// // Created by Keuin on 2022/4/11. // #ifndef RT_BITMAP_H #define RT_BITMAP_H #include #include #include #include #include #include "bitfont.h" #include "vec.h" #define COLORMIX_OVERFLOW_CHECK enum text_policy { hard = 0, // cut off overflown parts newline = 1, // write overflown characters to new line }; //// T is some unsigned integer //template //T saturate_add(T a, T b) { // T c = a + b; // if (a > c || b > c) { // c = (1ULL << (sizeof(T) * 8U)) - 1ULL; // } // return c; //} // T is some unsigned integer, do not use float point types! template struct pixel { T r, g, b; static constexpr auto mod = (1ULL << (sizeof(T) * 8U)) - 1ULL; // FIXME bool operator==(const pixel &other) const { return r == other.r && g == other.g && b == other.b; } /** * Create a pixel of given depth, from normalized color values. * r, g, b must in range [0, 1]. * For example: Set color depth to 8bit, for normalized color (1, 0.5, 0.25), we get: (255, 127, 63). */ static inline pixel from_normalized(double r, double g, double b) { return pixel{.r = (T) (mod * r), .g = (T) (mod * g), .b = (T) (mod * b)}; } // v3d must be a normalized vector static inline pixel from_normalized(const vec3d &v3d) { return from_normalized(v3d.x / 2.0 + 0.5, v3d.y / 2.0 + 0.5, v3d.z / 2.0 + 0.5); } // Convert pixels between different color depths. template static inline pixel from(const pixel &orig) { return from_normalized( 1.0 * orig.r / pixel::max_value(), 1.0 * orig.g / pixel::max_value(), 1.0 * orig.b / pixel::max_value() ); } static inline pixel black() { return pixel{(T) 0, (T) 0, (T) 0}; } static inline pixel white() { return pixel{(T) mod, (T) mod, (T) mod}; // FIXME float-point values } static inline T max_value() { return mod; // FIXME } pixel gamma2() const { const auto max = max_value(); if (sizeof(T) <= 2) { // 26% faster than using double const auto r_ = sqrtf((float) (this->r) / (float) max); const auto g_ = sqrtf((float) (this->g) / (float) max); const auto b_ = sqrtf((float) (this->b) / (float) max); return pixel::from_normalized(r_, g_, b_); } else { const auto r_ = sqrt(1.0 * this->r / max); const auto g_ = sqrt(1.0 * this->g / max); const auto b_ = sqrt(1.0 * this->b / max); return pixel::from_normalized(r_, g_, b_); } } }; //template<> //pixel pixel::gamma2() const { // // 26% faster than using double // const auto max = max_value(); // const auto r_ = sqrtf((float) (this->r) / (float) (max)); // const auto g_ = sqrtf((float) (this->g) / (float) (max)); // const auto b_ = sqrtf((float) (this->b) / (float) (max)); // return pixel::from_normalized(r_, g_, b_); //} template< typename T, typename S, typename = typename std::enable_if::value, S>::type > pixel operator*(const pixel &pixel, S scale) { return ::pixel < T > {.r=(T) (pixel.r * scale), .g=(T) (pixel.g * scale), .b=(T) (pixel.b * scale)}; } template< typename T, typename S, typename = typename std::enable_if::value, S>::type > pixel operator*(S scale, const pixel &pixel) { return ::pixel < T > {.r=(T) (pixel.r * scale), .g=(T) (pixel.g * scale), .b=(T) (pixel.b * scale)}; } // Mix two colors a and b. Returns a*u + b*v template inline pixel mix(const pixel &a, const pixel &b, double u, double v) { assert(u >= 0); assert(v >= 0); assert(u <= 1); assert(v <= 1); assert(u + v <= 1); pixel c{0, 0, 0}; c.r = (T) (u * a.r + v * b.r); c.g = (T) (u * a.g + v * b.g); c.b = (T) (u * a.b + v * b.b); return c; } // 8 bit pixel using pixel8b = pixel; template class bitmap { unsigned width, height; std::vector> content; // pixels scanned by rows, from top to bottom pixel &image(unsigned x, unsigned y) { assert(x < width); assert(y < height); return content[x + y * width]; } pixel &image(unsigned x, unsigned y) const { assert(x < width); assert(y < height); return content[x + y * width]; } public: bitmap() = delete; bitmap(unsigned int width, unsigned int height) : width(width), height(height), content{width * height, pixel{}} {} bitmap(unsigned int width, unsigned int height, std::vector> &&data) : width(width), height(height), content{data} {} static bitmap average(const std::vector> &images) { using Acc = typename std::conditional< (sizeof(T) <= 1), uint_fast16_t, typename std::conditional< (sizeof(T) <= 2), uint_fast32_t, typename std::conditional< (sizeof(T) <= 4), uint_fast64_t, uintmax_t >::type >::type >::type; // pick the smallest suitable type for accumulator static_assert(sizeof(Acc) > sizeof(T), "accumulator may overflow"); assert(!images.empty()); bitmap result{images[0].width, images[0].height}; const auto m = images.size(); const auto n = images[0].content.size(); Acc acc_r, acc_g, acc_b; for (size_t i = 0; i < n; ++i) { acc_r = 0; acc_g = 0; acc_b = 0; for (size_t j = 0; j < m; ++j) { acc_r += images[j].content[i].r; acc_g += images[j].content[i].g; acc_b += images[j].content[i].b; } result.content[i] = pixel{(T) (1.0 * acc_r / m), (T) (1.0 * acc_g / m), (T) (1.0 * acc_b / m)}; } return result; } void set(unsigned x, unsigned y, const pixel &pixel) { image(x, y) = pixel; } pixel get(unsigned x, unsigned y) const { return image(x, y); } const pixel &operator[](size_t loc) const { assert(loc < width * height); return content[loc]; } pixel &operator[](size_t loc) { assert(loc < width * height); return content[loc]; } // Do not use float-point pixels, or this routine will break. void write_plain_ppm(std::ostream &out) const; // Draw text on the image. Supports limited visual ASCII characters. void print(const std::string &s, const pixel &color, unsigned x, unsigned y, text_policy policy, unsigned scale = 1, double alpha = 1.0); bool normalized() const { return false; // TODO return true for float-point pixels } std::pair shape() const { return std::pair{width, height}; } // U: original color depth, T: desired color depth template static bitmap from(const bitmap &src) { const auto shape = src.shape(); const size_t sz = shape.first * shape.second; bitmap out{shape.first, shape.second}; for (size_t i = 0; i < sz; ++i) { out[i] = pixel::from(src[i]); } return out; } bitmap gamma2() const { std::vector> out; out.reserve(content.size()); for (const auto &pix: content) { out.push_back(pix.gamma2()); } return bitmap{width, height, std::move(out)}; } }; template void bitmap::write_plain_ppm(std::ostream &out) const { const auto depth = (1ULL << (sizeof(T) * 8)) - 1ULL; // color depth of pixels out << "P3\n" // file header << width << ' ' << height << '\n' // image width and height << depth << '\n'; // normalized max color depth (e.g. 255 for 8bit image) for (const auto &pixel: content) { out << (unsigned long long) pixel.r << ' ' << (unsigned long long) pixel.g << ' ' << (unsigned long long) pixel.b << '\n'; } } template void bitmap::print(const std::string &s, const pixel &color, unsigned x, unsigned y, text_policy policy, unsigned scale, double alpha) { assert(alpha >= 0); assert(alpha <= 1); const unsigned char_w = 8 * scale, char_h = 13 * scale; // char width and height size_t n = 0; // written characters for (const auto &c: s) { unsigned int idx = c - 32U; if (idx >= 95) idx = 1; // replace invisible chars with '!' unsigned char_x, char_y; const unsigned spacing = ((n > 1) ? ((n - 1) * scale) : 0); // total spacing between characters if (policy == text_policy::hard) { char_x = x + n * char_w + spacing; char_y = y; } else if (policy == text_policy::newline) { const auto newlines = (n * char_w + spacing + char_w - 1) / (width - x); char_x = (x + n * char_w + spacing) % (width - x); char_y = y + newlines * char_h + ((newlines > 0) ? ((newlines - 1) * scale) : 0); } else { abort(); // unknown policy } // char size is 13x8, stored line by line, from the bottom line to the top line // every line is represented in a single byte // in every byte, from MSB to LSB, the pixel goes from left to right for (unsigned i = 0; i < char_w; ++i) { for (unsigned j = 0; j < char_h; ++j) { // downscale (i, j) to pos on char bitmap i -> i/scale, j -> j/scale if (rasters[idx][12 - j / scale] & (1U << (7U - i / scale))) { const auto pen_x = char_x + i, pen_y = char_y + j; if (pen_x >= width || pen_y >= height) continue; image(pen_x, pen_y) = mix(image(pen_x, pen_y), color, 1.0 - alpha, alpha); } } } ++n; } } using bitmap8b = bitmap; #endif //RT_BITMAP_H