sw_engine: rastering the opaque radial gradient with masking

In the radial gradient rastering functions, the part supporting the (inverse) masking was added.
2025-07-29 01:26:03 +00:00 · 2021-04-04 17:09:00 +02:00 · 2021-04-04 17:09:00 +02:00 · 6b5db72f67
commit 6b5db72f67
parent 8284b3fdfc
1 changed files with 77 additions and 14 deletions
--- a/src/lib/sw_engine/tvgSwRaster.cpp
+++ b/src/lib/sw_engine/tvgSwRaster.cpp
@ -671,7 +671,6 @@ static bool _rasterRadialGradientRect(SwSurface* surface, const SwBBox& region,
    //Translucent Gradient
    if (fill->translucent) {
        auto tmpBuf = static_cast<uint32_t*>(alloca(surface->w * sizeof(uint32_t)));
        if (!tmpBuf) return false;
@ -684,9 +683,44 @@ static bool _rasterRadialGradientRect(SwSurface* surface, const SwBBox& region,
        }
    //Opaque Gradient
    } else {
-        for (uint32_t y = 0; y < h; ++y) {
+        if (surface->compositor) {
-            auto dst = &buffer[y * surface->stride];
+            auto method = surface->compositor->method;
-            fillFetchRadial(fill, dst, region.min.y + y, region.min.x, w);
+            auto cbuffer = surface->compositor->image.data + (region.min.y * surface->stride) + region.min.x;
            auto sbuffer = static_cast<uint32_t*>(alloca(w * sizeof(uint32_t)));
            if (!sbuffer) return false;
            if (method == CompositeMethod::AlphaMask) {
                for (uint32_t y = 0; y < h; ++y) {
                    fillFetchRadial(fill, sbuffer, region.min.y + y, region.min.x, w);
                    auto dst = buffer;
                    auto cmp = cbuffer;
                    auto src = sbuffer;
                    for (uint32_t x = 0; x < w; ++x, ++dst, ++cmp, ++src) {
                        auto tmp = ALPHA_BLEND(*src, surface->blender.alpha(*cmp));
                        *dst = tmp + ALPHA_BLEND(*dst, 255 - surface->blender.alpha(tmp));
                    }
                    buffer += surface->stride;
                    cbuffer += surface->stride;
                }
            } else if (method == CompositeMethod::InvAlphaMask) {
                for (uint32_t y = 0; y < h; ++y) {
                    fillFetchRadial(fill, sbuffer, region.min.y + y, region.min.x, w);
                    auto dst = buffer;
                    auto cmp = cbuffer;
                    auto src = sbuffer;
                    for (uint32_t x = 0; x < w; ++x, ++dst, ++cmp, ++src) {
                        auto tmp = ALPHA_BLEND(*src, 255 - surface->blender.alpha(*cmp));
                        *dst = tmp + ALPHA_BLEND(*dst, 255 - surface->blender.alpha(tmp));
                    }
                    buffer += surface->stride;
                    cbuffer += surface->stride;
                }
            }
        } else {
            for (uint32_t y = 0; y < h; ++y) {
                auto dst = &buffer[y * surface->stride];
                fillFetchRadial(fill, dst, region.min.y + y, region.min.x, w);
            }
        }
    }
    return true;
@ -796,18 +830,47 @@ static bool _rasterRadialGradientRle(SwSurface* surface, const SwRleData* rle, c
        }
    //Opaque Gradient
    } else {
-        for (uint32_t i = 0; i < rle->size; ++i) {
+        if (surface->compositor) {
-            auto dst = &surface->buffer[span->y * surface->stride + span->x];
+            auto method = surface->compositor->method;
-            if (span->coverage == 255) {
+            auto cbuffer = surface->compositor->image.data;
-                fillFetchRadial(fill, dst, span->y, span->x, span->len);
+
-            } else {
+            if (method == CompositeMethod::AlphaMask) {
-                fillFetchRadial(fill, buf, span->y, span->x, span->len);
+                for (uint32_t i = 0; i < rle->size; ++i, ++span) {
-                auto ialpha = 255 - span->coverage;
+                    fillFetchRadial(fill, buf, span->y, span->x, span->len);
-                for (uint32_t i = 0; i < span->len; ++i) {
+                    auto dst = &surface->buffer[span->y * surface->stride + span->x];
-                    dst[i] = ALPHA_BLEND(buf[i], span->coverage) + ALPHA_BLEND(dst[i], ialpha);
+                    auto cmp = &cbuffer[span->y * surface->stride + span->x];
                    auto src = buf;
                    for (uint32_t x = 0; x < span->len; ++x, ++dst, ++cmp, ++src) {
                        auto tmp = ALPHA_BLEND(*src, surface->blender.alpha(*cmp));
                        *dst = tmp + ALPHA_BLEND(*dst, 255 - surface->blender.alpha(tmp));
                    }
                }
            } else if (method == CompositeMethod::InvAlphaMask) {
                for (uint32_t i = 0; i < rle->size; ++i, ++span) {
                    fillFetchRadial(fill, buf, span->y, span->x, span->len);
                    auto dst = &surface->buffer[span->y * surface->stride + span->x];
                    auto cmp = &cbuffer[span->y * surface->stride + span->x];
                    auto src = buf;
                    for (uint32_t x = 0; x < span->len; ++x, ++dst, ++cmp, ++src) {
                        auto tmp = ALPHA_BLEND(*src, 255 - surface->blender.alpha(*cmp));
                        *dst = tmp + ALPHA_BLEND(*dst, 255 - surface->blender.alpha(tmp));
                    }
                }
            }
-            ++span;
+        } else {
            for (uint32_t i = 0; i < rle->size; ++i) {
                auto dst = &surface->buffer[span->y * surface->stride + span->x];
                if (span->coverage == 255) {
                    fillFetchRadial(fill, dst, span->y, span->x, span->len);
                } else {
                    fillFetchRadial(fill, buf, span->y, span->x, span->len);
                    auto ialpha = 255 - span->coverage;
                    for (uint32_t i = 0; i < span->len; ++i) {
                        dst[i] = ALPHA_BLEND(buf[i], span->coverage) + ALPHA_BLEND(dst[i], ialpha);
                    }
                }
                ++span;
            }
        }
    }
    return true;