(gfxFont::Metrics));
return;
}
// MS (P)Gothic and MS (P)Mincho are not having suitable values in their super script offset.
// If the values are not suitable, we should use x-height instead of them.
// See https://bugzilla.mozilla.org/show_bug.cgi?id=353632
if (aMetrics->superscriptOffset <= 0 ||
aMetrics->superscriptOffset >= aMetrics->maxAscent) {
aMetrics->superscriptOffset = aMetrics->xHeight;
}
// And also checking the case of sub script offset. The old gfx for win has checked this too.
if (aMetrics->subscriptOffset <= 0 ||
aMetrics->subscriptOffset >= aMetrics->maxAscent) {
aMetrics->subscriptOffset = aMetrics->xHeight;
}
aMetrics->underlineSize = NS_MAX(1.0, aMetrics->underlineSize);
aMetrics->strikeoutSize = NS_MAX(1.0, aMetrics->strikeoutSize);
aMetrics->underlineOffset = NS_MIN(aMetrics->underlineOffset, -1.0);
if (aMetrics->maxAscent < 1.0) {
// We cannot draw strikeout line and overline in the ascent...
aMetrics->underlineSize = 0;
aMetrics->underlineOffset = 0;
aMetrics->strikeoutSize = 0;
aMetrics->strikeoutOffset = 0;
return;
}
/**
* Some CJK fonts have bad underline offset. Therefore, if this is such font,
* we need to lower the underline offset to bottom of *em* descent.
* However, if this is system font, we should not do this for the rendering compatibility with
* another application's UI on the platform.
* XXX Should not use this hack if the font size is too small?
* Such text cannot be read, this might be used for tight CSS rendering? (E.g., Acid2)
*/
if (!mStyle.systemFont && aIsBadUnderlineFont) {
// First, we need 2 pixels between baseline and underline at least. Because many CJK characters
// put their glyphs on the baseline, so, 1 pixel is too close for CJK characters.
aMetrics->underlineOffset = NS_MIN(aMetrics->underlineOffset, -2.0);
// Next, we put the underline to bottom of below of the descent space.
if (aMetrics->internalLeading + aMetrics->externalLeading > aMetrics->underlineSize) {
aMetrics->underlineOffset = NS_MIN(aMetrics->underlineOffset, -aMetrics->emDescent);
} else {
aMetrics->underlineOffset = NS_MIN(aMetrics->underlineOffset,
aMetrics->underlineSize - aMetrics->emDescent);
}
}
// If underline positioned is too far from the text, descent position is preferred so that underline
// will stay within the boundary.
else if (aMetrics->underlineSize - aMetrics->underlineOffset > aMetrics->maxDescent) {
if (aMetrics->underlineSize > aMetrics->maxDescent)
aMetrics->underlineSize = NS_MAX(aMetrics->maxDescent, 1.0);
// The max underlineOffset is 1px (the min underlineSize is 1px, and min maxDescent is 0px.)
aMetrics->underlineOffset = aMetrics->underlineSize - aMetrics->maxDescent;
}
// If strikeout line is overflowed from the ascent, the line should be resized and moved for
// that being in the ascent space.
// Note that the strikeoutOffset is *middle* of the strikeout line position.
gfxFloat halfOfStrikeoutSize = floor(aMetrics->strikeoutSize / 2.0 + 0.5);
if (halfOfStrikeoutSize + aMetrics->strikeoutOffset > aMetrics->maxAscent) {
if (aMetrics->strikeoutSize > aMetrics->maxAscent) {
aMetrics->strikeoutSize = NS_MAX(aMetrics->maxAscent, 1.0);
halfOfStrikeoutSize = floor(aMetrics->strikeoutSize / 2.0 + 0.5);
}
gfxFloat ascent = floor(aMetrics->maxAscent + 0.5);
aMetrics->strikeoutOffset = NS_MAX(halfOfStrikeoutSize, ascent / 2.0);
}
// If overline is larger than the ascent, the line should be resized.
if (aMetrics->underlineSize > aMetrics->maxAscent) {
aMetrics->underlineSize = aMetrics->maxAscent;
}
}
gfxFloat
gfxFont::SynthesizeSpaceWidth(uint32_t aCh)
{
// return an appropriate width for various Unicode space characters
// that we "fake" if they're not actually present in the font;
// returns negative value if the char is not a known space.
switch (aCh) {
case 0x2000: // en quad
case 0x2002: return GetAdjustedSize() / 2; // en space
case 0x2001: // em quad
case 0x2003: return GetAdjustedSize(); // em space
case 0x2004: return GetAdjustedSize() / 3; // three-per-em space
case 0x2005: return GetAdjustedSize() / 4; // four-per-em space
case 0x2006: return GetAdjustedSize() / 6; // six-per-em space
case 0x2007: return GetMetrics().zeroOrAveCharWidth; // figure space
case 0x2008: return GetMetrics().spaceWidth; // punctuation space
case 0x2009: return GetAdjustedSize() / 5; // thin space
case 0x200a: return GetAdjustedSize() / 10; // hair space
case 0x202f: return GetAdjustedSize() / 5; // narrow no-break space
default: return -1.0;
}
}
/*static*/ size_t
gfxFont::WordCacheEntrySizeOfExcludingThis(CacheHashEntry* aHashEntry,
nsMallocSizeOfFun aMallocSizeOf,
void* aUserArg)
{
return aMallocSizeOf(aHashEntry->mShapedWord.get());
}
void
gfxFont::SizeOfExcludingThis(nsMallocSizeOfFun aMallocSizeOf,
FontCacheSizes* aSizes) const
{
for (uint32_t i = 0; i < mGlyphExtentsArray.Length(); ++i) {
aSizes->mFontInstances +=
mGlyphExtentsArray[i]->SizeOfIncludingThis(aMallocSizeOf);
}
aSizes->mShapedWords +=
mWordCache.SizeOfExcludingThis(WordCacheEntrySizeOfExcludingThis,
aMallocSizeOf);
}
void
gfxFont::SizeOfIncludingThis(nsMallocSizeOfFun aMallocSizeOf,
FontCacheSizes* aSizes) const
{
aSizes->mFontInstances += aMallocSizeOf(this);
SizeOfExcludingThis(aMallocSizeOf, aSizes);
}
gfxGlyphExtents::~gfxGlyphExtents()
{
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
gGlyphExtentsWidthsTotalSize +=
mContainedGlyphWidths.SizeOfExcludingThis(&FontCacheMallocSizeOf);
gGlyphExtentsCount++;
#endif
MOZ_COUNT_DTOR(gfxGlyphExtents);
}
bool
gfxGlyphExtents::GetTightGlyphExtentsAppUnits(gfxFont *aFont,
gfxContext *aContext, uint32_t aGlyphID, gfxRect *aExtents)
{
HashEntry *entry = mTightGlyphExtents.GetEntry(aGlyphID);
if (!entry) {
if (!aContext) {
NS_WARNING("Could not get glyph extents (no aContext)");
return false;
}
if (aFont->SetupCairoFont(aContext)) {
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
++gGlyphExtentsSetupLazyTight;
#endif
aFont->SetupGlyphExtents(aContext, aGlyphID, true, this);
entry = mTightGlyphExtents.GetEntry(aGlyphID);
}
if (!entry) {
NS_WARNING("Could not get glyph extents");
return false;
}
}
*aExtents = gfxRect(entry->x, entry->y, entry->width, entry->height);
return true;
}
gfxGlyphExtents::GlyphWidths::~GlyphWidths()
{
uint32_t i, count = mBlocks.Length();
for (i = 0; i < count; ++i) {
PtrBits bits = mBlocks[i];
if (bits && !(bits & 0x1)) {
delete[] reinterpret_cast<uint16_t *>(bits);
}
}
}
uint32_t
gfxGlyphExtents::GlyphWidths::SizeOfExcludingThis(nsMallocSizeOfFun aMallocSizeOf) const
{
uint32_t i;
uint32_t size = mBlocks.SizeOfExcludingThis(aMallocSizeOf);
for (i = 0; i < mBlocks.Length(); ++i) {
PtrBits bits = mBlocks[i];
if (bits && !(bits & 0x1)) {
size += aMallocSizeOf(reinterpret_cast<void*>(bits));
}
}
return size;
}
void
gfxGlyphExtents::GlyphWidths::Set(uint32_t aGlyphID, uint16_t aWidth)
{
uint32_t block = aGlyphID >> BLOCK_SIZE_BITS;
uint32_t len = mBlocks.Length();
if (block >= len) {
PtrBits *elems = mBlocks.AppendElements(block + 1 - len);
if (!elems)
return;
memset(elems, 0, sizeof(PtrBits)*(block + 1 - len));
}
PtrBits bits = mBlocks[block];
uint32_t glyphOffset = aGlyphID & (BLOCK_SIZE - 1);
if (!bits) {
mBlocks[block] = MakeSingle(glyphOffset, aWidth);
return;
}
uint16_t *newBlock;
if (bits & 0x1) {
// Expand the block to a real block. We could avoid this by checking
// glyphOffset == GetGlyphOffset(bits), but that never happens so don't bother
newBlock = new uint16_t[BLOCK_SIZE];
if (!newBlock)
return;
uint32_t i;
for (i = 0; i < BLOCK_SIZE; ++i) {
newBlock[i] = INVALID_WIDTH;
}
newBlock[GetGlyphOffset(bits)] = GetWidth(bits);
mBlocks[block] = reinterpret_cast<PtrBits>(newBlock);
} else {
newBlock = reinterpret_cast<uint16_t *>(bits);
}
newBlock[glyphOffset] = aWidth;
}
void
gfxGlyphExtents::SetTightGlyphExtents(uint32_t aGlyphID, const gfxRect& aExtentsAppUnits)
{
HashEntry *entry = mTightGlyphExtents.PutEntry(aGlyphID);
if (!entry)
return;
entry->x = aExtentsAppUnits.X();
entry->y = aExtentsAppUnits.Y();
entry->width = aExtentsAppUnits.Width();
entry->height = aExtentsAppUnits.Height();
}
size_t
gfxGlyphExtents::SizeOfExcludingThis(nsMallocSizeOfFun aMallocSizeOf) const
{
return mContainedGlyphWidths.SizeOfExcludingThis(aMallocSizeOf) +
mTightGlyphExtents.SizeOfExcludingThis(nullptr, aMallocSizeOf);
}
size_t
gfxGlyphExtents::SizeOfIncludingThis(nsMallocSizeOfFun aMallocSizeOf) const
{
return aMallocSizeOf(this) + SizeOfExcludingThis(aMallocSizeOf);
}
gfxFontGroup::gfxFontGroup(const nsAString& aFamilies, const gfxFontStyle *aStyle, gfxUserFontSet *aUserFontSet)
: mFamilies(aFamilies), mStyle(*aStyle), mUnderlineOffset(UNDERLINE_OFFSET_NOT_SET)
{
mUserFontSet = nullptr;
SetUserFontSet(aUserFontSet);
mSkipDrawing = false;
mPageLang = gfxPlatform::GetFontPrefLangFor(mStyle.language);
BuildFontList();
}
void
gfxFontGroup::BuildFontList()
{
// "#if" to be removed once all platforms are moved to gfxPlatformFontList interface
// and subclasses of gfxFontGroup eliminated
#if defined(XP_MACOSX) || defined(XP_WIN) || defined(ANDROID)
ForEachFont(FindPlatformFont, this);
if (mFonts.Length() == 0) {
bool needsBold;
gfxPlatformFontList *pfl = gfxPlatformFontList::PlatformFontList();
gfxFontEntry *defaultFont = pfl->GetDefaultFont(&mStyle, needsBold);
NS_ASSERTION(defaultFont, "invalid default font returned by GetDefaultFont");
if (defaultFont) {
nsRefPtr<gfxFont> font = defaultFont->FindOrMakeFont(&mStyle,
needsBold);
if (font) {
mFonts.AppendElement(font);
}
}
if (mFonts.Length() == 0) {
// Try for a "font of last resort...."
// Because an empty font list would be Really Bad for later code
// that assumes it will be able to get valid metrics for layout,
// just look for the first usable font and put in the list.
// (see bug 554544)
nsAutoTArray<nsRefPtr<gfxFontFamily>,200> families;
pfl->GetFontFamilyList(families);
uint32_t count = families.Length();
for (uint32_t i = 0; i < count; ++i) {
gfxFontEntry *fe = families[i]->FindFontForStyle(mStyle,
needsBold);
if (fe) {
nsRefPtr<gfxFont> font = fe->FindOrMakeFont(&mStyle,
needsBold);
if (font) {
mFonts.AppendElement(font);
break;
}
}
}
}
if (mFonts.Length() == 0) {
// an empty font list at this point is fatal; we're not going to
// be able to do even the most basic layout operations
char msg[256]; // CHECK buffer length if revising message below
sprintf(msg, "unable to find a usable font (%.220s)",
NS_ConvertUTF16toUTF8(mFamilies).get());
NS_RUNTIMEABORT(msg);
}
}
if (!mStyle.systemFont) {
uint32_t count = mFonts.Length();
for (uint32_t i = 0; i < count; ++i) {
gfxFont* font = mFonts[i];
if (font->GetFontEntry()->mIsBadUnderlineFont) {
gfxFloat first = mFonts[0]->GetMetrics().underlineOffset;
gfxFloat bad = font->GetMetrics().underlineOffset;
mUnderlineOffset = NS_MIN(first, bad);
break;
}
}
}
#endif
}
bool
gfxFontGroup::FindPlatformFont(const nsAString& aName,
const nsACString& aGenericName,
bool aUseFontSet,
void *aClosure)
{
gfxFontGroup *fontGroup = static_cast<gfxFontGroup*>(aClosure);
const gfxFontStyle *fontStyle = fontGroup->GetStyle();
bool needsBold;
gfxFontEntry *fe = nullptr;
bool foundFamily = false;
if (aUseFontSet) {
// First, look up in the user font set...
// If the fontSet matches the family, we must not look for a platform
// font of the same name, even if we fail to actually get a fontEntry
// here; we'll fall back to the next name in the CSS font-family list.
gfxUserFontSet *fs = fontGroup->GetUserFontSet();
if (fs) {
// If the fontSet matches the family, but the font has not yet finished
// loading (nor has its load timeout fired), the fontGroup should wait
// for the download, and not actually draw its text yet.
bool waitForUserFont = false;
fe = fs->FindFontEntry(aName, *fontStyle, foundFamily,
needsBold, waitForUserFont);
if (!fe && waitForUserFont) {
fontGroup->mSkipDrawing = true;
}
}
}
// Not known in the user font set ==> check system fonts
if (!foundFamily) {
fe = gfxPlatformFontList::PlatformFontList()->
FindFontForFamily(aName, fontStyle, needsBold);
}
// add to the font group, unless it's already there
if (fe && !fontGroup->HasFont(fe)) {
nsRefPtr<gfxFont> font = fe->FindOrMakeFont(fontStyle, needsBold);
if (font) {
fontGroup->mFonts.AppendElement(font);
}
}
return true;
}
bool
gfxFontGroup::HasFont(const gfxFontEntry *aFontEntry)
{
uint32_t count = mFonts.Length();
for (uint32_t i = 0; i < count; ++i) {
if (mFonts.ElementAt(i)->GetFontEntry() == aFontEntry)
return true;
}
return false;
}
gfxFontGroup::~gfxFontGroup() {
mFonts.Clear();
SetUserFontSet(nullptr);
}
gfxFontGroup *
gfxFontGroup::Copy(const gfxFontStyle *aStyle)
{
return new gfxFontGroup(mFamilies, aStyle, mUserFontSet);
}
bool
gfxFontGroup::IsInvalidChar(uint8_t ch)
{
return ((ch & 0x7f) < 0x20);
}
bool
gfxFontGroup::IsInvalidChar(PRUnichar ch)
{
// All printable 7-bit ASCII values are OK
if (ch >= ' ' && ch < 0x80) {
return false;
}
// No point in sending non-printing control chars through font shaping
if (ch <= 0x9f) {
return true;
}
return ((ch & 0xFF00) == 0x2000 /* Unicode control character */ &&
(ch == 0x200B/*ZWSP*/ || ch == 0x2028/*LSEP*/ || ch == 0x2029/*PSEP*/ ||
IS_BIDI_CONTROL_CHAR(ch)));
}
bool
gfxFontGroup::ForEachFont(FontCreationCallback fc,
void *closure)
{
return ForEachFontInternal(mFamilies, mStyle.language,
true, true, true, fc, closure);
}
bool
gfxFontGroup::ForEachFont(const nsAString& aFamilies,
nsIAtom *aLanguage,
FontCreationCallback fc,
void *closure)
{
return ForEachFontInternal(aFamilies, aLanguage,
false, true, true, fc, closure);
}
struct ResolveData {
ResolveData(gfxFontGroup::FontCreationCallback aCallback,
nsACString& aGenericFamily,
bool aUseFontSet,
void *aClosure) :
mCallback(aCallback),
mGenericFamily(aGenericFamily),
mUseFontSet(aUseFontSet),
mClosure(aClosure) {
}
gfxFontGroup::FontCreationCallback mCallback;
nsCString mGenericFamily;
bool mUseFontSet;
void *mClosure;
};
bool
gfxFontGroup::ForEachFontInternal(const nsAString& aFamilies,
nsIAtom *aLanguage,
bool aResolveGeneric,
bool aResolveFontName,
bool aUseFontSet,
FontCreationCallback fc,
void *closure)
{
const PRUnichar kSingleQuote = PRUnichar('\'');
const PRUnichar kDoubleQuote = PRUnichar('\"');
const PRUnichar kComma = PRUnichar(',');
nsIAtom *groupAtom = nullptr;
nsCAutoString groupString;
if (aLanguage) {
if (!gLangService) {
CallGetService(NS_LANGUAGEATOMSERVICE_CONTRACTID, &gLangService);
}
if (gLangService) {
nsresult rv;
groupAtom = gLangService->GetLanguageGroup(aLanguage, &rv);
}
}
if (!groupAtom) {
groupAtom = nsGkAtoms::Unicode;
}
groupAtom->ToUTF8String(groupString);
nsPromiseFlatString families(aFamilies);
const PRUnichar *p, *p_end;
families.BeginReading(p);
families.EndReading(p_end);
nsAutoString family;
nsCAutoString lcFamily;
nsAutoString genericFamily;
while (p < p_end) {
while (nsCRT::IsAsciiSpace(*p) || *p == kComma)
if (++p == p_end)
return true;
bool generic;
if (*p == kSingleQuote || *p == kDoubleQuote) {
// quoted font family
PRUnichar quoteMark = *p;
if (++p == p_end)
return true;
const PRUnichar *nameStart = p;
// XXX What about CSS character escapes?
while (*p != quoteMark)
if (++p == p_end)
return true;
family = Substring(nameStart, p);
generic = false;
genericFamily.SetIsVoid(true);
while (++p != p_end && *p != kComma)
/* nothing */ ;
} else {
// unquoted font family
const PRUnichar *nameStart = p;
while (++p != p_end && *p != kComma)
/* nothing */ ;
family = Substring(nameStart, p);
family.CompressWhitespace(false, true);
if (aResolveGeneric &&
(family.LowerCaseEqualsLiteral("serif") ||
family.LowerCaseEqualsLiteral("sans-serif") ||
family.LowerCaseEqualsLiteral("monospace") ||
family.LowerCaseEqualsLiteral("cursive") ||
family.LowerCaseEqualsLiteral("fantasy")))
{
generic = true;
ToLowerCase(NS_LossyConvertUTF16toASCII(family), lcFamily);
nsCAutoString prefName("font.name.");
prefName.Append(lcFamily);
prefName.AppendLiteral(".");
prefName.Append(groupString);
nsAdoptingString value = Preferences::GetString(prefName.get());
if (value) {
CopyASCIItoUTF16(lcFamily, genericFamily);
family = value;
}
} else {
generic = false;
genericFamily.SetIsVoid(true);
}
}
NS_LossyConvertUTF16toASCII gf(genericFamily);
if (generic) {
ForEachFontInternal(family, groupAtom, false,
aResolveFontName, false,
fc, closure);
} else if (!family.IsEmpty()) {
if (aResolveFontName) {
ResolveData data(fc, gf, aUseFontSet, closure);
bool aborted = false, needsBold;
nsresult rv = NS_OK;
bool foundFamily = false;
bool waitForUserFont = false;
if (aUseFontSet && mUserFontSet &&
mUserFontSet->FindFontEntry(family, mStyle, foundFamily,
needsBold, waitForUserFont))
{
gfxFontGroup::FontResolverProc(family, &data);
} else {
if (waitForUserFont) {
mSkipDrawing = true;
}
if (!foundFamily) {
gfxPlatform *pf = gfxPlatform::GetPlatform();
rv = pf->ResolveFontName(family,
gfxFontGroup::FontResolverProc,
&data, aborted);
}
}
if (NS_FAILED(rv) || aborted)
return false;
}
else {
if (!fc(family, gf, aUseFontSet, closure))
return false;
}
}
if (generic && aResolveGeneric) {
nsCAutoString prefName("font.name-list.");
prefName.Append(lcFamily);
prefName.AppendLiteral(".");
prefName.Append(groupString);
nsAdoptingString value = Preferences::GetString(prefName.get());
if (value) {
ForEachFontInternal(value, groupAtom, false,
aResolveFontName, false,
fc, closure);
}
}
++p; // may advance past p_end
}
return true;
}
bool
gfxFontGroup::FontResolverProc(const nsAString& aName, void *aClosure)
{
ResolveData *data = reinterpret_cast<ResolveData*>(aClosure);
return (data->mCallback)(aName, data->mGenericFamily, data->mUseFontSet,
data->mClosure);
}
gfxTextRun *
gfxFontGroup::MakeEmptyTextRun(const Parameters *aParams, uint32_t aFlags)
{
aFlags |= TEXT_IS_8BIT | TEXT_IS_ASCII | TEXT_IS_PERSISTENT;
return gfxTextRun::Create(aParams, 0, this, aFlags);
}
gfxTextRun *
gfxFontGroup::MakeSpaceTextRun(const Parameters *aParams, uint32_t aFlags)
{
aFlags |= TEXT_IS_8BIT | TEXT_IS_ASCII | TEXT_IS_PERSISTENT;
gfxTextRun *textRun = gfxTextRun::Create(aParams, 1, this, aFlags);
if (!textRun) {
return nullptr;
}
gfxFont *font = GetFontAt(0);
if (NS_UNLIKELY(GetStyle()->size == 0)) {
// Short-circuit for size-0 fonts, as Windows and ATSUI can't handle
// them, and always create at least size 1 fonts, i.e. they still
// render something for size 0 fonts.
textRun->AddGlyphRun(font, gfxTextRange::kFontGroup, 0, false);
}
else {
textRun->SetSpaceGlyph(font, aParams->mContext, 0);
}
// Note that the gfxGlyphExtents glyph bounds storage for the font will
// always contain an entry for the font's space glyph, so we don't have
// to call FetchGlyphExtents here.
return textRun;
}
gfxTextRun *
gfxFontGroup::MakeBlankTextRun(uint32_t aLength,
const Parameters *aParams, uint32_t aFlags)
{
gfxTextRun *textRun =
gfxTextRun::Create(aParams, aLength, this, aFlags);
if (!textRun) {
return nullptr;
}
textRun->AddGlyphRun(GetFontAt(0), gfxTextRange::kFontGroup, 0, false);
return textRun;
}
gfxTextRun *
gfxFontGroup::MakeTextRun(const uint8_t *aString, uint32_t aLength,
const Parameters *aParams, uint32_t aFlags)
{
if (aLength == 0) {
return MakeEmptyTextRun(aParams, aFlags);
}
if (aLength == 1 && aString[0] == ' ') {
return MakeSpaceTextRun(aParams, aFlags);
}
aFlags |= TEXT_IS_8BIT;
if (GetStyle()->size == 0) {
// Short-circuit for size-0 fonts, as Windows and ATSUI can't handle
// them, and always create at least size 1 fonts, i.e. they still
// render something for size 0 fonts.
return MakeBlankTextRun(aLength, aParams, aFlags);
}
gfxTextRun *textRun = gfxTextRun::Create(aParams, aLength,
this, aFlags);
if (!textRun) {
return nullptr;
}
InitTextRun(aParams->mContext, textRun, aString, aLength);
textRun->FetchGlyphExtents(aParams->mContext);
return textRun;
}
gfxTextRun *
gfxFontGroup::MakeTextRun(const PRUnichar *aString, uint32_t aLength,
const Parameters *aParams, uint32_t aFlags)
{
if (aLength == 0) {
return MakeEmptyTextRun(aParams, aFlags);
}
if (aLength == 1 && aString[0] == ' ') {
return MakeSpaceTextRun(aParams, aFlags);
}
if (GetStyle()->size == 0) {
return MakeBlankTextRun(aLength, aParams, aFlags);
}
gfxTextRun *textRun = gfxTextRun::Create(aParams, aLength,
this, aFlags);
if (!textRun) {
return nullptr;
}
InitTextRun(aParams->mContext, textRun, aString, aLength);
textRun->FetchGlyphExtents(aParams->mContext);
return textRun;
}
template<typename T>
void
gfxFontGroup::InitTextRun(gfxContext *aContext,
gfxTextRun *aTextRun,
const T *aString,
uint32_t aLength)
{
NS_ASSERTION(aLength > 0, "don't call InitTextRun for a zero-length run");
// we need to do numeral processing even on 8-bit text,
// in case we're converting Western to Hindi/Arabic digits
int32_t numOption = gfxPlatform::GetPlatform()->GetBidiNumeralOption();
nsAutoArrayPtr<PRUnichar> transformedString;
if (numOption != IBMBIDI_NUMERAL_NOMINAL) {
// scan the string for numerals that may need to be transformed;
// if we find any, we'll make a local copy here and use that for
// font matching and glyph generation/shaping
bool prevIsArabic =
(aTextRun->GetFlags() & gfxTextRunFactory::TEXT_INCOMING_ARABICCHAR) != 0;
for (uint32_t i = 0; i < aLength; ++i) {
PRUnichar origCh = aString[i];
PRUnichar newCh = HandleNumberInChar(origCh, prevIsArabic, numOption);
if (newCh != origCh) {
if (!transformedString) {
transformedString = new PRUnichar[aLength];
if (sizeof(T) == sizeof(PRUnichar)) {
memcpy(transformedString.get(), aString, i * sizeof(PRUnichar));
} else {
for (uint32_t j = 0; j < i; ++j) {
transformedString[j] = aString[j];
}
}
}
}
if (transformedString) {
transformedString[i] = newCh;
}
prevIsArabic = IS_ARABIC_CHAR(newCh);
}
}
if (sizeof(T) == sizeof(uint8_t) && !transformedString) {
// the text is still purely 8-bit; bypass the script-run itemizer
// and treat it as a single Latin run
InitScriptRun(aContext, aTextRun, aString,
0, aLength, MOZ_SCRIPT_LATIN);
} else {
const PRUnichar *textPtr;
if (transformedString) {
textPtr = transformedString.get();
} else {
// typecast to avoid compilation error for the 8-bit version,
// even though this is dead code in that case
textPtr = reinterpret_cast<const PRUnichar*>(aString);
}
// split into script runs so that script can potentially influence
// the font matching process below
gfxScriptItemizer scriptRuns(textPtr, aLength);
#ifdef PR_LOGGING
PRLogModuleInfo *log = (mStyle.systemFont ?
gfxPlatform::GetLog(eGfxLog_textrunui) :
gfxPlatform::GetLog(eGfxLog_textrun));
#endif
uint32_t runStart = 0, runLimit = aLength;
int32_t runScript = MOZ_SCRIPT_LATIN;
while (scriptRuns.Next(runStart, runLimit, runScript)) {
#ifdef PR_LOGGING
if (NS_UNLIKELY(log)) {
nsCAutoString lang;
mStyle.language->ToUTF8String(lang);
uint32_t runLen = runLimit - runStart;
PR_LOG(log, PR_LOG_WARNING,\
("(%s) fontgroup: [%s] lang: %s script: %d len %d "
"weight: %d width: %d style: %s "
"TEXTRUN [%s] ENDTEXTRUN\n",
(mStyle.systemFont ? "textrunui" : "textrun"),
NS_ConvertUTF16toUTF8(mFamilies).get(),
lang.get(), runScript, runLen,
uint32_t(mStyle.weight), uint32_t(mStyle.stretch),
(mStyle.style & NS_FONT_STYLE_ITALIC ? "italic" :
(mStyle.style & NS_FONT_STYLE_OBLIQUE ? "oblique" :
"normal")),
NS_ConvertUTF16toUTF8(textPtr + runStart, runLen).get()));
}
#endif
InitScriptRun(aContext, aTextRun, textPtr,
runStart, runLimit, runScript);
}
}
if (sizeof(T) == sizeof(PRUnichar) && aLength > 0) {
gfxTextRun::CompressedGlyph *glyph = aTextRun->GetCharacterGlyphs();
if (!glyph->IsSimpleGlyph()) {
glyph->SetClusterStart(true);
}
}
// It's possible for CoreText to omit glyph runs if it decides they contain
// only invisibles (e.g., U+FEFF, see reftest 474417-1). In this case, we
// need to eliminate them from the glyph run array to avoid drawing "partial
// ligatures" with the wrong font.
// We don't do this during InitScriptRun (or gfxFont::InitTextRun) because
// it will iterate back over all glyphruns in the textrun, which leads to
// pathologically-bad perf in the case where a textrun contains many script
// changes (see bug 680402) - we'd end up re-sanitizing all the earlier runs
// every time a new script subrun is processed.
aTextRun->SanitizeGlyphRuns();
aTextRun->SortGlyphRuns();
}
template<typename T>
void
gfxFontGroup::InitScriptRun(gfxContext *aContext,
gfxTextRun *aTextRun,
const T *aString,
uint32_t aScriptRunStart,
uint32_t aScriptRunEnd,
int32_t aRunScript)
{
NS_ASSERTION(aScriptRunEnd > aScriptRunStart,
"don't call InitScriptRun for a zero-length run");
gfxFont *mainFont = GetFontAt(0);
uint32_t runStart = aScriptRunStart;
nsAutoTArray<gfxTextRange,3> fontRanges;
ComputeRanges(fontRanges, aString + aScriptRunStart,
aScriptRunEnd - aScriptRunStart, aRunScript);
uint32_t numRanges = fontRanges.Length();
for (uint32_t r = 0; r < numRanges; r++) {
const gfxTextRange& range = fontRanges[r];
uint32_t matchedLength = range.Length();
gfxFont *matchedFont = (range.font ? range.font.get() : nullptr);
// create the glyph run for this range
if (matchedFont) {
aTextRun->AddGlyphRun(matchedFont, range.matchType,
runStart, (matchedLength > 0));
// do glyph layout and record the resulting positioned glyphs
if (!matchedFont->SplitAndInitTextRun(aContext, aTextRun, aString,
runStart, matchedLength,
aRunScript)) {
// glyph layout failed! treat as missing glyphs
matchedFont = nullptr;
}
} else {
aTextRun->AddGlyphRun(mainFont, gfxTextRange::kFontGroup,
runStart, (matchedLength > 0));
}
if (!matchedFont) {
// for PRUnichar text, we need to set cluster boundaries so that
// surrogate pairs, combining characters, etc behave properly,
// even if we don't have glyphs for them
if (sizeof(T) == sizeof(PRUnichar)) {
gfxShapedWord::SetupClusterBoundaries(aTextRun->GetCharacterGlyphs() + runStart,
reinterpret_cast<const PRUnichar*>(aString) + runStart,
matchedLength);
}
// various "missing" characters may need special handling,
// so we check for them here
uint32_t runLimit = runStart + matchedLength;
for (uint32_t index = runStart; index < runLimit; index++) {
T ch = aString[index];
// tab and newline are not to be displayed as hexboxes,
// but do need to be recorded in the textrun
if (ch == '\n') {
aTextRun->SetIsNewline(index);
continue;
}
if (ch == '\t') {
aTextRun->SetIsTab(index);
continue;
}
// for 16-bit textruns only, check for surrogate pairs and
// special Unicode spaces; omit these checks in 8-bit runs
if (sizeof(T) == sizeof(PRUnichar)) {
if (NS_IS_HIGH_SURROGATE(ch) &&
index + 1 < aScriptRunEnd &&
NS_IS_LOW_SURROGATE(aString[index + 1]))
{
aTextRun->SetMissingGlyph(index,
SURROGATE_TO_UCS4(ch,
aString[index + 1]));
index++;
aTextRun->SetIsLowSurrogate(index);
continue;
}
// check if this is a known Unicode whitespace character that
// we can render using the space glyph with a custom width
gfxFloat wid = mainFont->SynthesizeSpaceWidth(ch);
if (wid >= 0.0) {
nscoord advance =
aTextRun->GetAppUnitsPerDevUnit() * floor(wid + 0.5);
gfxTextRun::CompressedGlyph g;
if (gfxTextRun::CompressedGlyph::IsSimpleAdvance(advance)) {
aTextRun->SetSimpleGlyph(index,
g.SetSimpleGlyph(advance,
mainFont->GetSpaceGlyph()));
} else {
gfxTextRun::DetailedGlyph detailedGlyph;
detailedGlyph.mGlyphID = mainFont->GetSpaceGlyph();
detailedGlyph.mAdvance = advance;
detailedGlyph.mXOffset = detailedGlyph.mYOffset = 0;
g.SetComplex(true, true, 1);
aTextRun->SetGlyphs(index,
g, &detailedGlyph);
}
continue;
}
}
if (IsInvalidChar(ch)) {
// invalid chars are left as zero-width/invisible
continue;
}
// record char code so we can draw a box with the Unicode value
aTextRun->SetMissingGlyph(index, ch);
}
}
runStart += matchedLength;
}
}
already_AddRefed<gfxFont>
gfxFontGroup::TryOtherFamilyMembers(gfxFont* aFont, uint32_t aCh)
{
gfxFontFamily *family = aFont->GetFontEntry()->Family();
if (family && !aFont->GetFontEntry()->mIsProxy &&
family->TestCharacterMap(aCh)) {
// Note that we don't need the actual runScript in matchData for
// gfxFontFamily::SearchAllFontsForChar, it's only used for the
// system-fallback case. So we can just set it to 0 here.
GlobalFontMatch matchData(aCh, 0, &mStyle);
family->SearchAllFontsForChar(&matchData);
gfxFontEntry *fe = matchData.mBestMatch;
if (fe) {
bool needsBold = aFont->GetStyle()->weight >= 600 && !fe->IsBold();
nsRefPtr<gfxFont> font = fe->FindOrMakeFont(&mStyle, needsBold);
if (font) {
return font.forget();
}
}
}
return nullptr;
}
already_AddRefed<gfxFont>
gfxFontGroup::FindFontForChar(uint32_t aCh, uint32_t aPrevCh,
int32_t aRunScript, gfxFont *aPrevMatchedFont,
uint8_t *aMatchType)
{
// To optimize common cases, try the first font in the font-group
// before going into the more detailed checks below
uint32_t nextIndex = 0;
bool isJoinControl = gfxFontUtils::IsJoinControl(aCh);
bool wasJoinCauser = gfxFontUtils::IsJoinCauser(aPrevCh);
bool isVarSelector = gfxFontUtils::IsVarSelector(aCh);
if (!isJoinControl && !wasJoinCauser && !isVarSelector) {
gfxFont *firstFont = mFonts[0];
if (firstFont->HasCharacter(aCh)) {
*aMatchType = gfxTextRange::kFontGroup;
firstFont->AddRef();
return firstFont;
}
// It's possible that another font in the family (e.g. regular face,
// where the requested style was italic) will support the character
nsRefPtr<gfxFont> font = TryOtherFamilyMembers(firstFont, aCh);
if (font) {
*aMatchType = gfxTextRange::kFontGroup;
return font.forget();
}
// we don't need to check the first font again below
++nextIndex;
}
if (aPrevMatchedFont) {
// Don't switch fonts for control characters, regardless of
// whether they are present in the current font, as they won't
// actually be rendered (see bug 716229)
uint8_t category = GetGeneralCategory(aCh);
if (category == HB_UNICODE_GENERAL_CATEGORY_CONTROL) {
aPrevMatchedFont->AddRef();
return aPrevMatchedFont;
}
// if this character is a join-control or the previous is a join-causer,
// use the same font as the previous range if we can
if (isJoinControl || wasJoinCauser) {
if (aPrevMatchedFont->HasCharacter(aCh)) {
aPrevMatchedFont->AddRef();
return aPrevMatchedFont;
}
}
}
// if this character is a variation selector,
// use the previous font regardless of whether it supports VS or not.
// otherwise the text run will be divided.
if (isVarSelector) {
if (aPrevMatchedFont) {
aPrevMatchedFont->AddRef();
return aPrevMatchedFont;
}
// VS alone. it's meaningless to search different fonts
return nullptr;
}
// 1. check remaining fonts in the font group
uint32_t fontListLength = FontListLength();
for (uint32_t i = nextIndex; i < fontListLength; i++) {
nsRefPtr<gfxFont> font = mFonts[i];
if (font->HasCharacter(aCh)) {
*aMatchType = gfxTextRange::kFontGroup;
return font.forget();
}
font = TryOtherFamilyMembers(font, aCh);
if (font) {
*aMatchType = gfxTextRange::kFontGroup;
return font.forget();
}
}
// if character is in Private Use Area, don't do matching against pref or system fonts
if ((aCh >= 0xE000 && aCh <= 0xF8FF) || (aCh >= 0xF0000 && aCh <= 0x10FFFD))
return nullptr;
// 2. search pref fonts
nsRefPtr<gfxFont> font = WhichPrefFontSupportsChar(aCh);
if (font) {
*aMatchType = gfxTextRange::kPrefsFallback;
return font.forget();
}
// 3. use fallback fonts
// -- before searching for something else check the font used for the previous character
if (aPrevMatchedFont && aPrevMatchedFont->HasCharacter(aCh)) {
*aMatchType = gfxTextRange::kSystemFallback;
aPrevMatchedFont->AddRef();
return aPrevMatchedFont;
}
// never fall back for characters from unknown scripts
if (aRunScript == HB_SCRIPT_UNKNOWN) {
return nullptr;
}
// for known "space" characters, don't do a full system-fallback search;
// we'll synthesize appropriate-width spaces instead of missing-glyph boxes
if (GetGeneralCategory(aCh) ==
HB_UNICODE_GENERAL_CATEGORY_SPACE_SEPARATOR &&
GetFontAt(0)->SynthesizeSpaceWidth(aCh) >= 0.0)
{
return nullptr;
}
// -- otherwise look for other stuff
*aMatchType = gfxTextRange::kSystemFallback;
font = WhichSystemFontSupportsChar(aCh, aRunScript);
return font.forget();
}
template<typename T>
void gfxFontGroup::ComputeRanges(nsTArray<gfxTextRange>& aRanges,
const T *aString, uint32_t aLength,
int32_t aRunScript)
{
NS_ASSERTION(aRanges.Length() == 0, "aRanges must be initially empty");
NS_ASSERTION(aLength > 0, "don't call ComputeRanges for zero-length text");
uint32_t prevCh = 0;
uint8_t matchType = 0;
int32_t lastRangeIndex = -1;
// initialize prevFont to the group's primary font, so that this will be
// used for string-initial control chars, etc rather than risk hitting font
// fallback for these (bug 716229)
gfxFont *prevFont = GetFontAt(0);
for (uint32_t i = 0; i < aLength; i++) {
const uint32_t origI = i; // save off in case we increase for surrogate
// set up current ch
uint32_t ch = aString[i];
// in 16-bit case only, check for surrogate pair
if (sizeof(T) == sizeof(PRUnichar)) {
if ((i + 1 < aLength) && NS_IS_HIGH_SURROGATE(ch) &&
NS_IS_LOW_SURROGATE(aString[i + 1])) {
i++;
ch = SURROGATE_TO_UCS4(ch, aString[i]);
}
}
if (ch == 0xa0) {
ch = ' ';
}
// find the font for this char
nsRefPtr<gfxFont> font =
FindFontForChar(ch, prevCh, aRunScript, prevFont, &matchType);
prevCh = ch;
if (lastRangeIndex == -1) {
// first char ==> make a new range
aRanges.AppendElement(gfxTextRange(0, 1, font, matchType));
lastRangeIndex++;
prevFont = font;
} else {
// if font has changed, make a new range
gfxTextRange& prevRange = aRanges[lastRangeIndex];
if (prevRange.font != font || prevRange.matchType != matchType) {
// close out the previous range
prevRange.end = origI;
aRanges.AppendElement(gfxTextRange(origI, i + 1,
font, matchType));
lastRangeIndex++;
// update prevFont for the next match, *unless* we switched
// fonts on a ZWJ, in which case propagating the changed font
// is probably not a good idea (see bug 619511)
if (sizeof(T) == sizeof(uint8_t) ||
!gfxFontUtils::IsJoinCauser(ch))
{
prevFont = font;
}
}
}
}
aRanges[lastRangeIndex].end = aLength;
}
gfxUserFontSet*
gfxFontGroup::GetUserFontSet()
{
return mUserFontSet;
}
void
gfxFontGroup::SetUserFontSet(gfxUserFontSet *aUserFontSet)
{
NS_IF_RELEASE(mUserFontSet);
mUserFontSet = aUserFontSet;
NS_IF_ADDREF(mUserFontSet);
mCurrGeneration = GetGeneration();
}
uint64_t
gfxFontGroup::GetGeneration()
{
if (!mUserFontSet)
return 0;
return mUserFontSet->GetGeneration();
}
void
gfxFontGroup::UpdateFontList()
{
if (mUserFontSet && mCurrGeneration != GetGeneration()) {
// xxx - can probably improve this to detect when all fonts were found, so no need to update list
mFonts.Clear();
mUnderlineOffset = UNDERLINE_OFFSET_NOT_SET;
mSkipDrawing = false;
// bug 548184 - need to clean up FT2, OS/2 platform code to use BuildFontList
#if defined(XP_MACOSX) || defined(XP_WIN) || defined(ANDROID)
BuildFontList();
#else
ForEachFont(FindPlatformFont, this);
#endif
mCurrGeneration = GetGeneration();
}
}
struct PrefFontCallbackData {
PrefFontCallbackData(nsTArray<nsRefPtr<gfxFontFamily> >& aFamiliesArray)
: mPrefFamilies(aFamiliesArray)
{}
nsTArray<nsRefPtr<gfxFontFamily> >& mPrefFamilies;
static bool AddFontFamilyEntry(eFontPrefLang aLang, const nsAString& aName, void *aClosure)
{
PrefFontCallbackData *prefFontData = static_cast<PrefFontCallbackData*>(aClosure);
gfxFontFamily *family = gfxPlatformFontList::PlatformFontList()->FindFamily(aName);
if (family) {
prefFontData->mPrefFamilies.AppendElement(family);
}
return true;
}
};
already_AddRefed<gfxFont>
gfxFontGroup::WhichPrefFontSupportsChar(uint32_t aCh)
{
gfxFont *font;
// get the pref font list if it hasn't been set up already
uint32_t unicodeRange = FindCharUnicodeRange(aCh);
eFontPrefLang charLang = gfxPlatform::GetPlatform()->GetFontPrefLangFor(unicodeRange);
// if the last pref font was the first family in the pref list, no need to recheck through a list of families
if (mLastPrefFont && charLang == mLastPrefLang &&
mLastPrefFirstFont && mLastPrefFont->HasCharacter(aCh)) {
font = mLastPrefFont;
NS_ADDREF(font);
return font;
}
// based on char lang and page lang, set up list of pref lang fonts to check
eFontPrefLang prefLangs[kMaxLenPrefLangList];
uint32_t i, numLangs = 0;
gfxPlatform::GetPlatform()->GetLangPrefs(prefLangs, numLangs, charLang, mPageLang);
for (i = 0; i < numLangs; i++) {
nsAutoTArray<nsRefPtr<gfxFontFamily>, 5> families;
eFontPrefLang currentLang = prefLangs[i];
gfxPlatformFontList *fontList = gfxPlatformFontList::PlatformFontList();
// get the pref families for a single pref lang
if (!fontList->GetPrefFontFamilyEntries(currentLang, &families)) {
eFontPrefLang prefLangsToSearch[1] = { currentLang };
PrefFontCallbackData prefFontData(families);
gfxPlatform::ForEachPrefFont(prefLangsToSearch, 1, PrefFontCallbackData::AddFontFamilyEntry,
&prefFontData);
fontList->SetPrefFontFamilyEntries(currentLang, families);
}
// find the first pref font that includes the character
uint32_t j, numPrefs;
numPrefs = families.Length();
for (j = 0; j < numPrefs; j++) {
// look up the appropriate face
gfxFontFamily *family = families[j];
if (!family) continue;
// if a pref font is used, it's likely to be used again in the same text run.
// the style doesn't change so the face lookup can be cached rather than calling
// FindOrMakeFont repeatedly. speeds up FindFontForChar lookup times for subsequent
// pref font lookups
if (family == mLastPrefFamily && mLastPrefFont->HasCharacter(aCh)) {
font = mLastPrefFont;
NS_ADDREF(font);
return font;
}
bool needsBold;
gfxFontEntry *fe = family->FindFontForStyle(mStyle, needsBold);
// if ch in cmap, create and return a gfxFont
if (fe && fe->TestCharacterMap(aCh)) {
nsRefPtr<gfxFont> prefFont = fe->FindOrMakeFont(&mStyle, needsBold);
if (!prefFont) continue;
mLastPrefFamily = family;
mLastPrefFont = prefFont;
mLastPrefLang = charLang;
mLastPrefFirstFont = (i == 0 && j == 0);
return prefFont.forget();
}
}
}
return nullptr;
}
already_AddRefed<gfxFont>
gfxFontGroup::WhichSystemFontSupportsChar(uint32_t aCh, int32_t aRunScript)
{
gfxFontEntry *fe =
gfxPlatformFontList::PlatformFontList()->
SystemFindFontForChar(aCh, aRunScript, &mStyle);
if (fe) {
bool wantBold = mStyle.ComputeWeight() >= 6;
nsRefPtr<gfxFont> font =
fe->FindOrMakeFont(&mStyle, wantBold && !fe->IsBold());
return font.forget();
}
return nullptr;
}
/*static*/ void
gfxFontGroup::Shutdown()
{
NS_IF_RELEASE(gLangService);
}
nsILanguageAtomService* gfxFontGroup::gLangService = nullptr;
#define DEFAULT_PIXEL_FONT_SIZE 16.0f
/*static*/ uint32_t
gfxFontStyle::ParseFontLanguageOverride(const nsString& aLangTag)
{
if (!aLangTag.Length() || aLangTag.Length() > 4) {
return NO_FONT_LANGUAGE_OVERRIDE;
}
uint32_t index, result = 0;
for (index = 0; index < aLangTag.Length(); ++index) {
PRUnichar ch = aLangTag[index];
if (!nsCRT::IsAscii(ch)) { // valid tags are pure ASCII
return NO_FONT_LANGUAGE_OVERRIDE;
}
result = (result << 8) + ch;
}
while (index++ < 4) {
result = (result << 8) + 0x20;
}
return result;
}
gfxFontStyle::gfxFontStyle() :
language(nsGkAtoms::x_western),
size(DEFAULT_PIXEL_FONT_SIZE), sizeAdjust(0.0f),
languageOverride(NO_FONT_LANGUAGE_OVERRIDE),
weight(NS_FONT_WEIGHT_NORMAL), stretch(NS_FONT_STRETCH_NORMAL),
systemFont(true), printerFont(false),
style(NS_FONT_STYLE_NORMAL)
{
}
gfxFontStyle::gfxFontStyle(uint8_t aStyle, uint16_t aWeight, int16_t aStretch,
gfxFloat aSize, nsIAtom *aLanguage,
float aSizeAdjust, bool aSystemFont,
bool aPrinterFont,
const nsString& aLanguageOverride):
language(aLanguage),
size(aSize), sizeAdjust(aSizeAdjust),
languageOverride(ParseFontLanguageOverride(aLanguageOverride)),
weight(aWeight), stretch(aStretch),
systemFont(aSystemFont), printerFont(aPrinterFont),
style(aStyle)
{
if (weight > 900)
weight = 900;
if (weight < 100)
weight = 100;
if (size >= FONT_MAX_SIZE) {
size = FONT_MAX_SIZE;
sizeAdjust = 0.0;
} else if (size < 0.0) {
NS_WARNING("negative font size");
size = 0.0;
}
if (!language) {
NS_WARNING("null language");
language = nsGkAtoms::x_western;
}
}
gfxFontStyle::gfxFontStyle(const gfxFontStyle& aStyle) :
language(aStyle.language),
size(aStyle.size), sizeAdjust(aStyle.sizeAdjust),
languageOverride(aStyle.languageOverride),
weight(aStyle.weight), stretch(aStyle.stretch),
systemFont(aStyle.systemFont), printerFont(aStyle.printerFont),
style(aStyle.style)
{
featureSettings.AppendElements(aStyle.featureSettings);
}
int8_t
gfxFontStyle::ComputeWeight() const
{
int8_t baseWeight = (weight + 50) / 100;
if (baseWeight < 0)
baseWeight = 0;
if (baseWeight > 9)
baseWeight = 9;
return baseWeight;
}
// This is not a member function of gfxShapedWord because it is also used
// by gfxFontGroup on missing-glyph runs, where we don't actually "shape"
// anything but still need to set cluster info.
/*static*/ void
gfxShapedWord::SetupClusterBoundaries(CompressedGlyph *aGlyphs,
const PRUnichar *aString, uint32_t aLength)
{
gfxTextRun::CompressedGlyph extendCluster;
extendCluster.SetComplex(false, true, 0);
ClusterIterator iter(aString, aLength);
// the ClusterIterator won't be able to tell us if the string
// _begins_ with a cluster-extender, so we handle that here
if (aLength && IsClusterExtender(*aString)) {
*aGlyphs = extendCluster;
}
while (!iter.AtEnd()) {
// advance iter to the next cluster-start (or end of text)
iter.Next();
// step past the first char of the cluster
aString++;
aGlyphs++;
// mark all the rest as cluster-continuations
while (aString < iter) {
*aGlyphs++ = extendCluster;
aString++;
}
}
}
gfxShapedWord::DetailedGlyph *
gfxShapedWord::AllocateDetailedGlyphs(uint32_t aIndex, uint32_t aCount)
{
NS_ASSERTION(aIndex < Length(), "Index out of range");
if (!mDetailedGlyphs) {
mDetailedGlyphs = new DetailedGlyphStore();
}
DetailedGlyph *details = mDetailedGlyphs->Allocate(aIndex, aCount);
if (!details) {
mCharacterGlyphs[aIndex].SetMissing(0);
return nullptr;
}
return details;
}
void
gfxShapedWord::SetGlyphs(uint32_t aIndex, CompressedGlyph aGlyph,
const DetailedGlyph *aGlyphs)
{
NS_ASSERTION(!aGlyph.IsSimpleGlyph(), "Simple glyphs not handled here");
NS_ASSERTION(aIndex > 0 || aGlyph.IsLigatureGroupStart(),
"First character can't be a ligature continuation!");
uint32_t glyphCount = aGlyph.GetGlyphCount();
if (glyphCount > 0) {
DetailedGlyph *details = AllocateDetailedGlyphs(aIndex, glyphCount);
if (!details) {
return;
}
memcpy(details, aGlyphs, sizeof(DetailedGlyph)*glyphCount);
}
mCharacterGlyphs[aIndex] = aGlyph;
}
#define ZWNJ 0x200C
#define ZWJ 0x200D
static inline bool
IsDefaultIgnorable(uint32_t aChar)
{
return GetIdentifierModification(aChar) == XIDMOD_DEFAULT_IGNORABLE ||
aChar == ZWNJ || aChar == ZWJ;
}
void
gfxShapedWord::SetMissingGlyph(uint32_t aIndex, uint32_t aChar, gfxFont *aFont)
{
DetailedGlyph *details = AllocateDetailedGlyphs(aIndex, 1);
if (!details) {
return;
}
details->mGlyphID = aChar;
if (IsDefaultIgnorable(aChar)) {
// Setting advance width to zero will prevent drawing the hexbox
details->mAdvance = 0;
} else {
gfxFloat width = NS_MAX(aFont->GetMetrics().aveCharWidth,
gfxFontMissingGlyphs::GetDesiredMinWidth(aChar));
details->mAdvance = uint32_t(width * mAppUnitsPerDevUnit);
}
details->mXOffset = 0;
details->mYOffset = 0;
mCharacterGlyphs[aIndex].SetMissing(1);
}
bool
gfxShapedWord::FilterIfIgnorable(uint32_t aIndex)
{
uint32_t ch = GetCharAt(aIndex);
if (IsDefaultIgnorable(ch)) {
DetailedGlyph *details = AllocateDetailedGlyphs(aIndex, 1);
if (details) {
details->mGlyphID = ch;
details->mAdvance = 0;
details->mXOffset = 0;
details->mYOffset = 0;
mCharacterGlyphs[aIndex].SetMissing(1);
return true;
}
}
return false;
}
void
gfxShapedWord::AdjustAdvancesForSyntheticBold(float aSynBoldOffset)
{
uint32_t synAppUnitOffset = aSynBoldOffset * mAppUnitsPerDevUnit;
for (uint32_t i = 0; i < Length(); ++i) {
CompressedGlyph *glyphData = &mCharacterGlyphs[i];
if (glyphData->IsSimpleGlyph()) {
// simple glyphs ==> just add the advance
int32_t advance = glyphData->GetSimpleAdvance() + synAppUnitOffset;
if (CompressedGlyph::IsSimpleAdvance(advance)) {
glyphData->SetSimpleGlyph(advance, glyphData->GetSimpleGlyph());
} else {
// rare case, tested by making this the default
uint32_t glyphIndex = glyphData->GetSimpleGlyph();
glyphData->SetComplex(true, true, 1);
DetailedGlyph detail = {glyphIndex, advance, 0, 0};
SetGlyphs(i, *glyphData, &detail);
}
} else {
// complex glyphs ==> add offset at cluster/ligature boundaries
uint32_t detailedLength = glyphData->GetGlyphCount();
if (detailedLength) {
DetailedGlyph *details = GetDetailedGlyphs(i);
if (!details) {
continue;
}
if (IsRightToLeft()) {
details[0].mAdvance += synAppUnitOffset;
} else {
details[detailedLength - 1].mAdvance += synAppUnitOffset;
}
}
}
}
}
bool
gfxTextRun::GlyphRunIterator::NextRun() {
if (mNextIndex >= mTextRun->mGlyphRuns.Length())
return false;
mGlyphRun = &mTextRun->mGlyphRuns[mNextIndex];
if (mGlyphRun->mCharacterOffset >= mEndOffset)
return false;
mStringStart = NS_MAX(mStartOffset, mGlyphRun->mCharacterOffset);
uint32_t last = mNextIndex + 1 < mTextRun->mGlyphRuns.Length()
? mTextRun->mGlyphRuns[mNextIndex + 1].mCharacterOffset : mTextRun->mCharacterCount;
mStringEnd = NS_MIN(mEndOffset, last);
++mNextIndex;
return true;
}
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
static void
AccountStorageForTextRun(gfxTextRun *aTextRun, int32_t aSign)
{
// Ignores detailed glyphs... we don't know when those have been constructed
// Also ignores gfxSkipChars dynamic storage (which won't be anything
// for preformatted text)
// Also ignores GlyphRun array, again because it hasn't been constructed
// by the time this gets called. If there's only one glyphrun that's stored
// directly in the textrun anyway so no additional overhead.
uint32_t length = aTextRun->GetLength();
int32_t bytes = length * sizeof(gfxTextRun::CompressedGlyph);
bytes += sizeof(gfxTextRun);
gTextRunStorage += bytes*aSign;
gTextRunStorageHighWaterMark = NS_MAX(gTextRunStorageHighWaterMark, gTextRunStorage);
}
#endif
// Helper for textRun creation to preallocate storage for glyph records;
// this function returns a pointer to the newly-allocated glyph storage.
// Returns nullptr if allocation fails.
void *
gfxTextRun::AllocateStorageForTextRun(size_t aSize, uint32_t aLength)
{
// Allocate the storage we need, returning nullptr on failure rather than
// throwing an exception (because web content can create huge runs).
void *storage = moz_malloc(aSize + aLength * sizeof(CompressedGlyph));
if (!storage) {
NS_WARNING("failed to allocate storage for text run!");
return nullptr;
}
// Initialize the glyph storage (beyond aSize) to zero
memset(reinterpret_cast<char*>(storage) + aSize, 0,
aLength * sizeof(CompressedGlyph));
return storage;
}
gfxTextRun *
gfxTextRun::Create(const gfxTextRunFactory::Parameters *aParams,
uint32_t aLength, gfxFontGroup *aFontGroup, uint32_t aFlags)
{
void *storage = AllocateStorageForTextRun(sizeof(gfxTextRun), aLength);
if (!storage) {
return nullptr;
}
return new (storage) gfxTextRun(aParams, aLength, aFontGroup, aFlags);
}
gfxTextRun::gfxTextRun(const gfxTextRunFactory::Parameters *aParams,
uint32_t aLength, gfxFontGroup *aFontGroup, uint32_t aFlags)
: mUserData(aParams->mUserData),
mFontGroup(aFontGroup),
mAppUnitsPerDevUnit(aParams->mAppUnitsPerDevUnit),
mFlags(aFlags), mCharacterCount(aLength)
{
NS_ASSERTION(mAppUnitsPerDevUnit != 0, "Invalid app unit scale");
MOZ_COUNT_CTOR(gfxTextRun);
NS_ADDREF(mFontGroup);
mCharacterGlyphs = reinterpret_cast<CompressedGlyph*>(this + 1);
if (aParams->mSkipChars) {
mSkipChars.TakeFrom(aParams->mSkipChars);
}
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
AccountStorageForTextRun(this, 1);
#endif
mSkipDrawing = mFontGroup->ShouldSkipDrawing();
}
gfxTextRun::~gfxTextRun()
{
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
AccountStorageForTextRun(this, -1);
#endif
#ifdef DEBUG
// Make it easy to detect a dead text run
mFlags = 0xFFFFFFFF;
#endif
NS_RELEASE(mFontGroup);
MOZ_COUNT_DTOR(gfxTextRun);
}
bool
gfxTextRun::SetPotentialLineBreaks(uint32_t aStart, uint32_t aLength,
uint8_t *aBreakBefore,
gfxContext *aRefContext)
{
NS_ASSERTION(aStart + aLength <= mCharacterCount, "Overflow");
uint32_t changed = 0;
uint32_t i;
CompressedGlyph *charGlyphs = mCharacterGlyphs + aStart;
for (i = 0; i < aLength; ++i) {
uint8_t canBreak = aBreakBefore[i];
if (canBreak && !charGlyphs[i].IsClusterStart()) {
// This can happen ... there is no guarantee that our linebreaking rules
// align with the platform's idea of what constitutes a cluster.
NS_WARNING("Break suggested inside cluster!");
canBreak = CompressedGlyph::FLAG_BREAK_TYPE_NONE;
}
changed |= charGlyphs[i].SetCanBreakBefore(canBreak);
}
return changed != 0;
}
gfxTextRun::LigatureData
gfxTextRun::ComputeLigatureData(uint32_t aPartStart, uint32_t aPartEnd,
PropertyProvider *aProvider)
{
NS_ASSERTION(aPartStart < aPartEnd, "Computing ligature data for empty range");
NS_ASSERTION(aPartEnd <= mCharacterCount, "Character length overflow");
LigatureData result;
CompressedGlyph *charGlyphs = mCharacterGlyphs;
uint32_t i;
for (i = aPartStart; !charGlyphs[i].IsLigatureGroupStart(); --i) {
NS_ASSERTION(i > 0, "Ligature at the start of the run??");
}
result.mLigatureStart = i;
for (i = aPartStart + 1; i < mCharacterCount && !charGlyphs[i].IsLigatureGroupStart(); ++i) {
}
result.mLigatureEnd = i;
int32_t ligatureWidth =
GetAdvanceForGlyphs(result.mLigatureStart, result.mLigatureEnd);
// Count the number of started clusters we have seen
uint32_t totalClusterCount = 0;
uint32_t partClusterIndex = 0;
uint32_t partClusterCount = 0;
for (i = result.mLigatureStart; i < result.mLigatureEnd; ++i) {
// Treat the first character of the ligature as the start of a
// cluster for our purposes of allocating ligature width to its
// characters.
if (i == result.mLigatureStart || charGlyphs[i].IsClusterStart()) {
++totalClusterCount;
if (i < aPartStart) {
++partClusterIndex;
} else if (i < aPartEnd) {
++partClusterCount;
}
}
}
NS_ASSERTION(totalClusterCount > 0, "Ligature involving no clusters??");
result.mPartAdvance = partClusterIndex * (ligatureWidth / totalClusterCount);
result.mPartWidth = partClusterCount * (ligatureWidth / totalClusterCount);
// Any rounding errors are apportioned to the final part of the ligature,
// so that measuring all parts of a ligature and summing them is equal to
// the ligature width.
if (aPartEnd == result.mLigatureEnd) {
gfxFloat allParts = totalClusterCount * (ligatureWidth / totalClusterCount);
result.mPartWidth += ligatureWidth - allParts;
}
if (partClusterCount == 0) {
// nothing to draw
result.mClipBeforePart = result.mClipAfterPart = true;
} else {
// Determine whether we should clip before or after this part when
// drawing its slice of the ligature.
// We need to clip before the part if any cluster is drawn before
// this part.
result.mClipBeforePart = partClusterIndex > 0;
// We need to clip after the part if any cluster is drawn after
// this part.
result.mClipAfterPart = partClusterIndex + partClusterCount < totalClusterCount;
}
if (aProvider && (mFlags & gfxTextRunFactory::TEXT_ENABLE_SPACING)) {
gfxFont::Spacing spacing;
if (aPartStart == result.mLigatureStart) {
aProvider->GetSpacing(aPartStart, 1, &spacing);
result.mPartWidth += spacing.mBefore;
}
if (aPartEnd == result.mLigatureEnd) {
aProvider->GetSpacing(aPartEnd - 1, 1, &spacing);
result.mPartWidth += spacing.mAfter;
}
}
return result;
}
gfxFloat
gfxTextRun::ComputePartialLigatureWidth(uint32_t aPartStart, uint32_t aPartEnd,
PropertyProvider *aProvider)
{
if (aPartStart >= aPartEnd)
return 0;
LigatureData data = ComputeLigatureData(aPartStart, aPartEnd, aProvider);
return data.mPartWidth;
}
int32_t
gfxTextRun::GetAdvanceForGlyphs(uint32_t aStart, uint32_t aEnd)
{
const CompressedGlyph *glyphData = mCharacterGlyphs + aStart;
int32_t advance = 0;
uint32_t i;
for (i = aStart; i < aEnd; ++i, ++glyphData) {
if (glyphData->IsSimpleGlyph()) {
advance += glyphData->GetSimpleAdvance();
} else {
uint32_t glyphCount = glyphData->GetGlyphCount();
if (glyphCount == 0) {
continue;
}
const DetailedGlyph *details = GetDetailedGlyphs(i);
if (details) {
uint32_t j;
for (j = 0; j < glyphCount; ++j, ++details) {
advance += details->mAdvance;
}
}
}
}
return advance;
}
static void
GetAdjustedSpacing(gfxTextRun *aTextRun, uint32_t aStart, uint32_t aEnd,
gfxTextRun::PropertyProvider *aProvider,
gfxTextRun::PropertyProvider::Spacing *aSpacing)
{
if (aStart >= aEnd)
return;
aProvider->GetSpacing(aStart, aEnd - aStart, aSpacing);
#ifdef DEBUG
// Check to see if we have spacing inside ligatures
const gfxTextRun::CompressedGlyph *charGlyphs = aTextRun->GetCharacterGlyphs();
uint32_t i;
for (i = aStart; i < aEnd; ++i) {
if (!charGlyphs[i].IsLigatureGroupStart()) {
NS_ASSERTION(i == aStart || aSpacing[i - aStart].mBefore == 0,
"Before-spacing inside a ligature!");
NS_ASSERTION(i - 1 <= aStart || aSpacing[i - 1 - aStart].mAfter == 0,
"After-spacing inside a ligature!");
}
}
#endif
}
bool
gfxTextRun::GetAdjustedSpacingArray(uint32_t aStart, uint32_t aEnd,
PropertyProvider *aProvider,
uint32_t aSpacingStart, uint32_t aSpacingEnd,
nsTArray<PropertyProvider::Spacing> *aSpacing)
{
if (!aProvider || !(mFlags & gfxTextRunFactory::TEXT_ENABLE_SPACING))
return false;
if (!aSpacing->AppendElements(aEnd - aStart))
return false;
memset(aSpacing->Elements(), 0, sizeof(gfxFont::Spacing)*(aSpacingStart - aStart));
GetAdjustedSpacing(this, aSpacingStart, aSpacingEnd, aProvider,
aSpacing->Elements() + aSpacingStart - aStart);
memset(aSpacing->Elements() + aSpacingEnd - aStart, 0, sizeof(gfxFont::Spacing)*(aEnd - aSpacingEnd));
return true;
}
void
gfxTextRun::ShrinkToLigatureBoundaries(uint32_t *aStart, uint32_t *aEnd)
{
if (*aStart >= *aEnd)
return;
CompressedGlyph *charGlyphs = mCharacterGlyphs;
while (*aStart < *aEnd && !charGlyphs[*aStart].IsLigatureGroupStart()) {
++(*aStart);
}
if (*aEnd < mCharacterCount) {
while (*aEnd > *aStart && !charGlyphs[*aEnd].IsLigatureGroupStart()) {
--(*aEnd);
}
}
}
void
gfxTextRun::DrawGlyphs(gfxFont *aFont, gfxContext *aContext,
gfxFont::DrawMode aDrawMode, gfxPoint *aPt,
gfxPattern *aStrokePattern,
uint32_t aStart, uint32_t aEnd,
PropertyProvider *aProvider,
uint32_t aSpacingStart, uint32_t aSpacingEnd)
{
nsAutoTArray<PropertyProvider::Spacing,200> spacingBuffer;
bool haveSpacing = GetAdjustedSpacingArray(aStart, aEnd, aProvider,
aSpacingStart, aSpacingEnd, &spacingBuffer);
aFont->Draw(this, aStart, aEnd, aContext, aDrawMode, aPt,
haveSpacing ? spacingBuffer.Elements() : nullptr, aStrokePattern);
}
static void
ClipPartialLigature(gfxTextRun *aTextRun, gfxFloat *aLeft, gfxFloat *aRight,
gfxFloat aXOrigin, gfxTextRun::LigatureData *aLigature)
{
if (aLigature->mClipBeforePart) {
if (aTextRun->IsRightToLeft()) {
*aRight = NS_MIN(*aRight, aXOrigin);
} else {
*aLeft = NS_MAX(*aLeft, aXOrigin);
}
}
if (aLigature->mClipAfterPart) {
gfxFloat endEdge = aXOrigin + aTextRun->GetDirection()*aLigature->mPartWidth;
if (aTextRun->IsRightToLeft()) {
*aLeft = NS_MAX(*aLeft, endEdge);
} else {
*aRight = NS_MIN(*aRight, endEdge);
}
}
}
void
gfxTextRun::DrawPartialLigature(gfxFont *aFont, gfxContext *aCtx,
uint32_t aStart, uint32_t aEnd,
gfxPoint *aPt,
PropertyProvider *aProvider,
gfxTextRun::DrawCallbacks *aCallbacks)
{
if (aStart >= aEnd)
return;
// Draw partial ligature. We hack this by clipping the ligature.
LigatureData data = ComputeLigatureData(aStart, aEnd, aProvider);
gfxRect clipExtents = aCtx->GetClipExtents();
gfxFloat left = clipExtents.X()*mAppUnitsPerDevUnit;
gfxFloat right = clipExtents.XMost()*mAppUnitsPerDevUnit;
ClipPartialLigature(this, &left, &right, aPt->x, &data);
{
// Need to preserve the path, otherwise this can break canvas text-on-path;
// in general it seems like a good thing, as naive callers probably won't
// expect gfxTextRun::Draw to implicitly destroy the current path.
gfxContextPathAutoSaveRestore savePath(aCtx);
// use division here to ensure that when the rect is aligned on multiples
// of mAppUnitsPerDevUnit, we clip to true device unit boundaries.
// Also, make sure we snap the rectangle to device pixels.
aCtx->Save();
aCtx->NewPath();
aCtx->Rectangle(gfxRect(left / mAppUnitsPerDevUnit,
clipExtents.Y(),
(right - left) / mAppUnitsPerDevUnit,
clipExtents.Height()), true);
aCtx->Clip();
}
gfxFloat direction = GetDirection();
gfxPoint pt(aPt->x - direction*data.mPartAdvance, aPt->y);
DrawGlyphs(aFont, aCtx,
aCallbacks ? gfxFont::GLYPH_PATH : gfxFont::GLYPH_FILL, &pt,
nullptr, data.mLigatureStart, data.mLigatureEnd, aProvider,
aStart, aEnd);
if (aCallbacks) {
aCallbacks->NotifyGlyphPathEmitted();
}
aCtx->Restore();
aPt->x += direction*data.mPartWidth;
}
// returns true if a glyph run is using a font with synthetic bolding enabled, false otherwise
static bool
HasSyntheticBold(gfxTextRun *aRun, uint32_t aStart, uint32_t aLength)
{
gfxTextRun::GlyphRunIterator iter(aRun, aStart, aLength);
while (iter.NextRun()) {
gfxFont *font = iter.GetGlyphRun()->mFont;
if (font && font->IsSyntheticBold()) {
return true;
}
}
return false;
}
// returns true if color is non-opaque (i.e. alpha != 1.0) or completely transparent, false otherwise
// if true, color is set on output
static bool
HasNonOpaqueColor(gfxContext *aContext, gfxRGBA& aCurrentColor)
{
if (aContext->GetDeviceColor(aCurrentColor)) {
if (aCurrentColor.a < 1.0 && aCurrentColor.a > 0.0) {
return true;
}
}
return false;
}
// helper class for double-buffering drawing with non-opaque color
struct BufferAlphaColor {
BufferAlphaColor(gfxContext *aContext)
: mContext(aContext)
{
}
~BufferAlphaColor() {}
void PushSolidColor(const gfxRect& aBounds, const gfxRGBA& aAlphaColor, uint32_t appsPerDevUnit)
{
mContext->Save();
mContext->NewPath();
mContext->Rectangle(gfxRect(aBounds.X() / appsPerDevUnit,
aBounds.Y() / appsPerDevUnit,
aBounds.Width() / appsPerDevUnit,
aBounds.Height() / appsPerDevUnit), true);
mContext->Clip();
mContext->SetColor(gfxRGBA(aAlphaColor.r, aAlphaColor.g, aAlphaColor.b));
mContext->PushGroup(gfxASurface::CONTENT_COLOR_ALPHA);
mAlpha = aAlphaColor.a;
}
void PopAlpha()
{
// pop the text, using the color alpha as the opacity
mContext->PopGroupToSource();
mContext->SetOperator(gfxContext::OPERATOR_OVER);
mContext->Paint(mAlpha);
mContext->Restore();
}
gfxContext *mContext;
gfxFloat mAlpha;
};
void
gfxTextRun::Draw(gfxContext *aContext, gfxPoint aPt, gfxFont::DrawMode aDrawMode,
uint32_t aStart, uint32_t aLength,
PropertyProvider *aProvider, gfxFloat *aAdvanceWidth,
gfxPattern *aStrokePattern,
gfxTextRun::DrawCallbacks *aCallbacks)
{
NS_ASSERTION(aStart + aLength <= mCharacterCount, "Substring out of range");
NS_ASSERTION(aDrawMode <= gfxFont::GLYPH_PATH, "GLYPH_PATH cannot be used with GLYPH_FILL or GLYPH_STROKE");
NS_ASSERTION(aDrawMode == gfxFont::GLYPH_PATH || !aCallbacks, "callback must not be specified unless using GLYPH_PATH");
gfxFloat direction = GetDirection();
if (mSkipDrawing) {
// We're waiting for a user font to finish downloading;
// but if the caller wants advance width, we need to compute it here
if (aAdvanceWidth) {
gfxTextRun::Metrics metrics = MeasureText(aStart, aLength,
gfxFont::LOOSE_INK_EXTENTS,
aContext, aProvider);
*aAdvanceWidth = metrics.mAdvanceWidth * direction;
}
// return without drawing
return;
}
gfxPoint pt = aPt;
// synthetic bolding draws glyphs twice ==> colors with opacity won't draw correctly unless first drawn without alpha
BufferAlphaColor syntheticBoldBuffer(aContext);
gfxRGBA currentColor;
bool needToRestore = false;
if (aDrawMode == gfxFont::GLYPH_FILL && HasNonOpaqueColor(aContext, currentColor)
&& HasSyntheticBold(this, aStart, aLength)) {
needToRestore = true;
// measure text, use the bounding box
gfxTextRun::Metrics metrics = MeasureText(aStart, aLength, gfxFont::LOOSE_INK_EXTENTS,
aContext, aProvider);
metrics.mBoundingBox.MoveBy(aPt);
syntheticBoldBuffer.PushSolidColor(metrics.mBoundingBox, currentColor, GetAppUnitsPerDevUnit());
}
GlyphRunIterator iter(this, aStart, aLength);
while (iter.NextRun()) {
gfxFont *font = iter.GetGlyphRun()->mFont;
uint32_t start = iter.GetStringStart();
uint32_t end = iter.GetStringEnd();
uint32_t ligatureRunStart = start;
uint32_t ligatureRunEnd = end;
ShrinkToLigatureBoundaries(&ligatureRunStart, &ligatureRunEnd);
bool drawPartial = aDrawMode == gfxFont::GLYPH_FILL ||
aDrawMode == gfxFont::GLYPH_PATH && aCallbacks;
if (drawPartial) {
DrawPartialLigature(font, aContext, start, ligatureRunStart, &pt,
aProvider, aCallbacks);
}
DrawGlyphs(font, aContext, aDrawMode, &pt, aStrokePattern, ligatureRunStart,
ligatureRunEnd, aProvider, ligatureRunStart, ligatureRunEnd);
if (aCallbacks) {
aCallbacks->NotifyGlyphPathEmitted();
}
if (drawPartial) {
DrawPartialLigature(font, aContext, ligatureRunEnd, end, &pt,
aProvider, aCallbacks);
}
}
// composite result when synthetic bolding used
if (needToRestore) {
syntheticBoldBuffer.PopAlpha();
}
if (aAdvanceWidth) {
*aAdvanceWidth = (pt.x - aPt.x)*direction;
}
}
void
gfxTextRun::AccumulateMetricsForRun(gfxFont *aFont,
uint32_t aStart, uint32_t aEnd,
gfxFont::BoundingBoxType aBoundingBoxType,
gfxContext *aRefContext,
PropertyProvider *aProvider,
uint32_t aSpacingStart, uint32_t aSpacingEnd,
Metrics *aMetrics)
{
nsAutoTArray<PropertyProvider::Spacing,200> spacingBuffer;
bool haveSpacing = GetAdjustedSpacingArray(aStart, aEnd, aProvider,
aSpacingStart, aSpacingEnd, &spacingBuffer);
Metrics metrics = aFont->Measure(this, aStart, aEnd, aBoundingBoxType, aRefContext,
haveSpacing ? spacingBuffer.Elements() : nullptr);
aMetrics->CombineWith(metrics, IsRightToLeft());
}
void
gfxTextRun::AccumulatePartialLigatureMetrics(gfxFont *aFont,
uint32_t aStart, uint32_t aEnd,
gfxFont::BoundingBoxType aBoundingBoxType, gfxContext *aRefContext,
PropertyProvider *aProvider, Metrics *aMetrics)
{
if (aStart >= aEnd)
return;
// Measure partial ligature. We hack this by clipping the metrics in the
// same way we clip the drawing.
LigatureData data = ComputeLigatureData(aStart, aEnd, aProvider);
// First measure the complete ligature
Metrics metrics;
AccumulateMetricsForRun(aFont, data.mLigatureStart, data.mLigatureEnd,
aBoundingBoxType, aRefContext,
aProvider, aStart, aEnd, &metrics);
// Clip the bounding box to the ligature part
gfxFloat bboxLeft = metrics.mBoundingBox.X();
gfxFloat bboxRight = metrics.mBoundingBox.XMost();
// Where we are going to start "drawing" relative to our left baseline origin
gfxFloat origin = IsRightToLeft() ? metrics.mAdvanceWidth - data.mPartAdvance : 0;
ClipPartialLigature(this, &bboxLeft, &bboxRight, origin, &data);
metrics.mBoundingBox.x = bboxLeft;
metrics.mBoundingBox.width = bboxRight - bboxLeft;
// mBoundingBox is now relative to the left baseline origin for the entire
// ligature. Shift it left.
metrics.mBoundingBox.x -=
IsRightToLeft() ? metrics.mAdvanceWidth - (data.mPartAdvance + data.mPartWidth)
: data.mPartAdvance;
metrics.mAdvanceWidth = data.mPartWidth;
aMetrics->CombineWith(metrics, IsRightToLeft());
}
gfxTextRun::Metrics
gfxTextRun::MeasureText(uint32_t aStart, uint32_t aLength,
gfxFont::BoundingBoxType aBoundingBoxType,
gfxContext *aRefContext,
PropertyProvider *aProvider)
{
NS_ASSERTION(aStart + aLength <= mCharacterCount, "Substring out of range");
Metrics accumulatedMetrics;
GlyphRunIterator iter(this, aStart, aLength);
while (iter.NextRun()) {
gfxFont *font = iter.GetGlyphRun()->mFont;
uint32_t start = iter.GetStringStart();
uint32_t end = iter.GetStringEnd();
uint32_t ligatureRunStart = start;
uint32_t ligatureRunEnd = end;
ShrinkToLigatureBoundaries(&ligatureRunStart, &ligatureRunEnd);
AccumulatePartialLigatureMetrics(font, start, ligatureRunStart,
aBoundingBoxType, aRefContext, aProvider, &accumulatedMetrics);
// XXX This sucks. We have to get glyph extents just so we can detect
// glyphs outside the font box, even when aBoundingBoxType is LOOSE,
// even though in almost all cases we could get correct results just
// by getting some ascent/descent from the font and using our stored
// advance widths.
AccumulateMetricsForRun(font,
ligatureRunStart, ligatureRunEnd, aBoundingBoxType,
aRefContext, aProvider, ligatureRunStart, ligatureRunEnd,
&accumulatedMetrics);
AccumulatePartialLigatureMetrics(font, ligatureRunEnd, end,
aBoundingBoxType, aRefContext, aProvider, &accumulatedMetrics);
}
return accumulatedMetrics;
}
#define MEASUREMENT_BUFFER_SIZE 100
uint32_t
gfxTextRun::BreakAndMeasureText(uint32_t aStart, uint32_t aMaxLength,
bool aLineBreakBefore, gfxFloat aWidth,
PropertyProvider *aProvider,
bool aSuppressInitialBreak,
gfxFloat *aTrimWhitespace,
Metrics *aMetrics,
gfxFont::BoundingBoxType aBoundingBoxType,
gfxContext *aRefContext,
bool *aUsedHyphenation,
uint32_t *aLastBreak,
bool aCanWordWrap,
gfxBreakPriority *aBreakPriority)
{
aMaxLength = NS_MIN(aMaxLength, mCharacterCount - aStart);
NS_ASSERTION(aStart + aMaxLength <= mCharacterCount, "Substring out of range");
uint32_t bufferStart = aStart;
uint32_t bufferLength = NS_MIN<uint32_t>(aMaxLength, MEASUREMENT_BUFFER_SIZE);
PropertyProvider::Spacing spacingBuffer[MEASUREMENT_BUFFER_SIZE];
bool haveSpacing = aProvider && (mFlags & gfxTextRunFactory::TEXT_ENABLE_SPACING) != 0;
if (haveSpacing) {
GetAdjustedSpacing(this, bufferStart, bufferStart + bufferLength, aProvider,
spacingBuffer);
}
bool hyphenBuffer[MEASUREMENT_BUFFER_SIZE];
bool haveHyphenation = aProvider &&
(aProvider->GetHyphensOption() == NS_STYLE_HYPHENS_AUTO ||
(aProvider->GetHyphensOption() == NS_STYLE_HYPHENS_MANUAL &&
(mFlags & gfxTextRunFactory::TEXT_ENABLE_HYPHEN_BREAKS) != 0));
if (haveHyphenation) {
aProvider->GetHyphenationBreaks(bufferStart, bufferLength,
hyphenBuffer);
}
gfxFloat width = 0;
gfxFloat advance = 0;
// The number of space characters that can be trimmed
uint32_t trimmableChars = 0;
// The amount of space removed by ignoring trimmableChars
gfxFloat trimmableAdvance = 0;
int32_t lastBreak = -1;
int32_t lastBreakTrimmableChars = -1;
gfxFloat lastBreakTrimmableAdvance = -1;
bool aborted = false;
uint32_t end = aStart + aMaxLength;
bool lastBreakUsedHyphenation = false;
uint32_t ligatureRunStart = aStart;
uint32_t ligatureRunEnd = end;
ShrinkToLigatureBoundaries(&ligatureRunStart, &ligatureRunEnd);
uint32_t i;
for (i = aStart; i < end; ++i) {
if (i >= bufferStart + bufferLength) {
// Fetch more spacing and hyphenation data
bufferStart = i;
bufferLength = NS_MIN(aStart + aMaxLength, i + MEASUREMENT_BUFFER_SIZE) - i;
if (haveSpacing) {
GetAdjustedSpacing(this, bufferStart, bufferStart + bufferLength, aProvider,
spacingBuffer);
}
if (haveHyphenation) {
aProvider->GetHyphenationBreaks(bufferStart, bufferLength,
hyphenBuffer);
}
}
// There can't be a word-wrap break opportunity at the beginning of the
// line: if the width is too small for even one character to fit, it
// could be the first and last break opportunity on the line, and that
// would trigger an infinite loop.
if (!aSuppressInitialBreak || i > aStart) {
bool lineBreakHere = mCharacterGlyphs[i].CanBreakBefore() == 1;
bool hyphenation = haveHyphenation && hyphenBuffer[i - bufferStart];
bool wordWrapping =
aCanWordWrap && mCharacterGlyphs[i].IsClusterStart() &&
*aBreakPriority <= eWordWrapBreak;
if (lineBreakHere || hyphenation || wordWrapping) {
gfxFloat hyphenatedAdvance = advance;
if (!lineBreakHere && !wordWrapping) {
hyphenatedAdvance += aProvider->GetHyphenWidth();
}
if (lastBreak < 0 || width + hyphenatedAdvance - trimmableAdvance <= aWidth) {
// We can break here.
lastBreak = i;
lastBreakTrimmableChars = trimmableChars;
lastBreakTrimmableAdvance = trimmableAdvance;
lastBreakUsedHyphenation = !lineBreakHere && !wordWrapping;
*aBreakPriority = hyphenation || lineBreakHere ?
eNormalBreak : eWordWrapBreak;
}
width += advance;
advance = 0;
if (width - trimmableAdvance > aWidth) {
// No more text fits. Abort
aborted = true;
break;
}
}
}
gfxFloat charAdvance;
if (i >= ligatureRunStart && i < ligatureRunEnd) {
charAdvance = GetAdvanceForGlyphs(i, i + 1);
if (haveSpacing) {
PropertyProvider::Spacing *space = &spacingBuffer[i - bufferStart];
charAdvance += space->mBefore + space->mAfter;
}
} else {
charAdvance = ComputePartialLigatureWidth(i, i + 1, aProvider);
}
advance += charAdvance;
if (aTrimWhitespace) {
if (mCharacterGlyphs[i].CharIsSpace()) {
++trimmableChars;
trimmableAdvance += charAdvance;
} else {
trimmableAdvance = 0;
trimmableChars = 0;
}
}
}
if (!aborted) {
width += advance;
}
// There are three possibilities:
// 1) all the text fit (width <= aWidth)
// 2) some of the text fit up to a break opportunity (width > aWidth && lastBreak >= 0)
// 3) none of the text fits before a break opportunity (width > aWidth && lastBreak < 0)
uint32_t charsFit;
bool usedHyphenation = false;
if (width - trimmableAdvance <= aWidth) {
charsFit = aMaxLength;
} else if (lastBreak >= 0) {
charsFit = lastBreak - aStart;
trimmableChars = lastBreakTrimmableChars;
trimmableAdvance = lastBreakTrimmableAdvance;
usedHyphenation = lastBreakUsedHyphenation;
} else {
charsFit = aMaxLength;
}
if (aMetrics) {
*aMetrics = MeasureText(aStart, charsFit - trimmableChars,
aBoundingBoxType, aRefContext, aProvider);
}
if (aTrimWhitespace) {
*aTrimWhitespace = trimmableAdvance;
}
if (aUsedHyphenation) {
*aUsedHyphenation = usedHyphenation;
}
if (aLastBreak && charsFit == aMaxLength) {
if (lastBreak < 0) {
*aLastBreak = PR_UINT32_MAX;
} else {
*aLastBreak = lastBreak - aStart;
}
}
return charsFit;
}
gfxFloat
gfxTextRun::GetAdvanceWidth(uint32_t aStart, uint32_t aLength,
PropertyProvider *aProvider)
{
NS_ASSERTION(aStart + aLength <= mCharacterCount, "Substring out of range");
uint32_t ligatureRunStart = aStart;
uint32_t ligatureRunEnd = aStart + aLength;
ShrinkToLigatureBoundaries(&ligatureRunStart, &ligatureRunEnd);
gfxFloat result = ComputePartialLigatureWidth(aStart, ligatureRunStart, aProvider) +
ComputePartialLigatureWidth(ligatureRunEnd, aStart + aLength, aProvider);
// Account for all remaining spacing here. This is more efficient than
// processing it along with the glyphs.
if (aProvider && (mFlags & gfxTextRunFactory::TEXT_ENABLE_SPACING)) {
uint32_t i;
nsAutoTArray<PropertyProvider::Spacing,200> spacingBuffer;
if (spacingBuffer.AppendElements(aLength)) {
GetAdjustedSpacing(this, ligatureRunStart, ligatureRunEnd, aProvider,
spacingBuffer.Elements());
for (i = 0; i < ligatureRunEnd - ligatureRunStart; ++i) {
PropertyProvider::Spacing *space = &spacingBuffer[i];
result += space->mBefore + space->mAfter;
}
}
}
return result + GetAdvanceForGlyphs(ligatureRunStart, ligatureRunEnd);
}
bool
gfxTextRun::SetLineBreaks(uint32_t aStart, uint32_t aLength,
bool aLineBreakBefore, bool aLineBreakAfter,
gfxFloat *aAdvanceWidthDelta,
gfxContext *aRefContext)
{
// Do nothing because our shaping does not currently take linebreaks into
// account. There is no change in advance width.
if (aAdvanceWidthDelta) {
*aAdvanceWidthDelta = 0;
}
return false;
}
uint32_t
gfxTextRun::FindFirstGlyphRunContaining(uint32_t aOffset)
{
NS_ASSERTION(aOffset <= mCharacterCount, "Bad offset looking for glyphrun");
NS_ASSERTION(mCharacterCount == 0 || mGlyphRuns.Length() > 0,
"non-empty text but no glyph runs present!");
if (aOffset == mCharacterCount)
return mGlyphRuns.Length();
uint32_t start = 0;
uint32_t end = mGlyphRuns.Length();
while (end - start > 1) {
uint32_t mid = (start + end)/2;
if (mGlyphRuns[mid].mCharacterOffset <= aOffset) {
start = mid;
} else {
end = mid;
}
}
NS_ASSERTION(mGlyphRuns[start].mCharacterOffset <= aOffset,
"Hmm, something went wrong, aOffset should have been found");
return start;
}
nsresult
gfxTextRun::AddGlyphRun(gfxFont *aFont, uint8_t aMatchType,
uint32_t aUTF16Offset, bool aForceNewRun)
{
NS_ASSERTION(aFont, "adding glyph run for null font!");
if (!aFont) {
return NS_OK;
}
uint32_t numGlyphRuns = mGlyphRuns.Length();
if (!aForceNewRun && numGlyphRuns > 0) {
GlyphRun *lastGlyphRun = &mGlyphRuns[numGlyphRuns - 1];
NS_ASSERTION(lastGlyphRun->mCharacterOffset <= aUTF16Offset,
"Glyph runs out of order (and run not forced)");
// Don't append a run if the font is already the one we want
if (lastGlyphRun->mFont == aFont &&
lastGlyphRun->mMatchType == aMatchType)
{
return NS_OK;
}
// If the offset has not changed, avoid leaving a zero-length run
// by overwriting the last entry instead of appending...
if (lastGlyphRun->mCharacterOffset == aUTF16Offset) {
// ...except that if the run before the last entry had the same
// font as the new one wants, merge with it instead of creating
// adjacent runs with the same font
if (numGlyphRuns > 1 &&
mGlyphRuns[numGlyphRuns - 2].mFont == aFont &&
mGlyphRuns[numGlyphRuns - 2].mMatchType == aMatchType)
{
mGlyphRuns.TruncateLength(numGlyphRuns - 1);
return NS_OK;
}
lastGlyphRun->mFont = aFont;
lastGlyphRun->mMatchType = aMatchType;
return NS_OK;
}
}
NS_ASSERTION(aForceNewRun || numGlyphRuns > 0 || aUTF16Offset == 0,
"First run doesn't cover the first character (and run not forced)?");
GlyphRun *glyphRun = mGlyphRuns.AppendElement();
if (!glyphRun)
return NS_ERROR_OUT_OF_MEMORY;
glyphRun->mFont = aFont;
glyphRun->mCharacterOffset = aUTF16Offset;
glyphRun->mMatchType = aMatchType;
return NS_OK;
}
void
gfxTextRun::SortGlyphRuns()
{
if (mGlyphRuns.Length() <= 1)
return;
nsTArray<GlyphRun> runs(mGlyphRuns);
GlyphRunOffsetComparator comp;
runs.Sort(comp);
// Now copy back, coalescing adjacent glyph runs that have the same font
mGlyphRuns.Clear();
uint32_t i, count = runs.Length();
for (i = 0; i < count; ++i) {
// a GlyphRun with the same font as the previous GlyphRun can just
// be skipped; the last GlyphRun will cover its character range.
if (i == 0 || runs[i].mFont != runs[i - 1].mFont) {
mGlyphRuns.AppendElement(runs[i]);
// If two fonts have the same character offset, Sort() will have
// randomized the order.
NS_ASSERTION(i == 0 ||
runs[i].mCharacterOffset !=
runs[i - 1].mCharacterOffset,
"Two fonts for the same run, glyph indices may not match the font");
}
}
}
// Note that SanitizeGlyphRuns scans all glyph runs in the textrun;
// therefore we only call it once, at the end of textrun construction,
// NOT incrementally as each glyph run is added (bug 680402).
void
gfxTextRun::SanitizeGlyphRuns()
{
if (mGlyphRuns.Length() <= 1)
return;
// If any glyph run starts with ligature-continuation characters, we need to advance it
// to the first "real" character to avoid drawing partial ligature glyphs from wrong font
// (seen with U+FEFF in reftest 474417-1, as Core Text eliminates the glyph, which makes
// it appear as if a ligature has been formed)
int32_t i, lastRunIndex = mGlyphRuns.Length() - 1;
const CompressedGlyph *charGlyphs = mCharacterGlyphs;
for (i = lastRunIndex; i >= 0; --i) {
GlyphRun& run = mGlyphRuns[i];
while (charGlyphs[run.mCharacterOffset].IsLigatureContinuation() &&
run.mCharacterOffset < mCharacterCount) {
run.mCharacterOffset++;
}
// if the run has become empty, eliminate it
if ((i < lastRunIndex &&
run.mCharacterOffset >= mGlyphRuns[i+1].mCharacterOffset) ||
(i == lastRunIndex && run.mCharacterOffset == mCharacterCount)) {
mGlyphRuns.RemoveElementAt(i);
--lastRunIndex;
}
}
}
uint32_t
gfxTextRun::CountMissingGlyphs()
{
uint32_t i;
uint32_t count = 0;
for (i = 0; i < mCharacterCount; ++i) {
if (mCharacterGlyphs[i].IsMissing()) {
++count;
}
}
return count;
}
gfxTextRun::DetailedGlyph *
gfxTextRun::AllocateDetailedGlyphs(uint32_t aIndex, uint32_t aCount)
{
NS_ASSERTION(aIndex < mCharacterCount, "Index out of range");
if (!mDetailedGlyphs) {
mDetailedGlyphs = new DetailedGlyphStore();
}
DetailedGlyph *details = mDetailedGlyphs->Allocate(aIndex, aCount);
if (!details) {
mCharacterGlyphs[aIndex].SetMissing(0);
return nullptr;
}
return details;
}
void
gfxTextRun::SetGlyphs(uint32_t aIndex, CompressedGlyph aGlyph,
const DetailedGlyph *aGlyphs)
{
NS_ASSERTION(!aGlyph.IsSimpleGlyph(), "Simple glyphs not handled here");
NS_ASSERTION(aIndex > 0 || aGlyph.IsLigatureGroupStart(),
"First character can't be a ligature continuation!");
uint32_t glyphCount = aGlyph.GetGlyphCount();
if (glyphCount > 0) {
DetailedGlyph *details = AllocateDetailedGlyphs(aIndex, glyphCount);
if (!details)
return;
memcpy(details, aGlyphs, sizeof(DetailedGlyph)*glyphCount);
}
mCharacterGlyphs[aIndex] = aGlyph;
}
void
gfxTextRun::SetMissingGlyph(uint32_t aIndex, uint32_t aChar)
{
uint8_t category = GetGeneralCategory(aChar);
if (category >= HB_UNICODE_GENERAL_CATEGORY_SPACING_MARK &&
category <= HB_UNICODE_GENERAL_CATEGORY_NON_SPACING_MARK)
{
mCharacterGlyphs[aIndex].SetComplex(false, true, 0);
}
DetailedGlyph *details = AllocateDetailedGlyphs(aIndex, 1);
if (!details)
return;
details->mGlyphID = aChar;
GlyphRun *glyphRun = &mGlyphRuns[FindFirstGlyphRunContaining(aIndex)];
if (IsDefaultIgnorable(aChar)) {
// Setting advance width to zero will prevent drawing the hexbox
details->mAdvance = 0;
} else {
gfxFloat width = NS_MAX(glyphRun->mFont->GetMetrics().aveCharWidth,
gfxFontMissingGlyphs::GetDesiredMinWidth(aChar));
details->mAdvance = uint32_t(width*GetAppUnitsPerDevUnit());
}
details->mXOffset = 0;
details->mYOffset = 0;
mCharacterGlyphs[aIndex].SetMissing(1);
}
void
gfxTextRun::CopyGlyphDataFrom(const gfxShapedWord *aShapedWord, uint32_t aOffset)
{
uint32_t wordLen = aShapedWord->Length();
NS_ASSERTION(aOffset + wordLen <= GetLength(),
"word overruns end of textrun!");
const CompressedGlyph *wordGlyphs = aShapedWord->GetCharacterGlyphs();
if (aShapedWord->HasDetailedGlyphs()) {
for (uint32_t i = 0; i < wordLen; ++i, ++aOffset) {
const CompressedGlyph& g = wordGlyphs[i];
if (g.IsSimpleGlyph()) {
SetSimpleGlyph(aOffset, g);
} else {
const DetailedGlyph *details =
g.GetGlyphCount() > 0 ?
aShapedWord->GetDetailedGlyphs(i) : nullptr;
SetGlyphs(aOffset, g, details);
}
}
} else {
memcpy(GetCharacterGlyphs() + aOffset, wordGlyphs,
wordLen * sizeof(CompressedGlyph));
}
}
void
gfxTextRun::CopyGlyphDataFrom(gfxTextRun *aSource, uint32_t aStart,
uint32_t aLength, uint32_t aDest)
{
NS_ASSERTION(aStart + aLength <= aSource->GetLength(),
"Source substring out of range");
NS_ASSERTION(aDest + aLength <= GetLength(),
"Destination substring out of range");
if (aSource->mSkipDrawing) {
mSkipDrawing = true;
}
// Copy base glyph data, and DetailedGlyph data where present
const CompressedGlyph *srcGlyphs = aSource->mCharacterGlyphs + aStart;
CompressedGlyph *dstGlyphs = mCharacterGlyphs + aDest;
for (uint32_t i = 0; i < aLength; ++i) {
CompressedGlyph g = srcGlyphs[i];
g.SetCanBreakBefore(!g.IsClusterStart() ?
CompressedGlyph::FLAG_BREAK_TYPE_NONE :
dstGlyphs[i].CanBreakBefore());
if (!g.IsSimpleGlyph()) {
uint32_t count = g.GetGlyphCount();
if (count > 0) {
DetailedGlyph *dst = AllocateDetailedGlyphs(i + aDest, count);
if (dst) {
DetailedGlyph *src = aSource->GetDetailedGlyphs(i + aStart);
if (src) {
::memcpy(dst, src, count * sizeof(DetailedGlyph));
} else {
g.SetMissing(0);
}
} else {
g.SetMissing(0);
}
}
}
dstGlyphs[i] = g;
}
// Copy glyph runs
GlyphRunIterator iter(aSource, aStart, aLength);
#ifdef DEBUG
gfxFont *lastFont = nullptr;
#endif
while (iter.NextRun()) {
gfxFont *font = iter.GetGlyphRun()->mFont;
NS_ASSERTION(font != lastFont, "Glyphruns not coalesced?");
#ifdef DEBUG
lastFont = font;
uint32_t end = iter.GetStringEnd();
#endif
uint32_t start = iter.GetStringStart();
// These used to be NS_ASSERTION()s, but WARNING is more appropriate.
// Although it's unusual (and not desirable), it's possible for us to assign
// different fonts to a base character and a following diacritic.
// Example on OSX 10.5/10.6 with default fonts installed:
// data:text/html,<p style="font-family:helvetica, arial, sans-serif;">
// &%23x043E;&%23x0486;&%23x20;&%23x043E;&%23x0486;
// This means the rendering of the cluster will probably not be very good,
// but it's the best we can do for now if the specified font only covered the
// initial base character and not its applied marks.
NS_WARN_IF_FALSE(aSource->IsClusterStart(start),
"Started font run in the middle of a cluster");
NS_WARN_IF_FALSE(end == aSource->GetLength() || aSource->IsClusterStart(end),
"Ended font run in the middle of a cluster");
nsresult rv = AddGlyphRun(font, iter.GetGlyphRun()->mMatchType,
start - aStart + aDest, false);
if (NS_FAILED(rv))
return;
}
}
void
gfxTextRun::SetSpaceGlyph(gfxFont *aFont, gfxContext *aContext,
uint32_t aCharIndex)
{
if (SetSpaceGlyphIfSimple(aFont, aContext, aCharIndex, ' ')) {
return;
}
aFont->InitWordCache();
static const uint8_t space = ' ';
gfxShapedWord *sw = aFont->GetShapedWord(aContext,
&space, 1,
HashMix(0, ' '),
MOZ_SCRIPT_LATIN,
mAppUnitsPerDevUnit,
gfxTextRunFactory::TEXT_IS_8BIT |
gfxTextRunFactory::TEXT_IS_ASCII |
gfxTextRunFactory::TEXT_IS_PERSISTENT);
if (sw) {
AddGlyphRun(aFont, gfxTextRange::kFontGroup, aCharIndex, false);
CopyGlyphDataFrom(sw, aCharIndex);
}
}
bool
gfxTextRun::SetSpaceGlyphIfSimple(gfxFont *aFont, gfxContext *aContext,
uint32_t aCharIndex, PRUnichar aSpaceChar)
{
uint32_t spaceGlyph = aFont->GetSpaceGlyph();
if (!spaceGlyph || !CompressedGlyph::IsSimpleGlyphID(spaceGlyph)) {
return false;
}
uint32_t spaceWidthAppUnits =
NS_lroundf(aFont->GetMetrics().spaceWidth * mAppUnitsPerDevUnit);
if (!CompressedGlyph::IsSimpleAdvance(spaceWidthAppUnits)) {
return false;
}
AddGlyphRun(aFont, gfxTextRange::kFontGroup, aCharIndex, false);
CompressedGlyph g;
g.SetSimpleGlyph(spaceWidthAppUnits, spaceGlyph);
if (aSpaceChar == ' ') {
g.SetIsSpace();
}
SetSimpleGlyph(aCharIndex, g);
return true;
}
void
gfxTextRun::FetchGlyphExtents(gfxContext *aRefContext)
{
bool needsGlyphExtents = NeedsGlyphExtents(this);
if (!needsGlyphExtents && !mDetailedGlyphs)
return;
uint32_t i, runCount = mGlyphRuns.Length();
CompressedGlyph *charGlyphs = mCharacterGlyphs;
for (i = 0; i < runCount; ++i) {
const GlyphRun& run = mGlyphRuns[i];
gfxFont *font = run.mFont;
uint32_t start = run.mCharacterOffset;
uint32_t end = i + 1 < runCount ?
mGlyphRuns[i + 1].mCharacterOffset : GetLength();
bool fontIsSetup = false;
uint32_t j;
gfxGlyphExtents *extents = font->GetOrCreateGlyphExtents(mAppUnitsPerDevUnit);
for (j = start; j < end; ++j) {
const gfxTextRun::CompressedGlyph *glyphData = &charGlyphs[j];
if (glyphData->IsSimpleGlyph()) {
// If we're in speed mode, don't set up glyph extents here; we'll
// just return "optimistic" glyph bounds later
if (needsGlyphExtents) {
uint32_t glyphIndex = glyphData->GetSimpleGlyph();
if (!extents->IsGlyphKnown(glyphIndex)) {
if (!fontIsSetup) {
if (!font->SetupCairoFont(aRefContext)) {
NS_WARNING("failed to set up font for glyph extents");
break;
}
fontIsSetup = true;
}
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
++gGlyphExtentsSetupEagerSimple;
#endif
font->SetupGlyphExtents(aRefContext, glyphIndex, false, extents);
}
}
} else if (!glyphData->IsMissing()) {
uint32_t glyphCount = glyphData->GetGlyphCount();
if (glyphCount == 0) {
continue;
}
const gfxTextRun::DetailedGlyph *details = GetDetailedGlyphs(j);
if (!details) {
continue;
}
for (uint32_t k = 0; k < glyphCount; ++k, ++details) {
uint32_t glyphIndex = details->mGlyphID;
if (!extents->IsGlyphKnownWithTightExtents(glyphIndex)) {
if (!fontIsSetup) {
if (!font->SetupCairoFont(aRefContext)) {
NS_WARNING("failed to set up font for glyph extents");
break;
}
fontIsSetup = true;
}
#ifdef DEBUG_TEXT_RUN_STORAGE_METRICS
++gGlyphExtentsSetupEagerTight;
#endif
font->SetupGlyphExtents(aRefContext, glyphIndex, true, extents);
}
}
}
}
}
}
gfxTextRun::ClusterIterator::ClusterIterator(gfxTextRun *aTextRun)
: mTextRun(aTextRun), mCurrentChar(uint32_t(-1))
{
}
void
gfxTextRun::ClusterIterator::Reset()
{
mCurrentChar = uint32_t(-1);
}
bool
gfxTextRun::ClusterIterator::NextCluster()
{
uint32_t len = mTextRun->GetLength();
while (++mCurrentChar < len) {
if (mTextRun->IsClusterStart(mCurrentChar)) {
return true;
}
}
mCurrentChar = uint32_t(-1);
return false;
}
uint32_t
gfxTextRun::ClusterIterator::ClusterLength() const
{
if (mCurrentChar == uint32_t(-1)) {
return 0;
}
uint32_t i = mCurrentChar,
len = mTextRun->GetLength();
while (++i < len) {
if (mTextRun->IsClusterStart(i)) {
break;
}
}
return i - mCurrentChar;
}
gfxFloat
gfxTextRun::ClusterIterator::ClusterAdvance(PropertyProvider *aProvider) const
{
if (mCurrentChar == uint32_t(-1)) {
return 0;
}
return mTextRun->GetAdvanceWidth(mCurrentChar, ClusterLength(), aProvider);
}
size_t
gfxTextRun::SizeOfExcludingThis(nsMallocSizeOfFun aMallocSizeOf)
{
// The second arg is how much gfxTextRun::AllocateStorage would have
// allocated.
size_t total = mGlyphRuns.SizeOfExcludingThis(aMallocSizeOf);
if (mDetailedGlyphs) {
total += mDetailedGlyphs->SizeOfIncludingThis(aMallocSizeOf);
}
return total;
}
size_t
gfxTextRun::SizeOfIncludingThis(nsMallocSizeOfFun aMallocSizeOf)
{
return aMallocSizeOf(this) + SizeOfExcludingThis(aMallocSizeOf);
}
#ifdef DEBUG
void
gfxTextRun::Dump(FILE* aOutput) {
if (!aOutput) {
aOutput = stdout;
}
uint32_t i;
fputc('[', aOutput);
for (i = 0; i < mGlyphRuns.Length(); ++i) {
if (i > 0) {
fputc(',', aOutput);
}
gfxFont* font = mGlyphRuns[i].mFont;
const gfxFontStyle* style = font->GetStyle();
NS_ConvertUTF16toUTF8 fontName(font->GetName());
nsCAutoString lang;
style->language->ToUTF8String(lang);
fprintf(aOutput, "%d: %s %f/%d/%d/%s", mGlyphRuns[i].mCharacterOffset,
fontName.get(), style->size,
style->weight, style->style, lang.get());
}
fputc(']', aOutput);
}
#endif