/*************************************************************************/ /*! @Title System dependent utilities @Copyright Copyright (c) Imagination Technologies Ltd. All Rights Reserved @Description Provides system-specific functions @License Dual MIT/GPLv2 The contents of this file are subject to the MIT license as set out below. 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 the rights to use, copy, modify, merge, publish, distribute, sublicense, 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 shall be included in all copies or substantial portions of the Software. Alternatively, the contents of this file may be used under the terms of the GNU General Public License Version 2 ("GPL") in which case the provisions of GPL are applicable instead of those above. If you wish to allow use of your version of this file only under the terms of GPL, and not to allow others to use your version of this file under the terms of the MIT license, indicate your decision by deleting the provisions above and replace them with the notice and other provisions required by GPL as set out in the file called "GPL-COPYING" included in this distribution. If you do not delete the provisions above, a recipient may use your version of this file under the terms of either the MIT license or GPL. This License is also included in this distribution in the file called "MIT-COPYING". EXCEPT AS OTHERWISE STATED IN A NEGOTIATED AGREEMENT: (A) 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 NONINFRINGEMENT; AND (B) IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS 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. */ /**************************************************************************/ #include #include #include #include #include #include #include "sgxdefs.h" #include "services_headers.h" #include "sysinfo.h" #include "sgxapi_km.h" #include "sysconfig.h" #include "sgxinfokm.h" #include "syslocal.h" #include #include #if defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) #include "sgxfreq.h" #endif #if defined(SUPPORT_DRI_DRM_PLUGIN) #include #include #include #include "pvr_drm.h" #endif #if defined(CONFIG_OMAP4_DPLL_CASCADING) #include #endif #define ONE_MHZ 1000000 #define HZ_TO_MHZ(m) ((m) / ONE_MHZ) #if defined(SUPPORT_OMAP3430_SGXFCLK_96M) #define SGX_PARENT_CLOCK "cm_96m_fck" #else #define SGX_PARENT_CLOCK "core_ck" #endif #if defined(LDM_PLATFORM) && !defined(PVR_DRI_DRM_NOT_PCI) extern struct platform_device *gpsPVRLDMDev; #endif static PVRSRV_ERROR PowerLockWrap(SYS_SPECIFIC_DATA *psSysSpecData, IMG_BOOL bTryLock) { if (!in_interrupt()) { if (bTryLock) { int locked = mutex_trylock(&psSysSpecData->sPowerLock); if (locked == 0) { return PVRSRV_ERROR_RETRY; } } else { mutex_lock(&psSysSpecData->sPowerLock); } } return PVRSRV_OK; } static IMG_VOID PowerLockUnwrap(SYS_SPECIFIC_DATA *psSysSpecData) { if (!in_interrupt()) { mutex_unlock(&psSysSpecData->sPowerLock); } } PVRSRV_ERROR SysPowerLockWrap(IMG_BOOL bTryLock) { SYS_DATA *psSysData; SysAcquireData(&psSysData); return PowerLockWrap(psSysData->pvSysSpecificData, bTryLock); } IMG_VOID SysPowerLockUnwrap(IMG_VOID) { SYS_DATA *psSysData; SysAcquireData(&psSysData); PowerLockUnwrap(psSysData->pvSysSpecificData); } /* * This function should be called to unwrap the Services power lock, prior * to calling any function that might sleep. * This function shouldn't be called prior to calling EnableSystemClocks * or DisableSystemClocks, as those functions perform their own power lock * unwrapping. * If the function returns IMG_TRUE, UnwrapSystemPowerChange must be * called to rewrap the power lock, prior to returning to Services. */ IMG_BOOL WrapSystemPowerChange(SYS_SPECIFIC_DATA *psSysSpecData) { return IMG_TRUE; } IMG_VOID UnwrapSystemPowerChange(SYS_SPECIFIC_DATA *psSysSpecData) { } /* * Return SGX timining information to caller. */ IMG_VOID SysGetSGXTimingInformation(SGX_TIMING_INFORMATION *psTimingInfo) { #if !defined(NO_HARDWARE) PVR_ASSERT(atomic_read(&gpsSysSpecificData->sSGXClocksEnabled) != 0); #endif #if defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) /* * The core SGX driver and ukernel code expects SGX frequency * changes to occur only just prior to SGX initialization. We * don't wish to constrain the DVFS implementation as such. So * we let these components believe that frequency setting is * always at maximum. This produces safe values for derived * parameters such as APM and HWR timeouts. */ psTimingInfo->ui32CoreClockSpeed = (IMG_UINT32)sgxfreq_get_freq_max(); #else /* defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) */ psTimingInfo->ui32CoreClockSpeed = SYS_SGX_CLOCK_SPEED; #endif psTimingInfo->ui32HWRecoveryFreq = SYS_SGX_HWRECOVERY_TIMEOUT_FREQ; psTimingInfo->ui32uKernelFreq = SYS_SGX_PDS_TIMER_FREQ; #if defined(SUPPORT_ACTIVE_POWER_MANAGEMENT) psTimingInfo->bEnableActivePM = IMG_TRUE; #else psTimingInfo->bEnableActivePM = IMG_FALSE; #endif /* SUPPORT_ACTIVE_POWER_MANAGEMENT */ psTimingInfo->ui32ActivePowManLatencyms = SYS_SGX_ACTIVE_POWER_LATENCY_MS; } /*! ****************************************************************************** @Function EnableSGXClocks @Description Enable SGX clocks @Return PVRSRV_ERROR ******************************************************************************/ PVRSRV_ERROR EnableSGXClocks(SYS_DATA *psSysData) { #if !defined(NO_HARDWARE) SYS_SPECIFIC_DATA *psSysSpecData = (SYS_SPECIFIC_DATA *) psSysData->pvSysSpecificData; /* SGX clocks already enabled? */ if (atomic_read(&psSysSpecData->sSGXClocksEnabled) != 0) { return PVRSRV_OK; } PVR_DPF((PVR_DBG_MESSAGE, "EnableSGXClocks: Enabling SGX Clocks")); #if defined(LDM_PLATFORM) && !defined(PVR_DRI_DRM_NOT_PCI) { int res; #if defined(CONFIG_OMAP4_DPLL_CASCADING) if (omap4_dpll_cascading_blocker_hold(&gpsPVRLDMDev->dev)) { PVR_DPF((PVR_DBG_WARNING, "EnableSGXClocks: " "omap4_dpll_cascading_blocker_hold failed")); } #endif /* * pm_runtime_get_sync returns 1 after the module has * been reloaded. */ res = pm_runtime_get_sync(&gpsPVRLDMDev->dev); if (res < 0) { PVR_DPF((PVR_DBG_ERROR, "EnableSGXClocks: pm_runtime_get_sync failed (%d)", -res)); return PVRSRV_ERROR_UNABLE_TO_ENABLE_CLOCK; } } #if defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) sgxfreq_notif_sgx_clk_on(); #endif /* defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) */ #endif /* defined(LDM_PLATFORM) && !defined(PVR_DRI_DRM_NOT_PCI) */ SysEnableSGXInterrupts(psSysData); /* Indicate that the SGX clocks are enabled */ atomic_set(&psSysSpecData->sSGXClocksEnabled, 1); #else /* !defined(NO_HARDWARE) */ PVR_UNREFERENCED_PARAMETER(psSysData); #endif /* !defined(NO_HARDWARE) */ return PVRSRV_OK; } /*! ****************************************************************************** @Function DisableSGXClocks @Description Disable SGX clocks. @Return none ******************************************************************************/ IMG_VOID DisableSGXClocks(SYS_DATA *psSysData) { #if !defined(NO_HARDWARE) SYS_SPECIFIC_DATA *psSysSpecData = (SYS_SPECIFIC_DATA *) psSysData->pvSysSpecificData; /* SGX clocks already disabled? */ if (atomic_read(&psSysSpecData->sSGXClocksEnabled) == 0) { return; } PVR_DPF((PVR_DBG_MESSAGE, "DisableSGXClocks: Disabling SGX Clocks")); SysDisableSGXInterrupts(psSysData); #if defined(LDM_PLATFORM) && !defined(PVR_DRI_DRM_NOT_PCI) { int res = pm_runtime_put_sync(&gpsPVRLDMDev->dev); if (res < 0) { PVR_DPF((PVR_DBG_ERROR, "DisableSGXClocks: pm_runtime_put_sync failed (%d)", -res)); } #if defined(CONFIG_OMAP4_DPLL_CASCADING) if (omap4_dpll_cascading_blocker_release(&gpsPVRLDMDev->dev)) { PVR_DPF((PVR_DBG_WARNING, "DisableSGXClocks: " "omap4_dpll_cascading_blocker_release failed")); } #endif } #if defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) sgxfreq_notif_sgx_clk_off(); #endif /* defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) */ #endif /* defined(LDM_PLATFORM) && !defined(PVR_DRI_DRM_NOT_PCI) */ /* Indicate that the SGX clocks are disabled */ atomic_set(&psSysSpecData->sSGXClocksEnabled, 0); #else /* !defined(NO_HARDWARE) */ PVR_UNREFERENCED_PARAMETER(psSysData); #endif /* !defined(NO_HARDWARE) */ } #if (defined(DEBUG) || defined(TIMING)) && !defined(PVR_NO_OMAP_TIMER) #if defined(PVR_OMAP_USE_DM_TIMER_API) #define GPTIMER_TO_USE 11 /*! ****************************************************************************** @Function AcquireGPTimer @Description Acquire a GP timer @Return PVRSRV_ERROR ******************************************************************************/ static PVRSRV_ERROR AcquireGPTimer(SYS_SPECIFIC_DATA *psSysSpecData) { PVR_ASSERT(psSysSpecData->psGPTimer == NULL); /* * This code could try requesting registers 9, 10, and 11, * stopping at the first succesful request. We'll stick with * 11 for now, as it avoids having to hard code yet more * physical addresses into the code. */ psSysSpecData->psGPTimer = omap_dm_timer_request_specific(GPTIMER_TO_USE); if (psSysSpecData->psGPTimer == NULL) { PVR_DPF((PVR_DBG_WARNING, "%s: omap_dm_timer_request_specific failed", __FUNCTION__)); return PVRSRV_ERROR_CLOCK_REQUEST_FAILED; } /* Set timer source to system clock */ omap_dm_timer_set_source(psSysSpecData->psGPTimer, OMAP_TIMER_SRC_SYS_CLK); omap_dm_timer_enable(psSysSpecData->psGPTimer); /* Set autoreload, and start value of 0 */ omap_dm_timer_set_load_start(psSysSpecData->psGPTimer, 1, 0); omap_dm_timer_start(psSysSpecData->psGPTimer); /* * The DM timer API doesn't have a mechansim for obtaining the * physical address of the counter register. */ psSysSpecData->sTimerRegPhysBase.uiAddr = SYS_OMAP4430_GP11TIMER_REGS_SYS_PHYS_BASE; return PVRSRV_OK; } /*! ****************************************************************************** @Function ReleaseGPTimer @Description Release a GP timer @Return PVRSRV_ERROR ******************************************************************************/ static void ReleaseGPTimer(SYS_SPECIFIC_DATA *psSysSpecData) { if (psSysSpecData->psGPTimer != NULL) { /* Always returns 0 */ (void) omap_dm_timer_stop(psSysSpecData->psGPTimer); omap_dm_timer_disable(psSysSpecData->psGPTimer); omap_dm_timer_free(psSysSpecData->psGPTimer); psSysSpecData->sTimerRegPhysBase.uiAddr = 0; psSysSpecData->psGPTimer = NULL; } } #else /* PVR_OMAP_USE_DM_TIMER_API */ /*! ****************************************************************************** @Function AcquireGPTimer @Description Acquire a GP timer @Return PVRSRV_ERROR ******************************************************************************/ static PVRSRV_ERROR AcquireGPTimer(SYS_SPECIFIC_DATA *psSysSpecData) { #if defined(PVR_OMAP4_TIMING_PRCM) struct clk *psCLK; IMG_INT res; struct clk *sys_ck; IMG_INT rate; #endif PVRSRV_ERROR eError; IMG_CPU_PHYADDR sTimerRegPhysBase; IMG_HANDLE hTimerEnable; IMG_UINT32 *pui32TimerEnable; PVR_ASSERT(psSysSpecData->sTimerRegPhysBase.uiAddr == 0); #if defined(PVR_OMAP4_TIMING_PRCM) /* assert our dependence on the GPTIMER11 module */ psCLK = clk_get(NULL, "gpt11_fck"); if (IS_ERR(psCLK)) { PVR_DPF((PVR_DBG_ERROR, "EnableSystemClocks: Couldn't get GPTIMER11 functional clock")); goto ExitError; } psSysSpecData->psGPT11_FCK = psCLK; psCLK = clk_get(NULL, "gpt11_ick"); if (IS_ERR(psCLK)) { PVR_DPF((PVR_DBG_ERROR, "EnableSystemClocks: Couldn't get GPTIMER11 interface clock")); goto ExitError; } psSysSpecData->psGPT11_ICK = psCLK; sys_ck = clk_get(NULL, "sys_clkin_ck"); if (IS_ERR(sys_ck)) { PVR_DPF((PVR_DBG_ERROR, "EnableSystemClocks: Couldn't get System clock")); goto ExitError; } if(clk_get_parent(psSysSpecData->psGPT11_FCK) != sys_ck) { PVR_TRACE(("Setting GPTIMER11 parent to System Clock")); res = clk_set_parent(psSysSpecData->psGPT11_FCK, sys_ck); if (res < 0) { PVR_DPF((PVR_DBG_ERROR, "EnableSystemClocks: Couldn't set GPTIMER11 parent clock (%d)", res)); goto ExitError; } } rate = clk_get_rate(psSysSpecData->psGPT11_FCK); PVR_TRACE(("GPTIMER11 clock is %dMHz", HZ_TO_MHZ(rate))); res = clk_enable(psSysSpecData->psGPT11_FCK); if (res < 0) { PVR_DPF((PVR_DBG_ERROR, "EnableSystemClocks: Couldn't enable GPTIMER11 functional clock (%d)", res)); goto ExitError; } res = clk_enable(psSysSpecData->psGPT11_ICK); if (res < 0) { PVR_DPF((PVR_DBG_ERROR, "EnableSystemClocks: Couldn't enable GPTIMER11 interface clock (%d)", res)); goto ExitDisableGPT11FCK; } #endif /* defined(PVR_OMAP4_TIMING_PRCM) */ /* Set the timer to non-posted mode */ sTimerRegPhysBase.uiAddr = SYS_OMAP4430_GP11TIMER_TSICR_SYS_PHYS_BASE; pui32TimerEnable = OSMapPhysToLin(sTimerRegPhysBase, 4, PVRSRV_HAP_KERNEL_ONLY|PVRSRV_HAP_UNCACHED, &hTimerEnable); if (pui32TimerEnable == IMG_NULL) { PVR_DPF((PVR_DBG_ERROR, "EnableSystemClocks: OSMapPhysToLin failed")); goto ExitDisableGPT11ICK; } if(!(*pui32TimerEnable & 4)) { PVR_TRACE(("Setting GPTIMER11 mode to posted (currently is non-posted)")); /* Set posted mode */ *pui32TimerEnable |= 4; } OSUnMapPhysToLin(pui32TimerEnable, 4, PVRSRV_HAP_KERNEL_ONLY|PVRSRV_HAP_UNCACHED, hTimerEnable); /* Enable the timer */ sTimerRegPhysBase.uiAddr = SYS_OMAP4430_GP11TIMER_ENABLE_SYS_PHYS_BASE; pui32TimerEnable = OSMapPhysToLin(sTimerRegPhysBase, 4, PVRSRV_HAP_KERNEL_ONLY|PVRSRV_HAP_UNCACHED, &hTimerEnable); if (pui32TimerEnable == IMG_NULL) { PVR_DPF((PVR_DBG_ERROR, "EnableSystemClocks: OSMapPhysToLin failed")); goto ExitDisableGPT11ICK; } /* Enable and set autoreload on overflow */ *pui32TimerEnable = 3; OSUnMapPhysToLin(pui32TimerEnable, 4, PVRSRV_HAP_KERNEL_ONLY|PVRSRV_HAP_UNCACHED, hTimerEnable); psSysSpecData->sTimerRegPhysBase = sTimerRegPhysBase; eError = PVRSRV_OK; goto Exit; ExitDisableGPT11ICK: #if defined(PVR_OMAP4_TIMING_PRCM) clk_disable(psSysSpecData->psGPT11_ICK); ExitDisableGPT11FCK: clk_disable(psSysSpecData->psGPT11_FCK); ExitError: #endif /* defined(PVR_OMAP4_TIMING_PRCM) */ eError = PVRSRV_ERROR_CLOCK_REQUEST_FAILED; Exit: return eError; } /*! ****************************************************************************** @Function ReleaseGPTimer @Description Release a GP timer @Return PVRSRV_ERROR ******************************************************************************/ static void ReleaseGPTimer(SYS_SPECIFIC_DATA *psSysSpecData) { IMG_HANDLE hTimerDisable; IMG_UINT32 *pui32TimerDisable; if (psSysSpecData->sTimerRegPhysBase.uiAddr == 0) { return; } /* Disable the timer */ pui32TimerDisable = OSMapPhysToLin(psSysSpecData->sTimerRegPhysBase, 4, PVRSRV_HAP_KERNEL_ONLY|PVRSRV_HAP_UNCACHED, &hTimerDisable); if (pui32TimerDisable == IMG_NULL) { PVR_DPF((PVR_DBG_ERROR, "DisableSystemClocks: OSMapPhysToLin failed")); } else { *pui32TimerDisable = 0; OSUnMapPhysToLin(pui32TimerDisable, 4, PVRSRV_HAP_KERNEL_ONLY|PVRSRV_HAP_UNCACHED, hTimerDisable); } psSysSpecData->sTimerRegPhysBase.uiAddr = 0; #if defined(PVR_OMAP4_TIMING_PRCM) clk_disable(psSysSpecData->psGPT11_ICK); clk_disable(psSysSpecData->psGPT11_FCK); #endif /* defined(PVR_OMAP4_TIMING_PRCM) */ } #endif /* PVR_OMAP_USE_DM_TIMER_API */ #else /* (DEBUG || TIMING) && !PVR_NO_OMAP_TIMER */ static PVRSRV_ERROR AcquireGPTimer(SYS_SPECIFIC_DATA *psSysSpecData) { PVR_UNREFERENCED_PARAMETER(psSysSpecData); return PVRSRV_OK; } static void ReleaseGPTimer(SYS_SPECIFIC_DATA *psSysSpecData) { PVR_UNREFERENCED_PARAMETER(psSysSpecData); } #endif /* (DEBUG || TIMING) && !PVR_NO_OMAP_TIMER */ /*! ****************************************************************************** @Function EnableSystemClocks @Description Setup up the clocks for the graphics device to work. @Return PVRSRV_ERROR ******************************************************************************/ PVRSRV_ERROR EnableSystemClocks(SYS_DATA *psSysData) { SYS_SPECIFIC_DATA *psSysSpecData = (SYS_SPECIFIC_DATA *) psSysData->pvSysSpecificData; PVR_TRACE(("EnableSystemClocks: Enabling System Clocks")); if (!psSysSpecData->bSysClocksOneTimeInit) { mutex_init(&psSysSpecData->sPowerLock); atomic_set(&psSysSpecData->sSGXClocksEnabled, 0); psSysSpecData->bSysClocksOneTimeInit = IMG_TRUE; } return AcquireGPTimer(psSysSpecData); } /*! ****************************************************************************** @Function DisableSystemClocks @Description Disable the graphics clocks. @Return none ******************************************************************************/ IMG_VOID DisableSystemClocks(SYS_DATA *psSysData) { SYS_SPECIFIC_DATA *psSysSpecData = (SYS_SPECIFIC_DATA *) psSysData->pvSysSpecificData; PVR_TRACE(("DisableSystemClocks: Disabling System Clocks")); /* * Always disable the SGX clocks when the system clocks are disabled. * This saves having to make an explicit call to DisableSGXClocks if * active power management is enabled. */ DisableSGXClocks(psSysData); ReleaseGPTimer(psSysSpecData); } PVRSRV_ERROR SysPMRuntimeRegister(SYS_SPECIFIC_DATA *psSysSpecificData) { #if defined(LDM_PLATFORM) && !defined(PVR_DRI_DRM_NOT_PCI) pm_runtime_enable(&gpsPVRLDMDev->dev); #endif #if defined(CONFIG_HAS_WAKELOCK) wake_lock_init(&psSysSpecificData->wake_lock, WAKE_LOCK_SUSPEND, "pvrsrvkm"); #endif return PVRSRV_OK; } PVRSRV_ERROR SysPMRuntimeUnregister(SYS_SPECIFIC_DATA *psSysSpecificData) { #if defined(LDM_PLATFORM) && !defined(PVR_DRI_DRM_NOT_PCI) pm_runtime_disable(&gpsPVRLDMDev->dev); #endif #if defined(CONFIG_HAS_WAKELOCK) wake_lock_destroy(&psSysSpecificData->wake_lock); #endif return PVRSRV_OK; } PVRSRV_ERROR SysDvfsInitialize(SYS_SPECIFIC_DATA *psSysSpecificData) { PVR_UNREFERENCED_PARAMETER(psSysSpecificData); #if defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) if (sgxfreq_init(&gpsPVRLDMDev->dev)) return PVRSRV_ERROR_NOT_SUPPORTED; #endif /* defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) */ return PVRSRV_OK; } PVRSRV_ERROR SysDvfsDeinitialize(SYS_SPECIFIC_DATA *psSysSpecificData) { PVR_UNREFERENCED_PARAMETER(psSysSpecificData); #if defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) if (sgxfreq_deinit()) return PVRSRV_ERROR_NOT_SUPPORTED; #endif /* defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) */ return PVRSRV_OK; } #if defined(SUPPORT_DRI_DRM_PLUGIN) static struct omap_gpu_plugin sOMAPGPUPlugin; #define SYS_DRM_SET_PLUGIN_FIELD(d, s, f) (d)->f = (s)->f int SysDRMRegisterPlugin(PVRSRV_DRM_PLUGIN *psDRMPlugin) { int iRes; SYS_DRM_SET_PLUGIN_FIELD(&sOMAPGPUPlugin, psDRMPlugin, name); SYS_DRM_SET_PLUGIN_FIELD(&sOMAPGPUPlugin, psDRMPlugin, open); SYS_DRM_SET_PLUGIN_FIELD(&sOMAPGPUPlugin, psDRMPlugin, load); SYS_DRM_SET_PLUGIN_FIELD(&sOMAPGPUPlugin, psDRMPlugin, unload); SYS_DRM_SET_PLUGIN_FIELD(&sOMAPGPUPlugin, psDRMPlugin, release); SYS_DRM_SET_PLUGIN_FIELD(&sOMAPGPUPlugin, psDRMPlugin, mmap); SYS_DRM_SET_PLUGIN_FIELD(&sOMAPGPUPlugin, psDRMPlugin, ioctls); SYS_DRM_SET_PLUGIN_FIELD(&sOMAPGPUPlugin, psDRMPlugin, num_ioctls); SYS_DRM_SET_PLUGIN_FIELD(&sOMAPGPUPlugin, psDRMPlugin, ioctl_start); iRes = omap_gpu_register_plugin(&sOMAPGPUPlugin); if (iRes != 0) { PVR_DPF((PVR_DBG_ERROR, "%s: omap_gpu_register_plugin failed (%d)", __FUNCTION__, iRes)); } return iRes; } void SysDRMUnregisterPlugin(PVRSRV_DRM_PLUGIN *psDRMPlugin) { int iRes = omap_gpu_unregister_plugin(&sOMAPGPUPlugin); if (iRes != 0) { PVR_DPF((PVR_DBG_ERROR, "%s: omap_gpu_unregister_plugin failed (%d)", __FUNCTION__, iRes)); } } #endif int pvr_access_process_vm(struct task_struct *tsk, unsigned long addr, void *buf, int len, int write) { struct gpu_platform_data *pdata; pdata = (struct gpu_platform_data *)gpsPVRLDMDev->dev.platform_data; if(!pdata || !pdata->access_process_vm) return -1; return pdata->access_process_vm(tsk, addr, buf, len, write); } IMG_VOID SysSGXIdleEntered(IMG_VOID) { #if defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) sgxfreq_notif_sgx_idle(); #endif } IMG_VOID SysSGXCommandPending(IMG_BOOL bSGXIdle) { #if defined(SYS_OMAP4_HAS_DVFS_FRAMEWORK) if (bSGXIdle) sgxfreq_notif_sgx_active(); #else PVR_UNREFERENCED_PARAMETER(bSGXIdle); #endif }