renderer: add partial rendering support

Partial Rendering refers to a rendering technique where only a portion of the scene or screen is updated, rather than redrawing the entire output. It is commonly used as a performance optimization strategy, focusing on redrawing only the regions that have changed, often called dirty regions. This introduces RenderDirtyRegion, which assists in collecting a compact dirty region from render tasks. Each backend can utilize this class to support efficient partial rendering. This is implemented using a Line Sweep and Subdivision Merging O(NlogN). The basic per-frame workflow is as follows: 1. RenderDirtyRegion::prepare() //Call this in Renderer::preRender(). 2. RenderDirtyRegion::add() //Add all dirty paints for the frame before rendering. 3. RenderDirtyRegion::commit() //Generate the partial rendering region list before rendering. 4. RenderDirtyRegion::get() //Retrieve the current dirty region list and use it when drawing paints. 5. RenderDirtyRegion::clear() //Reset the state. also removed the skip() from paint since engines need to capture the drawable object in any case. issue: https://github.com/thorvg/thorvg/issues/1747
2025-06-19 14:31:39 +00:00 · 2025-06-17 15:50:31 +09:00 · 2025-06-17 15:50:31 +09:00 · a005ef2811
commit a005ef2811
parent f6bfeda4fa
5 changed files with 226 additions and 7 deletions
--- a/src/renderer/tvgPaint.h
+++ b/src/renderer/tvgPaint.h
@ -144,6 +144,11 @@ namespace tvg
            return (renderFlag & flag) ? true : false;
        }
        void damage()
        {
            if (renderer) renderer->damage(bounds(renderer));
        }
        void mark(RenderUpdateFlag flag)
        {
            renderFlag |= flag;
--- a/src/renderer/tvgRender.cpp
+++ b/src/renderer/tvgRender.cpp
@ -20,6 +20,7 @@
 * SOFTWARE.
 */
 #include <algorithm>
 #include "tvgMath.h"
 #include "tvgRender.h"
@ -54,6 +55,18 @@ bool RenderMethod::viewport(const RenderRegion& vp)
 }
 void RenderMethod::damage(const RenderRegion& region)
 {
    dirtyRegion.add(region);
 }
 bool RenderMethod::partial(bool disable)
 {
    std::swap(dirtyRegion.disabled, disable);
    return disable;
 }
 /************************************************************************/
 /* RenderPath Class Implementation                                      */
 /************************************************************************/
@ -130,6 +143,130 @@ void RenderRegion::intersect(const RenderRegion& rhs)
    if (max.y < min.y) max.y = min.y;
 }
 void RenderDirtyRegion::subdivide(Array<RenderRegion>& targets, uint32_t idx, RenderRegion& lhs, RenderRegion& rhs)
 {
    RenderRegion temp[5];
    int cnt = 0;
    temp[cnt++] = RenderRegion::intersect(lhs, rhs);
    auto max = std::min(lhs.max.x, rhs.max.x);
    auto subtract = [&](RenderRegion& lhs, RenderRegion& rhs) {
        //top
        if (rhs.min.y < lhs.min.y) {
            temp[cnt++] = {{rhs.min.x, rhs.min.y}, {rhs.max.x, lhs.min.y}};
            rhs.min.y = lhs.min.y;
        }
        //bottom
        if (rhs.max.y > lhs.max.y) {
            temp[cnt++] = {{rhs.min.x, lhs.max.y}, {rhs.max.x, rhs.max.y}};
            rhs.max.y = lhs.max.y;
        }
        //left
        if (rhs.min.x < lhs.min.x) {
            temp[cnt++] = {{rhs.min.x, rhs.min.y}, {lhs.min.x, rhs.max.y}};
            rhs.min.x = lhs.min.x;
        }
        //right
        if (rhs.max.x > lhs.max.x) {
            temp[cnt++] = {{lhs.max.x, rhs.min.y}, {rhs.max.x, rhs.max.y}};
            //rhs.max.x = lhs.max.x;
        }
    };
    subtract(temp[0], lhs);
    subtract(temp[0], rhs);
    //TODO: remove this
    if (targets.reserved <  targets.count + cnt - 1) {
        TVGERR("RENDERER", "reserved: %d, required: %d (+%d)\n", targets.reserved, targets.count + cnt - 1, cnt - 1);
        abort();
    }
    /* Note: We considered using a list to avoid memory shifting,
       but ultimately, the array outperformed the list due to better cache locality. */
    //shift data
    auto dst = &targets[idx + cnt];
    memmove(dst, &targets[idx + 1], sizeof(RenderRegion) * (targets.count - idx - 1));
    memcpy(&targets[idx], temp, sizeof(RenderRegion) * cnt);
    targets.count += (cnt - 1);
    //sorting by x coord again, only for the updated region
    while (dst < targets.end() && dst->min.x < max) ++dst;
    stable_sort(&targets[idx], dst, [](const RenderRegion& a, const RenderRegion& b) -> bool {
        return a.min.x < b.min.x;
    });
 }
 void RenderDirtyRegion::commit()
 {
    if (disabled) return;
    auto& targets = list[current];
    if (targets.empty()) return;
    current = !current;  //swapping buffers
    auto& output = list[current];
    //sorting by x coord. guarantee the stable performance: O(NlogN)
    stable_sort(targets.begin(), targets.end(), [](const RenderRegion& a, const RenderRegion& b) -> bool {
        return a.min.x < b.min.x;
    });
    //Optimized using sweep-line algorithm: O(NlogN)
    for (uint32_t i = 0; i < targets.count; ++i) {
        auto& lhs = targets[i];
        if (lhs.invalid()) continue;
        auto merged = false;
        for (uint32_t j = i + 1; j < targets.count; ++j) {
            auto& rhs = targets[j];
            if (rhs.invalid()) continue;
            if (lhs.max.x < rhs.min.x) break;   //line sweeping
            //fully overlapped. drop lhs
            if (rhs.contained(lhs)) {
                merged = true;
                break;
            }
            //fully overlapped. replace the lhs with rhs
            if (lhs.contained(rhs)) {
                rhs = {};
                continue;
            }
            //just merge & expand on x axis
            if (lhs.min.y == rhs.min.y && lhs.max.y == rhs.max.y) {
                if (lhs.min.x <= rhs.max.x && rhs.min.x <= lhs.max.x) {
                    rhs.min.x = std::min(lhs.min.x, rhs.min.x);
                    rhs.max.x = std::max(lhs.max.x, rhs.max.x);
                    merged = true;
                    break;
                }
            }
            //just merge & expand on y axis
            if (lhs.min.x == rhs.min.x && lhs.max.x == rhs.max.x) {
                if (lhs.min.y <= rhs.max.y && rhs.min.y < lhs.max.y) {
                    rhs.min.y = std::min(lhs.min.y, rhs.min.y);
                    rhs.max.y = std::max(lhs.max.y, rhs.max.y);
                    merged = true;
                    break;
                }
            }
            //subdivide regions
            if (lhs.intersected(rhs)) {
                subdivide(targets, j, lhs, rhs);
                merged = true;
                break;
            }
        }
        if (!merged) output.push(lhs);  //this region is complete isolated
        lhs = {};
    }
 }
 /************************************************************************/
 /* RenderTrimPath Class Implementation                                  */
 /************************************************************************/
--- a/src/renderer/tvgRender.h
+++ b/src/renderer/tvgRender.h
@ -50,7 +50,6 @@ static inline RenderUpdateFlag operator|(const RenderUpdateFlag a, const RenderU
    return RenderUpdateFlag(uint16_t(a) | uint16_t(b));
 }
 struct RenderSurface
 {
    union {
@ -111,6 +110,11 @@ struct RenderRegion
        return ret;
    }
    static constexpr RenderRegion add(const RenderRegion& lhs, const RenderRegion& rhs)
    {
        return {{std::min(lhs.min.x, rhs.min.x), std::min(lhs.min.y, rhs.min.y)}, {std::max(lhs.max.x, rhs.max.x), std::max(lhs.max.y, rhs.max.y)}};
    }
    void intersect(const RenderRegion& rhs);
    void add(const RenderRegion& rhs)
@ -121,6 +125,16 @@ struct RenderRegion
        if (rhs.max.y > max.y) max.y = rhs.max.y;
    }
    bool contained(const RenderRegion& rhs)
    {
        return (min.x <= rhs.min.x && max.x >= rhs.max.x && min.y <= rhs.min.y && max.y >= rhs.max.y);
    }
    bool intersected(const RenderRegion& rhs) const
    {
        return (rhs.min.x < max.x && rhs.max.x > min.x && rhs.min.y < max.y && rhs.max.y > min.y);
    }
    bool operator==(const RenderRegion& rhs) const
    {
        return (min.x == rhs.min.x && min.y == rhs.min.y && max.x == rhs.max.x && max.y == rhs.max.y);
@ -141,6 +155,56 @@ struct RenderRegion
    uint32_t h() const { return (uint32_t) sh(); }
 };
 struct RenderDirtyRegion
 {
    void add(const RenderRegion& region)
    {
        if (disabled || region.invalid()) return;
        ScopedLock lock(key);
        list[current].push(region);
    }
    bool prepare(uint32_t count = 0)
    {
        if (disabled) return false;
        count *= 120;   //FIXME: enough?
        list[0].reserve(count);
        list[1].reserve(count);
        return true;
    }
    bool deactivated()
    {
        if (disabled) return true;
        return false;
    }
    void clear()
    {
        list[0].clear();
        list[1].clear();
    }
    const Array<RenderRegion>& get()
    {
        return list[current];
    }
    void commit();
    bool disabled = false;
 private:
    void subdivide(Array<RenderRegion>& targets, uint32_t idx, RenderRegion& lhs, RenderRegion& rhs);
    Array<RenderRegion> list[2];  //double buffer swapping
    Key key;
    uint8_t current = 0;          //list index. 0 or 1
 };
 struct RenderPath
 {
    Array<PathCommand> cmds;
@ -420,11 +484,12 @@ struct RenderEffectTritone : RenderEffect
 class RenderMethod
 {
 private:
-    uint32_t refCnt = 0;        //reference count
+    uint32_t refCnt = 0;
    Key key;
 protected:
    RenderRegion vport;         //viewport
    RenderDirtyRegion dirtyRegion;
 public:
    //common implementation
@ -448,11 +513,10 @@ public:
    virtual bool blend(BlendMethod method) = 0;
    virtual ColorSpace colorSpace() = 0;
    virtual const RenderSurface* mainSurface() = 0;
    virtual bool clear() = 0;
    virtual bool sync() = 0;
-    //compositions
+    //composition
    virtual RenderCompositor* target(const RenderRegion& region, ColorSpace cs, CompositionFlag flags) = 0;
    virtual bool beginComposite(RenderCompositor* cmp, MaskMethod method, uint8_t opacity) = 0;
    virtual bool endComposite(RenderCompositor* cmp) = 0;
@ -462,6 +526,10 @@ public:
    virtual bool region(RenderEffect* effect) = 0;
    virtual bool render(RenderCompositor* cmp, const RenderEffect* effect, bool direct) = 0;
    virtual void dispose(RenderEffect* effect) = 0;
    //partial rendering
    virtual void damage(const RenderRegion& region);
    virtual bool partial(bool disable);
 };
 static inline bool MASK_REGION_MERGING(MaskMethod method)
@ -532,4 +600,4 @@ static inline uint8_t MULTIPLY(uint8_t c, uint8_t a)
 }
-#endif //_TVG_RENDER_H_
+#endif //_TVG_RENDER_H_
--- a/src/renderer/tvgScene.h
+++ b/src/renderer/tvgScene.h
@ -131,6 +131,9 @@ struct SceneImpl : Scene
        vport = renderer->viewport();
        vdirty = true;
        //bounds(renderer) here hinders parallelization.
        if (effects) renderer->damage(vport);
        return true;
    }
@ -257,7 +260,10 @@ struct SceneImpl : Scene
    {
        auto itr = paints.begin();
        while (itr != paints.end()) {
-            PAINT((*itr))->unref();
+            auto paint = PAINT((*itr));
            //when the paint is destroyed damage will be triggered
            if (paint->refCnt > 1) paint->damage();
            paint->unref();
            paints.erase(itr++);
        }
        return Result::Success;
@ -266,6 +272,8 @@ struct SceneImpl : Scene
    Result remove(Paint* paint)
    {
        if (PAINT(paint)->parent != this) return Result::InsufficientCondition;
        //when the paint is destroyed damage will be triggered
        if (PAINT(paint)->refCnt > 1) PAINT(paint)->damage();
        PAINT(paint)->unref();
        paints.remove(paint);
        return Result::Success;
@ -310,6 +318,7 @@ struct SceneImpl : Scene
            }
            delete(effects);
            effects = nullptr;
            impl.renderer->damage(vport);
        }
        return Result::Success;
    }
--- a/src/renderer/tvgText.h
+++ b/src/renderer/tvgText.h
@ -111,7 +111,7 @@ struct TextImpl : Text
        return loader->transform(shape, metrics, fontSize, italic);
    }
-
+ 
    bool skip(RenderUpdateFlag flag)
    {
        if (flag == RenderUpdateFlag::None) return true;