/* ** v_font.cpp ** Font management ** **--------------------------------------------------------------------------- ** Copyright 1998-2016 Randy Heit ** Copyright 2005-2019 Christoph Oelckers ** All rights reserved. ** ** Redistribution and use in source and binary forms, with or without ** modification, are permitted provided that the following conditions ** are met: ** ** 1. Redistributions of source code must retain the above copyright ** notice, this list of conditions and the following disclaimer. ** 2. Redistributions in binary form must reproduce the above copyright ** notice, this list of conditions and the following disclaimer in the ** documentation and/or other materials provided with the distribution. ** 3. The name of the author may not be used to endorse or promote products ** derived from this software without specific prior written permission. ** ** THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR ** IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES ** OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. ** IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, ** INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT ** NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, ** DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY ** THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ** (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF ** THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. **--------------------------------------------------------------------------- ** */ // HEADER FILES ------------------------------------------------------------ #include #include #include #include #include #include "templates.h" #include "m_swap.h" #include "v_font.h" #include "cmdlib.h" #include "sc_man.h" #include "v_text.h" #include "image.h" #include "utf8.h" #include "myiswalpha.h" #include "fontchars.h" #include "imagehelpers.h" #include "glbackend/glbackend.h" #include "palettecontainer.h" #include "textures.h" #include "fontinternals.h" //========================================================================== // // FFont :: ~FFont // //========================================================================== FFont::~FFont () { FFont **prev = &FirstFont; FFont *font = *prev; while (font != nullptr && font != this) { prev = &font->Next; font = *prev; } if (font != nullptr) { *prev = font->Next; } } //========================================================================== // // FFont :: CheckCase // //========================================================================== void FFont::CheckCase() { int lowercount = 0, uppercount = 0; for (unsigned i = 0; i < Chars.Size(); i++) { unsigned chr = i + FirstChar; if (lowerforupper[chr] == chr && upperforlower[chr] == chr) { continue; // not a letter; } if (myislower(chr)) { if (Chars[i].TranslatedPic != nullptr) lowercount++; } else { if (Chars[i].TranslatedPic != nullptr) uppercount++; } } if (lowercount == 0) return; // This is an uppercase-only font and we are done. // The ß needs special treatment because it is far more likely to be supplied lowercase only, even in an uppercase font. if (Chars[0xdf - FirstChar].TranslatedPic != nullptr) { if (LastChar < 0x1e9e) { Chars.Resize(0x1e9f - FirstChar); LastChar = 0x1e9e; } if (Chars[0x1e9e - FirstChar].TranslatedPic == nullptr) { std::swap(Chars[0xdf - FirstChar], Chars[0x1e9e - FirstChar]); lowercount--; uppercount++; if (lowercount == 0) return; } } } //========================================================================== // // FFont :: FindFont // // Searches for the named font in the list of loaded fonts, returning the // font if it was found. The disk is not checked if it cannot be found. // //========================================================================== FFont *FFont::FindFont (FName name) { if (name == NAME_None) { return nullptr; } FFont *font = FirstFont; while (font != nullptr) { if (font->FontName == name) return font; font = font->Next; } return nullptr; } //========================================================================== // // RecordTextureColors // // Given a 256 entry buffer, sets every entry that corresponds to a color // used by the texture to 1. // //========================================================================== void RecordTextureColors (FImageSource *pic, uint32_t *usedcolors) { int x; auto pixels = pic->GetPalettedPixels(false); auto size = pic->GetWidth() * pic->GetHeight(); for(x = 0;x < size; x++) { usedcolors[pixels[x]]++; } } //========================================================================== // // RecordAllTextureColors // // Given a 256 entry buffer, sets every entry that corresponds to a color // used by the font. // //========================================================================== void FFont::RecordAllTextureColors(uint32_t *usedcolors) { for (unsigned int i = 0; i < Chars.Size(); i++) { if (Chars[i].TranslatedPic) { FFontChar1 *pic = static_cast(Chars[i].TranslatedPic->GetImage()); if (pic) { // The remap must be temporarily reset here because this can be called on an initialized font. auto sr = pic->ResetSourceRemap(); RecordTextureColors(pic, usedcolors); pic->SetSourceRemap(sr); } } } } //========================================================================== // // SetDefaultTranslation // // Builds a translation to map the stock font to a mod provided replacement. // //========================================================================== void FFont::SetDefaultTranslation(uint32_t *othercolors) { uint32_t mycolors[256] = {}; RecordAllTextureColors(mycolors); uint8_t mytranslation[256], othertranslation[256], myreverse[256], otherreverse[256]; TArray myluminosity, otherluminosity; SimpleTranslation(mycolors, mytranslation, myreverse, myluminosity); SimpleTranslation(othercolors, othertranslation, otherreverse, otherluminosity); FRemapTable remap(ActiveColors); remap.Remap[0] = 0; remap.Palette[0] = 0; for (unsigned l = 1; l < myluminosity.Size(); l++) { for (unsigned o = 1; o < otherluminosity.Size()-1; o++) // luminosity[0] is for the transparent color { if (myluminosity[l] >= otherluminosity[o] && myluminosity[l] <= otherluminosity[o+1]) { PalEntry color1 = GPalette.BaseColors[otherreverse[o]]; PalEntry color2 = GPalette.BaseColors[otherreverse[o+1]]; double weight = 0; if (otherluminosity[o] != otherluminosity[o + 1]) { weight = (myluminosity[l] - otherluminosity[o]) / (otherluminosity[o + 1] - otherluminosity[o]); } int r = int(color1.r + weight * (color2.r - color1.r)); int g = int(color1.g + weight * (color2.g - color1.g)); int b = int(color1.b + weight * (color2.b - color1.b)); r = clamp(r, 0, 255); g = clamp(g, 0, 255); b = clamp(b, 0, 255); remap.Remap[l] = ColorMatcher.Pick(r, g, b); remap.Palette[l] = PalEntry(255, r, g, b); break; } } } Ranges[CR_UNTRANSLATED] = GLInterface.GetPaletteIndex(remap.Palette); forceremap = true; } //========================================================================== // // compare // // Used for sorting colors by brightness. // //========================================================================== static int compare (const void *arg1, const void *arg2) { if (RPART(GPalette.BaseColors[*((uint8_t *)arg1)]) * 299 + GPART(GPalette.BaseColors[*((uint8_t *)arg1)]) * 587 + BPART(GPalette.BaseColors[*((uint8_t *)arg1)]) * 114 < RPART(GPalette.BaseColors[*((uint8_t *)arg2)]) * 299 + GPART(GPalette.BaseColors[*((uint8_t *)arg2)]) * 587 + BPART(GPalette.BaseColors[*((uint8_t *)arg2)]) * 114) return -1; else return 1; } //========================================================================== // // FFont :: SimpleTranslation // // Colorsused, translation, and reverse must all be 256 entry buffers. // Colorsused must already be filled out. // Translation be set to remap the source colors to a new range of // consecutive colors based at 1 (0 is transparent). // Reverse will be just the opposite of translation: It maps the new color // range to the original colors. // *Luminosity will be an array just large enough to hold the brightness // levels of all the used colors, in consecutive order. It is sorted from // darkest to lightest and scaled such that the darkest color is 0.0 and // the brightest color is 1.0. // The return value is the number of used colors and thus the number of // entries in *luminosity. // //========================================================================== int FFont::SimpleTranslation (uint32_t *colorsused, uint8_t *translation, uint8_t *reverse, TArray &Luminosity) { double min, max, diver; int i, j; memset (translation, 0, 256); reverse[0] = 0; for (i = 1, j = 1; i < 256; i++) { if (colorsused[i]) { reverse[j++] = i; } } qsort (reverse+1, j-1, 1, compare); Luminosity.Resize(j); Luminosity[0] = 0.0; // [BL] Prevent uninitalized memory max = 0.0; min = 100000000.0; for (i = 1; i < j; i++) { translation[reverse[i]] = i; Luminosity[i] = RPART(GPalette.BaseColors[reverse[i]]) * 0.299 + GPART(GPalette.BaseColors[reverse[i]]) * 0.587 + BPART(GPalette.BaseColors[reverse[i]]) * 0.114; if (Luminosity[i] > max) max = Luminosity[i]; if (Luminosity[i] < min) min = Luminosity[i]; } diver = 1.0 / (max - min); for (i = 1; i < j; i++) { Luminosity[i] = (Luminosity[i] - min) * diver; } return j; } //========================================================================== // // FFont :: BuildTranslations // // Build color translations for this font. Luminosity is an array of // brightness levels. The ActiveColors member must be set to indicate how // large this array is. Identity is an array that remaps the colors to // their original values; it is only used for CR_UNTRANSLATED. Ranges // is an array of TranslationParm structs defining the ranges for every // possible color, in order. Palette is the colors to use for the // untranslated version of the font. // //========================================================================== void FFont::BuildTranslations (const double *luminosity, const uint8_t *identity, const void *ranges, int total_colors, const PalEntry *palette) { int i, j; const TranslationParm *parmstart = (const TranslationParm *)ranges; FRemapTable remap; // Create different translations for different color ranges Ranges.Clear(); for (i = 0; i < NumTextColors; i++) { if (i == CR_UNTRANSLATED) { if (identity != nullptr) { if (palette != nullptr) { memcpy (remap.Palette, palette, ActiveColors*sizeof(PalEntry)); } else { remap.Palette[0] = GPalette.BaseColors[identity[0]] & MAKEARGB(0,255,255,255); for (j = 1; j < ActiveColors; ++j) { remap.Palette[j] = GPalette.BaseColors[identity[j]] | MAKEARGB(255,0,0,0); } } } else { } Ranges.Push(GLInterface.GetPaletteIndex(remap.Palette)); continue; } assert(parmstart->RangeStart >= 0); remap.Palette[0] = 0; for (j = 1; j < ActiveColors; j++) { int v = int(luminosity[j] * 256.0); // Find the color range that this luminosity value lies within. const TranslationParm *parms = parmstart - 1; do { parms++; if (parms->RangeStart <= v && parms->RangeEnd >= v) break; } while (parms[1].RangeStart > parms[0].RangeEnd); // Linearly interpolate to find out which color this luminosity level gets. int rangev = ((v - parms->RangeStart) << 8) / (parms->RangeEnd - parms->RangeStart); int r = ((parms->Start[0] << 8) + rangev * (parms->End[0] - parms->Start[0])) >> 8; // red int g = ((parms->Start[1] << 8) + rangev * (parms->End[1] - parms->Start[1])) >> 8; // green int b = ((parms->Start[2] << 8) + rangev * (parms->End[2] - parms->Start[2])) >> 8; // blue r = clamp(r, 0, 255); g = clamp(g, 0, 255); b = clamp(b, 0, 255); remap.Palette[j] = PalEntry(255,r,g,b); } Ranges.Push(GLInterface.GetPaletteIndex(remap.Palette)); // Advance to the next color range. while (parmstart[1].RangeStart > parmstart[0].RangeEnd) { parmstart++; } parmstart++; } } //========================================================================== // // FFont :: GetColorTranslation // //========================================================================== int FFont::GetColorTranslation (EColorRange range, PalEntry *color) const { if (noTranslate) { PalEntry retcolor = PalEntry(255, 255, 255, 255); if (range >= 0 && range < NumTextColors && range != CR_UNTRANSLATED) { retcolor = TranslationColors[range]; retcolor.a = 255; } if (color != nullptr) *color = retcolor; } if (ActiveColors == 0) return -1; else if (range >= NumTextColors) range = CR_UNTRANSLATED; //if (range == CR_UNTRANSLATED && !translateUntranslated) return nullptr; return Ranges[range]; } //========================================================================== // // FFont :: GetCharCode // // If the character code is in the font, returns it. If it is not, but it // is lowercase and has an uppercase variant present, return that. Otherwise // return -1. // //========================================================================== int FFont::GetCharCode(int code, bool needpic) const { if (code < 0 && code >= -128) { // regular chars turn negative when the 8th bit is set. code &= 255; } if (code >= FirstChar && code <= LastChar && (!needpic || Chars[code - FirstChar].TranslatedPic != nullptr)) { return code; } // Use different substitution logic based on the fonts content: // In a font which has both upper and lower case, prefer unaccented small characters over capital ones. // In a pure upper-case font, do not check for lower case replacements. if (!MixedCase) { // Try converting lowercase characters to uppercase. if (myislower(code)) { code = upperforlower[code]; if (code >= FirstChar && code <= LastChar && (!needpic || Chars[code - FirstChar].TranslatedPic != nullptr)) { return code; } } // Try stripping accents from accented characters. int newcode = stripaccent(code); if (newcode != code) { code = newcode; if (code >= FirstChar && code <= LastChar && (!needpic || Chars[code - FirstChar].TranslatedPic != nullptr)) { return code; } } } else { int originalcode = code; int newcode; // Try stripping accents from accented characters. This may repeat to allow multi-step fallbacks. while ((newcode = stripaccent(code)) != code) { code = newcode; if (code >= FirstChar && code <= LastChar && (!needpic || Chars[code - FirstChar].TranslatedPic != nullptr)) { return code; } } code = originalcode; if (myislower(code)) { int upper = upperforlower[code]; // Stripping accents did not help - now try uppercase for lowercase if (upper != code) return GetCharCode(upper, needpic); } // Same for the uppercase character. Since we restart at the accented version this must go through the entire thing again. while ((newcode = stripaccent(code)) != code) { code = newcode; if (code >= FirstChar && code <= LastChar && (!needpic || Chars[code - FirstChar].TranslatedPic != nullptr)) { return code; } } } return -1; } //========================================================================== // // FFont :: GetChar // //========================================================================== FTexture *FFont::GetChar (int code, int translation, int *const width, bool *redirected) const { code = GetCharCode(code, true); int xmove = SpaceWidth; if (code >= 0) { code -= FirstChar; xmove = Chars[code].XMove; } if (width != nullptr) { *width = xmove; } if (code < 0) return nullptr; if (translation == CR_UNTRANSLATED && !forceremap) { bool redirect = Chars[code].OriginalPic && Chars[code].OriginalPic != Chars[code].TranslatedPic; if (redirected) *redirected = redirect; if (redirect) { assert(Chars[code].OriginalPic->GetUseType() == ETextureType::FontChar); return Chars[code].OriginalPic; } } if (redirected) *redirected = false; assert(Chars[code].TranslatedPic->GetUseType() == ETextureType::FontChar); return Chars[code].TranslatedPic; } //========================================================================== // // FFont :: CharWidth // //========================================================================== int FFont::CharWidth (int code) const { code = GetCharCode(code, true); if (code >= 0) return Chars[code - FirstChar].XMove; return SpaceWidth; } //========================================================================== // // // //========================================================================== double GetBottomAlignOffset(FFont *font, int c) { int w; FTexture *tex_zero = font->GetChar('0', CR_UNDEFINED, &w); FTexture *texc = font->GetChar(c, CR_UNDEFINED, &w); double offset = 0; if (texc) offset += texc->GetDisplayTopOffsetDouble(); if (tex_zero) offset += -tex_zero->GetDisplayTopOffsetDouble() + tex_zero->GetDisplayHeightDouble(); return offset; } //========================================================================== // // Checks if the font contains proper glyphs for all characters in the string // //========================================================================== bool FFont::CanPrint(const uint8_t *string) const { if (!string) return true; while (*string) { auto chr = GetCharFromString(string); if (!MixedCase) chr = upperforlower[chr]; // For uppercase-only fonts we shouldn't check lowercase characters. if (chr == TEXTCOLOR_ESCAPE) { // We do not need to check for UTF-8 in here. if (*string == '[') { while (*string != '\0' && *string != ']') { ++string; } } if (*string != '\0') { ++string; } continue; } else if (chr != '\n') { int cc = GetCharCode(chr, true); if (chr != cc && myiswalpha(chr))// && cc != getAlternative(chr)) { return false; } } } return true; } //========================================================================== // // Find string width using this font // //========================================================================== int FFont::StringWidth(const uint8_t *string) const { int w = 0; int maxw = 0; while (*string) { auto chr = GetCharFromString(string); if (chr == TEXTCOLOR_ESCAPE) { // We do not need to check for UTF-8 in here. if (*string == '[') { while (*string != '\0' && *string != ']') { ++string; } } if (*string != '\0') { ++string; } continue; } else if (chr == '\n') { if (w > maxw) maxw = w; w = 0; } else { w += CharWidth(chr) + GlobalKerning; } } return std::max(maxw, w); } //========================================================================== // // Get the largest ascender in the first line of this text. // //========================================================================== int FFont::GetMaxAscender(const uint8_t* string) const { int retval = 0; while (*string) { auto chr = GetCharFromString(string); if (chr == TEXTCOLOR_ESCAPE) { // We do not need to check for UTF-8 in here. if (*string == '[') { while (*string != '\0' && *string != ']') { ++string; } } if (*string != '\0') { ++string; } continue; } else if (chr == '\n') { break; } else { auto ctex = GetChar(chr, CR_UNTRANSLATED, nullptr); if (ctex) { auto offs = int(ctex->GetDisplayTopOffset()); if (offs > retval) retval = offs; } } } return retval; } //========================================================================== // // FFont :: LoadTranslations // //========================================================================== void FFont::LoadTranslations() { unsigned int count = LastChar - FirstChar + 1; uint32_t usedcolors[256] = {}; uint8_t identity[256]; TArray Luminosity; for (unsigned int i = 0; i < count; i++) { if (Chars[i].TranslatedPic) { FFontChar1 *pic = static_cast(Chars[i].TranslatedPic->GetImage()); if (pic) { pic->SetSourceRemap(nullptr); // Force the FFontChar1 to return the same pixels as the base texture RecordTextureColors(pic, usedcolors); } } } ActiveColors = SimpleTranslation (usedcolors, PatchRemap, identity, Luminosity); for (unsigned int i = 0; i < count; i++) { if(Chars[i].TranslatedPic) static_cast(Chars[i].TranslatedPic->GetImage())->SetSourceRemap(PatchRemap); } BuildTranslations (Luminosity.Data(), identity, &TranslationParms[TranslationType][0], ActiveColors, nullptr); } //========================================================================== // // FFont :: FFont - default constructor // //========================================================================== FFont::FFont () { FontName = NAME_None; Cursor = '_'; noTranslate = false; uint8_t pp = 0; for (auto &p : PatchRemap) p = pp++; } //========================================================================== // // FFont :: FixXMoves // // If a font has gaps in its characters, set the missing characters' // XMoves to either SpaceWidth or the unaccented or uppercase variant's // XMove. Missing XMoves must be initialized with INT_MIN beforehand. // //========================================================================== void FFont::FixXMoves() { for (int i = 0; i <= LastChar - FirstChar; ++i) { if (Chars[i].XMove == INT_MIN) { // Try an uppercase character. if (myislower(i + FirstChar)) { int upper = upperforlower[FirstChar + i]; if (upper >= FirstChar && upper <= LastChar ) { Chars[i].XMove = Chars[upper - FirstChar].XMove; continue; } } // Try an unnaccented character. int noaccent = stripaccent(i + FirstChar); if (noaccent != i + FirstChar) { noaccent -= FirstChar; if (noaccent >= 0) { Chars[i].XMove = Chars[noaccent].XMove; continue; } } Chars[i].XMove = SpaceWidth; } if (Chars[i].OriginalPic) { int ofs = Chars[i].OriginalPic->GetDisplayTopOffset(); if (ofs > Displacement) Displacement = ofs; } } }