/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- * * The contents of this file are subject to the Netscape Public License * Version 1.0 (the "NPL"); you may not use this file except in * compliance with the NPL. You may obtain a copy of the NPL at * http://www.mozilla.org/NPL/ * * Software distributed under the NPL is distributed on an "AS IS" basis, * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the NPL * for the specific language governing rights and limitations under the * NPL. * * The Initial Developer of this code under the NPL is Netscape * Communications Corporation. Portions created by Netscape are * Copyright (C) 1998 Netscape Communications Corporation. All Rights * Reserved. */ #include "nsCSSRendering.h" #include "nsStyleConsts.h" #include "nsIPresContext.h" #include "nsIImage.h" #include "nsIFrame.h" #include "nsPoint.h" #include "nsRect.h" #include "nsIViewManager.h" #include "nsIPresShell.h" #include "nsIFrameImageLoader.h" #include "nsIStyleContext.h" #include "nsGlobalVariables.h" #define BORDER_FULL 0 //entire side #define BORDER_INSIDE 1 //inside half #define BORDER_OUTSIDE 2 //outside half //thickness of dashed line relative to dotted line #define DOT_LENGTH 1 //square #define DASH_LENGTH 3 //3 times longer than dot // Draw a line, skipping that portion which crosses aGap. aGap defines a rectangle gap // This services fieldset legends and only works for coords defining horizontal lines. void nsCSSRendering::DrawLine (nsIRenderingContext& aContext, nscoord aX1, nscoord aY1, nscoord aX2, nscoord aY2, nsRect* aGap) { if (nsnull == aGap) { aContext.DrawLine(aX1, aY1, aX2, aY2); } else { nscoord x1 = (aX1 < aX2) ? aX1 : aX2; nscoord x2 = (aX1 < aX2) ? aX2 : aX1; nsPoint gapUpperRight(aGap->x + aGap->width, aGap->y); nsPoint gapLowerRight(aGap->x + aGap->width, aGap->y + aGap->height); if ((aGap->y <= aY1) && (gapLowerRight.y >= aY2)) { if ((aGap->x > x1) && (aGap->x < x2)) { aContext.DrawLine(x1, aY1, aGap->x, aY1); } if ((gapLowerRight.x > x1) && (gapLowerRight.x < x2)) { aContext.DrawLine(gapUpperRight.x, aY2, x2, aY2); } } else { aContext.DrawLine(aX1, aY1, aX2, aY2); } } } // Fill a polygon, skipping that portion which crosses aGap. aGap defines a rectangle gap // This services fieldset legends and only works for points defining a horizontal rectangle void nsCSSRendering::FillPolygon (nsIRenderingContext& aContext, const nsPoint aPoints[], PRInt32 aNumPoints, nsRect* aGap) { if (nsnull == aGap) { aContext.FillPolygon(aPoints, aNumPoints); } else if (4 == aNumPoints) { nsPoint gapUpperRight(aGap->x + aGap->width, aGap->y); nsPoint gapLowerRight(aGap->x + aGap->width, aGap->y + aGap->height); // sort the 4 points by x nsPoint points[4]; for (PRInt32 pX = 0; pX < 4; pX++) { points[pX] = aPoints[pX]; } for (PRInt32 i = 0; i < 3; i++) { for (PRInt32 j = i+1; j < 4; j++) { if (points[j].x < points[i].x) { nsPoint swap = points[i]; points[i] = points[j]; points[j] = swap; } } } nsPoint upperLeft = (points[0].y <= points[1].y) ? points[0] : points[1]; nsPoint lowerLeft = (points[0].y <= points[1].y) ? points[1] : points[0]; nsPoint upperRight = (points[2].y <= points[3].y) ? points[2] : points[3]; nsPoint lowerRight = (points[2].y <= points[3].y) ? points[3] : points[2]; if ((aGap->y <= upperLeft.y) && (gapLowerRight.y >= lowerRight.y)) { if ((aGap->x > upperLeft.x) && (aGap->x < upperRight.x)) { nsPoint leftRect[4]; leftRect[0] = upperLeft; leftRect[1] = nsPoint(aGap->x, upperLeft.y); leftRect[2] = nsPoint(aGap->x, lowerLeft.y); leftRect[3] = lowerLeft; aContext.FillPolygon(leftRect, 4); } if ((gapUpperRight.x > upperLeft.x) && (gapUpperRight.x < upperRight.x)) { nsPoint rightRect[4]; rightRect[0] = nsPoint(gapUpperRight.x, upperRight.y); rightRect[1] = upperRight; rightRect[2] = lowerRight; rightRect[3] = nsPoint(gapLowerRight.x, lowerRight.y); aContext.FillPolygon(rightRect, 4); } } else { aContext.FillPolygon(aPoints, aNumPoints); } } } /** * Make a bevel color */ nscolor nsCSSRendering::MakeBevelColor(PRIntn whichSide, PRUint8 style, nscolor baseColor, PRBool printing) { PRBool blackLines = nsGlobalVariables::Instance()->GetBlackLines(); nscolor colors[2]; nscolor theColor; // Get the background color that applies to this HR if (printing && blackLines) { colors[0] = NS_RGB(0,0,0); colors[1] = colors[0]; } else { // Given a background color and a border color // calculate the color used for the shading NS_Get3DColors(colors, baseColor); } if ((style == NS_STYLE_BORDER_STYLE_OUTSET) || (style == NS_STYLE_BORDER_STYLE_RIDGE)) { // Flip colors for these two border style switch (whichSide) { case NS_SIDE_BOTTOM: whichSide = NS_SIDE_TOP; break; case NS_SIDE_RIGHT: whichSide = NS_SIDE_LEFT; break; case NS_SIDE_TOP: whichSide = NS_SIDE_BOTTOM; break; case NS_SIDE_LEFT: whichSide = NS_SIDE_RIGHT; break; } } switch (whichSide) { case NS_SIDE_BOTTOM: theColor = colors[1]; break; case NS_SIDE_RIGHT: theColor = colors[1]; break; case NS_SIDE_TOP: theColor = colors[0]; break; case NS_SIDE_LEFT: theColor = colors[0]; break; } return theColor; } // Maximum poly points in any of the polygons we generate below #define MAX_POLY_POINTS 4 // a nifty helper function to create a polygon representing a // particular side of a border. This helps localize code for figuring // mitered edges. It is mainly used by the solid, inset, and outset // styles. // // If the side can be represented as a line segment (because the thickness // is one pixel), then a line with two endpoints is returned PRIntn nsCSSRendering::MakeSide(nsPoint aPoints[], nsIRenderingContext& aContext, PRIntn whichSide, const nsRect& outside, const nsRect& inside, PRIntn borderPart, float borderFrac, nscoord twipsPerPixel) { float borderRest = 1.0f - borderFrac; // XXX QQQ We really should decide to do a bevel based on whether there // is a side adjacent or not. This could let you join borders across // block elements (paragraphs). PRIntn np = 0; nscoord thickness; // Base our thickness check on the segment being less than a pixel and 1/2 twipsPerPixel += twipsPerPixel >> 2; switch (whichSide) { case NS_SIDE_TOP: if (borderPart == BORDER_FULL) { thickness = inside.y - outside.y; aPoints[np++].MoveTo(outside.x, outside.y); aPoints[np++].MoveTo(outside.XMost(), outside.y); if (thickness >= twipsPerPixel) { aPoints[np++].MoveTo(inside.XMost(), inside.y); aPoints[np++].MoveTo(inside.x, inside.y); } } else if (borderPart == BORDER_INSIDE) { aPoints[np++].MoveTo(nscoord(outside.x * borderFrac + inside.x * borderRest), nscoord(outside.y * borderFrac + inside.y * borderRest)); aPoints[np++].MoveTo(nscoord(outside.XMost() * borderFrac + inside.XMost() * borderRest), nscoord(outside.y * borderFrac + inside.y * borderRest)); aPoints[np++].MoveTo(inside.XMost(), inside.y); aPoints[np++].MoveTo(inside.x, inside.y); } else { aPoints[np++].MoveTo(outside.x, outside.y); aPoints[np++].MoveTo(outside.XMost(), outside.y); aPoints[np++].MoveTo(nscoord(inside.XMost() * borderFrac + outside.XMost() * borderRest), nscoord(inside.y * borderFrac + outside.y * borderRest)); aPoints[np++].MoveTo(nscoord(inside.x * borderFrac + outside.x * borderRest), nscoord(inside.y * borderFrac + outside.y * borderRest)); } break; case NS_SIDE_LEFT: if (borderPart == BORDER_FULL) { thickness = inside.x - outside.x; aPoints[np++].MoveTo(outside.x, outside.y); if (thickness >= twipsPerPixel) { aPoints[np++].MoveTo(inside.x, inside.y); aPoints[np++].MoveTo(inside.x, inside.YMost()); } aPoints[np++].MoveTo(outside.x, outside.YMost()); } else if (borderPart == BORDER_INSIDE) { aPoints[np++].MoveTo(nscoord(outside.x * borderFrac + inside.x * borderRest), nscoord(outside.y * borderFrac + inside.y * borderRest)); aPoints[np++].MoveTo(inside.x, inside.y); aPoints[np++].MoveTo(inside.x, inside.YMost()); aPoints[np++].MoveTo(nscoord(outside.x * borderFrac + inside.x * borderRest), nscoord(outside.YMost() * borderFrac + inside.YMost() * borderRest)); } else { aPoints[np++].MoveTo(outside.x, outside.y); aPoints[np++].MoveTo(nscoord(inside.x * borderFrac + outside.x * borderRest), nscoord(inside.y * borderFrac + outside.y * borderRest)); aPoints[np++].MoveTo(nscoord(inside.x * borderFrac + outside.x * borderRest), nscoord(inside.YMost() * borderFrac + outside.YMost() * borderRest)); aPoints[np++].MoveTo(outside.x, outside.YMost()); } break; case NS_SIDE_BOTTOM: if (borderPart == BORDER_FULL) { thickness = outside.YMost() - inside.YMost(); if (thickness >= twipsPerPixel) { aPoints[np++].MoveTo(outside.x, outside.YMost()); aPoints[np++].MoveTo(inside.x, inside.YMost()); aPoints[np++].MoveTo(inside.XMost(), inside.YMost()); aPoints[np++].MoveTo(outside.XMost(), outside.YMost()); } else { aPoints[np++].MoveTo(outside.x, inside.YMost()); aPoints[np++].MoveTo(outside.XMost(), inside.YMost()); } } else if (borderPart == BORDER_INSIDE) { aPoints[np++].MoveTo(nscoord(outside.x * borderFrac + inside.x * borderRest), nscoord(outside.YMost() * borderFrac + inside.YMost() * borderRest)); aPoints[np++].MoveTo(inside.x, inside.YMost()); aPoints[np++].MoveTo(inside.XMost(), inside.YMost()); aPoints[np++].MoveTo(nscoord(outside.XMost() * borderFrac + inside.XMost() * borderRest), nscoord(outside.YMost() * borderFrac + inside.YMost() * borderRest)); } else { aPoints[np++].MoveTo(outside.x, outside.YMost()); aPoints[np++].MoveTo(nscoord(inside.x * borderFrac + outside.x * borderRest), nscoord(inside.YMost() * borderFrac + outside.YMost() * borderRest)); aPoints[np++].MoveTo(nscoord(inside.XMost() * borderFrac + outside.XMost() * borderRest), nscoord(inside.YMost() * borderFrac + outside.YMost() * borderRest)); aPoints[np++].MoveTo(outside.XMost(), outside.YMost()); } break; case NS_SIDE_RIGHT: if (borderPart == BORDER_FULL) { thickness = outside.XMost() - inside.XMost(); if (thickness >= twipsPerPixel) { aPoints[np++].MoveTo(outside.XMost(), outside.YMost()); aPoints[np++].MoveTo(outside.XMost(), outside.y); } aPoints[np++].MoveTo(inside.XMost(), inside.y); aPoints[np++].MoveTo(inside.XMost(), inside.YMost()); } else if (borderPart == BORDER_INSIDE) { aPoints[np++].MoveTo(inside.XMost(), inside.y); aPoints[np++].MoveTo(nscoord(outside.XMost() * borderFrac + inside.XMost() * borderRest), nscoord(outside.y * borderFrac + inside.y * borderRest)); aPoints[np++].MoveTo(nscoord(outside.XMost() * borderFrac + inside.XMost() * borderRest), nscoord(outside.YMost() * borderFrac + inside.YMost() * borderRest)); aPoints[np++].MoveTo(inside.XMost(), inside.YMost()); } else { aPoints[np++].MoveTo(nscoord(inside.XMost() * borderFrac + outside.XMost() * borderRest), nscoord(inside.y * borderFrac + outside.y * borderRest)); aPoints[np++].MoveTo(outside.XMost(), outside.y); aPoints[np++].MoveTo(outside.XMost(), outside.YMost()); aPoints[np++].MoveTo(nscoord(inside.XMost() * borderFrac + outside.XMost() * borderRest), nscoord(inside.YMost() * borderFrac + outside.YMost() * borderRest)); } break; } return np; } void nsCSSRendering::DrawSide(nsIRenderingContext& aContext, PRIntn whichSide, const PRUint8 borderStyle, const nscolor borderColor, const nsRect& borderOutside, const nsRect& borderInside, PRBool printing, nscoord twipsPerPixel, nsRect* aGap) { nsPoint theSide[MAX_POLY_POINTS]; nscolor theColor = borderColor; PRUint8 theStyle = borderStyle; PRInt32 np; switch (theStyle) { case NS_STYLE_BORDER_STYLE_NONE: case NS_STYLE_BORDER_STYLE_BLANK: return; case NS_STYLE_BORDER_STYLE_DOTTED: //handled a special case elsewhere case NS_STYLE_BORDER_STYLE_DASHED: //handled a special case elsewhere break; // That was easy... case NS_STYLE_BORDER_STYLE_GROOVE: case NS_STYLE_BORDER_STYLE_RIDGE: np = MakeSide (theSide, aContext, whichSide, borderOutside, borderInside, BORDER_INSIDE, 0.5f, twipsPerPixel); aContext.SetColor ( MakeBevelColor (whichSide, ((theStyle == NS_STYLE_BORDER_STYLE_RIDGE) ? NS_STYLE_BORDER_STYLE_GROOVE : NS_STYLE_BORDER_STYLE_RIDGE), theColor, printing)); if (2 == np) { //aContext.DrawLine (theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y); DrawLine (aContext, theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y, aGap); } else { //aContext.FillPolygon (theSide, np); FillPolygon (aContext, theSide, np, aGap); } np = MakeSide (theSide, aContext, whichSide, borderOutside, borderInside, BORDER_OUTSIDE, 0.5f, twipsPerPixel); aContext.SetColor ( MakeBevelColor (whichSide, theStyle, theColor,printing)); if (2 == np) { //aContext.DrawLine (theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y); DrawLine (aContext, theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y, aGap); } else { //aContext.FillPolygon (theSide, np); FillPolygon (aContext, theSide, np, aGap); } break; case NS_STYLE_BORDER_STYLE_SOLID: np = MakeSide (theSide, aContext, whichSide, borderOutside, borderInside, BORDER_FULL, 1.0f, twipsPerPixel); aContext.SetColor (borderColor); if (2 == np) { //aContext.DrawLine (theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y); DrawLine (aContext, theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y, aGap); } else { //aContext.FillPolygon (theSide, np); FillPolygon (aContext, theSide, np, aGap); } break; case NS_STYLE_BORDER_STYLE_DOUBLE: np = MakeSide (theSide, aContext, whichSide, borderOutside, borderInside, BORDER_INSIDE, 0.333333f, twipsPerPixel); aContext.SetColor (borderColor); if (2 == np) { //aContext.DrawLine (theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y); DrawLine (aContext, theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y, aGap); } else { //aContext.FillPolygon (theSide, np); FillPolygon (aContext, theSide, np, aGap); } np = MakeSide (theSide, aContext, whichSide, borderOutside, borderInside, BORDER_OUTSIDE, 0.333333f, twipsPerPixel); if (2 == np) { //aContext.DrawLine (theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y); DrawLine (aContext, theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y, aGap); } else { //aContext.FillPolygon (theSide, np); FillPolygon (aContext, theSide, np, aGap); } break; case NS_STYLE_BORDER_STYLE_OUTSET: case NS_STYLE_BORDER_STYLE_INSET: np = MakeSide (theSide, aContext, whichSide, borderOutside, borderInside, BORDER_FULL, 1.0f, twipsPerPixel); aContext.SetColor ( MakeBevelColor (whichSide, theStyle, theColor,printing)); if (2 == np) { //aContext.DrawLine (theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y); DrawLine (aContext, theSide[0].x, theSide[0].y, theSide[1].x, theSide[1].y, aGap); } else { //aContext.FillPolygon (theSide, np); FillPolygon (aContext, theSide, np, aGap); } break; } } /** * Draw a dotted/dashed sides of a box */ //XXX dashes which span more than two edges are not handled properly MMP void nsCSSRendering::DrawDashedSides(PRIntn startSide, nsIRenderingContext& aContext, const PRUint8 borderStyles[], const nscolor borderColors[], const nsRect& borderOutside, const nsRect& borderInside, PRIntn aSkipSides, nsRect* aGap) { PRIntn dashLength; nsRect dashRect, firstRect, currRect; PRBool bSolid = PR_TRUE; float over = 0.0f; PRUint8 style = borderStyles[startSide]; PRBool skippedSide = PR_FALSE; for (PRIntn whichSide = startSide; whichSide < 4; whichSide++) { PRUint8 prevStyle = style; style = borderStyles[whichSide]; if ((1< 0.0f) { firstRect.x = dashRect.x; firstRect.width = dashRect.width; firstRect.height = nscoord(dashRect.height * over); firstRect.y = dashRect.y + (dashRect.height - firstRect.height); over = 0.0f; currRect = firstRect; } else { currRect = dashRect; } while (currRect.YMost() > borderInside.y) { //clip if necessary if (currRect.y < borderInside.y) { over = float(borderInside.y - dashRect.y) / float(dashRect.height); currRect.height = currRect.height - (borderInside.y - currRect.y); currRect.y = borderInside.y; } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.y = dashRect.y - currRect.height; currRect = dashRect; } break; case NS_SIDE_TOP: //if we are continuing a solid rect, fill in the corner first if (bSolid) { aContext.FillRect(borderOutside.x, borderOutside.y, borderInside.x - borderOutside.x, borderInside.y - borderOutside.y); } dashRect.height = borderInside.y - borderOutside.y; dashRect.width = dashRect.height * dashLength; dashRect.x = borderInside.x; dashRect.y = borderOutside.y; if (over > 0.0f) { firstRect.x = dashRect.x; firstRect.y = dashRect.y; firstRect.width = nscoord(dashRect.width * over); firstRect.height = dashRect.height; over = 0.0f; currRect = firstRect; } else { currRect = dashRect; } while (currRect.x < borderInside.XMost()) { //clip if necessary if (currRect.XMost() > borderInside.XMost()) { over = float(dashRect.XMost() - borderInside.XMost()) / float(dashRect.width); currRect.width = currRect.width - (currRect.XMost() - borderInside.XMost()); } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.x = dashRect.x + currRect.width; currRect = dashRect; } break; case NS_SIDE_RIGHT: //if we are continuing a solid rect, fill in the corner first if (bSolid) { aContext.FillRect(borderInside.XMost(), borderOutside.y, borderOutside.XMost() - borderInside.XMost(), borderInside.y - borderOutside.y); } dashRect.width = borderOutside.XMost() - borderInside.XMost(); dashRect.height = nscoord(dashRect.width * dashLength); dashRect.x = borderInside.XMost(); dashRect.y = borderInside.y; if (over > 0.0f) { firstRect.x = dashRect.x; firstRect.y = dashRect.y; firstRect.width = dashRect.width; firstRect.height = nscoord(dashRect.height * over); over = 0.0f; currRect = firstRect; } else { currRect = dashRect; } while (currRect.y < borderInside.YMost()) { //clip if necessary if (currRect.YMost() > borderInside.YMost()) { over = float(dashRect.YMost() - borderInside.YMost()) / float(dashRect.height); currRect.height = currRect.height - (currRect.YMost() - borderInside.YMost()); } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.y = dashRect.y + currRect.height; currRect = dashRect; } break; case NS_SIDE_BOTTOM: //if we are continuing a solid rect, fill in the corner first if (bSolid) { aContext.FillRect(borderInside.XMost(), borderInside.YMost(), borderOutside.XMost() - borderInside.XMost(), borderOutside.YMost() - borderInside.YMost()); } dashRect.height = borderOutside.YMost() - borderInside.YMost(); dashRect.width = nscoord(dashRect.height * dashLength); dashRect.x = borderInside.XMost() - dashRect.width; dashRect.y = borderInside.YMost(); if (over > 0.0f) { firstRect.y = dashRect.y; firstRect.width = nscoord(dashRect.width * over); firstRect.height = dashRect.height; firstRect.x = dashRect.x + (dashRect.width - firstRect.width); over = 0.0f; currRect = firstRect; } else { currRect = dashRect; } while (currRect.XMost() > borderInside.x) { //clip if necessary if (currRect.x < borderInside.x) { over = float(borderInside.x - dashRect.x) / float(dashRect.width); currRect.width = currRect.width - (borderInside.x - currRect.x); currRect.x = borderInside.x; } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.x = dashRect.x - currRect.width; currRect = dashRect; } break; } } skippedSide = PR_FALSE; } } void nsCSSRendering::DrawDashedSides(PRIntn startSide, nsIRenderingContext& aContext, const nsStyleSpacing& aSpacing, const nsRect& borderOutside, const nsRect& borderInside, PRIntn aSkipSides, nsRect* aGap) { PRIntn dashLength; nsRect dashRect, firstRect, currRect; PRBool bSolid = PR_TRUE; float over = 0.0f; PRUint8 style = aSpacing.GetBorderStyle(startSide); PRBool skippedSide = PR_FALSE; for (PRIntn whichSide = startSide; whichSide < 4; whichSide++) { PRUint8 prevStyle = style; style = aSpacing.GetBorderStyle(whichSide); if ((1< 0.0f) { firstRect.x = dashRect.x; firstRect.width = dashRect.width; firstRect.height = nscoord(dashRect.height * over); firstRect.y = dashRect.y + (dashRect.height - firstRect.height); over = 0.0f; currRect = firstRect; } else { currRect = dashRect; } while (currRect.YMost() > borderInside.y) { //clip if necessary if (currRect.y < borderInside.y) { over = float(borderInside.y - dashRect.y) / float(dashRect.height); currRect.height = currRect.height - (borderInside.y - currRect.y); currRect.y = borderInside.y; } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.y = dashRect.y - currRect.height; currRect = dashRect; } break; case NS_SIDE_TOP: //if we are continuing a solid rect, fill in the corner first if (bSolid) { aContext.FillRect(borderOutside.x, borderOutside.y, borderInside.x - borderOutside.x, borderInside.y - borderOutside.y); } dashRect.height = borderInside.y - borderOutside.y; dashRect.width = dashRect.height * dashLength; dashRect.x = borderInside.x; dashRect.y = borderOutside.y; if (over > 0.0f) { firstRect.x = dashRect.x; firstRect.y = dashRect.y; firstRect.width = nscoord(dashRect.width * over); firstRect.height = dashRect.height; over = 0.0f; currRect = firstRect; } else { currRect = dashRect; } while (currRect.x < borderInside.XMost()) { //clip if necessary if (currRect.XMost() > borderInside.XMost()) { over = float(dashRect.XMost() - borderInside.XMost()) / float(dashRect.width); currRect.width = currRect.width - (currRect.XMost() - borderInside.XMost()); } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.x = dashRect.x + currRect.width; currRect = dashRect; } break; case NS_SIDE_RIGHT: //if we are continuing a solid rect, fill in the corner first if (bSolid) { aContext.FillRect(borderInside.XMost(), borderOutside.y, borderOutside.XMost() - borderInside.XMost(), borderInside.y - borderOutside.y); } dashRect.width = borderOutside.XMost() - borderInside.XMost(); dashRect.height = nscoord(dashRect.width * dashLength); dashRect.x = borderInside.XMost(); dashRect.y = borderInside.y; if (over > 0.0f) { firstRect.x = dashRect.x; firstRect.y = dashRect.y; firstRect.width = dashRect.width; firstRect.height = nscoord(dashRect.height * over); over = 0.0f; currRect = firstRect; } else { currRect = dashRect; } while (currRect.y < borderInside.YMost()) { //clip if necessary if (currRect.YMost() > borderInside.YMost()) { over = float(dashRect.YMost() - borderInside.YMost()) / float(dashRect.height); currRect.height = currRect.height - (currRect.YMost() - borderInside.YMost()); } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.y = dashRect.y + currRect.height; currRect = dashRect; } break; case NS_SIDE_BOTTOM: //if we are continuing a solid rect, fill in the corner first if (bSolid) { aContext.FillRect(borderInside.XMost(), borderInside.YMost(), borderOutside.XMost() - borderInside.XMost(), borderOutside.YMost() - borderInside.YMost()); } dashRect.height = borderOutside.YMost() - borderInside.YMost(); dashRect.width = nscoord(dashRect.height * dashLength); dashRect.x = borderInside.XMost() - dashRect.width; dashRect.y = borderInside.YMost(); if (over > 0.0f) { firstRect.y = dashRect.y; firstRect.width = nscoord(dashRect.width * over); firstRect.height = dashRect.height; firstRect.x = dashRect.x + (dashRect.width - firstRect.width); over = 0.0f; currRect = firstRect; } else { currRect = dashRect; } while (currRect.XMost() > borderInside.x) { //clip if necessary if (currRect.x < borderInside.x) { over = float(borderInside.x - dashRect.x) / float(dashRect.width); currRect.width = currRect.width - (borderInside.x - currRect.x); currRect.x = borderInside.x; } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.x = dashRect.x - currRect.width; currRect = dashRect; } break; } } skippedSide = PR_FALSE; } } /* draw the portions of the border described in aBorderEdges that are dashed. * a border has 4 edges. Each edge has 1 or more segments. * "inside edges" are drawn differently than "outside edges" so the shared edges will match up. * in the case of table collapsing borders, the table edge is the "outside" edge and * cell edges are always "inside" edges (so adjacent cells have 2 shared "inside" edges.) * There is a case for each of the four sides. Only the left side is well documented. The others * are very similar. */ // XXX: doesn't do corners or junctions well at all. Just uses logic stolen // from DrawDashedSides which is insufficient void nsCSSRendering::DrawDashedSegments(nsIRenderingContext& aContext, const nsRect& aBounds, nsBorderEdges * aBorderEdges, PRIntn aSkipSides, nsRect* aGap) { PRIntn dashLength; nsRect dashRect, firstRect, currRect; PRBool bSolid = PR_TRUE; float over = 0.0f; PRBool skippedSide = PR_FALSE; PRIntn whichSide=0; // do this just to set up initial condition for loop // "segment" is the current portion of the edge we are computing nsBorderEdge * segment = (nsBorderEdge *)(aBorderEdges->mEdges[whichSide].ElementAt(0)); PRUint8 style = segment->mStyle; for ( ; whichSide < 4; whichSide++) { PRUint8 prevStyle = style; if ((1<mEdges[whichSide].Count(); nsBorderEdges * neighborBorderEdges=nsnull; PRIntn neighborEdgeCount=0; // keeps track of which inside neighbor is shared with an outside segment for (i=0; imEdges[whichSide].ElementAt(i)); style = segment->mStyle; // XXX units for dash & dot? if (style == NS_STYLE_BORDER_STYLE_DASHED) { dashLength = DASH_LENGTH; } else { dashLength = DOT_LENGTH; } aContext.SetColor(segment->mColor); switch (whichSide) { case NS_SIDE_LEFT: { // draw left segment i nsBorderEdge * topEdge = (nsBorderEdge *)(aBorderEdges->mEdges[NS_SIDE_TOP].ElementAt(0)); if (0==y) { // y is the offset to the top of this segment. 0 means its the topmost left segment y = aBorderEdges->mMaxBorderWidth.top - topEdge->mWidth; if (PR_TRUE==aBorderEdges->mOutsideEdge) y += topEdge->mWidth; } // the x offset is the x position offset by the max width of the left edge minus this segment's width x = aBounds.x + (aBorderEdges->mMaxBorderWidth.left - segment->mWidth); nscoord height = segment->mLength; // the space between borderOutside and borderInside inclusive is the segment. nsRect borderOutside(x, y, aBounds.width, height); y += segment->mLength; // keep track of the y offset for the next segment if ((style == NS_STYLE_BORDER_STYLE_DASHED) || (style == NS_STYLE_BORDER_STYLE_DOTTED)) { nsRect borderInside(borderOutside); nsMargin outsideMargin(segment->mWidth, 0, 0, 0); borderInside.Deflate(outsideMargin); nscoord totalLength = segment->mLength; // the computed length of this segment // outside edges need info from their inside neighbor. The following code keeps track // of which segment of the inside neighbor's shared edge we should use for this outside segment if (PR_TRUE==aBorderEdges->mOutsideEdge) { if (segment->mInsideNeighbor == neighborBorderEdges) { neighborEdgeCount++; } else { neighborBorderEdges = segment->mInsideNeighbor; neighborEdgeCount=0; } nsBorderEdge * neighborLeft = (nsBorderEdge *)(segment->mInsideNeighbor->mEdges[NS_SIDE_LEFT].ElementAt(neighborEdgeCount)); totalLength = neighborLeft->mLength; } dashRect.width = borderInside.x - borderOutside.x; dashRect.height = nscoord(dashRect.width * dashLength); dashRect.x = borderOutside.x; dashRect.y = borderOutside.y + (totalLength/2) - dashRect.height; if ((PR_TRUE==aBorderEdges->mOutsideEdge) && (0!=i)) dashRect.y -= topEdge->mWidth; // account for the topmost left edge corner with the leftmost top edge if (0) { printf(" L: totalLength = %d, borderOutside.y = %d, midpoint %d, dashRect.y = %d\n", totalLength, borderOutside.y, borderOutside.y +(totalLength/2), dashRect.y); } currRect = dashRect; // we draw the segment in 2 halves to get the inside and outside edges to line up on the // centerline of the shared edge. // draw the top half while (currRect.YMost() > borderInside.y) { //clip if necessary if (currRect.y < borderInside.y) { over = float(borderInside.y - dashRect.y) / float(dashRect.height); currRect.height = currRect.height - (borderInside.y - currRect.y); currRect.y = borderInside.y; } //draw if necessary if (0) { printf("DASHED LEFT: xywh in loop currRect = %d %d %d %d %s\n", currRect.x, currRect.y, currRect.width, currRect.height, bSolid?"TRUE":"FALSE"); } if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.y = dashRect.y - currRect.height; currRect = dashRect; } // draw the bottom half dashRect.y = borderOutside.y + (totalLength/2) + dashRect.height; if ((PR_TRUE==aBorderEdges->mOutsideEdge) && (0!=i)) dashRect.y -= topEdge->mWidth; currRect = dashRect; bSolid=PR_TRUE; over = 0.0f; while (currRect.YMost() < borderInside.YMost()) { //clip if necessary if (currRect.y < borderInside.y) { over = float(borderInside.y - dashRect.y) / float(dashRect.height); currRect.height = currRect.height - (borderInside.y - currRect.y); currRect.y = borderInside.y; } //draw if necessary if (0) { printf("DASHED LEFT: xywh in loop currRect = %d %d %d %d %s\n", currRect.x, currRect.y, currRect.width, currRect.height, bSolid?"TRUE":"FALSE"); } if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.y = dashRect.y + currRect.height; currRect = dashRect; } } } break; case NS_SIDE_TOP: { // draw top segment i if (0==x) { nsBorderEdge * leftEdge = (nsBorderEdge *)(aBorderEdges->mEdges[NS_SIDE_LEFT].ElementAt(0)); x = aBorderEdges->mMaxBorderWidth.left - leftEdge->mWidth; } y = aBounds.y; if (PR_TRUE==aBorderEdges->mOutsideEdge) // segments of the outside edge are bottom-aligned y += aBorderEdges->mMaxBorderWidth.top - segment->mWidth; nsRect borderOutside(x, y, segment->mLength, aBounds.height); x += segment->mLength; if ((style == NS_STYLE_BORDER_STYLE_DASHED) || (style == NS_STYLE_BORDER_STYLE_DOTTED)) { nsRect borderInside(borderOutside); nsBorderEdge * neighbor; if (PR_TRUE==aBorderEdges->mOutsideEdge) neighbor = (nsBorderEdge *)(segment->mInsideNeighbor->mEdges[NS_SIDE_LEFT].ElementAt(0)); else neighbor = (nsBorderEdge *)(aBorderEdges->mEdges[NS_SIDE_LEFT].ElementAt(0)); nsMargin outsideMargin(neighbor->mWidth, segment->mWidth, 0, segment->mWidth); borderInside.Deflate(outsideMargin); nscoord firstRectWidth = 0; if (PR_TRUE==aBorderEdges->mOutsideEdge && 0==i) { firstRectWidth = borderInside.x - borderOutside.x; aContext.FillRect(borderOutside.x, borderOutside.y, firstRectWidth, borderInside.y - borderOutside.y); } dashRect.height = borderInside.y - borderOutside.y; dashRect.width = dashRect.height * dashLength; dashRect.x = borderOutside.x + firstRectWidth; dashRect.y = borderOutside.y; currRect = dashRect; while (currRect.x < borderInside.XMost()) { //clip if necessary if (currRect.XMost() > borderInside.XMost()) { over = float(dashRect.XMost() - borderInside.XMost()) / float(dashRect.width); currRect.width = currRect.width - (currRect.XMost() - borderInside.XMost()); } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.x = dashRect.x + currRect.width; currRect = dashRect; } } } break; case NS_SIDE_RIGHT: { // draw right segment i nsBorderEdge * topEdge = (nsBorderEdge *) (aBorderEdges->mEdges[NS_SIDE_TOP].ElementAt(aBorderEdges->mEdges[NS_SIDE_TOP].Count()-1)); if (0==y) { y = aBorderEdges->mMaxBorderWidth.top - topEdge->mWidth; if (PR_TRUE==aBorderEdges->mOutsideEdge) y += topEdge->mWidth; } nscoord width; if (PR_TRUE==aBorderEdges->mOutsideEdge) { width = aBounds.width - aBorderEdges->mMaxBorderWidth.right; width += segment->mWidth; } else { width = aBounds.width; } nscoord height = segment->mLength; nsRect borderOutside(aBounds.x, y, width, height); y += segment->mLength; if ((style == NS_STYLE_BORDER_STYLE_DASHED) || (style == NS_STYLE_BORDER_STYLE_DOTTED)) { nsRect borderInside(borderOutside); nsMargin outsideMargin(segment->mWidth, 0, (segment->mWidth), 0); borderInside.Deflate(outsideMargin); nscoord totalLength = segment->mLength; if (PR_TRUE==aBorderEdges->mOutsideEdge) { if (segment->mInsideNeighbor == neighborBorderEdges) { neighborEdgeCount++; } else { neighborBorderEdges = segment->mInsideNeighbor; neighborEdgeCount=0; } nsBorderEdge * neighborRight = (nsBorderEdge *)(segment->mInsideNeighbor->mEdges[NS_SIDE_RIGHT].ElementAt(neighborEdgeCount)); totalLength = neighborRight->mLength; } dashRect.width = borderOutside.XMost() - borderInside.XMost(); dashRect.height = nscoord(dashRect.width * dashLength); dashRect.x = borderInside.XMost(); dashRect.y = borderOutside.y + (totalLength/2) - dashRect.height; if ((PR_TRUE==aBorderEdges->mOutsideEdge) && (0!=i)) dashRect.y -= topEdge->mWidth; currRect = dashRect; // draw the top half while (currRect.YMost() > borderInside.y) { //clip if necessary if (currRect.y < borderInside.y) { over = float(borderInside.y - dashRect.y) / float(dashRect.height); currRect.height = currRect.height - (borderInside.y - currRect.y); currRect.y = borderInside.y; } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.y = dashRect.y - currRect.height; currRect = dashRect; } // draw the bottom half dashRect.y = borderOutside.y + (totalLength/2) + dashRect.height; if ((PR_TRUE==aBorderEdges->mOutsideEdge) && (0!=i)) dashRect.y -= topEdge->mWidth; currRect = dashRect; bSolid=PR_TRUE; over = 0.0f; while (currRect.YMost() < borderInside.YMost()) { //clip if necessary if (currRect.y < borderInside.y) { over = float(borderInside.y - dashRect.y) / float(dashRect.height); currRect.height = currRect.height - (borderInside.y - currRect.y); currRect.y = borderInside.y; } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.y = dashRect.y + currRect.height; currRect = dashRect; } } } break; case NS_SIDE_BOTTOM: { // draw bottom segment i if (0==x) { nsBorderEdge * leftEdge = (nsBorderEdge *) (aBorderEdges->mEdges[NS_SIDE_LEFT].ElementAt(aBorderEdges->mEdges[NS_SIDE_LEFT].Count()-1)); x = aBorderEdges->mMaxBorderWidth.left - leftEdge->mWidth; } y = aBounds.y; if (PR_TRUE==aBorderEdges->mOutsideEdge) // segments of the outside edge are top-aligned y -= aBorderEdges->mMaxBorderWidth.bottom - segment->mWidth; nsRect borderOutside(x, y, segment->mLength, aBounds.height); x += segment->mLength; if ((style == NS_STYLE_BORDER_STYLE_DASHED) || (style == NS_STYLE_BORDER_STYLE_DOTTED)) { nsRect borderInside(borderOutside); nsBorderEdge * neighbor; if (PR_TRUE==aBorderEdges->mOutsideEdge) neighbor = (nsBorderEdge *)(segment->mInsideNeighbor->mEdges[NS_SIDE_LEFT].ElementAt(0)); else neighbor = (nsBorderEdge *)(aBorderEdges->mEdges[NS_SIDE_LEFT].ElementAt(0)); nsMargin outsideMargin(neighbor->mWidth, segment->mWidth, 0, segment->mWidth); borderInside.Deflate(outsideMargin); nscoord firstRectWidth = 0; if (PR_TRUE==aBorderEdges->mOutsideEdge && 0==i) { firstRectWidth = borderInside.x - borderOutside.x; aContext.FillRect(borderOutside.x, borderInside.YMost(), firstRectWidth, borderOutside.YMost() - borderInside.YMost()); } dashRect.height = borderOutside.YMost() - borderInside.YMost(); dashRect.width = nscoord(dashRect.height * dashLength); dashRect.x = borderOutside.x + firstRectWidth; dashRect.y = borderInside.YMost(); currRect = dashRect; while (currRect.x < borderInside.XMost()) { //clip if necessary if (currRect.XMost() > borderInside.XMost()) { over = float(dashRect.XMost() - borderInside.XMost()) / float(dashRect.width); currRect.width = currRect.width - (currRect.XMost() - borderInside.XMost()); } //draw if necessary if (bSolid) { aContext.FillRect(currRect); } //setup for next iteration if (over == 0.0f) { bSolid = PRBool(!bSolid); } dashRect.x = dashRect.x + currRect.width; currRect = dashRect; } } } break; } } skippedSide = PR_FALSE; } } // XXX improve this to constrain rendering to the damaged area void nsCSSRendering::PaintBorder(nsIPresContext& aPresContext, nsIRenderingContext& aRenderingContext, nsIFrame* aForFrame, const nsRect& aDirtyRect, const nsRect& aBorderArea, const nsStyleSpacing& aStyle, PRIntn aSkipSides, nsRect* aGap) { PRIntn cnt; nsMargin border; PRBool printing = nsGlobalVariables::Instance()->GetPrinting(&aPresContext); aStyle.CalcBorderFor(aForFrame, border); if ((0 == border.left) && (0 == border.right) && (0 == border.top) && (0 == border.bottom)) { // Empty border area return; } // Turn off rendering for all of the zero sized sides if (0 == border.top) aSkipSides |= (1 << NS_SIDE_TOP); if (0 == border.right) aSkipSides |= (1 << NS_SIDE_RIGHT); if (0 == border.bottom) aSkipSides |= (1 << NS_SIDE_BOTTOM); if (0 == border.left) aSkipSides |= (1 << NS_SIDE_LEFT); nsRect inside(aBorderArea); nsRect outside(inside); outside.Deflate(border); //see if any sides are dotted or dashed for (cnt = 0; cnt < 4; cnt++) { if ((aStyle.GetBorderStyle(cnt) == NS_STYLE_BORDER_STYLE_DOTTED) || (aStyle.GetBorderStyle(cnt) == NS_STYLE_BORDER_STYLE_DASHED)) { break; } } if (cnt < 4) { DrawDashedSides(cnt, aRenderingContext,aStyle, inside, outside, aSkipSides, aGap); } // Draw all the other sides nscoord twipsPerPixel = (nscoord)aPresContext.GetPixelsToTwips(); if (0 == (aSkipSides & (1<GetPrinting(&aPresContext); if (nsnull==aBorderEdges) { // Empty border segments return; } // Turn off rendering for all of the zero sized sides if (0 == aBorderEdges->mMaxBorderWidth.top) aSkipSides |= (1 << NS_SIDE_TOP); if (0 == aBorderEdges->mMaxBorderWidth.right) aSkipSides |= (1 << NS_SIDE_RIGHT); if (0 == aBorderEdges->mMaxBorderWidth.bottom) aSkipSides |= (1 << NS_SIDE_BOTTOM); if (0 == aBorderEdges->mMaxBorderWidth.left) aSkipSides |= (1 << NS_SIDE_LEFT); // Draw any dashed or dotted segments separately DrawDashedSegments(aRenderingContext, aBorderArea, aBorderEdges, aSkipSides, aGap); // Draw all the other sides nscoord twipsPerPixel = (nscoord)aPresContext.GetPixelsToTwips(); if (0 == (aSkipSides & (1<mEdges[NS_SIDE_TOP].Count(); PRInt32 i; nsBorderEdge * leftEdge = (nsBorderEdge *)(aBorderEdges->mEdges[NS_SIDE_LEFT].ElementAt(0)); nscoord x = aBorderEdges->mMaxBorderWidth.left - leftEdge->mWidth; for (i=0; imEdges[NS_SIDE_TOP].ElementAt(i)); nscoord y = aBorderArea.y; if (PR_TRUE==aBorderEdges->mOutsideEdge) // segments of the outside edge are bottom-aligned y += aBorderEdges->mMaxBorderWidth.top - borderEdge->mWidth; nsRect inside(x, y, borderEdge->mLength, aBorderArea.height); x += borderEdge->mLength; nsRect outside(inside); nsMargin outsideMargin(0, borderEdge->mWidth, 0, 0); outside.Deflate(outsideMargin); DrawSide(aRenderingContext, NS_SIDE_TOP, borderEdge->mStyle, borderEdge->mColor, inside, outside, printing, twipsPerPixel, aGap); } } if (0 == (aSkipSides & (1<mEdges[NS_SIDE_LEFT].Count(); PRInt32 i; nsBorderEdge * topEdge = (nsBorderEdge *)(aBorderEdges->mEdges[NS_SIDE_TOP].ElementAt(0)); nscoord y = aBorderEdges->mMaxBorderWidth.top - topEdge->mWidth; for (i=0; imEdges[NS_SIDE_LEFT].ElementAt(i)); nscoord x = aBorderArea.x + (aBorderEdges->mMaxBorderWidth.left - borderEdge->mWidth); nsRect inside(x, y, aBorderArea.width, borderEdge->mLength); y += borderEdge->mLength; nsRect outside(inside); nsMargin outsideMargin(borderEdge->mWidth, 0, 0, 0); outside.Deflate(outsideMargin); DrawSide(aRenderingContext, NS_SIDE_LEFT, borderEdge->mStyle, borderEdge->mColor, inside, outside, printing, twipsPerPixel, aGap); } } if (0 == (aSkipSides & (1<mEdges[NS_SIDE_BOTTOM].Count(); PRInt32 i; nsBorderEdge * leftEdge = (nsBorderEdge *) (aBorderEdges->mEdges[NS_SIDE_LEFT].ElementAt(aBorderEdges->mEdges[NS_SIDE_LEFT].Count()-1)); nscoord x = aBorderEdges->mMaxBorderWidth.left - leftEdge->mWidth; for (i=0; imEdges[NS_SIDE_BOTTOM].ElementAt(i)); nscoord y = aBorderArea.y; if (PR_TRUE==aBorderEdges->mOutsideEdge) // segments of the outside edge are top-aligned y -= (aBorderEdges->mMaxBorderWidth.bottom - borderEdge->mWidth); nsRect inside(x, y, borderEdge->mLength, aBorderArea.height); x += borderEdge->mLength; nsRect outside(inside); nsMargin outsideMargin(0, 0, 0, borderEdge->mWidth); outside.Deflate(outsideMargin); DrawSide(aRenderingContext, NS_SIDE_BOTTOM, borderEdge->mStyle, borderEdge->mColor, inside, outside, printing, twipsPerPixel, aGap); } } if (0 == (aSkipSides & (1<mEdges[NS_SIDE_RIGHT].Count(); PRInt32 i; nsBorderEdge * topEdge = (nsBorderEdge *) (aBorderEdges->mEdges[NS_SIDE_TOP].ElementAt(aBorderEdges->mEdges[NS_SIDE_TOP].Count()-1)); nscoord y = aBorderEdges->mMaxBorderWidth.top - topEdge->mWidth; for (i=0; imEdges[NS_SIDE_RIGHT].ElementAt(i)); nscoord width; if (PR_TRUE==aBorderEdges->mOutsideEdge) { width = aBorderArea.width - aBorderEdges->mMaxBorderWidth.right; width += borderEdge->mWidth; } else { width = aBorderArea.width; } nsRect inside(aBorderArea.x, y, width, borderEdge->mLength); y += borderEdge->mLength; nsRect outside(inside); nsMargin outsideMargin(0, 0, (borderEdge->mWidth), 0); outside.Deflate(outsideMargin); DrawSide(aRenderingContext, NS_SIDE_RIGHT, borderEdge->mStyle, borderEdge->mColor, inside, outside, printing, twipsPerPixel, aGap); } } } //---------------------------------------------------------------------- static void ComputeBackgroundAnchorPoint(const nsStyleColor& aColor, const nsRect& aBounds, nscoord aTileWidth, nscoord aTileHeight, nsPoint& aResult) { nscoord x; if (NS_STYLE_BG_X_POSITION_LENGTH & aColor.mBackgroundFlags) { x = aColor.mBackgroundXPosition; } else { nscoord t = aColor.mBackgroundXPosition; if (0 == (NS_STYLE_BG_X_POSITION_PERCENT & aColor.mBackgroundFlags)) { // XXX map enum to pct here t = 0; } float pct = float(t) / 100.0f; nscoord tilePos = nscoord(pct * aTileWidth); nscoord boxPos = nscoord(pct * aBounds.width); x = boxPos - tilePos; } if (NS_STYLE_BG_REPEAT_X & aColor.mBackgroundRepeat) { // When we are tiling in the x direction the loop will run from // the left edge of the box to the right edge of the box. We need // to adjust the starting coordinate to lie within the band being // rendered. if (x < 0) { x = -x; if (x < 0) { // Some joker gave us max-negative-integer. x = 0; } x %= aTileWidth; x = -x; } else { x %= aTileWidth; x = x - aTileWidth; } } aResult.x = x; nscoord y; if (NS_STYLE_BG_Y_POSITION_LENGTH & aColor.mBackgroundFlags) { y = aColor.mBackgroundYPosition; } else { nscoord t = aColor.mBackgroundYPosition; if (0 == (NS_STYLE_BG_Y_POSITION_PERCENT & aColor.mBackgroundFlags)) { // XXX map enum to pct here t = 0; } float pct = float(t) / 100.0f; nscoord tilePos = nscoord(pct * aTileHeight); nscoord boxPos = nscoord(pct * aBounds.height); y = boxPos - tilePos; } if (NS_STYLE_BG_REPEAT_Y & aColor.mBackgroundRepeat) { // When we are tiling in the y direction the loop will run from // the top edge of the box to the bottom edge of the box. We need // to adjust the starting coordinate to lie within the band being // rendered. if (y < 0) { y = -y; if (y < 0) { // Some joker gave us max-negative-integer. y = 0; } y %= aTileHeight; y = -y; } else { y %= aTileHeight; y = y - aTileHeight; } } aResult.y = y; } void nsCSSRendering::PaintBackground(nsIPresContext& aPresContext, nsIRenderingContext& aRenderingContext, nsIFrame* aForFrame, const nsRect& aDirtyRect, const nsRect& aBorderArea, const nsStyleColor& aColor, const nsStyleSpacing& aSpacing, nscoord aDX, nscoord aDY) { if (0 < aColor.mBackgroundImage.Length()) { // Lookup the image nsSize imageSize; nsIImage* image = nsnull; nsIFrameImageLoader* loader = nsnull; PRBool transparentBG = NS_STYLE_BG_COLOR_TRANSPARENT == (aColor.mBackgroundFlags & NS_STYLE_BG_COLOR_TRANSPARENT); nsresult rv = aPresContext.StartLoadImage(aColor.mBackgroundImage, transparentBG ? nsnull : &aColor.mBackgroundColor, aForFrame, nsnull, PR_FALSE, loader); if ((NS_OK != rv) || (nsnull == loader) || (loader->GetImage(image), (nsnull == image))) { NS_IF_RELEASE(loader); // Redraw will happen later if (!transparentBG) { aRenderingContext.SetColor(aColor.mBackgroundColor); aRenderingContext.FillRect(aBorderArea); } return; } loader->GetSize(imageSize); NS_RELEASE(loader); PRBool needBackgroundColor = PR_FALSE; #if XXX // XXX enable this code as soon as nsIImage can support it if (image->NeedsBlend()) { needBackgroundColor = PR_TRUE; } #endif // Convert image dimensions into nscoord's float p2t; aPresContext.GetScaledPixelsToTwips(p2t); nscoord tileWidth = NSIntPixelsToTwips(imageSize.width, p2t); nscoord tileHeight = NSIntPixelsToTwips(imageSize.height, p2t); if ((tileWidth == 0) || (tileHeight == 0)) { return; } // Background images are tiled over the 'content' and 'padding' areas // only (not the 'border' area) nsRect paddingArea(aBorderArea); nsMargin border; aSpacing.GetBorder(border); paddingArea.Deflate(border); // The actual dirty rect is the intersection of the padding area and the // dirty rect we were given nsRect dirtyRect; if (!dirtyRect.IntersectRect(paddingArea, aDirtyRect)) { // Nothing to paint return; } // Based on the repeat setting, compute how many tiles we should // lay down for each axis. The value computed is the maximum based // on the dirty rect before accounting for the background-position. PRIntn repeat = aColor.mBackgroundRepeat; nscoord xDistance, yDistance; switch (aColor.mBackgroundRepeat) { case NS_STYLE_BG_REPEAT_OFF: default: xDistance = tileWidth; yDistance = tileHeight; needBackgroundColor = PR_TRUE; break; case NS_STYLE_BG_REPEAT_X: xDistance = dirtyRect.width; yDistance = tileHeight; needBackgroundColor = PR_TRUE; break; case NS_STYLE_BG_REPEAT_Y: xDistance = tileWidth; yDistance = dirtyRect.height; needBackgroundColor = PR_TRUE; break; case NS_STYLE_BG_REPEAT_XY: xDistance = dirtyRect.width; yDistance = dirtyRect.height; break; } // The background color is rendered over the 'border' 'padding' and // 'content' areas if (needBackgroundColor) { aRenderingContext.SetColor(aColor.mBackgroundColor); aRenderingContext.FillRect(aBorderArea); } // Compute the anchor point, relative to the padding area where the // background image rendering should begin. When tiling, the anchor // coordinate values will be negative offsets from the padding area nsPoint anchor; ComputeBackgroundAnchorPoint(aColor, paddingArea, tileWidth, tileHeight, anchor); // Setup clipping so that rendering doesn't leak out of the computed // dirty rect PRBool clipState; aRenderingContext.PushState(); aRenderingContext.SetClipRect(dirtyRect, nsClipCombine_kIntersect, clipState); // Compute the x and y starting points and limits for tiling nscoord x0, x1; if (NS_STYLE_BG_REPEAT_X & aColor.mBackgroundRepeat) { // When tiling in the x direction, adjust the starting position of the // tile to account for dirtyRect.x. When tiling in x, the anchor.x value // will be a negative value used to adjust the starting coordinate. x0 = (dirtyRect.x / tileWidth) * tileWidth + anchor.x; x1 = x0 + xDistance + tileWidth; if (0 != anchor.x) { x1 += tileWidth; } } else { // When tiling is off in x, anchor.x is relative to padding area x0 = paddingArea.x + anchor.x; x1 = x0 + tileWidth; } nscoord y0, y1; if (NS_STYLE_BG_REPEAT_Y & aColor.mBackgroundRepeat) { // When tiling in the y direction, adjust the starting position of the // tile to account for dirtyRect.y. When tiling in y, the anchor.y value // will be a negative value used to adjust the starting coordinate. y0 = (dirtyRect.y / tileHeight) * tileHeight + anchor.y; y1 = y0 + yDistance + tileHeight; if (0 != anchor.y) { y1 += tileHeight; } } else { // When tiling is off in y, anchor.y is relative to padding area y0 = paddingArea.y + anchor.y; y1 = y0 + tileHeight; } // Tile the image in x and y nscoord x, y; for (y = y0; y < y1; y += tileHeight) { for (x = x0; x < x1; x += tileWidth) { aRenderingContext.DrawImage(image, x, y, tileWidth, tileHeight); } } // Restore clipping aRenderingContext.PopState(clipState); } else { // See if there's a background color specified. The background color // is rendered over the 'border' 'padding' and 'content' areas if (0 == (aColor.mBackgroundFlags & NS_STYLE_BG_COLOR_TRANSPARENT)) { // XXX This step can be avoided if we have an image and it doesn't // have any transparent pixels, and the image is tiled in both // the x and the y aRenderingContext.SetColor(aColor.mBackgroundColor); aRenderingContext.FillRect(aBorderArea); } } }