/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 4 -*- * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "gfxXlibSurface.h" #include "cairo.h" #include "cairo-xlib.h" #include "cairo-xlib-xrender.h" #include /* For XESetCloseDisplay */ #undef max // Xlibint.h defines this and it breaks std::max #undef min // Xlibint.h defines this and it breaks std::min #include "nsAutoPtr.h" #include "nsTArray.h" #include "nsAlgorithm.h" #include "mozilla/Preferences.h" #include #include "mozilla/CheckedInt.h" using namespace mozilla; // Although the dimension parameters in the xCreatePixmapReq wire protocol are // 16-bit unsigned integers, the server's CreatePixmap returns BadAlloc if // either dimension cannot be represented by a 16-bit *signed* integer. #define XLIB_IMAGE_SIDE_SIZE_LIMIT 0x7fff gfxXlibSurface::gfxXlibSurface(Display *dpy, Drawable drawable, Visual *visual) : mPixmapTaken(false), mDisplay(dpy), mDrawable(drawable) #if defined(GL_PROVIDER_GLX) , mGLXPixmap(None) #endif { const gfxIntSize size = DoSizeQuery(); cairo_surface_t *surf = cairo_xlib_surface_create(dpy, drawable, visual, size.width, size.height); Init(surf); } gfxXlibSurface::gfxXlibSurface(Display *dpy, Drawable drawable, Visual *visual, const gfxIntSize& size) : mPixmapTaken(false), mDisplay(dpy), mDrawable(drawable) #if defined(GL_PROVIDER_GLX) , mGLXPixmap(None) #endif { NS_ASSERTION(CheckSurfaceSize(size, XLIB_IMAGE_SIDE_SIZE_LIMIT), "Bad size"); cairo_surface_t *surf = cairo_xlib_surface_create(dpy, drawable, visual, size.width, size.height); Init(surf); } gfxXlibSurface::gfxXlibSurface(Screen *screen, Drawable drawable, XRenderPictFormat *format, const gfxIntSize& size) : mPixmapTaken(false), mDisplay(DisplayOfScreen(screen)), mDrawable(drawable) #if defined(GL_PROVIDER_GLX) , mGLXPixmap(None) #endif { NS_ASSERTION(CheckSurfaceSize(size, XLIB_IMAGE_SIDE_SIZE_LIMIT), "Bad Size"); cairo_surface_t *surf = cairo_xlib_surface_create_with_xrender_format(mDisplay, drawable, screen, format, size.width, size.height); Init(surf); } gfxXlibSurface::gfxXlibSurface(cairo_surface_t *csurf) : mPixmapTaken(false) #if defined(GL_PROVIDER_GLX) , mGLXPixmap(None) #endif { NS_PRECONDITION(cairo_surface_status(csurf) == 0, "Not expecting an error surface"); mDrawable = cairo_xlib_surface_get_drawable(csurf); mDisplay = cairo_xlib_surface_get_display(csurf); Init(csurf, true); } gfxXlibSurface::~gfxXlibSurface() { #if defined(GL_PROVIDER_GLX) if (mGLXPixmap) { gl::sGLXLibrary.DestroyPixmap(mDisplay, mGLXPixmap); } #endif // gfxASurface's destructor calls RecordMemoryFreed(). if (mPixmapTaken) { XFreePixmap (mDisplay, mDrawable); } } static Drawable CreatePixmap(Screen *screen, const gfxIntSize& size, unsigned int depth, Drawable relatedDrawable) { if (!gfxASurface::CheckSurfaceSize(size, XLIB_IMAGE_SIDE_SIZE_LIMIT)) return None; if (relatedDrawable == None) { relatedDrawable = RootWindowOfScreen(screen); } Display *dpy = DisplayOfScreen(screen); // X gives us a fatal error if we try to create a pixmap of width // or height 0 return XCreatePixmap(dpy, relatedDrawable, std::max(1, size.width), std::max(1, size.height), depth); } void gfxXlibSurface::TakePixmap() { NS_ASSERTION(!mPixmapTaken, "I already own the Pixmap!"); mPixmapTaken = true; // The bit depth returned from Cairo is technically int, but this is // the last place we'd be worried about that scenario. unsigned int bitDepth = cairo_xlib_surface_get_depth(CairoSurface()); MOZ_ASSERT((bitDepth % 8) == 0, "Memory used not recorded correctly"); // Divide by 8 because surface_get_depth gives us the number of *bits* per // pixel. gfxIntSize size = GetSize(); CheckedInt32 totalBytes = CheckedInt32(size.width) * CheckedInt32(size.height) * (bitDepth/8); // Don't do anything in the "else" case. We could add INT32_MAX, but that // would overflow the memory used counter. It would also mean we tried for // a 2G image. For now, we'll just assert, MOZ_ASSERT(totalBytes.isValid(),"Did not expect to exceed 2Gb image"); if (totalBytes.isValid()) { RecordMemoryUsed(totalBytes.value()); } } Drawable gfxXlibSurface::ReleasePixmap() { NS_ASSERTION(mPixmapTaken, "I don't own the Pixmap!"); mPixmapTaken = false; RecordMemoryFreed(); return mDrawable; } static cairo_user_data_key_t gDestroyPixmapKey; struct DestroyPixmapClosure { DestroyPixmapClosure(Drawable d, Screen *s) : mPixmap(d), mScreen(s) {} Drawable mPixmap; Screen *mScreen; }; static void DestroyPixmap(void *data) { DestroyPixmapClosure *closure = static_cast(data); XFreePixmap(DisplayOfScreen(closure->mScreen), closure->mPixmap); delete closure; } /* static */ cairo_surface_t * gfxXlibSurface::CreateCairoSurface(Screen *screen, Visual *visual, const gfxIntSize& size, Drawable relatedDrawable) { Drawable drawable = CreatePixmap(screen, size, DepthOfVisual(screen, visual), relatedDrawable); if (!drawable) return nullptr; cairo_surface_t* surface = cairo_xlib_surface_create(DisplayOfScreen(screen), drawable, visual, size.width, size.height); if (cairo_surface_status(surface)) { cairo_surface_destroy(surface); XFreePixmap(DisplayOfScreen(screen), drawable); return nullptr; } DestroyPixmapClosure *closure = new DestroyPixmapClosure(drawable, screen); cairo_surface_set_user_data(surface, &gDestroyPixmapKey, closure, DestroyPixmap); return surface; } /* static */ already_AddRefed gfxXlibSurface::Create(Screen *screen, Visual *visual, const gfxIntSize& size, Drawable relatedDrawable) { Drawable drawable = CreatePixmap(screen, size, DepthOfVisual(screen, visual), relatedDrawable); if (!drawable) return nullptr; nsRefPtr result = new gfxXlibSurface(DisplayOfScreen(screen), drawable, visual, size); result->TakePixmap(); if (result->CairoStatus() != 0) return nullptr; return result.forget(); } /* static */ already_AddRefed gfxXlibSurface::Create(Screen *screen, XRenderPictFormat *format, const gfxIntSize& size, Drawable relatedDrawable) { Drawable drawable = CreatePixmap(screen, size, format->depth, relatedDrawable); if (!drawable) return nullptr; nsRefPtr result = new gfxXlibSurface(screen, drawable, format, size); result->TakePixmap(); if (result->CairoStatus() != 0) return nullptr; return result.forget(); } static bool GetForce24bppPref() { return Preferences::GetBool("mozilla.widget.force-24bpp", false); } already_AddRefed gfxXlibSurface::CreateSimilarSurface(gfxContentType aContent, const gfxIntSize& aSize) { if (!mSurface || !mSurfaceValid) { return nullptr; } if (aContent == gfxContentType::COLOR) { // cairo_surface_create_similar will use a matching visual if it can. // However, systems with 16-bit or indexed default visuals may benefit // from rendering with 24-bit formats. static bool force24bpp = GetForce24bppPref(); if (force24bpp && cairo_xlib_surface_get_depth(CairoSurface()) != 24) { XRenderPictFormat* format = XRenderFindStandardFormat(mDisplay, PictStandardRGB24); if (format) { // Cairo only performs simple self-copies as desired if it // knows that this is a Pixmap surface. It only knows that // surfaces are pixmap surfaces if it creates the Pixmap // itself, so we use cairo_surface_create_similar with a // temporary reference surface to indicate the format. Screen* screen = cairo_xlib_surface_get_screen(CairoSurface()); nsRefPtr depth24reference = gfxXlibSurface::Create(screen, format, gfxIntSize(1, 1), mDrawable); if (depth24reference) return depth24reference-> gfxASurface::CreateSimilarSurface(aContent, aSize); } } } return gfxASurface::CreateSimilarSurface(aContent, aSize); } void gfxXlibSurface::Finish() { #if defined(GL_PROVIDER_GLX) if (mGLXPixmap) { gl::sGLXLibrary.DestroyPixmap(mDisplay, mGLXPixmap); mGLXPixmap = None; } #endif gfxASurface::Finish(); } const gfxIntSize gfxXlibSurface::GetSize() const { if (!mSurfaceValid) return gfxIntSize(0,0); return gfxIntSize(cairo_xlib_surface_get_width(mSurface), cairo_xlib_surface_get_height(mSurface)); } const gfxIntSize gfxXlibSurface::DoSizeQuery() { // figure out width/height/depth Window root_ignore; int x_ignore, y_ignore; unsigned int bwidth_ignore, width, height, depth; XGetGeometry(mDisplay, mDrawable, &root_ignore, &x_ignore, &y_ignore, &width, &height, &bwidth_ignore, &depth); return gfxIntSize(width, height); } class DisplayTable { public: static bool GetColormapAndVisual(Screen* screen, XRenderPictFormat* format, Visual* visual, Colormap* colormap, Visual** visualForColormap); private: struct ColormapEntry { XRenderPictFormat* mFormat; // The Screen is needed here because colormaps (and their visuals) may // only be used on one Screen, but XRenderPictFormats are not unique // to any one Screen. Screen* mScreen; Visual* mVisual; Colormap mColormap; }; class DisplayInfo { public: DisplayInfo(Display* display) : mDisplay(display) { } Display* mDisplay; nsTArray mColormapEntries; }; // Comparator for finding the DisplayInfo class FindDisplay { public: bool Equals(const DisplayInfo& info, const Display *display) const { return info.mDisplay == display; } }; static int DisplayClosing(Display *display, XExtCodes* codes); nsTArray mDisplays; static DisplayTable* sDisplayTable; }; DisplayTable* DisplayTable::sDisplayTable; // Pixmaps don't have a particular associated visual but the pixel values are // interpreted according to a visual/colormap pairs. // // cairo is designed for surfaces with either TrueColor visuals or the // default visual (which may not be true color). TrueColor visuals don't // really need a colormap because the visual indicates the pixel format, // and cairo uses the default visual with the default colormap, so cairo // surfaces don't need an explicit colormap. // // However, some toolkits (e.g. GDK) need a colormap even with TrueColor // visuals. We can create a colormap for these visuals, but it will use about // 20kB of memory in the server, so we use the default colormap when // suitable and share colormaps between surfaces. Another reason for // minimizing colormap turnover is that the plugin process must leak resources // for each new colormap id when using older GDK libraries (bug 569775). // // Only the format of the pixels is important for rendering to Pixmaps, so if // the format of a visual matches that of the surface, then that visual can be // used for rendering to the surface. Multiple visuals can match the same // format (but have different GLX properties), so the visual returned may // differ from the visual passed in. Colormaps are tied to a visual, so // should only be used with their visual. /* static */ bool DisplayTable::GetColormapAndVisual(Screen* aScreen, XRenderPictFormat* aFormat, Visual* aVisual, Colormap* aColormap, Visual** aVisualForColormap) { Display* display = DisplayOfScreen(aScreen); // Use the default colormap if the default visual matches. Visual *defaultVisual = DefaultVisualOfScreen(aScreen); if (aVisual == defaultVisual || (aFormat && aFormat == XRenderFindVisualFormat(display, defaultVisual))) { *aColormap = DefaultColormapOfScreen(aScreen); *aVisualForColormap = defaultVisual; return true; } // Only supporting TrueColor non-default visuals if (!aVisual || aVisual->c_class != TrueColor) return false; if (!sDisplayTable) { sDisplayTable = new DisplayTable(); } nsTArray* displays = &sDisplayTable->mDisplays; uint32_t d = displays->IndexOf(display, 0, FindDisplay()); if (d == displays->NoIndex) { d = displays->Length(); // Register for notification of display closing, when this info // becomes invalid. XExtCodes *codes = XAddExtension(display); if (!codes) return false; XESetCloseDisplay(display, codes->extension, DisplayClosing); // Add a new DisplayInfo. displays->AppendElement(display); } nsTArray* entries = &displays->ElementAt(d).mColormapEntries; // Only a small number of formats are expected to be used, so just do a // simple linear search. for (uint32_t i = 0; i < entries->Length(); ++i) { const ColormapEntry& entry = entries->ElementAt(i); // Only the format and screen need to match. (The visual may differ.) // If there is no format (e.g. no RENDER extension) then just compare // the visual. if ((aFormat && entry.mFormat == aFormat && entry.mScreen == aScreen) || aVisual == entry.mVisual) { *aColormap = entry.mColormap; *aVisualForColormap = entry.mVisual; return true; } } // No existing entry. Create a colormap and add an entry. Colormap colormap = XCreateColormap(display, RootWindowOfScreen(aScreen), aVisual, AllocNone); ColormapEntry* newEntry = entries->AppendElement(); newEntry->mFormat = aFormat; newEntry->mScreen = aScreen; newEntry->mVisual = aVisual; newEntry->mColormap = colormap; *aColormap = colormap; *aVisualForColormap = aVisual; return true; } /* static */ int DisplayTable::DisplayClosing(Display *display, XExtCodes* codes) { // No need to free the colormaps explicitly as they will be released when // the connection is closed. sDisplayTable->mDisplays.RemoveElement(display, FindDisplay()); if (sDisplayTable->mDisplays.Length() == 0) { delete sDisplayTable; sDisplayTable = nullptr; } return 0; } /* static */ bool gfxXlibSurface::GetColormapAndVisual(cairo_surface_t* aXlibSurface, Colormap* aColormap, Visual** aVisual) { XRenderPictFormat* format = cairo_xlib_surface_get_xrender_format(aXlibSurface); Screen* screen = cairo_xlib_surface_get_screen(aXlibSurface); Visual* visual = cairo_xlib_surface_get_visual(aXlibSurface); return DisplayTable::GetColormapAndVisual(screen, format, visual, aColormap, aVisual); } bool gfxXlibSurface::GetColormapAndVisual(Colormap* aColormap, Visual** aVisual) { if (!mSurfaceValid) return false; return GetColormapAndVisual(CairoSurface(), aColormap, aVisual); } /* static */ int gfxXlibSurface::DepthOfVisual(const Screen* screen, const Visual* visual) { for (int d = 0; d < screen->ndepths; d++) { const Depth& d_info = screen->depths[d]; if (visual >= &d_info.visuals[0] && visual < &d_info.visuals[d_info.nvisuals]) return d_info.depth; } NS_ERROR("Visual not on Screen."); return 0; } /* static */ Visual* gfxXlibSurface::FindVisual(Screen *screen, gfxImageFormat format) { int depth; unsigned long red_mask, green_mask, blue_mask; switch (format) { case gfxImageFormat::ARGB32: depth = 32; red_mask = 0xff0000; green_mask = 0xff00; blue_mask = 0xff; break; case gfxImageFormat::RGB24: depth = 24; red_mask = 0xff0000; green_mask = 0xff00; blue_mask = 0xff; break; case gfxImageFormat::RGB16_565: depth = 16; red_mask = 0xf800; green_mask = 0x7e0; blue_mask = 0x1f; break; case gfxImageFormat::A8: case gfxImageFormat::A1: default: return nullptr; } for (int d = 0; d < screen->ndepths; d++) { const Depth& d_info = screen->depths[d]; if (d_info.depth != depth) continue; for (int v = 0; v < d_info.nvisuals; v++) { Visual* visual = &d_info.visuals[v]; if (visual->c_class == TrueColor && visual->red_mask == red_mask && visual->green_mask == green_mask && visual->blue_mask == blue_mask) return visual; } } return nullptr; } /* static */ XRenderPictFormat* gfxXlibSurface::FindRenderFormat(Display *dpy, gfxImageFormat format) { switch (format) { case gfxImageFormat::ARGB32: return XRenderFindStandardFormat (dpy, PictStandardARGB32); case gfxImageFormat::RGB24: return XRenderFindStandardFormat (dpy, PictStandardRGB24); case gfxImageFormat::RGB16_565: { // PictStandardRGB16_565 is not standard Xrender format // we should try to find related visual // and find xrender format by visual Visual *visual = FindVisual(DefaultScreenOfDisplay(dpy), format); if (!visual) return nullptr; return XRenderFindVisualFormat(dpy, visual); } case gfxImageFormat::A8: return XRenderFindStandardFormat (dpy, PictStandardA8); case gfxImageFormat::A1: return XRenderFindStandardFormat (dpy, PictStandardA1); default: break; } return nullptr; } Screen* gfxXlibSurface::XScreen() { return cairo_xlib_surface_get_screen(CairoSurface()); } XRenderPictFormat* gfxXlibSurface::XRenderFormat() { return cairo_xlib_surface_get_xrender_format(CairoSurface()); } #if defined(GL_PROVIDER_GLX) GLXPixmap gfxXlibSurface::GetGLXPixmap() { if (!mGLXPixmap) { #ifdef DEBUG // cairo_surface_has_show_text_glyphs is used solely for the // side-effect of setting the error on surface if // cairo_surface_finish() has been called. cairo_surface_has_show_text_glyphs(CairoSurface()); NS_ASSERTION(CairoStatus() != CAIRO_STATUS_SURFACE_FINISHED, "GetGLXPixmap called after surface finished"); #endif mGLXPixmap = gl::sGLXLibrary.CreatePixmap(this); } return mGLXPixmap; } #endif gfxMemoryLocation gfxXlibSurface::GetMemoryLocation() const { return gfxMemoryLocation::OUT_OF_PROCESS; }