Пример #1
0
void SE_Bounds::Transform(const SE_Matrix& xform)
{
    double* last = hull + 2*size;
    double* cur = hull;
    min[0] = min[1] = +DBL_MAX;
    max[0] = max[1] = -DBL_MAX;

    while (cur < last)
    {
        xform.transform(cur[0], cur[1]);
        AddToBounds(cur[0], cur[1], min, max);
        cur += 2;
    }
}
Пример #2
0
/* NOTE: This method is intentionally unchecked, the caller must ensure that the
 *       destination SE_Bounds is large enough, that the source is valid, etc. */
void SE_Bounds::Transform(const SE_Matrix& xform, SE_Bounds* src)
{
    double* last = src->hull + 2*src->size;
    double* cur = src->hull;
    double* dst = hull;
    min[0] = min[1] = +DBL_MAX;
    max[0] = max[1] = -DBL_MAX;
    size = src->size;
    pivot = src->pivot;

    while (cur < last)
    {
        xform.transform(cur[0], cur[1], dst[0], dst[1]);
        AddToBounds(dst[0], dst[1], min, max);
        cur += 2;
        dst += 2;
    }
}
Пример #3
0
void SE_Renderer::DrawSymbol(SE_RenderPrimitiveList& symbol,
                             const SE_Matrix& xform,
                             double angleRad,
                             bool excludeRegion)
{
    RS_Bounds extents(DBL_MAX, DBL_MAX, DBL_MAX, -DBL_MAX, -DBL_MAX, -DBL_MAX);
    unsigned int nprims = symbol.size();

    for (unsigned int i=0; i<nprims; ++i)
    {
        SE_RenderPrimitive* primitive = symbol[i];

        if (primitive->type == SE_RenderPrimitive_Polygon || primitive->type == SE_RenderPrimitive_Polyline)
        {
            SE_RenderPolyline* rp = (SE_RenderPolyline*)primitive;

            LineBuffer* lb = rp->geometry->xf_buffer();

            // update the extents with this primitive
            RS_Bounds lbnds;
            lb->ComputeBounds(lbnds);
            extents.add_bounds(lbnds);

            if (m_bSelectionMode)
            {
                if (primitive->type == SE_RenderPrimitive_Polygon)
                    DrawScreenPolygon(lb, &xform, m_selFillColor);

                m_selLineStroke.cap        = rp->lineStroke.cap;
                m_selLineStroke.join       = rp->lineStroke.join;
                m_selLineStroke.miterLimit = rp->lineStroke.miterLimit;
                DrawScreenPolyline(lb, &xform, m_selLineStroke);
            }
            else
            {
                if (primitive->type == SE_RenderPrimitive_Polygon)
                    DrawScreenPolygon(lb, &xform, ((SE_RenderPolygon*)primitive)->fill);

                DrawScreenPolyline(lb, &xform, rp->lineStroke);
            }
        }
        else if (primitive->type == SE_RenderPrimitive_Text)
        {
            SE_RenderText* tp = (SE_RenderText*)primitive;

            // update the extents with this primitive's bounds
            for (int j=0; j<4; ++j)
                extents.add_point(primitive->bounds[j]);

            // get position and angle to use
            double x, y;
            xform.transform(tp->position[0], tp->position[1], x, y);
            RS_TextDef tdef = tp->tdef;
            tdef.rotation() += angleRad * M_180PI;

            if (m_bSelectionMode)
            {
                tdef.textcolor()   = m_textForeColor;
                tdef.ghostcolor()  = m_textBackColor;
//              tdef.framecolor()  = m_textBackColor;
//              tdef.opaquecolor() = m_textBackColor;
            }

            // Here we cannot use the cached RS_TextMetrics in the SE_RenderText object.
            // We must recalculate the text metrics with the new tdef before we can call DrawScreenText.
            RS_TextMetrics tm;
            if (this->GetRSFontEngine()->GetTextMetrics(tp->content, tdef, tm, false))
                DrawScreenText(tm, tdef, x, y, NULL, 0, 0.0);
        }
        else if (primitive->type == SE_RenderPrimitive_Raster)
        {
            SE_RenderRaster* rp = (SE_RenderRaster*)primitive;

            if (m_bSelectionMode)
            {
                // if the raster symbol is selected, then draw the mask selection polygon only
                LineBuffer *lb = LineBufferPool::NewLineBuffer(m_pPool, 5);
                std::auto_ptr<LineBuffer> spLB(lb);

                lb->MoveTo(rp->bounds[3].x, rp->bounds[3].y);
                for (int i = 0; i < 4; ++i)
                {
                    lb->LineTo(rp->bounds[i].x, rp->bounds[i].y);
                }
                
                DrawScreenPolygon(lb, &xform, m_selFillColor);
                DrawScreenPolyline(lb, &xform, m_selLineStroke);

                LineBufferPool::FreeLineBuffer(m_pPool, spLB.release());
            }
            else 
            {
                ImageData& imgData = rp->imageData;
                if (imgData.data != NULL)
                {
                    // update the extents with this primitive's bounds
                    for (int j=0; j<4; ++j)
                        extents.add_point(primitive->bounds[j]);

                    // get position and angle to use
                    double x, y;
                    xform.transform(rp->position[0], rp->position[1], x, y);
                    double angleDeg = (rp->angleRad + angleRad) * M_180PI;

                    DrawScreenRaster(imgData.data, imgData.size, imgData.format, imgData.width, imgData.height, x, y, rp->extent[0], rp->extent[1], angleDeg, rp->opacity);
                }
            }
        }
    }

    if (nprims > 0)
    {
        // always compute the last symbol extent
        xform.transform(extents.minx, extents.miny, m_lastSymbolExtent[0].x, m_lastSymbolExtent[0].y);
        xform.transform(extents.maxx, extents.miny, m_lastSymbolExtent[1].x, m_lastSymbolExtent[1].y);
        xform.transform(extents.maxx, extents.maxy, m_lastSymbolExtent[2].x, m_lastSymbolExtent[2].y);
        xform.transform(extents.minx, extents.maxy, m_lastSymbolExtent[3].x, m_lastSymbolExtent[3].y);

        if (excludeRegion)
            AddExclusionRegion(m_lastSymbolExtent, 4);
    }
    else
    {
        // symbol contains no primitives - update last symbol extent assuming
        // zero symbol extent, but don't add any exclusion region
        xform.transform(0.0, 0.0, m_lastSymbolExtent[0].x, m_lastSymbolExtent[0].y);
        m_lastSymbolExtent[1].x = m_lastSymbolExtent[2].x = m_lastSymbolExtent[3].x = m_lastSymbolExtent[0].x;
        m_lastSymbolExtent[1].y = m_lastSymbolExtent[2].y = m_lastSymbolExtent[3].y = m_lastSymbolExtent[0].y;
    }
}
Пример #4
0
///////////////////////////////////////////////////////////////////////////////
// Called when applying a point style on a feature geometry.  Point styles can
// be applied to all feature geometry types.
void SE_Renderer::ProcessPoint(SE_ApplyContext* ctx, SE_RenderPointStyle* style, RS_Bounds* bounds)
{
    // the feature geometry we're applying the style on...
    LineBuffer* featGeom = ctx->geometry;

    double angleRad = 0.0;
    if (style->angleControl == SE_AngleControl_FromGeometry)
    {
        switch (featGeom->geom_type())
        {
            case GeometryType_LineString:
            case GeometryType_MultiLineString:
            case GeometryType_Polygon:
            case GeometryType_MultiPolygon:
            {
                double x0, y0;
                featGeom->Centroid(LineBuffer::ctLine, &x0, &y0, &angleRad);
                break;
            }
        }
    }

    angleRad += style->angleRad;

    // also account for any viewport rotation
    angleRad += GetWorldToScreenRotation();

    SE_Matrix xform;
    bool yUp = YPointsUp();

    // see StylizationEngine::Stylize for a detailed explanation of these transforms
    SE_Matrix xformbase;
    xformbase.translate(style->offset[0], style->offset[1]);
    xformbase.rotate(yUp? angleRad : -angleRad);
    xformbase.premultiply(*ctx->xform);

    // render the points
    for (int i=0; i<featGeom->point_count(); ++i)
    {
        double x, y;
        featGeom->get_point(i, x, y);

        // transform to screen space - feature geometry is in [the original] mapping space
        WorldToScreenPoint(x, y, x, y);

        xform = xformbase;
        xform.translate(x, y);

        if (style->drawLast)
            AddLabel(featGeom, style, xform, angleRad);
        else
            DrawSymbol(style->symbol, xform, angleRad, style->addToExclusionRegion);
    }

    if (bounds)
    {
        // get the symbol bounds after applying the transforms
        bounds->minx = bounds->miny = +DBL_MAX;
        bounds->maxx = bounds->maxy = -DBL_MAX;
        for (int i=0; i<4; ++i)
        {
            RS_F_Point xfpt;
            xformbase.transform(style->bounds[i].x, style->bounds[i].y, xfpt.x, xfpt.y);
            bounds->add_point(xfpt);
        }
    }
}
void SE_PositioningAlgorithms::EightSurrounding(SE_ApplyContext* applyCtx,
                                                SE_RenderStyle*  rstyle,
                                                double           mm2su)
{
    SE_Renderer* se_renderer = applyCtx->renderer;
    LineBuffer* geometry = applyCtx->geometry;

    // eight surrounding labeling only applies to point feature geometry
    switch (geometry->geom_type())
    {
        case GeometryType_Point:
        case GeometryType_MultiPoint:
            break;

        default:
            return;
    }

    // eight surrounding labeling only works with point styles
    if (rstyle->type != SE_RenderStyle_Point)
        return;

    // the style needs to contain at least one primitive
    SE_RenderPrimitiveList& prims = rstyle->symbol;
    if (prims.size() == 0)
        return;

    SE_RenderPointStyle* rpstyle = (SE_RenderPointStyle*)rstyle;

    // get actual feature point and transform to screen space
    // TODO: in the case of a multi-point feature we get the average of all the points;
    //       generating candidate labels around this point doesn't make a whole lot of
    //       sense
    double cx = 0.0;
    double cy = 0.0;
    geometry->Centroid(LineBuffer::ctPoint, &cx, &cy, NULL);

    // don't add a label if we can't compute the centroid
    if (_isnan(cx) || _isnan(cy))
        return;

    se_renderer->WorldToScreenPoint(cx, cy, cx, cy);

    // Get the extent of the last drawn point symbol so that we know how much to offset
    // the label.  This call assumes the symbol draws right before the label.
    // TODO: remove this assumption
    const RS_F_Point* cfpts = se_renderer->GetLastSymbolExtent();
    RS_F_Point fpts[4];
    if(cfpts[0].x == 0 && cfpts[0].y == 0 &&
        cfpts[1].x == 0 && cfpts[1].y == 0 &&
        cfpts[2].x == 0 && cfpts[2].y == 0 &&
        cfpts[3].x == 0 && cfpts[3].y == 0)
    {
        for (int i=0; i<4; ++i)
        {
            fpts[i].x = cx;
            fpts[i].y = cy;
        }
    }
    else
        memcpy(fpts, cfpts, 4*sizeof(RS_F_Point));

    double dx = fpts[1].x - fpts[0].x;
    double dy = fpts[1].y - fpts[0].y;
    double symbol_rot_rad = atan2(dy, dx);

    // factor out position and rotation
    SE_Matrix ixform;
    ixform.translate(-cx, -cy);     // factor out point position
    ixform.rotate(-symbol_rot_rad); // factor out rotation
    for (int i=0; i<4; ++i)
        ixform.transform(fpts[i].x, fpts[i].y);

    bool yUp = se_renderer->YPointsUp();
    if (!yUp)
        symbol_rot_rad = -symbol_rot_rad;

    // unrotated bounds
    RS_Bounds symbol_bounds(fpts[0].x, fpts[0].y, fpts[2].x, fpts[2].y);
    double symbol_width  = symbol_bounds.width();   // symbol width in screen units
    double symbol_height = symbol_bounds.height();  // symbol height in screen units

    // offset the label from the symbol's edge
    double offset = POINT_LABEL_OFFSET_MM * mm2su;  // offset in screen units

    // make sure we have at least one pixel's worth of offset
    double screenUnitsPerPixel = MILLIMETERS_PER_INCH * se_renderer->GetScreenUnitsPerMillimeterDevice() / se_renderer->GetDpi();
    if (offset < screenUnitsPerPixel)
        offset = screenUnitsPerPixel;

    // compute how far label needs to be offset from center point of symbol
    double w2 = 0.5 * symbol_width;
    double h2 = 0.5 * symbol_height;
    double ch = 0.0;    // vertical center point
    double cw = 0.0;    // horizontal center point

    w2 += offset;
    h2 += offset;

    bool useBounds = symbol_bounds.IsValid();
    if (useBounds)
    {
        symbol_bounds.maxx += offset;    symbol_bounds.maxy += offset;
        symbol_bounds.minx -= offset;    symbol_bounds.miny -= offset;
        ch = 0.5*(symbol_bounds.maxy + symbol_bounds.miny);
        cw = 0.5*(symbol_bounds.maxx + symbol_bounds.minx);
    }

    // get the viewport rotation
    double w2sAngleRad = se_renderer->GetWorldToScreenRotation();

    // take into account rotation of the symbol - find increased extents
    // of the symbol bounds due to the rotation
    double op_pts[16];
    if (symbol_rot_rad != 0.0)
    {
        double cs = cos(symbol_rot_rad);
        double sn = sin(symbol_rot_rad);

        // check to see if the bounds have been set
        double wcs, nwcs, wsn, nwsn, hsn, nhsn, hcs, nhcs, cwsn, cwcs, chsn, chcs;
        if (useBounds)
        {
            wcs = symbol_bounds.maxx * cs;   nwcs = symbol_bounds.minx * cs;
            wsn = symbol_bounds.maxx * sn;   nwsn = symbol_bounds.minx * sn;
            hsn = symbol_bounds.maxy * sn;   nhsn = symbol_bounds.miny * sn;
            hcs = symbol_bounds.maxy * cs;   nhcs = symbol_bounds.miny * cs;
        }
        else
        {
            wcs = w2 * cs;   nwcs = -wcs;
            wsn = w2 * sn;   nwsn = -wsn;
            hsn = h2 * sn;   nhsn = -hsn;
            hcs = h2 * cs;   nhcs = -hcs;
        }

        cwsn = cw * sn;     chsn = ch * sn;
        cwcs = cw * cs;     chcs = ch * cs;

        // Find the octant that the symbol is rotated into, and shift the points accordingly.
        // This way the overpost points are still within 22.5 degrees of an axis-aligned box
        // (position 0 will always be the closest to Center-Right).
        // NOTE: The symbol rotation includes the viewport rotation.  We want to use the
        //       relative angle between these to compute the quadrant (it's the angle of
        //       the symbol relative to the viewport which matters).
        double relativeAngle = symbol_rot_rad - w2sAngleRad;
        double nangle = fmod(relativeAngle * M_180PI, 360.0);
        if (nangle < 0.0)
            nangle += 360.0;
        int i = (((int)((nangle/45.0) + 0.5)) << 1) & 0x0000000f; // i is 2 * the octant
        op_pts[i++] =  wcs - chsn;  op_pts[i++] =  wsn + chcs;  i &= 0x0000000f; // & 15 does (mod 16)
        op_pts[i++] =  wcs -  hsn;  op_pts[i++] =  wsn +  hcs;  i &= 0x0000000f;
        op_pts[i++] = cwcs -  hsn;  op_pts[i++] = cwsn +  hcs;  i &= 0x0000000f;
        op_pts[i++] = nwcs -  hsn;  op_pts[i++] = nwsn +  hcs;  i &= 0x0000000f;
        op_pts[i++] = nwcs - chsn;  op_pts[i++] = nwsn + chcs;  i &= 0x0000000f;
        op_pts[i++] = nwcs - nhsn;  op_pts[i++] = nwsn + nhcs;  i &= 0x0000000f;
        op_pts[i++] = cwcs - nhsn;  op_pts[i++] = cwsn + nhcs;  i &= 0x0000000f;
        op_pts[i++] =  wcs - nhsn;  op_pts[i  ] =  wsn + nhcs;
    }
    else
    {
        if (!useBounds)
        {
            symbol_bounds.maxx = w2; symbol_bounds.minx = -w2;
            symbol_bounds.maxy = h2; symbol_bounds.miny = -h2;
        }
        op_pts[0 ] = symbol_bounds.maxx; op_pts[1 ] = ch;
        op_pts[2 ] = symbol_bounds.maxx; op_pts[3 ] = symbol_bounds.maxy;
        op_pts[4 ] = cw;                 op_pts[5 ] = symbol_bounds.maxy;
        op_pts[6 ] = symbol_bounds.minx; op_pts[7 ] = symbol_bounds.maxy;
        op_pts[8 ] = symbol_bounds.minx; op_pts[9 ] = ch;
        op_pts[10] = symbol_bounds.minx; op_pts[11] = symbol_bounds.miny;
        op_pts[12] = cw;                 op_pts[13] = symbol_bounds.miny;
        op_pts[14] = symbol_bounds.maxx; op_pts[15] = symbol_bounds.miny;
    }

    // check if the incoming point style contains just a single text element
    bool foundSingleText = false;
    if (prims.size() == 1)
    {
        if (prims[0]->type == SE_RenderPrimitive_Text)
            foundSingleText = true;
    }

    // OK, who says I can't write bad code? Behold:
    SE_LabelInfo candidates[8];
    double yScale = yUp? 1.0 : -1.0; // which way does y go in the renderer?

    double angleRad = rpstyle->angleRad;

    // also account for the viewport rotation
    angleRad += w2sAngleRad;

    if (foundSingleText)
    {
        // In this case we set the appropriate alignments for the single text element
        // in each candidate label.  This allows us to draw the symbol directly at the
        // candidate points surrounding the feature point.

        SE_RenderStyle* st0 = se_renderer->CloneRenderStyle(rpstyle);
        ((SE_RenderText*)st0->symbol[0])->tdef.halign() = RS_HAlignment_Left;
        ((SE_RenderText*)st0->symbol[0])->tdef.valign() = RS_VAlignment_Half;
        UpdateStyleBounds(st0, se_renderer);
        candidates[0].Set(cx + op_pts[ 0], cy + op_pts[ 1]*yScale, RS_Units_Device, angleRad, st0);

        SE_RenderStyle* st1 = se_renderer->CloneRenderStyle(st0);
        ((SE_RenderText*)st1->symbol[0])->tdef.valign() = RS_VAlignment_Descent;
        UpdateStyleBounds(st1, se_renderer);
        candidates[1].Set(cx + op_pts[ 2], cy + op_pts[ 3]*yScale, RS_Units_Device, angleRad, st1);

        SE_RenderStyle* st2 = se_renderer->CloneRenderStyle(st1);
        ((SE_RenderText*)st2->symbol[0])->tdef.halign() = RS_HAlignment_Center;
        UpdateStyleBounds(st2, se_renderer);
        candidates[2].Set(cx + op_pts[ 4], cy + op_pts[ 5]*yScale, RS_Units_Device, angleRad, st2);

        SE_RenderStyle* st3 = se_renderer->CloneRenderStyle(st2);
        ((SE_RenderText*)st3->symbol[0])->tdef.halign() = RS_HAlignment_Right;
        UpdateStyleBounds(st3, se_renderer);
        candidates[3].Set(cx + op_pts[ 6], cy + op_pts[ 7]*yScale, RS_Units_Device, angleRad, st3);

        SE_RenderStyle* st4 = se_renderer->CloneRenderStyle(st3);
        ((SE_RenderText*)st4->symbol[0])->tdef.valign() = RS_VAlignment_Half;
        UpdateStyleBounds(st4, se_renderer);
        candidates[4].Set(cx + op_pts[ 8], cy + op_pts[ 9]*yScale, RS_Units_Device, angleRad, st4);

        SE_RenderStyle* st5 = se_renderer->CloneRenderStyle(st4);
        ((SE_RenderText*)st5->symbol[0])->tdef.valign() = RS_VAlignment_Ascent;
        UpdateStyleBounds(st5, se_renderer);
        candidates[5].Set(cx + op_pts[10], cy + op_pts[11]*yScale, RS_Units_Device, angleRad, st5);

        SE_RenderStyle* st6 = se_renderer->CloneRenderStyle(st5);
        ((SE_RenderText*)st6->symbol[0])->tdef.halign() = RS_HAlignment_Center;
        UpdateStyleBounds(st6, se_renderer);
        candidates[6].Set(cx + op_pts[12], cy + op_pts[13]*yScale, RS_Units_Device, angleRad, st6);

        SE_RenderStyle* st7 = se_renderer->CloneRenderStyle(st6);
        ((SE_RenderText*)st7->symbol[0])->tdef.halign() = RS_HAlignment_Left;
        UpdateStyleBounds(st7, se_renderer);
        candidates[7].Set(cx + op_pts[14], cy + op_pts[15]*yScale, RS_Units_Device, angleRad, st7);
    }
    else
    {
        // In the general case we have to account for the label symbol's extents when we
        // position each candidate.  For example, for candidate 1 (top right) we adjust the
        // position so that the bottom left corner of the label symbol's extent ends up at
        // the top right candidate point.

        double labelMinX = rpstyle->bounds[0].x;
        double labelMinY = rpstyle->bounds[0].y;
        double labelMaxX = rpstyle->bounds[2].x;
        double labelMaxY = rpstyle->bounds[2].y;
        double labelCtrX = 0.5*(labelMinX + labelMaxX);
        double labelCtrY = 0.5*(labelMinY + labelMaxY);

        SE_RenderStyle* st0 = se_renderer->CloneRenderStyle(rpstyle);
        candidates[0].Set(cx + op_pts[ 0] - labelMinX, cy + (op_pts[ 1] - labelCtrY)*yScale, RS_Units_Device, angleRad, st0);

        SE_RenderStyle* st1 = se_renderer->CloneRenderStyle(st0);
        candidates[1].Set(cx + op_pts[ 2] - labelMinX, cy + (op_pts[ 3] - labelMinY)*yScale, RS_Units_Device, angleRad, st1);

        SE_RenderStyle* st2 = se_renderer->CloneRenderStyle(st1);
        candidates[2].Set(cx + op_pts[ 4] - labelCtrX, cy + (op_pts[ 5] - labelMinY)*yScale, RS_Units_Device, angleRad, st2);

        SE_RenderStyle* st3 = se_renderer->CloneRenderStyle(st2);
        candidates[3].Set(cx + op_pts[ 6] - labelMaxX, cy + (op_pts[ 7] - labelMinY)*yScale, RS_Units_Device, angleRad, st3);

        SE_RenderStyle* st4 = se_renderer->CloneRenderStyle(st3);
        candidates[4].Set(cx + op_pts[ 8] - labelMaxX, cy + (op_pts[ 9] - labelCtrY)*yScale, RS_Units_Device, angleRad, st4);

        SE_RenderStyle* st5 = se_renderer->CloneRenderStyle(st4);
        candidates[5].Set(cx + op_pts[10] - labelMaxX, cy + (op_pts[11] - labelMaxY)*yScale, RS_Units_Device, angleRad, st5);

        SE_RenderStyle* st6 = se_renderer->CloneRenderStyle(st5);
        candidates[6].Set(cx + op_pts[12] - labelCtrX, cy + (op_pts[13] - labelMaxY)*yScale, RS_Units_Device, angleRad, st6);

        SE_RenderStyle* st7 = se_renderer->CloneRenderStyle(st6);
        candidates[7].Set(cx + op_pts[14] - labelMinX, cy + (op_pts[15] - labelMaxY)*yScale, RS_Units_Device, angleRad, st7);
    }

    se_renderer->ProcessSELabelGroup(candidates, 8, RS_OverpostType_FirstFit, true, NULL);
}