/*
* @(#)KernTable.cpp 1.1 04/10/13
*
* (C) Copyright IBM Corp. 2004-2007 - All Rights Reserved
*
*/
#include "KernTable.h"
#include "LEFontInstance.h"
#include "LEGlyphStorage.h"
#include "LESwaps.h"
#include "OpenTypeUtilities.h"
#include <stdio.h>
#define DEBUG 0
U_NAMESPACE_BEGIN
struct PairInfo {
le_uint16 left; // left glyph of kern pair
le_uint16 right; // right glyph of kern pair
le_int16 value; // fword, kern value in funits
};
#define KERN_PAIRINFO_SIZE 6
#define SWAP_KEY(p) (((le_uint32) SWAPW((p)->left) << 16) | SWAPW((p)->right))
struct Subtable_0 {
le_uint16 nPairs;
le_uint16 searchRange;
le_uint16 entrySelector;
le_uint16 rangeShift;
};
#define KERN_SUBTABLE_0_HEADER_SIZE 8
// Kern table version 0 only
struct SubtableHeader {
le_uint16 version;
le_uint16 length;
le_uint16 coverage;
};
#define KERN_SUBTABLE_HEADER_SIZE 6
// Version 0 only, version 1 has different layout
struct KernTableHeader {
le_uint16 version;
le_uint16 nTables;
};
#define KERN_TABLE_HEADER_SIZE 4
#define COVERAGE_HORIZONTAL 0x1
#define COVERAGE_MINIMUM 0x2
#define COVERAGE_CROSS 0x4
#define COVERAGE_OVERRIDE 0x8
/*
* This implementation has support for only one subtable, so if the font has
* multiple subtables, only the first will be used. If this turns out to
* be a problem in practice we should add it.
*
* This also supports only version 0 of the kern table header, only
* Apple supports the latter.
*
* This implementation isn't careful about the kern table flags, and
* might invoke kerning when it is not supposed to. That too I'm
* leaving for a bug fix.
*
* TODO: support multiple subtables
* TODO: respect header flags
*/
KernTable::KernTable(const LEFontInstance* font, const void* tableData)
: pairs(0), font(font)
{
const KernTableHeader* header = (const KernTableHeader*)tableData;
if (header == 0) {
#if DEBUG
fprintf(stderr, "no kern data\n");
#endif
return;
}
#if DEBUG
// dump first 32 bytes of header
for (int i = 0; i < 64; ++i) {
fprintf(stderr, "%0.2x ", ((const char*)tableData)[i]&0xff);
if (((i+1)&0xf) == 0) {
fprintf(stderr, "\n");
} else if (((i+1)&0x7) == 0) {
fprintf(stderr, " ");
}
}
#endif
if (header->version == 0 && SWAPW(header->nTables) > 0) {
const SubtableHeader* subhead = (const SubtableHeader*)((char*)tableData + KERN_TABLE_HEADER_SIZE);
if (subhead->version == 0) {
coverage = SWAPW(subhead->coverage);
if (coverage & COVERAGE_HORIZONTAL) { // only handle horizontal kerning
const Subtable_0* table = (const Subtable_0*)((char*)subhead + KERN_SUBTABLE_HEADER_SIZE);
nPairs = SWAPW(table->nPairs);
#if 0 // some old fonts have bad values here...
searchRange = SWAPW(table->searchRange);
entrySelector = SWAPW(table->entrySelector);
rangeShift = SWAPW(table->rangeShift);
#else
entrySelector = OpenTypeUtilities::highBit(nPairs);
searchRange = (1 << entrySelector) * KERN_PAIRINFO_SIZE;
rangeShift = (nPairs * KERN_PAIRINFO_SIZE) - searchRange;
#endif
pairs = (const PairInfo*)((char*)table + KERN_SUBTABLE_0_HEADER_SIZE);
#if DEBUG
fprintf(stderr, "coverage: %0.4x nPairs: %d pairs 0x%x\n", coverage, nPairs, pairs);
fprintf(stderr, " searchRange: %d entrySelector: %d rangeShift: %d\n", searchRange, entrySelector, rangeShift);
{
// dump part of the pair list
char ids[256];
for (int i = 256; --i >= 0;) {
LEGlyphID id = font->mapCharToGlyph(i);
if (id < 256) {
ids[id] = (char)i;
}
}
const PairInfo* p = pairs;
for (i = 0; i < nPairs; ++i, p = (const PairInfo*)((char*)p+KERN_PAIRINFO_SIZE)) {
le_uint16 left = p->left;
le_uint16 right = p->right;
if (left < 256 && right < 256) {
char c = ids[left];
if (c > 0x20 && c < 0x7f) {
fprintf(stderr, "%c/", c & 0xff);
} else {
printf(stderr, "%0.2x/", c & 0xff);
}
c = ids[right];
if (c > 0x20 && c < 0x7f) {
fprintf(stderr, "%c ", c & 0xff);
} else {
fprintf(stderr, "%0.2x ", c & 0xff);
}
}
}
}
#endif
}
}
}
}
/*
* Process the glyph positions. The positions array has two floats for each
* glyph, plus a trailing pair to mark the end of the last glyph.
*/
void KernTable::process(LEGlyphStorage& storage)
{
if (pairs) {
LEErrorCode success = LE_NO_ERROR;
le_uint32 key = storage[0]; // no need to mask off high bits
float adjust = 0;
for (int i = 1, e = storage.getGlyphCount(); i < e; ++i) {
key = key << 16 | (storage[i] & 0xffff);
// argh, to do a binary search, we need to have the pair list in sorted order
// but it is not in sorted order on win32 platforms because of the endianness difference
// so either I have to swap the element each time I examine it, or I have to swap
// all the elements ahead of time and store them in the font
const PairInfo* p = pairs;
const PairInfo* tp = (const PairInfo*)((char*)p + rangeShift);
if (key > SWAP_KEY(tp)) {
p = tp;
}
#if DEBUG
fprintf(stderr, "binary search for %0.8x\n", key);
#endif
le_uint32 probe = searchRange;
while (probe > KERN_PAIRINFO_SIZE) {
probe >>= 1;
tp = (const PairInfo*)((char*)p + probe);
le_uint32 tkey = SWAP_KEY(tp);
#if DEBUG
fprintf(stdout, " %.3d (%0.8x)\n", ((char*)tp - (char*)pairs)/KERN_PAIRINFO_SIZE, tkey);
#endif
if (tkey <= key) {
if (tkey == key) {
le_int16 value = SWAPW(tp->value);
#if DEBUG
fprintf(stdout, "binary found kerning pair %x:%x at %d, value: 0x%x (%g)\n",
storage[i-1], storage[i], i, value & 0xffff, font->xUnitsToPoints(value));
fflush(stdout);
#endif
adjust += font->xUnitsToPoints(value);
break;
}
p = tp;
}
}
storage.adjustPosition(i, adjust, 0, success);
}
storage.adjustPosition(storage.getGlyphCount(), adjust, 0, success);
}
}
U_NAMESPACE_END