#include "objectrenderer.h"
#include "view.h"
+#include <vector>
+#include <queue>
using namespace std;
*/
void ObjectRenderer::RenderUsingGPU(unsigned first_obj_id, unsigned last_obj_id)
{
+ // If we don't have anything to render, return.
+ if (first_obj_id == last_obj_id) return;
+ // If there are no objects of this type, return.
+ if (m_indexes.empty()) return;
unsigned first_index = 0;
- while (m_indexes[first_index] < first_obj_id*2) first_index += 2;
+ while (m_indexes.size() > first_index && m_indexes[first_index] < first_obj_id) first_index ++;
unsigned last_index = first_index;
- while (m_indexes[last_index] < last_obj_id*2) last_index += 2;
+ while (m_indexes.size() > last_index && m_indexes[last_index] < last_obj_id) last_index ++;
m_shader_program.Use();
m_ibo.Bind();
- glDrawElements(GL_LINES, (last_index-first_index)*2, GL_UNSIGNED_INT, (GLvoid*)(first_index*sizeof(uint32_t)));
+ glDrawElements(GL_LINES, (last_index-first_index)*2, GL_UNSIGNED_INT, (GLvoid*)(2*first_index*sizeof(uint32_t)));
}
/**
* Default implementation for rendering using CPU
*/
-void ObjectRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target)
+void ObjectRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target, unsigned first_obj_id, unsigned last_obj_id)
{
Error("Cannot render objects of type %d on CPU", m_type);
//TODO: Render a rect or something instead?
/**
* Rectangle (filled)
*/
-void RectFilledRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target)
+void RectFilledRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target, unsigned first_obj_id, unsigned last_obj_id)
{
for (unsigned i = 0; i < m_indexes.size(); ++i)
{
+ if (m_indexes[i] < first_obj_id) continue;
+ if (m_indexes[i] >= last_obj_id) continue;
PixelBounds bounds(CPURenderBounds(objects.bounds[m_indexes[i]], view, target));
- for (int64_t x = max(0L, bounds.x); x <= min(bounds.x+bounds.w, target.w-1); ++x)
+ FloodFillOnCPU(bounds.x+1, bounds.y+1, bounds, target, Colour(0,0,0,1));
+ /*
+ for (int64_t x = max((int64_t)0, bounds.x); x <= min(bounds.x+bounds.w, target.w-1); ++x)
{
- for (int64_t y = max(0L, bounds.y); y <= min(bounds.y+bounds.h, target.h-1); ++y)
+ for (int64_t y = max((int64_t)0, bounds.y); y <= min(bounds.y+bounds.h, target.h-1); ++y)
{
int index = (x+target.w*y)*4;
target.pixels[index+0] = 0;
target.pixels[index+3] = 255;
}
}
+ */
}
}
/**
* Rectangle (outine)
*/
-void RectOutlineRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target)
+void RectOutlineRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target, unsigned first_obj_id, unsigned last_obj_id)
{
//Debug("Render %u outlined rectangles on CPU", m_indexes.size());
for (unsigned i = 0; i < m_indexes.size(); ++i)
{
+ if (m_indexes[i] < first_obj_id) continue;
+ if (m_indexes[i] >= last_obj_id) continue;
PixelBounds bounds(CPURenderBounds(objects.bounds[m_indexes[i]], view, target));
// Using bresenham's lines now mainly because I want to see if they work
/**
* Circle (filled)
*/
-void CircleFilledRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target)
+void CircleFilledRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target, unsigned first_obj_id, unsigned last_obj_id)
{
for (unsigned i = 0; i < m_indexes.size(); ++i)
{
+ if (m_indexes[i] < first_obj_id) continue;
+ if (m_indexes[i] >= last_obj_id) continue;
PixelBounds bounds(CPURenderBounds(objects.bounds[m_indexes[i]], view, target));
int64_t centre_x = bounds.x + bounds.w / 2;
int64_t centre_y = bounds.y + bounds.h / 2;
//Debug("Centre is %d, %d", centre_x, centre_y);
//Debug("Bounds are %d,%d,%d,%d", bounds.x, bounds.y, bounds.w, bounds.h);
//Debug("Windos is %d,%d", target.w, target.h);
- for (int64_t x = max(0L, bounds.x); x <= min(bounds.x+bounds.w, target.w-1); ++x)
+ for (int64_t x = max((int64_t)0, bounds.x); x <= min(bounds.x+bounds.w, target.w-1); ++x)
{
- for (int64_t y = max(0L, bounds.y); y <= min(bounds.y + bounds.h, target.h-1); ++y)
+ for (int64_t y = max((int64_t)0, bounds.y); y <= min(bounds.y + bounds.h, target.h-1); ++y)
{
- double dx = 2.0*(double)(x - centre_x)/(double)(bounds.w);
- double dy = 2.0*(double)(y - centre_y)/(double)(bounds.h);
+ Real dx(2); dx *= Real(x - centre_x)/Real(bounds.w);
+ Real dy(2); dy *= Real(y - centre_y)/Real(bounds.h);
int64_t index = (x+target.w*y)*4;
- if (dx*dx + dy*dy <= 1.0)
+ if (dx*dx + dy*dy <= Real(1))
{
target.pixels[index+0] = 0;
target.pixels[index+1] = 0;
target.pixels[index+2] = 0;
target.pixels[index+3] = 255;
-
}
}
}
result.h *= Real(target.h);
return result;
}
+
+ObjectRenderer::PixelPoint ObjectRenderer::CPUPointLocation(const Vec2 & point, const View & view, const CPURenderTarget & target)
+{
+ // hack...
+ Rect result = view.TransformToViewCoords(Rect(point.x, point.y,1,1));
+ int64_t x = result.x*target.w;
+ int64_t y = result.y*target.h;
+ return PixelPoint(x,y);
+}
/**
* Bezier curve
* Not sure how to apply De'Casteljau, will just use a bunch of Bresnham lines for now.
*/
-void BezierRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target)
+void BezierRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target, unsigned first_obj_id, unsigned last_obj_id)
{
//Warn("Rendering Beziers on CPU. Things may explode.");
for (unsigned i = 0; i < m_indexes.size(); ++i)
{
- Rect bounds(CPURenderBounds(objects.bounds[m_indexes[i]], view, target));
- PixelBounds pix_bounds(bounds);
-
+ if (m_indexes[i] < first_obj_id) continue;
+ if (m_indexes[i] >= last_obj_id) continue;
+ const Rect & bounds = objects.bounds[m_indexes[i]];
+ PixelBounds pix_bounds(CPURenderBounds(bounds,view,target));
- Bezier control(objects.beziers[objects.data_indices[m_indexes[i]]], bounds);
+ Bezier control(objects.beziers[objects.data_indices[m_indexes[i]]].ToAbsolute(bounds),CPURenderBounds(Rect(0,0,1,1), view, target));
//Debug("%s -> %s via %s", objects.beziers[objects.data_indices[m_indexes[i]]].Str().c_str(), control.Str().c_str(), bounds.Str().c_str());
- // Draw a rectangle around the bezier for debugging the coord transforms
- //ObjectRenderer::RenderLineOnCPU(pix_bounds.x, pix_bounds.y, pix_bounds.x+pix_bounds.w, pix_bounds.y, target);
- //ObjectRenderer::RenderLineOnCPU(pix_bounds.x, pix_bounds.y+pix_bounds.h, pix_bounds.x+pix_bounds.w, pix_bounds.y+pix_bounds.h, target);
- //ObjectRenderer::RenderLineOnCPU(pix_bounds.x, pix_bounds.y, pix_bounds.x, pix_bounds.y+pix_bounds.h, target);
- //ObjectRenderer::RenderLineOnCPU(pix_bounds.x+pix_bounds.w, pix_bounds.y, pix_bounds.x+pix_bounds.w, pix_bounds.y+pix_bounds.h, target);
-
+ // Draw a rectangle around the bezier for debugging the bounds rectangle calculations
+ if (view.ShowingObjectBounds())
+ {
+ ObjectRenderer::RenderLineOnCPU(pix_bounds.x, pix_bounds.y, pix_bounds.x+pix_bounds.w, pix_bounds.y, target, Colour(1,0,0,1));
+ ObjectRenderer::RenderLineOnCPU(pix_bounds.x, pix_bounds.y+pix_bounds.h, pix_bounds.x+pix_bounds.w, pix_bounds.y+pix_bounds.h, target, Colour(0,1,0,1));
+ ObjectRenderer::RenderLineOnCPU(pix_bounds.x, pix_bounds.y, pix_bounds.x, pix_bounds.y+pix_bounds.h, target, Colour(1,0,0,1));
+ ObjectRenderer::RenderLineOnCPU(pix_bounds.x+pix_bounds.w, pix_bounds.y, pix_bounds.x+pix_bounds.w, pix_bounds.y+pix_bounds.h, target, Colour(0,1,0,1));
+ }
// Draw lines between the control points for debugging
//ObjectRenderer::RenderLineOnCPU((int64_t)control.x0, (int64_t)control.y0, (int64_t)control.x1, (int64_t)control.y1,target);
//ObjectRenderer::RenderLineOnCPU((int64_t)control.x1, (int64_t)control.y1, (int64_t)control.x2, (int64_t)control.y2,target);
Real x[2]; Real y[2];
control.Evaluate(x[0], y[0], Real(0));
- int64_t blen = max(2L, min(100L, pix_bounds.w));
+ //Debug("target is (%lu, %lu)", target.w, target.h);
+ int64_t blen = min(max((int64_t)2, (int64_t)(target.w/view.GetBounds().w)), (int64_t)100);
+
Real invblen(1); invblen /= blen;
- Debug("Using %li lines, inverse %f", blen, Double(invblen));
+ //Debug("Using %li lines, inverse %f", blen, Double(invblen));
for (int64_t j = 1; j <= blen; ++j)
{
control.Evaluate(x[j % 2],y[j % 2], invblen*j);
- ObjectRenderer::RenderLineOnCPU((int64_t)Double(x[0]),(int64_t)Double(y[0]), (int64_t)Double(x[1]),(int64_t)Double(y[1]), target);
+ ObjectRenderer::RenderLineOnCPU((int64_t)Double(x[0]),(int64_t)Double(y[0]), (int64_t)Double(x[1]),(int64_t)Double(y[1]), target, Colour(0,0,0,!view.PerformingShading()));
}
/*
m_bezier_coeffs.Resize(objects.beziers.size()*sizeof(GPUBezierCoeffs));
BufferBuilder<GPUBezierCoeffs> builder(m_bezier_coeffs.Map(false, true, true), m_bezier_coeffs.GetSize());
- for (auto bez : objects.beziers)
+
+ for (unsigned i = 0; i < objects.beziers.size(); ++i)
{
+ const Bezier & bez = objects.beziers[i];
+
GPUBezierCoeffs coeffs = {
Float(bez.x0), Float(bez.y0),
- Float(bez.x1 - bez.x0), Float(bez.y1 - bez.y0),
- Float(bez.x2 - bez.x0), Float(bez.y2 - bez.y0)
+ Float(bez.x1), Float(bez.y1),
+ Float(bez.x2), Float(bez.y2),
+ Float(bez.x3), Float(bez.y3)
};
builder.Add(coeffs);
}
if (!m_shader_program.Valid())
Warn("Shader is invalid (objects are of type %d)", m_type);
+ // If we don't have anything to render, return.
+ if (first_obj_id == last_obj_id) return;
+ // If there are no objects of this type, return.
+ if (m_indexes.empty()) return;
+
unsigned first_index = 0;
- while (m_indexes[first_index] < first_obj_id*2) first_index += 2;
+ while (m_indexes.size() > first_index && m_indexes[first_index] < first_obj_id) first_index ++;
unsigned last_index = first_index;
- while (m_indexes[last_index] < last_obj_id*2) last_index += 2;
+ while (m_indexes.size() > last_index && m_indexes[last_index] < last_obj_id) last_index ++;
m_shader_program.Use();
glUniform1i(m_shader_program.GetUniformLocation("bezier_buffer_texture"), 0);
glUniform1i(m_shader_program.GetUniformLocation("bezier_id_buffer_texture"), 1);
m_ibo.Bind();
- glDrawElements(GL_LINES, (last_index-first_index)*2, GL_UNSIGNED_INT, (GLvoid*)(first_index*sizeof(uint32_t)));
+ glDrawElements(GL_LINES, (last_index-first_index)*2, GL_UNSIGNED_INT, (GLvoid*)(2*first_index*sizeof(uint32_t)));
+}
+
+
+
+/**
+ * Render Path (shading)
+ */
+void PathRenderer::RenderUsingCPU(const Objects & objects, const View & view, const CPURenderTarget & target, unsigned first_obj_id, unsigned last_obj_id)
+{
+ if (!view.ShowingObjectBounds() && !view.PerformingShading())
+ return;
+
+ for (unsigned i = 0; i < m_indexes.size(); ++i)
+ {
+ if (m_indexes[i] < first_obj_id) continue;
+ if (m_indexes[i] >= last_obj_id) continue;
+
+
+ Rect bounds(CPURenderBounds(objects.bounds[m_indexes[i]], view, target));
+ PixelBounds pix_bounds(bounds);
+ const Path & path = objects.paths[objects.data_indices[m_indexes[i]]];
+ if (path.m_fill.a == 0 || !view.PerformingShading())
+ continue;
+
+ for (unsigned f = 0; f < path.m_fill_points.size(); ++f)
+ {
+ PixelPoint fill_point(CPUPointLocation(path.m_fill_points[f], view, target));
+ FloodFillOnCPU(fill_point.first, fill_point.second, pix_bounds, target, path.m_fill);
+ }
+
+ /*if (true)//(view.ShowingObjectBounds())
+ {
+
+ PixelPoint start(CPUPointLocation((path.m_top+path.m_left+path.m_right+path.m_bottom)/4, view, target));
+ for (unsigned f = 0; f < path.m_fill_points.size(); ++f)
+ {
+ PixelPoint end(CPUPointLocation(path.m_fill_points[f], view, target));
+ RenderLineOnCPU(start.first, start.second, end.first, end.second, target, Colour(0,0,1,1));
+ }
+ }
+ */
+
+ }
}
/**
// TODO: Avoid extra inner conditionals
do
- {
+ {
if (x >= 0 && x < width && y >= 0 && y < height)
{
int64_t index = (transpose ? (y + x*target.w)*4 : (x + y*target.w)*4);
for (int i = 0; i < 4; ++i)
target.pixels[index+i] = rgba[i];
}
-
if (p < 0)
p += two_dy;
else
if (neg_m) --y; else ++y;
p += two_dxdy;
}
- } while (++x < x_end);
+ } while (++x <= x_end);
+}
+
+void ObjectRenderer::FloodFillOnCPU(int64_t x, int64_t y, const PixelBounds & bounds, const CPURenderTarget & target, const Colour & fill)
+{
+ if (fill == Colour(1,1,1,1))
+ return;
+ queue<PixelPoint > traverse;
+ traverse.push(PixelPoint(x,y));
+ // now with 100% less stack overflows!
+ while (traverse.size() > 0)
+ {
+ PixelPoint cur(traverse.front());
+ traverse.pop();
+ if (cur.first < 0 || cur.first < bounds.x || cur.first >= bounds.x+bounds.w || cur.first >= target.w ||
+ cur.second < 0 || cur.second < bounds.y || cur.second >= bounds.y+bounds.h || cur.second >= target.h)
+ continue;
+ if (GetColour(target, cur.first, cur.second) != Colour(1,1,1,1))
+ continue;
+ SetColour(target, cur.first, cur.second, fill);
+
+
+ traverse.push(PixelPoint(cur.first+1, cur.second));
+ traverse.push(PixelPoint(cur.first-1, cur.second));
+ traverse.push(PixelPoint(cur.first, cur.second-1));
+ traverse.push(PixelPoint(cur.first, cur.second+1));
+ }
}
}