/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* 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/. */ #include "mozilla/ArrayUtils.h" // for ArrayLength #include "mozilla/mozalloc.h" // for operator delete, etc #include "nsColor.h" #include // for int32_t #include "nsColorNames.h" // for nsColorNames #include "nsDebug.h" // for NS_ASSERTION, etc #include "nsStaticNameTable.h" #include "nsString.h" // for nsAutoCString, nsString, etc #include "nscore.h" // for nsAString, etc using namespace mozilla; // define an array of all color names #define GFX_COLOR(_name, _value) #_name, static const char* const kColorNames[] = { #include "nsColorNameList.h" }; #undef GFX_COLOR // define an array of all color name values #define GFX_COLOR(_name, _value) _value, static const nscolor kColors[] = { #include "nsColorNameList.h" }; #undef GFX_COLOR #define eColorName_COUNT (ArrayLength(kColorNames)) #define eColorName_UNKNOWN (-1) static nsStaticCaseInsensitiveNameTable* gColorTable = nullptr; void nsColorNames::AddRefTable(void) { NS_ASSERTION(!gColorTable, "pre existing array!"); if (!gColorTable) { gColorTable = new nsStaticCaseInsensitiveNameTable(); if (gColorTable) { #ifdef DEBUG { // let's verify the table... for (uint32_t index = 0; index < eColorName_COUNT; ++index) { nsAutoCString temp1(kColorNames[index]); nsAutoCString temp2(kColorNames[index]); ToLowerCase(temp1); NS_ASSERTION(temp1.Equals(temp2), "upper case char in table"); } } #endif gColorTable->Init(kColorNames, eColorName_COUNT); } } } void nsColorNames::ReleaseTable(void) { if (gColorTable) { delete gColorTable; gColorTable = nullptr; } } static int ComponentValue(const char16_t* aColorSpec, int aLen, int color, int dpc) { int component = 0; int index = (color * dpc); if (2 < dpc) { dpc = 2; } while (--dpc >= 0) { char16_t ch = ((index < aLen) ? aColorSpec[index++] : '0'); if (('0' <= ch) && (ch <= '9')) { component = (component * 16) + (ch - '0'); } else if ((('a' <= ch) && (ch <= 'f')) || (('A' <= ch) && (ch <= 'F'))) { // "ch&7" handles lower and uppercase hex alphabetics component = (component * 16) + (ch & 7) + 9; } else { // not a hex digit, treat it like 0 component = (component * 16); } } return component; } NS_GFX_(bool) NS_HexToRGB(const nsAString& aColorSpec, nscolor* aResult) { const char16_t* buffer = aColorSpec.BeginReading(); int nameLen = aColorSpec.Length(); if ((nameLen == 3) || (nameLen == 6)) { // Make sure the digits are legal for (int i = 0; i < nameLen; i++) { char16_t ch = buffer[i]; if (((ch >= '0') && (ch <= '9')) || ((ch >= 'a') && (ch <= 'f')) || ((ch >= 'A') && (ch <= 'F'))) { // Legal character continue; } // Whoops. Illegal character. return false; } // Convert the ascii to binary int dpc = ((3 == nameLen) ? 1 : 2); // Translate components from hex to binary int r = ComponentValue(buffer, nameLen, 0, dpc); int g = ComponentValue(buffer, nameLen, 1, dpc); int b = ComponentValue(buffer, nameLen, 2, dpc); if (dpc == 1) { // Scale single digit component to an 8 bit value. Replicate the // single digit to compute the new value. r = (r << 4) | r; g = (g << 4) | g; b = (b << 4) | b; } NS_ASSERTION((r >= 0) && (r <= 255), "bad r"); NS_ASSERTION((g >= 0) && (g <= 255), "bad g"); NS_ASSERTION((b >= 0) && (b <= 255), "bad b"); *aResult = NS_RGB(r, g, b); return true; } // Improperly formatted color value return false; } // This implements part of the algorithm for legacy behavior described in // http://www.whatwg.org/specs/web-apps/current-work/complete/common-microsyntaxes.html#rules-for-parsing-a-legacy-color-value NS_GFX_(bool) NS_LooseHexToRGB(const nsString& aColorSpec, nscolor* aResult) { if (aColorSpec.EqualsLiteral("transparent")) { return false; } int nameLen = aColorSpec.Length(); const char16_t* colorSpec = aColorSpec.get(); if (nameLen > 128) { nameLen = 128; } if ('#' == colorSpec[0]) { ++colorSpec; --nameLen; } // digits per component int dpc = (nameLen + 2) / 3; int newdpc = dpc; // Use only the rightmost 8 characters of each component. if (newdpc > 8) { nameLen -= newdpc - 8; colorSpec += newdpc - 8; newdpc = 8; } // And then keep trimming characters at the left until we'd trim one // that would leave a nonzero value, but not past 2 characters per // component. while (newdpc > 2) { bool haveNonzero = false; for (int c = 0; c < 3; ++c) { NS_ABORT_IF_FALSE(c * dpc < nameLen, "should not pass end of string while newdpc > 2"); char16_t ch = colorSpec[c * dpc]; if (('1' <= ch && ch <= '9') || ('A' <= ch && ch <= 'F') || ('a' <= ch && ch <= 'f')) { haveNonzero = true; break; } } if (haveNonzero) { break; } --newdpc; --nameLen; ++colorSpec; } // Translate components from hex to binary int r = ComponentValue(colorSpec, nameLen, 0, dpc); int g = ComponentValue(colorSpec, nameLen, 1, dpc); int b = ComponentValue(colorSpec, nameLen, 2, dpc); NS_ASSERTION((r >= 0) && (r <= 255), "bad r"); NS_ASSERTION((g >= 0) && (g <= 255), "bad g"); NS_ASSERTION((b >= 0) && (b <= 255), "bad b"); *aResult = NS_RGB(r, g, b); return true; } NS_GFX_(bool) NS_ColorNameToRGB(const nsAString& aColorName, nscolor* aResult) { if (!gColorTable) return false; int32_t id = gColorTable->Lookup(aColorName); if (eColorName_UNKNOWN < id) { NS_ASSERTION(uint32_t(id) < eColorName_COUNT, "gColorTable->Lookup messed up"); if (aResult) { *aResult = kColors[id]; } return true; } return false; } // Returns kColorNames, an array of all possible color names, and sets // *aSizeArray to the size of that array. Do NOT call free() on this array. NS_GFX_(const char * const *) NS_AllColorNames(size_t *aSizeArray) { *aSizeArray = ArrayLength(kColorNames); return kColorNames; } // Macro to blend two colors // // equivalent to target = (bg*(255-fgalpha) + fg*fgalpha)/255 #define MOZ_BLEND(target, bg, fg, fgalpha) \ FAST_DIVIDE_BY_255(target, (bg)*(255-fgalpha) + (fg)*(fgalpha)) NS_GFX_(nscolor) NS_ComposeColors(nscolor aBG, nscolor aFG) { // This function uses colors that are non premultiplied alpha. int r, g, b, a; int bgAlpha = NS_GET_A(aBG); int fgAlpha = NS_GET_A(aFG); // Compute the final alpha of the blended color // a = fgAlpha + bgAlpha*(255 - fgAlpha)/255; FAST_DIVIDE_BY_255(a, bgAlpha*(255-fgAlpha)); a = fgAlpha + a; int blendAlpha; if (a == 0) { // In this case the blended color is totally trasparent, // we preserve the color information of the foreground color. blendAlpha = 255; } else { blendAlpha = (fgAlpha*255)/a; } MOZ_BLEND(r, NS_GET_R(aBG), NS_GET_R(aFG), blendAlpha); MOZ_BLEND(g, NS_GET_G(aBG), NS_GET_G(aFG), blendAlpha); MOZ_BLEND(b, NS_GET_B(aBG), NS_GET_B(aFG), blendAlpha); return NS_RGBA(r, g, b, a); } // Functions to convert from HSL color space to RGB color space. // This is the algorithm described in the CSS3 specification // helper static float HSL_HueToRGB(float m1, float m2, float h) { if (h < 0.0f) h += 1.0f; if (h > 1.0f) h -= 1.0f; if (h < (float)(1.0/6.0)) return m1 + (m2 - m1)*h*6.0f; if (h < (float)(1.0/2.0)) return m2; if (h < (float)(2.0/3.0)) return m1 + (m2 - m1)*((float)(2.0/3.0) - h)*6.0f; return m1; } // The float parameters are all expected to be in the range 0-1 NS_GFX_(nscolor) NS_HSL2RGB(float h, float s, float l) { uint8_t r, g, b; float m1, m2; if (l <= 0.5f) { m2 = l*(s+1); } else { m2 = l + s - l*s; } m1 = l*2 - m2; r = uint8_t(255 * HSL_HueToRGB(m1, m2, h + 1.0f/3.0f)); g = uint8_t(255 * HSL_HueToRGB(m1, m2, h)); b = uint8_t(255 * HSL_HueToRGB(m1, m2, h - 1.0f/3.0f)); return NS_RGB(r, g, b); } NS_GFX_(const char*) NS_RGBToColorName(nscolor aColor) { for (size_t idx = 0; idx < ArrayLength(kColors); ++idx) { if (kColors[idx] == aColor) { return kColorNames[idx]; } } return nullptr; }