/************************************************************************** Copyright 1999, 2000 ATI Technologies Inc. and Precision Insight, Inc., Cedar Park, Texas. All Rights Reserved. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation on the rights to use, copy, modify, merge, publish, distribute, sub license, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice (including the next paragraph) shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL ATI, PRECISION INSIGHT AND/OR THEIR SUPPLIERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. **************************************************************************/ /* * Authors: * Gareth Hughes * Kevin E. Martin * */ #include "r128_dri.h" #include "r128_context.h" #include "r128_ioctl.h" #include "r128_span.h" #include "main/context.h" #include "main/imports.h" #include "main/framebuffer.h" #include "main/renderbuffer.h" #include "utils.h" #include "vblank.h" #include "GL/internal/dri_interface.h" /* R128 configuration */ #include "xmlpool.h" PUBLIC const char __driConfigOptions[] = DRI_CONF_BEGIN DRI_CONF_SECTION_PERFORMANCE DRI_CONF_VBLANK_MODE(DRI_CONF_VBLANK_DEF_INTERVAL_0) DRI_CONF_SECTION_END DRI_CONF_SECTION_QUALITY DRI_CONF_TEXTURE_DEPTH(DRI_CONF_TEXTURE_DEPTH_FB) DRI_CONF_SECTION_END DRI_CONF_SECTION_DEBUG DRI_CONF_NO_RAST(false) #if ENABLE_PERF_BOXES DRI_CONF_PERFORMANCE_BOXES(false) #endif DRI_CONF_SECTION_END DRI_CONF_END; #if ENABLE_PERF_BOXES static const GLuint __driNConfigOptions = 4; #else static const GLuint __driNConfigOptions = 3; #endif #if 1 /* Including xf86PciInfo.h introduces a bunch of errors... */ #define PCI_CHIP_RAGE128LE 0x4C45 #define PCI_CHIP_RAGE128LF 0x4C46 #define PCI_CHIP_RAGE128PF 0x5046 #define PCI_CHIP_RAGE128PR 0x5052 #define PCI_CHIP_RAGE128RE 0x5245 #define PCI_CHIP_RAGE128RF 0x5246 #define PCI_CHIP_RAGE128RK 0x524B #define PCI_CHIP_RAGE128RL 0x524C #endif /* Create the device specific screen private data struct. */ static r128ScreenPtr r128CreateScreen( __DRIscreen *sPriv ) { r128ScreenPtr r128Screen; R128DRIPtr r128DRIPriv = (R128DRIPtr)sPriv->pDevPriv; int i; if (sPriv->devPrivSize != sizeof(R128DRIRec)) { fprintf(stderr,"\nERROR! sizeof(R128DRIRec) does not match passed size from device driver\n"); return GL_FALSE; } /* Allocate the private area */ r128Screen = (r128ScreenPtr) CALLOC( sizeof(*r128Screen) ); if ( !r128Screen ) return NULL; /* parse information in __driConfigOptions */ driParseOptionInfo (&r128Screen->optionCache, __driConfigOptions, __driNConfigOptions); /* This is first since which regions we map depends on whether or * not we are using a PCI card. */ r128Screen->IsPCI = r128DRIPriv->IsPCI; r128Screen->sarea_priv_offset = r128DRIPriv->sarea_priv_offset; if (sPriv->drm_version.minor >= 3) { drm_r128_getparam_t gp; int ret; gp.param = R128_PARAM_IRQ_NR; gp.value = &r128Screen->irq; ret = drmCommandWriteRead( sPriv->fd, DRM_R128_GETPARAM, &gp, sizeof(gp)); if (ret) { fprintf(stderr, "drmR128GetParam (R128_PARAM_IRQ_NR): %d\n", ret); FREE( r128Screen ); return NULL; } } r128Screen->mmio.handle = r128DRIPriv->registerHandle; r128Screen->mmio.size = r128DRIPriv->registerSize; if ( drmMap( sPriv->fd, r128Screen->mmio.handle, r128Screen->mmio.size, (drmAddressPtr)&r128Screen->mmio.map ) ) { FREE( r128Screen ); return NULL; } r128Screen->buffers = drmMapBufs( sPriv->fd ); if ( !r128Screen->buffers ) { drmUnmap( (drmAddress)r128Screen->mmio.map, r128Screen->mmio.size ); FREE( r128Screen ); return NULL; } if ( !r128Screen->IsPCI ) { r128Screen->agpTextures.handle = r128DRIPriv->agpTexHandle; r128Screen->agpTextures.size = r128DRIPriv->agpTexMapSize; if ( drmMap( sPriv->fd, r128Screen->agpTextures.handle, r128Screen->agpTextures.size, (drmAddressPtr)&r128Screen->agpTextures.map ) ) { drmUnmapBufs( r128Screen->buffers ); drmUnmap( (drmAddress)r128Screen->mmio.map, r128Screen->mmio.size ); FREE( r128Screen ); return NULL; } } switch ( r128DRIPriv->deviceID ) { case PCI_CHIP_RAGE128RE: case PCI_CHIP_RAGE128RF: case PCI_CHIP_RAGE128RK: case PCI_CHIP_RAGE128RL: r128Screen->chipset = R128_CARD_TYPE_R128; break; case PCI_CHIP_RAGE128PF: r128Screen->chipset = R128_CARD_TYPE_R128_PRO; break; case PCI_CHIP_RAGE128LE: case PCI_CHIP_RAGE128LF: r128Screen->chipset = R128_CARD_TYPE_R128_MOBILITY; break; default: r128Screen->chipset = R128_CARD_TYPE_R128; break; } r128Screen->cpp = r128DRIPriv->bpp / 8; r128Screen->AGPMode = r128DRIPriv->AGPMode; r128Screen->frontOffset = r128DRIPriv->frontOffset; r128Screen->frontPitch = r128DRIPriv->frontPitch; r128Screen->backOffset = r128DRIPriv->backOffset; r128Screen->backPitch = r128DRIPriv->backPitch; r128Screen->depthOffset = r128DRIPriv->depthOffset; r128Screen->depthPitch = r128DRIPriv->depthPitch; r128Screen->spanOffset = r128DRIPriv->spanOffset; if ( r128DRIPriv->textureSize == 0 ) { r128Screen->texOffset[R128_LOCAL_TEX_HEAP] = r128DRIPriv->agpTexOffset + R128_AGP_TEX_OFFSET; r128Screen->texSize[R128_LOCAL_TEX_HEAP] = r128DRIPriv->agpTexMapSize; r128Screen->logTexGranularity[R128_LOCAL_TEX_HEAP] = r128DRIPriv->log2AGPTexGran; } else { r128Screen->texOffset[R128_LOCAL_TEX_HEAP] = r128DRIPriv->textureOffset; r128Screen->texSize[R128_LOCAL_TEX_HEAP] = r128DRIPriv->textureSize; r128Screen->logTexGranularity[R128_LOCAL_TEX_HEAP] = r128DRIPriv->log2TexGran; } if ( !r128Screen->agpTextures.map || r128DRIPriv->textureSize == 0 ) { r128Screen->numTexHeaps = R128_NR_TEX_HEAPS - 1; r128Screen->texOffset[R128_AGP_TEX_HEAP] = 0; r128Screen->texSize[R128_AGP_TEX_HEAP] = 0; r128Screen->logTexGranularity[R128_AGP_TEX_HEAP] = 0; } else { r128Screen->numTexHeaps = R128_NR_TEX_HEAPS; r128Screen->texOffset[R128_AGP_TEX_HEAP] = r128DRIPriv->agpTexOffset + R128_AGP_TEX_OFFSET; r128Screen->texSize[R128_AGP_TEX_HEAP] = r128DRIPriv->agpTexMapSize; r128Screen->logTexGranularity[R128_AGP_TEX_HEAP] = r128DRIPriv->log2AGPTexGran; } r128Screen->driScreen = sPriv; i = 0; if ( r128Screen->irq != 0 ) { r128Screen->extensions[i++] = &driSwapControlExtension.base; r128Screen->extensions[i++] = &driMediaStreamCounterExtension.base; } r128Screen->extensions[i++] = NULL; sPriv->extensions = r128Screen->extensions; return r128Screen; } /* Destroy the device specific screen private data struct. */ static void r128DestroyScreen( __DRIscreen *sPriv ) { r128ScreenPtr r128Screen = (r128ScreenPtr)sPriv->private; if ( !r128Screen ) return; if ( !r128Screen->IsPCI ) { drmUnmap( (drmAddress)r128Screen->agpTextures.map, r128Screen->agpTextures.size ); } drmUnmapBufs( r128Screen->buffers ); drmUnmap( (drmAddress)r128Screen->mmio.map, r128Screen->mmio.size ); /* free all option information */ driDestroyOptionInfo (&r128Screen->optionCache); FREE( r128Screen ); sPriv->private = NULL; } /* Create and initialize the Mesa and driver specific pixmap buffer * data. */ static GLboolean r128CreateBuffer( __DRIscreen *driScrnPriv, __DRIdrawable *driDrawPriv, const struct gl_config *mesaVis, GLboolean isPixmap ) { r128ScreenPtr screen = (r128ScreenPtr) driScrnPriv->private; if (isPixmap) { return GL_FALSE; /* not implemented */ } else { const GLboolean swDepth = GL_FALSE; const GLboolean swAlpha = GL_FALSE; const GLboolean swAccum = mesaVis->accumRedBits > 0; const GLboolean swStencil = mesaVis->stencilBits > 0 && mesaVis->depthBits != 24; struct gl_framebuffer *fb = _mesa_create_framebuffer(mesaVis); { driRenderbuffer *frontRb = driNewRenderbuffer(MESA_FORMAT_ARGB8888, NULL, screen->cpp, screen->frontOffset, screen->frontPitch, driDrawPriv); r128SetSpanFunctions(frontRb, mesaVis); _mesa_add_renderbuffer(fb, BUFFER_FRONT_LEFT, &frontRb->Base); } if (mesaVis->doubleBufferMode) { driRenderbuffer *backRb = driNewRenderbuffer(MESA_FORMAT_ARGB8888, NULL, screen->cpp, screen->backOffset, screen->backPitch, driDrawPriv); r128SetSpanFunctions(backRb, mesaVis); _mesa_add_renderbuffer(fb, BUFFER_BACK_LEFT, &backRb->Base); } if (mesaVis->depthBits == 16) { driRenderbuffer *depthRb = driNewRenderbuffer(MESA_FORMAT_Z16, NULL, screen->cpp, screen->depthOffset, screen->depthPitch, driDrawPriv); r128SetSpanFunctions(depthRb, mesaVis); _mesa_add_renderbuffer(fb, BUFFER_DEPTH, &depthRb->Base); } else if (mesaVis->depthBits == 24) { driRenderbuffer *depthRb = driNewRenderbuffer(MESA_FORMAT_S8_Z24, NULL, screen->cpp, screen->depthOffset, screen->depthPitch, driDrawPriv); r128SetSpanFunctions(depthRb, mesaVis); _mesa_add_renderbuffer(fb, BUFFER_DEPTH, &depthRb->Base); } if (mesaVis->stencilBits > 0 && !swStencil) { driRenderbuffer *stencilRb = driNewRenderbuffer(MESA_FORMAT_S8, NULL, screen->cpp, screen->depthOffset, screen->depthPitch, driDrawPriv); r128SetSpanFunctions(stencilRb, mesaVis); _mesa_add_renderbuffer(fb, BUFFER_STENCIL, &stencilRb->Base); } _mesa_add_soft_renderbuffers(fb, GL_FALSE, /* color */ swDepth, swStencil, swAccum, swAlpha, GL_FALSE /* aux */); driDrawPriv->driverPrivate = (void *) fb; return (driDrawPriv->driverPrivate != NULL); } } static void r128DestroyBuffer(__DRIdrawable *driDrawPriv) { _mesa_reference_framebuffer((struct gl_framebuffer **)(&(driDrawPriv->driverPrivate)), NULL); } /* Copy the back color buffer to the front color buffer */ static void r128SwapBuffers(__DRIdrawable *dPriv) { if (dPriv->driContextPriv && dPriv->driContextPriv->driverPrivate) { r128ContextPtr rmesa; struct gl_context *ctx; rmesa = (r128ContextPtr) dPriv->driContextPriv->driverPrivate; ctx = rmesa->glCtx; if (ctx->Visual.doubleBufferMode) { _mesa_notifySwapBuffers( ctx ); /* flush pending rendering comands */ if ( rmesa->doPageFlip ) { r128PageFlip( dPriv ); } else { r128CopyBuffer( dPriv ); } } } else { /* XXX this shouldn't be an error but we can't handle it for now */ _mesa_problem(NULL, "%s: drawable has no context!", __FUNCTION__); } } /* Initialize the driver specific screen private data. */ static GLboolean r128InitDriver( __DRIscreen *sPriv ) { sPriv->private = (void *) r128CreateScreen( sPriv ); if ( !sPriv->private ) { r128DestroyScreen( sPriv ); return GL_FALSE; } return GL_TRUE; } static const __DRIconfig ** r128FillInModes( __DRIscreen *psp, unsigned pixel_bits, unsigned depth_bits, unsigned stencil_bits, GLboolean have_back_buffer ) { __DRIconfig **configs; struct gl_config * m; unsigned depth_buffer_factor; unsigned back_buffer_factor; GLenum fb_format; GLenum fb_type; int i; /* Right now GLX_SWAP_COPY_OML isn't supported, but it would be easy * enough to add support. Basically, if a context is created with an * fbconfig where the swap method is GLX_SWAP_COPY_OML, pageflipping * will never be used. */ static const GLenum back_buffer_modes[] = { GLX_NONE, GLX_SWAP_UNDEFINED_OML /*, GLX_SWAP_COPY_OML */ }; uint8_t depth_bits_array[2]; uint8_t stencil_bits_array[2]; uint8_t msaa_samples_array[1]; depth_bits_array[0] = depth_bits; depth_bits_array[1] = depth_bits; /* Just like with the accumulation buffer, always provide some modes * with a stencil buffer. It will be a sw fallback, but some apps won't * care about that. */ stencil_bits_array[0] = 0; stencil_bits_array[1] = (stencil_bits == 0) ? 8 : stencil_bits; msaa_samples_array[0] = 0; depth_buffer_factor = ((depth_bits != 0) || (stencil_bits != 0)) ? 2 : 1; back_buffer_factor = (have_back_buffer) ? 2 : 1; if ( pixel_bits == 16 ) { fb_format = GL_RGB; fb_type = GL_UNSIGNED_SHORT_5_6_5; } else { fb_format = GL_BGR; fb_type = GL_UNSIGNED_INT_8_8_8_8_REV; } configs = driCreateConfigs(fb_format, fb_type, depth_bits_array, stencil_bits_array, depth_buffer_factor, back_buffer_modes, back_buffer_factor, msaa_samples_array, 1, GL_TRUE); if (configs == NULL) { fprintf(stderr, "[%s:%u] Error creating FBConfig!\n", __func__, __LINE__); return NULL; } /* Mark the visual as slow if there are "fake" stencil bits. */ for (i = 0; configs[i]; i++) { m = &configs[i]->modes; if ((m->stencilBits != 0) && (m->stencilBits != stencil_bits)) { m->visualRating = GLX_SLOW_CONFIG; } } return (const __DRIconfig **) configs; } /** * This is the driver specific part of the createNewScreen entry point. * * \todo maybe fold this into intelInitDriver * * \return the struct gl_config supported by this driver */ static const __DRIconfig ** r128InitScreen(__DRIscreen *psp) { static const __DRIversion ddx_expected = { 4, 0, 0 }; static const __DRIversion dri_expected = { 4, 0, 0 }; static const __DRIversion drm_expected = { 2, 2, 0 }; R128DRIPtr dri_priv = (R128DRIPtr) psp->pDevPriv; if ( ! driCheckDriDdxDrmVersions2( "Rage128", &psp->dri_version, & dri_expected, &psp->ddx_version, & ddx_expected, &psp->drm_version, & drm_expected ) ) return NULL; if (!r128InitDriver(psp)) return NULL; return r128FillInModes( psp, dri_priv->bpp, (dri_priv->bpp == 16) ? 16 : 24, (dri_priv->bpp == 16) ? 0 : 8, (dri_priv->backOffset != dri_priv->depthOffset) ); } const struct __DriverAPIRec driDriverAPI = { .InitScreen = r128InitScreen, .DestroyScreen = r128DestroyScreen, .CreateContext = r128CreateContext, .DestroyContext = r128DestroyContext, .CreateBuffer = r128CreateBuffer, .DestroyBuffer = r128DestroyBuffer, .SwapBuffers = r128SwapBuffers, .MakeCurrent = r128MakeCurrent, .UnbindContext = r128UnbindContext, .GetSwapInfo = NULL, .GetDrawableMSC = driDrawableGetMSC32, .WaitForMSC = driWaitForMSC32, .WaitForSBC = NULL, .SwapBuffersMSC = NULL }; /* This is the table of extensions that the loader will dlsym() for. */ PUBLIC const __DRIextension *__driDriverExtensions[] = { &driCoreExtension.base, &driLegacyExtension.base, NULL };