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216 lines
7.3 KiB
216 lines
7.3 KiB
#include "utils/palette_kd_tree.hpp" |
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#include <array> |
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#include <cstddef> |
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#include <cstdint> |
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#include <span> |
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#include <string> |
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#include <utility> |
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#ifdef USE_SDL3 |
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#include <SDL3/SDL_pixels.h> |
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#elif defined(USE_SDL1) |
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#include <SDL_video.h> |
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#else |
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#include <SDL_pixels.h> |
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#endif |
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#include "utils/static_vector.hpp" |
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#include "utils/str_cat.hpp" |
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#if DEVILUTIONX_PRINT_PALETTE_BLENDING_TREE_GRAPHVIZ |
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#include <cstdio> |
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#endif |
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namespace devilution { |
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namespace { |
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template <size_t N> |
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uint8_t GetColorComponent(const SDL_Color &); |
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template <> |
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inline uint8_t GetColorComponent<0>(const SDL_Color &c) { return c.r; } |
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template <> |
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inline uint8_t GetColorComponent<1>(const SDL_Color &c) { return c.g; } |
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template <> |
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inline uint8_t GetColorComponent<2>(const SDL_Color &c) { return c.b; } |
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template <size_t RemainingDepth> |
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[[nodiscard]] PaletteKdTreeNode<0> &LeafByIndex(PaletteKdTreeNode<RemainingDepth> &node, uint8_t index) |
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{ |
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if constexpr (RemainingDepth == 1) { |
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return node.child(index % 2 == 0); |
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} else { |
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return LeafByIndex(node.child(index % 2 == 0), index / 2); |
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} |
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} |
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template <size_t RemainingDepth> |
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[[nodiscard]] uint8_t LeafIndexForColor(const PaletteKdTreeNode<RemainingDepth> &node, const SDL_Color &color, uint8_t result = 0) |
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{ |
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const bool isLeft = GetColorComponent<PaletteKdTreeNode<RemainingDepth>::Coord>(color) < node.pivot; |
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if constexpr (RemainingDepth == 1) { |
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return (2 * result) + (isLeft ? 0 : 1); |
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} else { |
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return (2 * LeafIndexForColor(node.child(isLeft), color, result)) + (isLeft ? 0 : 1); |
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} |
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} |
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struct MedianInfo { |
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std::array<uint16_t, 256> counts = {}; |
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uint16_t numValues = 0; |
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}; |
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[[nodiscard]] static uint8_t GetMedian(const MedianInfo &medianInfo) |
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{ |
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const std::span<const uint16_t, 256> counts = medianInfo.counts; |
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const uint_fast16_t numValues = medianInfo.numValues; |
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const auto medianTarget = static_cast<uint_fast16_t>((medianInfo.numValues + 1) / 2); |
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uint_fast16_t partialSum = 0; |
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uint_fast16_t i = 0; |
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for (; partialSum < medianTarget && partialSum != numValues; ++i) { |
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partialSum += counts[i]; |
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} |
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// Special cases: |
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// 1. If the elements are empty, this will return 0. |
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// 2. If all the elements are the same, this will be `value + 1` (rolling over to 0 if value is 256). |
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// This means all the elements will be on one side of the pivot (left unless the value is 255). |
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return static_cast<uint8_t>(i); |
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} |
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template <size_t RemainingDepth, size_t N> |
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void MaybeAddToSubdivisionForMedian( |
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const PaletteKdTreeNode<RemainingDepth> &node, |
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const SDL_Color palette[256], unsigned paletteIndex, |
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std::span<MedianInfo, N> medianInfos) |
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{ |
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const uint8_t color = GetColorComponent<PaletteKdTreeNode<RemainingDepth>::Coord>(palette[paletteIndex]); |
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if constexpr (N == 1) { |
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MedianInfo &medianInfo = medianInfos[0]; |
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++medianInfo.counts[color]; |
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++medianInfo.numValues; |
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} else { |
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const bool isLeft = color < node.pivot; |
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MaybeAddToSubdivisionForMedian(node.child(isLeft), |
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palette, |
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paletteIndex, |
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isLeft |
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? medianInfos.template subspan<0, N / 2>() |
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: medianInfos.template subspan<N / 2, N / 2>()); |
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} |
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} |
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template <size_t RemainingDepth, size_t N> |
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void SetPivotsRecursively( |
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PaletteKdTreeNode<RemainingDepth> &node, |
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std::span<MedianInfo, N> medianInfos) |
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{ |
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if constexpr (N == 1) { |
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node.pivot = GetMedian(medianInfos[0]); |
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} else { |
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SetPivotsRecursively(node.left, medianInfos.template subspan<0, N / 2>()); |
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SetPivotsRecursively(node.right, medianInfos.template subspan<N / 2, N / 2>()); |
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} |
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} |
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template <size_t TargetDepth> |
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void PopulatePivotsForTargetDepth(PaletteKdTreeNode<PaletteKdTreeDepth> &root, |
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const SDL_Color palette[256], int skipFrom, int skipTo) |
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{ |
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constexpr size_t NumSubdivisions = 1U << TargetDepth; |
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std::array<MedianInfo, NumSubdivisions> subdivisions = {}; |
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const std::span<MedianInfo, NumSubdivisions> subdivisionsSpan { subdivisions }; |
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for (int i = 0; i < 256; ++i) { |
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if (i >= skipFrom && i <= skipTo) continue; |
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MaybeAddToSubdivisionForMedian(root, palette, i, subdivisionsSpan); |
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} |
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SetPivotsRecursively(root, subdivisionsSpan); |
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} |
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template <size_t... TargetDepths> |
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void PopulatePivotsImpl(PaletteKdTreeNode<PaletteKdTreeDepth> &root, |
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const SDL_Color palette[256], int skipFrom, int skipTo, std::index_sequence<TargetDepths...> intSeq) // NOLINT(misc-unused-parameters) |
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{ |
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(PopulatePivotsForTargetDepth<TargetDepths>(root, palette, skipFrom, skipTo), ...); |
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} |
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void PopulatePivots(PaletteKdTreeNode<PaletteKdTreeDepth> &root, |
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const SDL_Color palette[256], int skipFrom, int skipTo) |
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{ |
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PopulatePivotsImpl(root, palette, skipFrom, skipTo, std::make_index_sequence<PaletteKdTreeDepth> {}); |
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} |
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} // namespace |
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PaletteKdTree::PaletteKdTree(const SDL_Color palette[256], int skipFrom, int skipTo) |
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{ |
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PopulatePivots(tree_, palette, skipFrom, skipTo); |
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StaticVector<uint8_t, 256> leafValues[NumLeaves]; |
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for (int i = 0; i < 256; ++i) { |
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if (i >= skipFrom && i <= skipTo) continue; |
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leafValues[LeafIndexForColor(tree_, palette[i])].emplace_back(i); |
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} |
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size_t totalLen = 0; |
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for (uint8_t leafIndex = 0; leafIndex < NumLeaves; ++leafIndex) { |
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PaletteKdTreeNode<0> &leaf = LeafByIndex(tree_, leafIndex); |
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const std::span<const uint8_t> values = leafValues[leafIndex]; |
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if (values.empty()) { |
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leaf.valuesBegin = 1; |
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leaf.valuesEndInclusive = 0; |
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} else { |
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leaf.valuesBegin = static_cast<uint8_t>(totalLen); |
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leaf.valuesEndInclusive = static_cast<uint8_t>(totalLen - 1 + values.size()); |
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for (size_t i = 0; i < values.size(); ++i) { |
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const uint8_t value = values[i]; |
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values_[totalLen + i] = std::make_pair(RGB { palette[value].r, palette[value].g, palette[value].b }, value); |
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} |
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totalLen += values.size(); |
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} |
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} |
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#if DEVILUTIONX_PRINT_PALETTE_BLENDING_TREE_GRAPHVIZ |
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// To generate palette.dot.svg, run: |
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// dot -O -Tsvg palette.dot |
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FILE *out = std::fopen("palette.dot", "w"); |
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std::string dot = toGraphvizDot(); |
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std::fwrite(dot.data(), dot.size(), 1, out); |
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std::fclose(out); |
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#endif |
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} |
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std::string PaletteKdTree::toGraphvizDot() const |
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{ |
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std::string dot = "graph palette_tree {\n rankdir=LR\n"; |
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tree_.toGraphvizDot(0, values_, dot); |
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dot.append("}\n"); |
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return dot; |
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} |
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void PaletteKdTreeNode<0>::toGraphvizDot( |
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size_t id, std::span<const std::pair<PaletteKdTreeNode<0>::RGB, uint8_t>, 256> values, std::string &dot) const |
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{ |
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StrAppend(dot, " node_", id, R"( [shape=plain label=< |
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<table border="0" cellborder="0" cellspacing="0" cellpadding="2" style="ROUNDED"> |
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<tr>)"); |
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const std::pair<RGB, uint8_t> *const end = values.data() + valuesEndInclusive; |
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for (const std::pair<RGB, uint8_t> *it = values.data() + valuesBegin; it <= end; ++it) { |
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const auto &[rgb, paletteIndex] = *it; |
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StrAppend(dot, R"(<td balign="left" bgcolor="#)", |
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AsHexPad2(rgb[0]), AsHexPad2(rgb[1]), AsHexPad2(rgb[2]), "\">"); |
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const bool useWhiteText = rgb[0] + rgb[1] + rgb[2] < 350; |
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if (useWhiteText) StrAppend(dot, R"(<font color="white">)"); |
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StrAppend(dot, |
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static_cast<int>(rgb[0]), " ", |
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static_cast<int>(rgb[1]), " ", |
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static_cast<int>(rgb[2]), R"(<br/>)", |
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static_cast<int>(paletteIndex)); |
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if (useWhiteText) StrAppend(dot, "</font>"); |
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StrAppend(dot, "</td>"); |
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} |
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if (valuesBegin > valuesEndInclusive) StrAppend(dot, "<td></td>"); |
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StrAppend(dot, "</tr>\n </table>>]\n"); |
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} |
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} // namespace devilution
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