linux/drivers/gpu/drm/msm/adreno/a5xx_gpu.c

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/* Copyright (c) 2016-2017 The Linux Foundation. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 and
* only version 2 as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
*/
#include <linux/kernel.h>
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
#include <linux/types.h>
#include <linux/cpumask.h>
#include <linux/qcom_scm.h>
#include <linux/dma-mapping.h>
drm/msm: gpu: don't abuse dma_alloc for non-DMA allocations In zap_shader_load_mdt(), we pass a pointer to a phys_addr_t into dmam_alloc_coherent, which the compiler warns about: drivers/gpu/drm/msm/adreno/a5xx_gpu.c: In function 'zap_shader_load_mdt': drivers/gpu/drm/msm/adreno/a5xx_gpu.c:54:50: error: passing argument 3 of 'dmam_alloc_coherent' from incompatible pointer type [-Werror=incompatible-pointer-types] The returned DMA address is later passed on to a function that takes a phys_addr_t, so it's clearly wrong to use the DMA mapping interface here: the memory may be uncached, or the address may be completely wrong if there is an IOMMU connected to the device. What the code actually wants to do is to get the physical address from the reserved-mem node. It goes through the dma-mapping interfaces for obscure reasons, and this apparently only works by chance, relying on specific bugs in the error handling of the arm64 dma-mapping implementation. The same problem existed in the "venus" media driver, which was now fixed by Stanimir Varbanov after long discussions. In order to make some progress here, I have now ported his approach over to the adreno driver. The patch is currently untested, and should get a good review, but it is now much simpler than the original, and it should be obvious what goes wrong if I made a mistake in the port. See also: a6e2d36bf6b7 ("media: venus: don't abuse dma_alloc for non-DMA allocations") Cc: Stanimir Varbanov <stanimir.varbanov@linaro.org> Fixes: 7c65817e6d38 ("drm/msm: gpu: Enable zap shader for A5XX") Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> Acked-and-Tested-by: Jordan Crouse <jcrouse@codeaurora.org> Signed-off-by: Arnd Bergmann <arnd@arndb.de> Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-07-27 03:59:21 +08:00
#include <linux/of_address.h>
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
#include <linux/soc/qcom/mdt_loader.h>
#include <linux/pm_opp.h>
#include <linux/nvmem-consumer.h>
#include <linux/iopoll.h>
#include <linux/slab.h>
#include "msm_gem.h"
#include "msm_mmu.h"
#include "a5xx_gpu.h"
extern bool hang_debug;
static void a5xx_dump(struct msm_gpu *gpu);
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
#define GPU_PAS_ID 13
static int zap_shader_load_mdt(struct msm_gpu *gpu, const char *fwname)
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
{
struct device *dev = &gpu->pdev->dev;
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
const struct firmware *fw;
drm/msm: gpu: don't abuse dma_alloc for non-DMA allocations In zap_shader_load_mdt(), we pass a pointer to a phys_addr_t into dmam_alloc_coherent, which the compiler warns about: drivers/gpu/drm/msm/adreno/a5xx_gpu.c: In function 'zap_shader_load_mdt': drivers/gpu/drm/msm/adreno/a5xx_gpu.c:54:50: error: passing argument 3 of 'dmam_alloc_coherent' from incompatible pointer type [-Werror=incompatible-pointer-types] The returned DMA address is later passed on to a function that takes a phys_addr_t, so it's clearly wrong to use the DMA mapping interface here: the memory may be uncached, or the address may be completely wrong if there is an IOMMU connected to the device. What the code actually wants to do is to get the physical address from the reserved-mem node. It goes through the dma-mapping interfaces for obscure reasons, and this apparently only works by chance, relying on specific bugs in the error handling of the arm64 dma-mapping implementation. The same problem existed in the "venus" media driver, which was now fixed by Stanimir Varbanov after long discussions. In order to make some progress here, I have now ported his approach over to the adreno driver. The patch is currently untested, and should get a good review, but it is now much simpler than the original, and it should be obvious what goes wrong if I made a mistake in the port. See also: a6e2d36bf6b7 ("media: venus: don't abuse dma_alloc for non-DMA allocations") Cc: Stanimir Varbanov <stanimir.varbanov@linaro.org> Fixes: 7c65817e6d38 ("drm/msm: gpu: Enable zap shader for A5XX") Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> Acked-and-Tested-by: Jordan Crouse <jcrouse@codeaurora.org> Signed-off-by: Arnd Bergmann <arnd@arndb.de> Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-07-27 03:59:21 +08:00
struct device_node *np;
struct resource r;
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
phys_addr_t mem_phys;
ssize_t mem_size;
void *mem_region = NULL;
int ret;
if (!IS_ENABLED(CONFIG_ARCH_QCOM))
return -EINVAL;
drm/msm: gpu: don't abuse dma_alloc for non-DMA allocations In zap_shader_load_mdt(), we pass a pointer to a phys_addr_t into dmam_alloc_coherent, which the compiler warns about: drivers/gpu/drm/msm/adreno/a5xx_gpu.c: In function 'zap_shader_load_mdt': drivers/gpu/drm/msm/adreno/a5xx_gpu.c:54:50: error: passing argument 3 of 'dmam_alloc_coherent' from incompatible pointer type [-Werror=incompatible-pointer-types] The returned DMA address is later passed on to a function that takes a phys_addr_t, so it's clearly wrong to use the DMA mapping interface here: the memory may be uncached, or the address may be completely wrong if there is an IOMMU connected to the device. What the code actually wants to do is to get the physical address from the reserved-mem node. It goes through the dma-mapping interfaces for obscure reasons, and this apparently only works by chance, relying on specific bugs in the error handling of the arm64 dma-mapping implementation. The same problem existed in the "venus" media driver, which was now fixed by Stanimir Varbanov after long discussions. In order to make some progress here, I have now ported his approach over to the adreno driver. The patch is currently untested, and should get a good review, but it is now much simpler than the original, and it should be obvious what goes wrong if I made a mistake in the port. See also: a6e2d36bf6b7 ("media: venus: don't abuse dma_alloc for non-DMA allocations") Cc: Stanimir Varbanov <stanimir.varbanov@linaro.org> Fixes: 7c65817e6d38 ("drm/msm: gpu: Enable zap shader for A5XX") Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> Acked-and-Tested-by: Jordan Crouse <jcrouse@codeaurora.org> Signed-off-by: Arnd Bergmann <arnd@arndb.de> Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-07-27 03:59:21 +08:00
np = of_get_child_by_name(dev->of_node, "zap-shader");
if (!np)
return -ENODEV;
np = of_parse_phandle(np, "memory-region", 0);
if (!np)
return -EINVAL;
ret = of_address_to_resource(np, 0, &r);
if (ret)
return ret;
mem_phys = r.start;
mem_size = resource_size(&r);
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
/* Request the MDT file for the firmware */
fw = adreno_request_fw(to_adreno_gpu(gpu), fwname);
if (IS_ERR(fw)) {
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
DRM_DEV_ERROR(dev, "Unable to load %s\n", fwname);
return PTR_ERR(fw);
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
}
/* Figure out how much memory we need */
mem_size = qcom_mdt_get_size(fw);
if (mem_size < 0) {
ret = mem_size;
goto out;
}
/* Allocate memory for the firmware image */
drm/msm: gpu: don't abuse dma_alloc for non-DMA allocations In zap_shader_load_mdt(), we pass a pointer to a phys_addr_t into dmam_alloc_coherent, which the compiler warns about: drivers/gpu/drm/msm/adreno/a5xx_gpu.c: In function 'zap_shader_load_mdt': drivers/gpu/drm/msm/adreno/a5xx_gpu.c:54:50: error: passing argument 3 of 'dmam_alloc_coherent' from incompatible pointer type [-Werror=incompatible-pointer-types] The returned DMA address is later passed on to a function that takes a phys_addr_t, so it's clearly wrong to use the DMA mapping interface here: the memory may be uncached, or the address may be completely wrong if there is an IOMMU connected to the device. What the code actually wants to do is to get the physical address from the reserved-mem node. It goes through the dma-mapping interfaces for obscure reasons, and this apparently only works by chance, relying on specific bugs in the error handling of the arm64 dma-mapping implementation. The same problem existed in the "venus" media driver, which was now fixed by Stanimir Varbanov after long discussions. In order to make some progress here, I have now ported his approach over to the adreno driver. The patch is currently untested, and should get a good review, but it is now much simpler than the original, and it should be obvious what goes wrong if I made a mistake in the port. See also: a6e2d36bf6b7 ("media: venus: don't abuse dma_alloc for non-DMA allocations") Cc: Stanimir Varbanov <stanimir.varbanov@linaro.org> Fixes: 7c65817e6d38 ("drm/msm: gpu: Enable zap shader for A5XX") Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> Acked-and-Tested-by: Jordan Crouse <jcrouse@codeaurora.org> Signed-off-by: Arnd Bergmann <arnd@arndb.de> Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-07-27 03:59:21 +08:00
mem_region = memremap(mem_phys, mem_size, MEMREMAP_WC);
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
if (!mem_region) {
ret = -ENOMEM;
goto out;
}
/*
* Load the rest of the MDT
*
* Note that we could be dealing with two different paths, since
* with upstream linux-firmware it would be in a qcom/ subdir..
* adreno_request_fw() handles this, but qcom_mdt_load() does
* not. But since we've already gotten thru adreno_request_fw()
* we know which of the two cases it is:
*/
if (to_adreno_gpu(gpu)->fwloc == FW_LOCATION_LEGACY) {
ret = qcom_mdt_load(dev, fw, fwname, GPU_PAS_ID,
mem_region, mem_phys, mem_size, NULL);
} else {
char *newname;
newname = kasprintf(GFP_KERNEL, "qcom/%s", fwname);
ret = qcom_mdt_load(dev, fw, newname, GPU_PAS_ID,
mem_region, mem_phys, mem_size, NULL);
kfree(newname);
}
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
if (ret)
goto out;
/* Send the image to the secure world */
ret = qcom_scm_pas_auth_and_reset(GPU_PAS_ID);
if (ret)
DRM_DEV_ERROR(dev, "Unable to authorize the image\n");
out:
drm/msm: gpu: don't abuse dma_alloc for non-DMA allocations In zap_shader_load_mdt(), we pass a pointer to a phys_addr_t into dmam_alloc_coherent, which the compiler warns about: drivers/gpu/drm/msm/adreno/a5xx_gpu.c: In function 'zap_shader_load_mdt': drivers/gpu/drm/msm/adreno/a5xx_gpu.c:54:50: error: passing argument 3 of 'dmam_alloc_coherent' from incompatible pointer type [-Werror=incompatible-pointer-types] The returned DMA address is later passed on to a function that takes a phys_addr_t, so it's clearly wrong to use the DMA mapping interface here: the memory may be uncached, or the address may be completely wrong if there is an IOMMU connected to the device. What the code actually wants to do is to get the physical address from the reserved-mem node. It goes through the dma-mapping interfaces for obscure reasons, and this apparently only works by chance, relying on specific bugs in the error handling of the arm64 dma-mapping implementation. The same problem existed in the "venus" media driver, which was now fixed by Stanimir Varbanov after long discussions. In order to make some progress here, I have now ported his approach over to the adreno driver. The patch is currently untested, and should get a good review, but it is now much simpler than the original, and it should be obvious what goes wrong if I made a mistake in the port. See also: a6e2d36bf6b7 ("media: venus: don't abuse dma_alloc for non-DMA allocations") Cc: Stanimir Varbanov <stanimir.varbanov@linaro.org> Fixes: 7c65817e6d38 ("drm/msm: gpu: Enable zap shader for A5XX") Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> Acked-and-Tested-by: Jordan Crouse <jcrouse@codeaurora.org> Signed-off-by: Arnd Bergmann <arnd@arndb.de> Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-07-27 03:59:21 +08:00
if (mem_region)
memunmap(mem_region);
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
release_firmware(fw);
return ret;
}
static void a5xx_flush(struct msm_gpu *gpu, struct msm_ringbuffer *ring)
{
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
struct a5xx_gpu *a5xx_gpu = to_a5xx_gpu(adreno_gpu);
uint32_t wptr;
unsigned long flags;
spin_lock_irqsave(&ring->lock, flags);
/* Copy the shadow to the actual register */
ring->cur = ring->next;
/* Make sure to wrap wptr if we need to */
wptr = get_wptr(ring);
spin_unlock_irqrestore(&ring->lock, flags);
/* Make sure everything is posted before making a decision */
mb();
/* Update HW if this is the current ring and we are not in preempt */
if (a5xx_gpu->cur_ring == ring && !a5xx_in_preempt(a5xx_gpu))
gpu_write(gpu, REG_A5XX_CP_RB_WPTR, wptr);
}
static void a5xx_submit_in_rb(struct msm_gpu *gpu, struct msm_gem_submit *submit,
struct msm_file_private *ctx)
{
struct msm_drm_private *priv = gpu->dev->dev_private;
struct msm_ringbuffer *ring = submit->ring;
struct msm_gem_object *obj;
uint32_t *ptr, dwords;
unsigned int i;
for (i = 0; i < submit->nr_cmds; i++) {
switch (submit->cmd[i].type) {
case MSM_SUBMIT_CMD_IB_TARGET_BUF:
break;
case MSM_SUBMIT_CMD_CTX_RESTORE_BUF:
if (priv->lastctx == ctx)
break;
case MSM_SUBMIT_CMD_BUF:
/* copy commands into RB: */
obj = submit->bos[submit->cmd[i].idx].obj;
dwords = submit->cmd[i].size;
ptr = msm_gem_get_vaddr(&obj->base);
/* _get_vaddr() shouldn't fail at this point,
* since we've already mapped it once in
* submit_reloc()
*/
if (WARN_ON(!ptr))
return;
for (i = 0; i < dwords; i++) {
/* normally the OUT_PKTn() would wait
* for space for the packet. But since
* we just OUT_RING() the whole thing,
* need to call adreno_wait_ring()
* ourself:
*/
adreno_wait_ring(ring, 1);
OUT_RING(ring, ptr[i]);
}
msm_gem_put_vaddr(&obj->base);
break;
}
}
a5xx_flush(gpu, ring);
a5xx_preempt_trigger(gpu);
/* we might not necessarily have a cmd from userspace to
* trigger an event to know that submit has completed, so
* do this manually:
*/
a5xx_idle(gpu, ring);
ring->memptrs->fence = submit->seqno;
msm_gpu_retire(gpu);
}
static void a5xx_submit(struct msm_gpu *gpu, struct msm_gem_submit *submit,
struct msm_file_private *ctx)
{
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
struct a5xx_gpu *a5xx_gpu = to_a5xx_gpu(adreno_gpu);
struct msm_drm_private *priv = gpu->dev->dev_private;
struct msm_ringbuffer *ring = submit->ring;
unsigned int i, ibs = 0;
if (IS_ENABLED(CONFIG_DRM_MSM_GPU_SUDO) && submit->in_rb) {
priv->lastctx = NULL;
a5xx_submit_in_rb(gpu, submit, ctx);
return;
}
OUT_PKT7(ring, CP_PREEMPT_ENABLE_GLOBAL, 1);
OUT_RING(ring, 0x02);
/* Turn off protected mode to write to special registers */
OUT_PKT7(ring, CP_SET_PROTECTED_MODE, 1);
OUT_RING(ring, 0);
/* Set the save preemption record for the ring/command */
OUT_PKT4(ring, REG_A5XX_CP_CONTEXT_SWITCH_SAVE_ADDR_LO, 2);
OUT_RING(ring, lower_32_bits(a5xx_gpu->preempt_iova[submit->ring->id]));
OUT_RING(ring, upper_32_bits(a5xx_gpu->preempt_iova[submit->ring->id]));
/* Turn back on protected mode */
OUT_PKT7(ring, CP_SET_PROTECTED_MODE, 1);
OUT_RING(ring, 1);
/* Enable local preemption for finegrain preemption */
OUT_PKT7(ring, CP_PREEMPT_ENABLE_GLOBAL, 1);
OUT_RING(ring, 0x02);
/* Allow CP_CONTEXT_SWITCH_YIELD packets in the IB2 */
OUT_PKT7(ring, CP_YIELD_ENABLE, 1);
OUT_RING(ring, 0x02);
/* Submit the commands */
for (i = 0; i < submit->nr_cmds; i++) {
switch (submit->cmd[i].type) {
case MSM_SUBMIT_CMD_IB_TARGET_BUF:
break;
case MSM_SUBMIT_CMD_CTX_RESTORE_BUF:
if (priv->lastctx == ctx)
break;
case MSM_SUBMIT_CMD_BUF:
OUT_PKT7(ring, CP_INDIRECT_BUFFER_PFE, 3);
OUT_RING(ring, lower_32_bits(submit->cmd[i].iova));
OUT_RING(ring, upper_32_bits(submit->cmd[i].iova));
OUT_RING(ring, submit->cmd[i].size);
ibs++;
break;
}
}
/*
* Write the render mode to NULL (0) to indicate to the CP that the IBs
* are done rendering - otherwise a lucky preemption would start
* replaying from the last checkpoint
*/
OUT_PKT7(ring, CP_SET_RENDER_MODE, 5);
OUT_RING(ring, 0);
OUT_RING(ring, 0);
OUT_RING(ring, 0);
OUT_RING(ring, 0);
OUT_RING(ring, 0);
/* Turn off IB level preemptions */
OUT_PKT7(ring, CP_YIELD_ENABLE, 1);
OUT_RING(ring, 0x01);
/* Write the fence to the scratch register */
OUT_PKT4(ring, REG_A5XX_CP_SCRATCH_REG(2), 1);
OUT_RING(ring, submit->seqno);
/*
* Execute a CACHE_FLUSH_TS event. This will ensure that the
* timestamp is written to the memory and then triggers the interrupt
*/
OUT_PKT7(ring, CP_EVENT_WRITE, 4);
OUT_RING(ring, CACHE_FLUSH_TS | (1 << 31));
OUT_RING(ring, lower_32_bits(rbmemptr(ring, fence)));
OUT_RING(ring, upper_32_bits(rbmemptr(ring, fence)));
OUT_RING(ring, submit->seqno);
/* Yield the floor on command completion */
OUT_PKT7(ring, CP_CONTEXT_SWITCH_YIELD, 4);
/*
* If dword[2:1] are non zero, they specify an address for the CP to
* write the value of dword[3] to on preemption complete. Write 0 to
* skip the write
*/
OUT_RING(ring, 0x00);
OUT_RING(ring, 0x00);
/* Data value - not used if the address above is 0 */
OUT_RING(ring, 0x01);
/* Set bit 0 to trigger an interrupt on preempt complete */
OUT_RING(ring, 0x01);
a5xx_flush(gpu, ring);
/* Check to see if we need to start preemption */
a5xx_preempt_trigger(gpu);
}
static const struct {
u32 offset;
u32 value;
} a5xx_hwcg[] = {
{REG_A5XX_RBBM_CLOCK_CNTL_SP0, 0x02222222},
{REG_A5XX_RBBM_CLOCK_CNTL_SP1, 0x02222222},
{REG_A5XX_RBBM_CLOCK_CNTL_SP2, 0x02222222},
{REG_A5XX_RBBM_CLOCK_CNTL_SP3, 0x02222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_SP0, 0x02222220},
{REG_A5XX_RBBM_CLOCK_CNTL2_SP1, 0x02222220},
{REG_A5XX_RBBM_CLOCK_CNTL2_SP2, 0x02222220},
{REG_A5XX_RBBM_CLOCK_CNTL2_SP3, 0x02222220},
{REG_A5XX_RBBM_CLOCK_HYST_SP0, 0x0000F3CF},
{REG_A5XX_RBBM_CLOCK_HYST_SP1, 0x0000F3CF},
{REG_A5XX_RBBM_CLOCK_HYST_SP2, 0x0000F3CF},
{REG_A5XX_RBBM_CLOCK_HYST_SP3, 0x0000F3CF},
{REG_A5XX_RBBM_CLOCK_DELAY_SP0, 0x00000080},
{REG_A5XX_RBBM_CLOCK_DELAY_SP1, 0x00000080},
{REG_A5XX_RBBM_CLOCK_DELAY_SP2, 0x00000080},
{REG_A5XX_RBBM_CLOCK_DELAY_SP3, 0x00000080},
{REG_A5XX_RBBM_CLOCK_CNTL_TP0, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL_TP1, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL_TP2, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL_TP3, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_TP0, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_TP1, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_TP2, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_TP3, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL3_TP0, 0x00002222},
{REG_A5XX_RBBM_CLOCK_CNTL3_TP1, 0x00002222},
{REG_A5XX_RBBM_CLOCK_CNTL3_TP2, 0x00002222},
{REG_A5XX_RBBM_CLOCK_CNTL3_TP3, 0x00002222},
{REG_A5XX_RBBM_CLOCK_HYST_TP0, 0x77777777},
{REG_A5XX_RBBM_CLOCK_HYST_TP1, 0x77777777},
{REG_A5XX_RBBM_CLOCK_HYST_TP2, 0x77777777},
{REG_A5XX_RBBM_CLOCK_HYST_TP3, 0x77777777},
{REG_A5XX_RBBM_CLOCK_HYST2_TP0, 0x77777777},
{REG_A5XX_RBBM_CLOCK_HYST2_TP1, 0x77777777},
{REG_A5XX_RBBM_CLOCK_HYST2_TP2, 0x77777777},
{REG_A5XX_RBBM_CLOCK_HYST2_TP3, 0x77777777},
{REG_A5XX_RBBM_CLOCK_HYST3_TP0, 0x00007777},
{REG_A5XX_RBBM_CLOCK_HYST3_TP1, 0x00007777},
{REG_A5XX_RBBM_CLOCK_HYST3_TP2, 0x00007777},
{REG_A5XX_RBBM_CLOCK_HYST3_TP3, 0x00007777},
{REG_A5XX_RBBM_CLOCK_DELAY_TP0, 0x11111111},
{REG_A5XX_RBBM_CLOCK_DELAY_TP1, 0x11111111},
{REG_A5XX_RBBM_CLOCK_DELAY_TP2, 0x11111111},
{REG_A5XX_RBBM_CLOCK_DELAY_TP3, 0x11111111},
{REG_A5XX_RBBM_CLOCK_DELAY2_TP0, 0x11111111},
{REG_A5XX_RBBM_CLOCK_DELAY2_TP1, 0x11111111},
{REG_A5XX_RBBM_CLOCK_DELAY2_TP2, 0x11111111},
{REG_A5XX_RBBM_CLOCK_DELAY2_TP3, 0x11111111},
{REG_A5XX_RBBM_CLOCK_DELAY3_TP0, 0x00001111},
{REG_A5XX_RBBM_CLOCK_DELAY3_TP1, 0x00001111},
{REG_A5XX_RBBM_CLOCK_DELAY3_TP2, 0x00001111},
{REG_A5XX_RBBM_CLOCK_DELAY3_TP3, 0x00001111},
{REG_A5XX_RBBM_CLOCK_CNTL_UCHE, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_UCHE, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL3_UCHE, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL4_UCHE, 0x00222222},
{REG_A5XX_RBBM_CLOCK_HYST_UCHE, 0x00444444},
{REG_A5XX_RBBM_CLOCK_DELAY_UCHE, 0x00000002},
{REG_A5XX_RBBM_CLOCK_CNTL_RB0, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL_RB1, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL_RB2, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL_RB3, 0x22222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_RB0, 0x00222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_RB1, 0x00222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_RB2, 0x00222222},
{REG_A5XX_RBBM_CLOCK_CNTL2_RB3, 0x00222222},
{REG_A5XX_RBBM_CLOCK_CNTL_CCU0, 0x00022220},
{REG_A5XX_RBBM_CLOCK_CNTL_CCU1, 0x00022220},
{REG_A5XX_RBBM_CLOCK_CNTL_CCU2, 0x00022220},
{REG_A5XX_RBBM_CLOCK_CNTL_CCU3, 0x00022220},
{REG_A5XX_RBBM_CLOCK_CNTL_RAC, 0x05522222},
{REG_A5XX_RBBM_CLOCK_CNTL2_RAC, 0x00505555},
{REG_A5XX_RBBM_CLOCK_HYST_RB_CCU0, 0x04040404},
{REG_A5XX_RBBM_CLOCK_HYST_RB_CCU1, 0x04040404},
{REG_A5XX_RBBM_CLOCK_HYST_RB_CCU2, 0x04040404},
{REG_A5XX_RBBM_CLOCK_HYST_RB_CCU3, 0x04040404},
{REG_A5XX_RBBM_CLOCK_HYST_RAC, 0x07444044},
{REG_A5XX_RBBM_CLOCK_DELAY_RB_CCU_L1_0, 0x00000002},
{REG_A5XX_RBBM_CLOCK_DELAY_RB_CCU_L1_1, 0x00000002},
{REG_A5XX_RBBM_CLOCK_DELAY_RB_CCU_L1_2, 0x00000002},
{REG_A5XX_RBBM_CLOCK_DELAY_RB_CCU_L1_3, 0x00000002},
{REG_A5XX_RBBM_CLOCK_DELAY_RAC, 0x00010011},
{REG_A5XX_RBBM_CLOCK_CNTL_TSE_RAS_RBBM, 0x04222222},
{REG_A5XX_RBBM_CLOCK_MODE_GPC, 0x02222222},
{REG_A5XX_RBBM_CLOCK_MODE_VFD, 0x00002222},
{REG_A5XX_RBBM_CLOCK_HYST_TSE_RAS_RBBM, 0x00000000},
{REG_A5XX_RBBM_CLOCK_HYST_GPC, 0x04104004},
{REG_A5XX_RBBM_CLOCK_HYST_VFD, 0x00000000},
{REG_A5XX_RBBM_CLOCK_DELAY_HLSQ, 0x00000000},
{REG_A5XX_RBBM_CLOCK_DELAY_TSE_RAS_RBBM, 0x00004000},
{REG_A5XX_RBBM_CLOCK_DELAY_GPC, 0x00000200},
{REG_A5XX_RBBM_CLOCK_DELAY_VFD, 0x00002222}
};
void a5xx_set_hwcg(struct msm_gpu *gpu, bool state)
{
unsigned int i;
for (i = 0; i < ARRAY_SIZE(a5xx_hwcg); i++)
gpu_write(gpu, a5xx_hwcg[i].offset,
state ? a5xx_hwcg[i].value : 0);
gpu_write(gpu, REG_A5XX_RBBM_CLOCK_CNTL, state ? 0xAAA8AA00 : 0);
gpu_write(gpu, REG_A5XX_RBBM_ISDB_CNT, state ? 0x182 : 0x180);
}
static int a5xx_me_init(struct msm_gpu *gpu)
{
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
struct msm_ringbuffer *ring = gpu->rb[0];
OUT_PKT7(ring, CP_ME_INIT, 8);
OUT_RING(ring, 0x0000002F);
/* Enable multiple hardware contexts */
OUT_RING(ring, 0x00000003);
/* Enable error detection */
OUT_RING(ring, 0x20000000);
/* Don't enable header dump */
OUT_RING(ring, 0x00000000);
OUT_RING(ring, 0x00000000);
/* Specify workarounds for various microcode issues */
if (adreno_is_a530(adreno_gpu)) {
/* Workaround for token end syncs
* Force a WFI after every direct-render 3D mode draw and every
* 2D mode 3 draw
*/
OUT_RING(ring, 0x0000000B);
} else {
/* No workarounds enabled */
OUT_RING(ring, 0x00000000);
}
OUT_RING(ring, 0x00000000);
OUT_RING(ring, 0x00000000);
gpu->funcs->flush(gpu, ring);
return a5xx_idle(gpu, ring) ? 0 : -EINVAL;
}
static int a5xx_preempt_start(struct msm_gpu *gpu)
{
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
struct a5xx_gpu *a5xx_gpu = to_a5xx_gpu(adreno_gpu);
struct msm_ringbuffer *ring = gpu->rb[0];
if (gpu->nr_rings == 1)
return 0;
/* Turn off protected mode to write to special registers */
OUT_PKT7(ring, CP_SET_PROTECTED_MODE, 1);
OUT_RING(ring, 0);
/* Set the save preemption record for the ring/command */
OUT_PKT4(ring, REG_A5XX_CP_CONTEXT_SWITCH_SAVE_ADDR_LO, 2);
OUT_RING(ring, lower_32_bits(a5xx_gpu->preempt_iova[ring->id]));
OUT_RING(ring, upper_32_bits(a5xx_gpu->preempt_iova[ring->id]));
/* Turn back on protected mode */
OUT_PKT7(ring, CP_SET_PROTECTED_MODE, 1);
OUT_RING(ring, 1);
OUT_PKT7(ring, CP_PREEMPT_ENABLE_GLOBAL, 1);
OUT_RING(ring, 0x00);
OUT_PKT7(ring, CP_PREEMPT_ENABLE_LOCAL, 1);
OUT_RING(ring, 0x01);
OUT_PKT7(ring, CP_YIELD_ENABLE, 1);
OUT_RING(ring, 0x01);
/* Yield the floor on command completion */
OUT_PKT7(ring, CP_CONTEXT_SWITCH_YIELD, 4);
OUT_RING(ring, 0x00);
OUT_RING(ring, 0x00);
OUT_RING(ring, 0x01);
OUT_RING(ring, 0x01);
gpu->funcs->flush(gpu, ring);
return a5xx_idle(gpu, ring) ? 0 : -EINVAL;
}
static int a5xx_ucode_init(struct msm_gpu *gpu)
{
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
struct a5xx_gpu *a5xx_gpu = to_a5xx_gpu(adreno_gpu);
int ret;
if (!a5xx_gpu->pm4_bo) {
a5xx_gpu->pm4_bo = adreno_fw_create_bo(gpu,
adreno_gpu->fw[ADRENO_FW_PM4], &a5xx_gpu->pm4_iova);
if (IS_ERR(a5xx_gpu->pm4_bo)) {
ret = PTR_ERR(a5xx_gpu->pm4_bo);
a5xx_gpu->pm4_bo = NULL;
dev_err(gpu->dev->dev, "could not allocate PM4: %d\n",
ret);
return ret;
}
}
if (!a5xx_gpu->pfp_bo) {
a5xx_gpu->pfp_bo = adreno_fw_create_bo(gpu,
adreno_gpu->fw[ADRENO_FW_PFP], &a5xx_gpu->pfp_iova);
if (IS_ERR(a5xx_gpu->pfp_bo)) {
ret = PTR_ERR(a5xx_gpu->pfp_bo);
a5xx_gpu->pfp_bo = NULL;
dev_err(gpu->dev->dev, "could not allocate PFP: %d\n",
ret);
return ret;
}
}
gpu_write64(gpu, REG_A5XX_CP_ME_INSTR_BASE_LO,
REG_A5XX_CP_ME_INSTR_BASE_HI, a5xx_gpu->pm4_iova);
gpu_write64(gpu, REG_A5XX_CP_PFP_INSTR_BASE_LO,
REG_A5XX_CP_PFP_INSTR_BASE_HI, a5xx_gpu->pfp_iova);
return 0;
}
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
#define SCM_GPU_ZAP_SHADER_RESUME 0
static int a5xx_zap_shader_resume(struct msm_gpu *gpu)
{
int ret;
ret = qcom_scm_set_remote_state(SCM_GPU_ZAP_SHADER_RESUME, GPU_PAS_ID);
if (ret)
DRM_ERROR("%s: zap-shader resume failed: %d\n",
gpu->name, ret);
return ret;
}
static int a5xx_zap_shader_init(struct msm_gpu *gpu)
{
static bool loaded;
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
struct platform_device *pdev = gpu->pdev;
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
int ret;
/*
* If the zap shader is already loaded into memory we just need to kick
* the remote processor to reinitialize it
*/
if (loaded)
return a5xx_zap_shader_resume(gpu);
/* We need SCM to be able to load the firmware */
if (!qcom_scm_is_available()) {
DRM_DEV_ERROR(&pdev->dev, "SCM is not available\n");
return -EPROBE_DEFER;
}
/* Each GPU has a target specific zap shader firmware name to use */
if (!adreno_gpu->info->zapfw) {
DRM_DEV_ERROR(&pdev->dev,
"Zap shader firmware file not specified for this target\n");
return -ENODEV;
}
ret = zap_shader_load_mdt(gpu, adreno_gpu->info->zapfw);
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
loaded = !ret;
return ret;
}
#define A5XX_INT_MASK (A5XX_RBBM_INT_0_MASK_RBBM_AHB_ERROR | \
A5XX_RBBM_INT_0_MASK_RBBM_TRANSFER_TIMEOUT | \
A5XX_RBBM_INT_0_MASK_RBBM_ME_MS_TIMEOUT | \
A5XX_RBBM_INT_0_MASK_RBBM_PFP_MS_TIMEOUT | \
A5XX_RBBM_INT_0_MASK_RBBM_ETS_MS_TIMEOUT | \
A5XX_RBBM_INT_0_MASK_RBBM_ATB_ASYNC_OVERFLOW | \
A5XX_RBBM_INT_0_MASK_CP_HW_ERROR | \
A5XX_RBBM_INT_0_MASK_MISC_HANG_DETECT | \
A5XX_RBBM_INT_0_MASK_CP_SW | \
A5XX_RBBM_INT_0_MASK_CP_CACHE_FLUSH_TS | \
A5XX_RBBM_INT_0_MASK_UCHE_OOB_ACCESS | \
A5XX_RBBM_INT_0_MASK_GPMU_VOLTAGE_DROOP)
static int a5xx_hw_init(struct msm_gpu *gpu)
{
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
int ret;
gpu_write(gpu, REG_A5XX_VBIF_ROUND_ROBIN_QOS_ARB, 0x00000003);
/* Make all blocks contribute to the GPU BUSY perf counter */
gpu_write(gpu, REG_A5XX_RBBM_PERFCTR_GPU_BUSY_MASKED, 0xFFFFFFFF);
/* Enable RBBM error reporting bits */
gpu_write(gpu, REG_A5XX_RBBM_AHB_CNTL0, 0x00000001);
if (adreno_gpu->info->quirks & ADRENO_QUIRK_FAULT_DETECT_MASK) {
/*
* Mask out the activity signals from RB1-3 to avoid false
* positives
*/
gpu_write(gpu, REG_A5XX_RBBM_INTERFACE_HANG_MASK_CNTL11,
0xF0000000);
gpu_write(gpu, REG_A5XX_RBBM_INTERFACE_HANG_MASK_CNTL12,
0xFFFFFFFF);
gpu_write(gpu, REG_A5XX_RBBM_INTERFACE_HANG_MASK_CNTL13,
0xFFFFFFFF);
gpu_write(gpu, REG_A5XX_RBBM_INTERFACE_HANG_MASK_CNTL14,
0xFFFFFFFF);
gpu_write(gpu, REG_A5XX_RBBM_INTERFACE_HANG_MASK_CNTL15,
0xFFFFFFFF);
gpu_write(gpu, REG_A5XX_RBBM_INTERFACE_HANG_MASK_CNTL16,
0xFFFFFFFF);
gpu_write(gpu, REG_A5XX_RBBM_INTERFACE_HANG_MASK_CNTL17,
0xFFFFFFFF);
gpu_write(gpu, REG_A5XX_RBBM_INTERFACE_HANG_MASK_CNTL18,
0xFFFFFFFF);
}
/* Enable fault detection */
gpu_write(gpu, REG_A5XX_RBBM_INTERFACE_HANG_INT_CNTL,
(1 << 30) | 0xFFFF);
/* Turn on performance counters */
gpu_write(gpu, REG_A5XX_RBBM_PERFCTR_CNTL, 0x01);
/* Select CP0 to always count cycles */
gpu_write(gpu, REG_A5XX_CP_PERFCTR_CP_SEL_0, PERF_CP_ALWAYS_COUNT);
/* Select RBBM0 to countable 6 to get the busy status for devfreq */
gpu_write(gpu, REG_A5XX_RBBM_PERFCTR_RBBM_SEL_0, 6);
/* Increase VFD cache access so LRZ and other data gets evicted less */
gpu_write(gpu, REG_A5XX_UCHE_CACHE_WAYS, 0x02);
/* Disable L2 bypass in the UCHE */
gpu_write(gpu, REG_A5XX_UCHE_TRAP_BASE_LO, 0xFFFF0000);
gpu_write(gpu, REG_A5XX_UCHE_TRAP_BASE_HI, 0x0001FFFF);
gpu_write(gpu, REG_A5XX_UCHE_WRITE_THRU_BASE_LO, 0xFFFF0000);
gpu_write(gpu, REG_A5XX_UCHE_WRITE_THRU_BASE_HI, 0x0001FFFF);
/* Set the GMEM VA range (0 to gpu->gmem) */
gpu_write(gpu, REG_A5XX_UCHE_GMEM_RANGE_MIN_LO, 0x00100000);
gpu_write(gpu, REG_A5XX_UCHE_GMEM_RANGE_MIN_HI, 0x00000000);
gpu_write(gpu, REG_A5XX_UCHE_GMEM_RANGE_MAX_LO,
0x00100000 + adreno_gpu->gmem - 1);
gpu_write(gpu, REG_A5XX_UCHE_GMEM_RANGE_MAX_HI, 0x00000000);
gpu_write(gpu, REG_A5XX_CP_MEQ_THRESHOLDS, 0x40);
gpu_write(gpu, REG_A5XX_CP_MERCIU_SIZE, 0x40);
gpu_write(gpu, REG_A5XX_CP_ROQ_THRESHOLDS_2, 0x80000060);
gpu_write(gpu, REG_A5XX_CP_ROQ_THRESHOLDS_1, 0x40201B16);
gpu_write(gpu, REG_A5XX_PC_DBG_ECO_CNTL, (0x400 << 11 | 0x300 << 22));
if (adreno_gpu->info->quirks & ADRENO_QUIRK_TWO_PASS_USE_WFI)
gpu_rmw(gpu, REG_A5XX_PC_DBG_ECO_CNTL, 0, (1 << 8));
gpu_write(gpu, REG_A5XX_PC_DBG_ECO_CNTL, 0xc0200100);
/* Enable USE_RETENTION_FLOPS */
gpu_write(gpu, REG_A5XX_CP_CHICKEN_DBG, 0x02000000);
/* Enable ME/PFP split notification */
gpu_write(gpu, REG_A5XX_RBBM_AHB_CNTL1, 0xA6FFFFFF);
/* Enable HWCG */
a5xx_set_hwcg(gpu, true);
gpu_write(gpu, REG_A5XX_RBBM_AHB_CNTL2, 0x0000003F);
/* Set the highest bank bit */
gpu_write(gpu, REG_A5XX_TPL1_MODE_CNTL, 2 << 7);
gpu_write(gpu, REG_A5XX_RB_MODE_CNTL, 2 << 1);
/* Protect registers from the CP */
gpu_write(gpu, REG_A5XX_CP_PROTECT_CNTL, 0x00000007);
/* RBBM */
gpu_write(gpu, REG_A5XX_CP_PROTECT(0), ADRENO_PROTECT_RW(0x04, 4));
gpu_write(gpu, REG_A5XX_CP_PROTECT(1), ADRENO_PROTECT_RW(0x08, 8));
gpu_write(gpu, REG_A5XX_CP_PROTECT(2), ADRENO_PROTECT_RW(0x10, 16));
gpu_write(gpu, REG_A5XX_CP_PROTECT(3), ADRENO_PROTECT_RW(0x20, 32));
gpu_write(gpu, REG_A5XX_CP_PROTECT(4), ADRENO_PROTECT_RW(0x40, 64));
gpu_write(gpu, REG_A5XX_CP_PROTECT(5), ADRENO_PROTECT_RW(0x80, 64));
/* Content protect */
gpu_write(gpu, REG_A5XX_CP_PROTECT(6),
ADRENO_PROTECT_RW(REG_A5XX_RBBM_SECVID_TSB_TRUSTED_BASE_LO,
16));
gpu_write(gpu, REG_A5XX_CP_PROTECT(7),
ADRENO_PROTECT_RW(REG_A5XX_RBBM_SECVID_TRUST_CNTL, 2));
/* CP */
gpu_write(gpu, REG_A5XX_CP_PROTECT(8), ADRENO_PROTECT_RW(0x800, 64));
gpu_write(gpu, REG_A5XX_CP_PROTECT(9), ADRENO_PROTECT_RW(0x840, 8));
gpu_write(gpu, REG_A5XX_CP_PROTECT(10), ADRENO_PROTECT_RW(0x880, 32));
gpu_write(gpu, REG_A5XX_CP_PROTECT(11), ADRENO_PROTECT_RW(0xAA0, 1));
/* RB */
gpu_write(gpu, REG_A5XX_CP_PROTECT(12), ADRENO_PROTECT_RW(0xCC0, 1));
gpu_write(gpu, REG_A5XX_CP_PROTECT(13), ADRENO_PROTECT_RW(0xCF0, 2));
/* VPC */
gpu_write(gpu, REG_A5XX_CP_PROTECT(14), ADRENO_PROTECT_RW(0xE68, 8));
gpu_write(gpu, REG_A5XX_CP_PROTECT(15), ADRENO_PROTECT_RW(0xE70, 4));
/* UCHE */
gpu_write(gpu, REG_A5XX_CP_PROTECT(16), ADRENO_PROTECT_RW(0xE80, 16));
if (adreno_is_a530(adreno_gpu))
gpu_write(gpu, REG_A5XX_CP_PROTECT(17),
ADRENO_PROTECT_RW(0x10000, 0x8000));
gpu_write(gpu, REG_A5XX_RBBM_SECVID_TSB_CNTL, 0);
/*
* Disable the trusted memory range - we don't actually supported secure
* memory rendering at this point in time and we don't want to block off
* part of the virtual memory space.
*/
gpu_write64(gpu, REG_A5XX_RBBM_SECVID_TSB_TRUSTED_BASE_LO,
REG_A5XX_RBBM_SECVID_TSB_TRUSTED_BASE_HI, 0x00000000);
gpu_write(gpu, REG_A5XX_RBBM_SECVID_TSB_TRUSTED_SIZE, 0x00000000);
ret = adreno_hw_init(gpu);
if (ret)
return ret;
a5xx_preempt_hw_init(gpu);
a5xx_gpmu_ucode_init(gpu);
ret = a5xx_ucode_init(gpu);
if (ret)
return ret;
/* Disable the interrupts through the initial bringup stage */
gpu_write(gpu, REG_A5XX_RBBM_INT_0_MASK, A5XX_INT_MASK);
/* Clear ME_HALT to start the micro engine */
gpu_write(gpu, REG_A5XX_CP_PFP_ME_CNTL, 0);
ret = a5xx_me_init(gpu);
if (ret)
return ret;
ret = a5xx_power_init(gpu);
if (ret)
return ret;
/*
* Send a pipeline event stat to get misbehaving counters to start
* ticking correctly
*/
if (adreno_is_a530(adreno_gpu)) {
OUT_PKT7(gpu->rb[0], CP_EVENT_WRITE, 1);
OUT_RING(gpu->rb[0], 0x0F);
gpu->funcs->flush(gpu, gpu->rb[0]);
if (!a5xx_idle(gpu, gpu->rb[0]))
return -EINVAL;
}
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
/*
* Try to load a zap shader into the secure world. If successful
* we can use the CP to switch out of secure mode. If not then we
* have no resource but to try to switch ourselves out manually. If we
* guessed wrong then access to the RBBM_SECVID_TRUST_CNTL register will
* be blocked and a permissions violation will soon follow.
*/
ret = a5xx_zap_shader_init(gpu);
if (!ret) {
OUT_PKT7(gpu->rb[0], CP_SET_SECURE_MODE, 1);
OUT_RING(gpu->rb[0], 0x00000000);
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
gpu->funcs->flush(gpu, gpu->rb[0]);
if (!a5xx_idle(gpu, gpu->rb[0]))
drm/msm: gpu: Enable zap shader for A5XX The A5XX GPU powers on in "secure" mode. In secure mode the GPU can only render to buffers that are marked as secure and inaccessible to the kernel and user through a series of hardware protections. In practice secure mode is used to draw things like a UI on a secure video frame. In order to switch out of secure mode the GPU executes a special shader that clears out the GMEM and other sensitve registers and then writes a register. Because the kernel can't be trusted the shader binary is signed and verified and programmed by the secure world. To do this we need to read the MDT header and the segments from the firmware location and put them in memory and present them for approval. For targets without secure support there is an out: if the secure world doesn't support secure then there are no hardware protections and we can freely write the SECVID_TRUST register from the CPU. We don't have 100% confidence that we can query the secure capabilities at run time but we have enough calls that need to go right to give us some confidence that we're at least doing something useful. Of course if we guess wrong you trigger a permissions violation which usually ends up in a system crash but thats a problem that shows up immediately. [v2: use child device per Bjorn] [v3: use generic MDT loader per Bjorn] [v4: use managed dma functions and ifdefs for the MDT loader] [v5: Add depends for QCOM_MDT_LOADER] Signed-off-by: Jordan Crouse <jcrouse@codeaurora.org> Acked-by: Bjorn Andersson <bjorn.andersson@linaro.org> [robclark: fix Kconfig to use select instead of depends + #if IS_ENABLED()] Signed-off-by: Rob Clark <robdclark@gmail.com>
2017-05-17 22:45:29 +08:00
return -EINVAL;
} else {
/* Print a warning so if we die, we know why */
dev_warn_once(gpu->dev->dev,
"Zap shader not enabled - using SECVID_TRUST_CNTL instead\n");
gpu_write(gpu, REG_A5XX_RBBM_SECVID_TRUST_CNTL, 0x0);
}
/* Last step - yield the ringbuffer */
a5xx_preempt_start(gpu);
return 0;
}
static void a5xx_recover(struct msm_gpu *gpu)
{
int i;
adreno_dump_info(gpu);
for (i = 0; i < 8; i++) {
printk("CP_SCRATCH_REG%d: %u\n", i,
gpu_read(gpu, REG_A5XX_CP_SCRATCH_REG(i)));
}
if (hang_debug)
a5xx_dump(gpu);
gpu_write(gpu, REG_A5XX_RBBM_SW_RESET_CMD, 1);
gpu_read(gpu, REG_A5XX_RBBM_SW_RESET_CMD);
gpu_write(gpu, REG_A5XX_RBBM_SW_RESET_CMD, 0);
adreno_recover(gpu);
}
static void a5xx_destroy(struct msm_gpu *gpu)
{
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
struct a5xx_gpu *a5xx_gpu = to_a5xx_gpu(adreno_gpu);
DBG("%s", gpu->name);
a5xx_preempt_fini(gpu);
if (a5xx_gpu->pm4_bo) {
if (a5xx_gpu->pm4_iova)
msm_gem_put_iova(a5xx_gpu->pm4_bo, gpu->aspace);
drm_gem_object_put_unlocked(a5xx_gpu->pm4_bo);
}
if (a5xx_gpu->pfp_bo) {
if (a5xx_gpu->pfp_iova)
msm_gem_put_iova(a5xx_gpu->pfp_bo, gpu->aspace);
drm_gem_object_put_unlocked(a5xx_gpu->pfp_bo);
}
if (a5xx_gpu->gpmu_bo) {
if (a5xx_gpu->gpmu_iova)
msm_gem_put_iova(a5xx_gpu->gpmu_bo, gpu->aspace);
drm_gem_object_put_unlocked(a5xx_gpu->gpmu_bo);
}
adreno_gpu_cleanup(adreno_gpu);
kfree(a5xx_gpu);
}
static inline bool _a5xx_check_idle(struct msm_gpu *gpu)
{
if (gpu_read(gpu, REG_A5XX_RBBM_STATUS) & ~A5XX_RBBM_STATUS_HI_BUSY)
return false;
/*
* Nearly every abnormality ends up pausing the GPU and triggering a
* fault so we can safely just watch for this one interrupt to fire
*/
return !(gpu_read(gpu, REG_A5XX_RBBM_INT_0_STATUS) &
A5XX_RBBM_INT_0_MASK_MISC_HANG_DETECT);
}
bool a5xx_idle(struct msm_gpu *gpu, struct msm_ringbuffer *ring)
{
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
struct a5xx_gpu *a5xx_gpu = to_a5xx_gpu(adreno_gpu);
if (ring != a5xx_gpu->cur_ring) {
WARN(1, "Tried to idle a non-current ringbuffer\n");
return false;
}
/* wait for CP to drain ringbuffer: */
if (!adreno_idle(gpu, ring))
return false;
if (spin_until(_a5xx_check_idle(gpu))) {
DRM_ERROR("%s: %ps: timeout waiting for GPU to idle: status %8.8X irq %8.8X rptr/wptr %d/%d\n",
gpu->name, __builtin_return_address(0),
gpu_read(gpu, REG_A5XX_RBBM_STATUS),
gpu_read(gpu, REG_A5XX_RBBM_INT_0_STATUS),
gpu_read(gpu, REG_A5XX_CP_RB_RPTR),
gpu_read(gpu, REG_A5XX_CP_RB_WPTR));
return false;
}
return true;
}
static int a5xx_fault_handler(void *arg, unsigned long iova, int flags)
{
struct msm_gpu *gpu = arg;
pr_warn_ratelimited("*** gpu fault: iova=%08lx, flags=%d (%u,%u,%u,%u)\n",
iova, flags,
gpu_read(gpu, REG_A5XX_CP_SCRATCH_REG(4)),
gpu_read(gpu, REG_A5XX_CP_SCRATCH_REG(5)),
gpu_read(gpu, REG_A5XX_CP_SCRATCH_REG(6)),
gpu_read(gpu, REG_A5XX_CP_SCRATCH_REG(7)));
return -EFAULT;
}
static void a5xx_cp_err_irq(struct msm_gpu *gpu)
{
u32 status = gpu_read(gpu, REG_A5XX_CP_INTERRUPT_STATUS);
if (status & A5XX_CP_INT_CP_OPCODE_ERROR) {
u32 val;
gpu_write(gpu, REG_A5XX_CP_PFP_STAT_ADDR, 0);
/*
* REG_A5XX_CP_PFP_STAT_DATA is indexed, and we want index 1 so
* read it twice
*/
gpu_read(gpu, REG_A5XX_CP_PFP_STAT_DATA);
val = gpu_read(gpu, REG_A5XX_CP_PFP_STAT_DATA);
dev_err_ratelimited(gpu->dev->dev, "CP | opcode error | possible opcode=0x%8.8X\n",
val);
}
if (status & A5XX_CP_INT_CP_HW_FAULT_ERROR)
dev_err_ratelimited(gpu->dev->dev, "CP | HW fault | status=0x%8.8X\n",
gpu_read(gpu, REG_A5XX_CP_HW_FAULT));
if (status & A5XX_CP_INT_CP_DMA_ERROR)
dev_err_ratelimited(gpu->dev->dev, "CP | DMA error\n");
if (status & A5XX_CP_INT_CP_REGISTER_PROTECTION_ERROR) {
u32 val = gpu_read(gpu, REG_A5XX_CP_PROTECT_STATUS);
dev_err_ratelimited(gpu->dev->dev,
"CP | protected mode error | %s | addr=0x%8.8X | status=0x%8.8X\n",
val & (1 << 24) ? "WRITE" : "READ",
(val & 0xFFFFF) >> 2, val);
}
if (status & A5XX_CP_INT_CP_AHB_ERROR) {
u32 status = gpu_read(gpu, REG_A5XX_CP_AHB_FAULT);
const char *access[16] = { "reserved", "reserved",
"timestamp lo", "timestamp hi", "pfp read", "pfp write",
"", "", "me read", "me write", "", "", "crashdump read",
"crashdump write" };
dev_err_ratelimited(gpu->dev->dev,
"CP | AHB error | addr=%X access=%s error=%d | status=0x%8.8X\n",
status & 0xFFFFF, access[(status >> 24) & 0xF],
(status & (1 << 31)), status);
}
}
static void a5xx_rbbm_err_irq(struct msm_gpu *gpu, u32 status)
{
if (status & A5XX_RBBM_INT_0_MASK_RBBM_AHB_ERROR) {
u32 val = gpu_read(gpu, REG_A5XX_RBBM_AHB_ERROR_STATUS);
dev_err_ratelimited(gpu->dev->dev,
"RBBM | AHB bus error | %s | addr=0x%X | ports=0x%X:0x%X\n",
val & (1 << 28) ? "WRITE" : "READ",
(val & 0xFFFFF) >> 2, (val >> 20) & 0x3,
(val >> 24) & 0xF);
/* Clear the error */
gpu_write(gpu, REG_A5XX_RBBM_AHB_CMD, (1 << 4));
/* Clear the interrupt */
gpu_write(gpu, REG_A5XX_RBBM_INT_CLEAR_CMD,
A5XX_RBBM_INT_0_MASK_RBBM_AHB_ERROR);
}
if (status & A5XX_RBBM_INT_0_MASK_RBBM_TRANSFER_TIMEOUT)
dev_err_ratelimited(gpu->dev->dev, "RBBM | AHB transfer timeout\n");
if (status & A5XX_RBBM_INT_0_MASK_RBBM_ME_MS_TIMEOUT)
dev_err_ratelimited(gpu->dev->dev, "RBBM | ME master split | status=0x%X\n",
gpu_read(gpu, REG_A5XX_RBBM_AHB_ME_SPLIT_STATUS));
if (status & A5XX_RBBM_INT_0_MASK_RBBM_PFP_MS_TIMEOUT)
dev_err_ratelimited(gpu->dev->dev, "RBBM | PFP master split | status=0x%X\n",
gpu_read(gpu, REG_A5XX_RBBM_AHB_PFP_SPLIT_STATUS));
if (status & A5XX_RBBM_INT_0_MASK_RBBM_ETS_MS_TIMEOUT)
dev_err_ratelimited(gpu->dev->dev, "RBBM | ETS master split | status=0x%X\n",
gpu_read(gpu, REG_A5XX_RBBM_AHB_ETS_SPLIT_STATUS));
if (status & A5XX_RBBM_INT_0_MASK_RBBM_ATB_ASYNC_OVERFLOW)
dev_err_ratelimited(gpu->dev->dev, "RBBM | ATB ASYNC overflow\n");
if (status & A5XX_RBBM_INT_0_MASK_RBBM_ATB_BUS_OVERFLOW)
dev_err_ratelimited(gpu->dev->dev, "RBBM | ATB bus overflow\n");
}
static void a5xx_uche_err_irq(struct msm_gpu *gpu)
{
uint64_t addr = (uint64_t) gpu_read(gpu, REG_A5XX_UCHE_TRAP_LOG_HI);
addr |= gpu_read(gpu, REG_A5XX_UCHE_TRAP_LOG_LO);
dev_err_ratelimited(gpu->dev->dev, "UCHE | Out of bounds access | addr=0x%llX\n",
addr);
}
static void a5xx_gpmu_err_irq(struct msm_gpu *gpu)
{
dev_err_ratelimited(gpu->dev->dev, "GPMU | voltage droop\n");
}
static void a5xx_fault_detect_irq(struct msm_gpu *gpu)
{
struct drm_device *dev = gpu->dev;
struct msm_drm_private *priv = dev->dev_private;
struct msm_ringbuffer *ring = gpu->funcs->active_ring(gpu);
dev_err(dev->dev, "gpu fault ring %d fence %x status %8.8X rb %4.4x/%4.4x ib1 %16.16llX/%4.4x ib2 %16.16llX/%4.4x\n",
ring ? ring->id : -1, ring ? ring->seqno : 0,
gpu_read(gpu, REG_A5XX_RBBM_STATUS),
gpu_read(gpu, REG_A5XX_CP_RB_RPTR),
gpu_read(gpu, REG_A5XX_CP_RB_WPTR),
gpu_read64(gpu, REG_A5XX_CP_IB1_BASE, REG_A5XX_CP_IB1_BASE_HI),
gpu_read(gpu, REG_A5XX_CP_IB1_BUFSZ),
gpu_read64(gpu, REG_A5XX_CP_IB2_BASE, REG_A5XX_CP_IB2_BASE_HI),
gpu_read(gpu, REG_A5XX_CP_IB2_BUFSZ));
/* Turn off the hangcheck timer to keep it from bothering us */
del_timer(&gpu->hangcheck_timer);
queue_work(priv->wq, &gpu->recover_work);
}
#define RBBM_ERROR_MASK \
(A5XX_RBBM_INT_0_MASK_RBBM_AHB_ERROR | \
A5XX_RBBM_INT_0_MASK_RBBM_TRANSFER_TIMEOUT | \
A5XX_RBBM_INT_0_MASK_RBBM_ME_MS_TIMEOUT | \
A5XX_RBBM_INT_0_MASK_RBBM_PFP_MS_TIMEOUT | \
A5XX_RBBM_INT_0_MASK_RBBM_ETS_MS_TIMEOUT | \
A5XX_RBBM_INT_0_MASK_RBBM_ATB_ASYNC_OVERFLOW)
static irqreturn_t a5xx_irq(struct msm_gpu *gpu)
{
u32 status = gpu_read(gpu, REG_A5XX_RBBM_INT_0_STATUS);
/*
* Clear all the interrupts except RBBM_AHB_ERROR - if we clear it
* before the source is cleared the interrupt will storm.
*/
gpu_write(gpu, REG_A5XX_RBBM_INT_CLEAR_CMD,
status & ~A5XX_RBBM_INT_0_MASK_RBBM_AHB_ERROR);
/* Pass status to a5xx_rbbm_err_irq because we've already cleared it */
if (status & RBBM_ERROR_MASK)
a5xx_rbbm_err_irq(gpu, status);
if (status & A5XX_RBBM_INT_0_MASK_CP_HW_ERROR)
a5xx_cp_err_irq(gpu);
if (status & A5XX_RBBM_INT_0_MASK_MISC_HANG_DETECT)
a5xx_fault_detect_irq(gpu);
if (status & A5XX_RBBM_INT_0_MASK_UCHE_OOB_ACCESS)
a5xx_uche_err_irq(gpu);
if (status & A5XX_RBBM_INT_0_MASK_GPMU_VOLTAGE_DROOP)
a5xx_gpmu_err_irq(gpu);
if (status & A5XX_RBBM_INT_0_MASK_CP_CACHE_FLUSH_TS) {
a5xx_preempt_trigger(gpu);
msm_gpu_retire(gpu);
}
if (status & A5XX_RBBM_INT_0_MASK_CP_SW)
a5xx_preempt_irq(gpu);
return IRQ_HANDLED;
}
static const u32 a5xx_register_offsets[REG_ADRENO_REGISTER_MAX] = {
REG_ADRENO_DEFINE(REG_ADRENO_CP_RB_BASE, REG_A5XX_CP_RB_BASE),
REG_ADRENO_DEFINE(REG_ADRENO_CP_RB_BASE_HI, REG_A5XX_CP_RB_BASE_HI),
REG_ADRENO_DEFINE(REG_ADRENO_CP_RB_RPTR_ADDR, REG_A5XX_CP_RB_RPTR_ADDR),
REG_ADRENO_DEFINE(REG_ADRENO_CP_RB_RPTR_ADDR_HI,
REG_A5XX_CP_RB_RPTR_ADDR_HI),
REG_ADRENO_DEFINE(REG_ADRENO_CP_RB_RPTR, REG_A5XX_CP_RB_RPTR),
REG_ADRENO_DEFINE(REG_ADRENO_CP_RB_WPTR, REG_A5XX_CP_RB_WPTR),
REG_ADRENO_DEFINE(REG_ADRENO_CP_RB_CNTL, REG_A5XX_CP_RB_CNTL),
};
static const u32 a5xx_registers[] = {
0x0000, 0x0002, 0x0004, 0x0020, 0x0022, 0x0026, 0x0029, 0x002B,
0x002E, 0x0035, 0x0038, 0x0042, 0x0044, 0x0044, 0x0047, 0x0095,
0x0097, 0x00BB, 0x03A0, 0x0464, 0x0469, 0x046F, 0x04D2, 0x04D3,
0x04E0, 0x0533, 0x0540, 0x0555, 0x0800, 0x081A, 0x081F, 0x0841,
0x0860, 0x0860, 0x0880, 0x08A0, 0x0B00, 0x0B12, 0x0B15, 0x0B28,
0x0B78, 0x0B7F, 0x0BB0, 0x0BBD, 0x0BC0, 0x0BC6, 0x0BD0, 0x0C53,
0x0C60, 0x0C61, 0x0C80, 0x0C82, 0x0C84, 0x0C85, 0x0C90, 0x0C98,
0x0CA0, 0x0CA0, 0x0CB0, 0x0CB2, 0x2180, 0x2185, 0x2580, 0x2585,
0x0CC1, 0x0CC1, 0x0CC4, 0x0CC7, 0x0CCC, 0x0CCC, 0x0CD0, 0x0CD8,
0x0CE0, 0x0CE5, 0x0CE8, 0x0CE8, 0x0CEC, 0x0CF1, 0x0CFB, 0x0D0E,
0x2100, 0x211E, 0x2140, 0x2145, 0x2500, 0x251E, 0x2540, 0x2545,
0x0D10, 0x0D17, 0x0D20, 0x0D23, 0x0D30, 0x0D30, 0x20C0, 0x20C0,
0x24C0, 0x24C0, 0x0E40, 0x0E43, 0x0E4A, 0x0E4A, 0x0E50, 0x0E57,
0x0E60, 0x0E7C, 0x0E80, 0x0E8E, 0x0E90, 0x0E96, 0x0EA0, 0x0EA8,
0x0EB0, 0x0EB2, 0xE140, 0xE147, 0xE150, 0xE187, 0xE1A0, 0xE1A9,
0xE1B0, 0xE1B6, 0xE1C0, 0xE1C7, 0xE1D0, 0xE1D1, 0xE200, 0xE201,
0xE210, 0xE21C, 0xE240, 0xE268, 0xE000, 0xE006, 0xE010, 0xE09A,
0xE0A0, 0xE0A4, 0xE0AA, 0xE0EB, 0xE100, 0xE105, 0xE380, 0xE38F,
0xE3B0, 0xE3B0, 0xE400, 0xE405, 0xE408, 0xE4E9, 0xE4F0, 0xE4F0,
0xE280, 0xE280, 0xE282, 0xE2A3, 0xE2A5, 0xE2C2, 0xE940, 0xE947,
0xE950, 0xE987, 0xE9A0, 0xE9A9, 0xE9B0, 0xE9B6, 0xE9C0, 0xE9C7,
0xE9D0, 0xE9D1, 0xEA00, 0xEA01, 0xEA10, 0xEA1C, 0xEA40, 0xEA68,
0xE800, 0xE806, 0xE810, 0xE89A, 0xE8A0, 0xE8A4, 0xE8AA, 0xE8EB,
0xE900, 0xE905, 0xEB80, 0xEB8F, 0xEBB0, 0xEBB0, 0xEC00, 0xEC05,
0xEC08, 0xECE9, 0xECF0, 0xECF0, 0xEA80, 0xEA80, 0xEA82, 0xEAA3,
0xEAA5, 0xEAC2, 0xA800, 0xA800, 0xA820, 0xA828, 0xA840, 0xA87D,
0XA880, 0xA88D, 0xA890, 0xA8A3, 0xA8D0, 0xA8D8, 0xA8E0, 0xA8F5,
0xAC60, 0xAC60, ~0,
};
static void a5xx_dump(struct msm_gpu *gpu)
{
dev_info(gpu->dev->dev, "status: %08x\n",
gpu_read(gpu, REG_A5XX_RBBM_STATUS));
adreno_dump(gpu);
}
static int a5xx_pm_resume(struct msm_gpu *gpu)
{
int ret;
/* Turn on the core power */
ret = msm_gpu_pm_resume(gpu);
if (ret)
return ret;
/* Turn the RBCCU domain first to limit the chances of voltage droop */
gpu_write(gpu, REG_A5XX_GPMU_RBCCU_POWER_CNTL, 0x778000);
/* Wait 3 usecs before polling */
udelay(3);
ret = spin_usecs(gpu, 20, REG_A5XX_GPMU_RBCCU_PWR_CLK_STATUS,
(1 << 20), (1 << 20));
if (ret) {
DRM_ERROR("%s: timeout waiting for RBCCU GDSC enable: %X\n",
gpu->name,
gpu_read(gpu, REG_A5XX_GPMU_RBCCU_PWR_CLK_STATUS));
return ret;
}
/* Turn on the SP domain */
gpu_write(gpu, REG_A5XX_GPMU_SP_POWER_CNTL, 0x778000);
ret = spin_usecs(gpu, 20, REG_A5XX_GPMU_SP_PWR_CLK_STATUS,
(1 << 20), (1 << 20));
if (ret)
DRM_ERROR("%s: timeout waiting for SP GDSC enable\n",
gpu->name);
return ret;
}
static int a5xx_pm_suspend(struct msm_gpu *gpu)
{
/* Clear the VBIF pipe before shutting down */
gpu_write(gpu, REG_A5XX_VBIF_XIN_HALT_CTRL0, 0xF);
spin_until((gpu_read(gpu, REG_A5XX_VBIF_XIN_HALT_CTRL1) & 0xF) == 0xF);
gpu_write(gpu, REG_A5XX_VBIF_XIN_HALT_CTRL0, 0);
/*
* Reset the VBIF before power collapse to avoid issue with FIFO
* entries
*/
gpu_write(gpu, REG_A5XX_RBBM_BLOCK_SW_RESET_CMD, 0x003C0000);
gpu_write(gpu, REG_A5XX_RBBM_BLOCK_SW_RESET_CMD, 0x00000000);
return msm_gpu_pm_suspend(gpu);
}
static int a5xx_get_timestamp(struct msm_gpu *gpu, uint64_t *value)
{
*value = gpu_read64(gpu, REG_A5XX_RBBM_PERFCTR_CP_0_LO,
REG_A5XX_RBBM_PERFCTR_CP_0_HI);
return 0;
}
struct a5xx_crashdumper {
void *ptr;
struct drm_gem_object *bo;
u64 iova;
};
struct a5xx_gpu_state {
struct msm_gpu_state base;
u32 *hlsqregs;
};
#define gpu_poll_timeout(gpu, addr, val, cond, interval, timeout) \
readl_poll_timeout((gpu)->mmio + ((addr) << 2), val, cond, \
interval, timeout)
static int a5xx_crashdumper_init(struct msm_gpu *gpu,
struct a5xx_crashdumper *dumper)
{
dumper->ptr = msm_gem_kernel_new_locked(gpu->dev,
SZ_1M, MSM_BO_UNCACHED, gpu->aspace,
&dumper->bo, &dumper->iova);
return PTR_ERR_OR_ZERO(dumper->ptr);
}
static void a5xx_crashdumper_free(struct msm_gpu *gpu,
struct a5xx_crashdumper *dumper)
{
msm_gem_put_iova(dumper->bo, gpu->aspace);
msm_gem_put_vaddr(dumper->bo);
drm_gem_object_put(dumper->bo);
}
static int a5xx_crashdumper_run(struct msm_gpu *gpu,
struct a5xx_crashdumper *dumper)
{
u32 val;
if (IS_ERR_OR_NULL(dumper->ptr))
return -EINVAL;
gpu_write64(gpu, REG_A5XX_CP_CRASH_SCRIPT_BASE_LO,
REG_A5XX_CP_CRASH_SCRIPT_BASE_HI, dumper->iova);
gpu_write(gpu, REG_A5XX_CP_CRASH_DUMP_CNTL, 1);
return gpu_poll_timeout(gpu, REG_A5XX_CP_CRASH_DUMP_CNTL, val,
val & 0x04, 100, 10000);
}
/*
* These are a list of the registers that need to be read through the HLSQ
* aperture through the crashdumper. These are not nominally accessible from
* the CPU on a secure platform.
*/
static const struct {
u32 type;
u32 regoffset;
u32 count;
} a5xx_hlsq_aperture_regs[] = {
{ 0x35, 0xe00, 0x32 }, /* HSLQ non-context */
{ 0x31, 0x2080, 0x1 }, /* HLSQ 2D context 0 */
{ 0x33, 0x2480, 0x1 }, /* HLSQ 2D context 1 */
{ 0x32, 0xe780, 0x62 }, /* HLSQ 3D context 0 */
{ 0x34, 0xef80, 0x62 }, /* HLSQ 3D context 1 */
{ 0x3f, 0x0ec0, 0x40 }, /* SP non-context */
{ 0x3d, 0x2040, 0x1 }, /* SP 2D context 0 */
{ 0x3b, 0x2440, 0x1 }, /* SP 2D context 1 */
{ 0x3e, 0xe580, 0x170 }, /* SP 3D context 0 */
{ 0x3c, 0xed80, 0x170 }, /* SP 3D context 1 */
{ 0x3a, 0x0f00, 0x1c }, /* TP non-context */
{ 0x38, 0x2000, 0xa }, /* TP 2D context 0 */
{ 0x36, 0x2400, 0xa }, /* TP 2D context 1 */
{ 0x39, 0xe700, 0x80 }, /* TP 3D context 0 */
{ 0x37, 0xef00, 0x80 }, /* TP 3D context 1 */
};
static void a5xx_gpu_state_get_hlsq_regs(struct msm_gpu *gpu,
struct a5xx_gpu_state *a5xx_state)
{
struct a5xx_crashdumper dumper = { 0 };
u32 offset, count = 0;
u64 *ptr;
int i;
if (a5xx_crashdumper_init(gpu, &dumper))
return;
/* The script will be written at offset 0 */
ptr = dumper.ptr;
/* Start writing the data at offset 256k */
offset = dumper.iova + (256 * SZ_1K);
/* Count how many additional registers to get from the HLSQ aperture */
for (i = 0; i < ARRAY_SIZE(a5xx_hlsq_aperture_regs); i++)
count += a5xx_hlsq_aperture_regs[i].count;
a5xx_state->hlsqregs = kcalloc(count, sizeof(u32), GFP_KERNEL);
if (!a5xx_state->hlsqregs)
return;
/* Build the crashdump script */
for (i = 0; i < ARRAY_SIZE(a5xx_hlsq_aperture_regs); i++) {
u32 type = a5xx_hlsq_aperture_regs[i].type;
u32 c = a5xx_hlsq_aperture_regs[i].count;
/* Write the register to select the desired bank */
*ptr++ = ((u64) type << 8);
*ptr++ = (((u64) REG_A5XX_HLSQ_DBG_READ_SEL) << 44) |
(1 << 21) | 1;
*ptr++ = offset;
*ptr++ = (((u64) REG_A5XX_HLSQ_DBG_AHB_READ_APERTURE) << 44)
| c;
offset += c * sizeof(u32);
}
/* Write two zeros to close off the script */
*ptr++ = 0;
*ptr++ = 0;
if (a5xx_crashdumper_run(gpu, &dumper)) {
kfree(a5xx_state->hlsqregs);
a5xx_crashdumper_free(gpu, &dumper);
return;
}
/* Copy the data from the crashdumper to the state */
memcpy(a5xx_state->hlsqregs, dumper.ptr + (256 * SZ_1K),
count * sizeof(u32));
a5xx_crashdumper_free(gpu, &dumper);
}
static struct msm_gpu_state *a5xx_gpu_state_get(struct msm_gpu *gpu)
{
struct a5xx_gpu_state *a5xx_state = kzalloc(sizeof(*a5xx_state),
GFP_KERNEL);
if (!a5xx_state)
return ERR_PTR(-ENOMEM);
/* Temporarily disable hardware clock gating before reading the hw */
a5xx_set_hwcg(gpu, false);
/* First get the generic state from the adreno core */
adreno_gpu_state_get(gpu, &(a5xx_state->base));
a5xx_state->base.rbbm_status = gpu_read(gpu, REG_A5XX_RBBM_STATUS);
/* Get the HLSQ regs with the help of the crashdumper */
a5xx_gpu_state_get_hlsq_regs(gpu, a5xx_state);
a5xx_set_hwcg(gpu, true);
return &a5xx_state->base;
}
static void a5xx_gpu_state_destroy(struct kref *kref)
{
struct msm_gpu_state *state = container_of(kref,
struct msm_gpu_state, ref);
struct a5xx_gpu_state *a5xx_state = container_of(state,
struct a5xx_gpu_state, base);
kfree(a5xx_state->hlsqregs);
adreno_gpu_state_destroy(state);
kfree(a5xx_state);
}
int a5xx_gpu_state_put(struct msm_gpu_state *state)
{
if (IS_ERR_OR_NULL(state))
return 1;
return kref_put(&state->ref, a5xx_gpu_state_destroy);
}
#if defined(CONFIG_DEBUG_FS) || defined(CONFIG_DEV_COREDUMP)
void a5xx_show(struct msm_gpu *gpu, struct msm_gpu_state *state,
struct drm_printer *p)
{
int i, j;
u32 pos = 0;
struct a5xx_gpu_state *a5xx_state = container_of(state,
struct a5xx_gpu_state, base);
if (IS_ERR_OR_NULL(state))
return;
adreno_show(gpu, state, p);
/* Dump the additional a5xx HLSQ registers */
if (!a5xx_state->hlsqregs)
return;
drm_printf(p, "registers-hlsq:\n");
for (i = 0; i < ARRAY_SIZE(a5xx_hlsq_aperture_regs); i++) {
u32 o = a5xx_hlsq_aperture_regs[i].regoffset;
u32 c = a5xx_hlsq_aperture_regs[i].count;
for (j = 0; j < c; j++, pos++, o++) {
/*
* To keep the crashdump simple we pull the entire range
* for each register type but not all of the registers
* in the range are valid. Fortunately invalid registers
* stick out like a sore thumb with a value of
* 0xdeadbeef
*/
if (a5xx_state->hlsqregs[pos] == 0xdeadbeef)
continue;
drm_printf(p, " - { offset: 0x%04x, value: 0x%08x }\n",
o << 2, a5xx_state->hlsqregs[pos]);
}
}
}
#endif
static struct msm_ringbuffer *a5xx_active_ring(struct msm_gpu *gpu)
{
struct adreno_gpu *adreno_gpu = to_adreno_gpu(gpu);
struct a5xx_gpu *a5xx_gpu = to_a5xx_gpu(adreno_gpu);
return a5xx_gpu->cur_ring;
}
static unsigned long a5xx_gpu_busy(struct msm_gpu *gpu)
{
u64 busy_cycles, busy_time;
busy_cycles = gpu_read64(gpu, REG_A5XX_RBBM_PERFCTR_RBBM_0_LO,
REG_A5XX_RBBM_PERFCTR_RBBM_0_HI);
busy_time = busy_cycles - gpu->devfreq.busy_cycles;
do_div(busy_time, clk_get_rate(gpu->core_clk) / 1000000);
gpu->devfreq.busy_cycles = busy_cycles;
if (WARN_ON(busy_time > ~0LU))
return ~0LU;
return (unsigned long)busy_time;
}
static const struct adreno_gpu_funcs funcs = {
.base = {
.get_param = adreno_get_param,
.hw_init = a5xx_hw_init,
.pm_suspend = a5xx_pm_suspend,
.pm_resume = a5xx_pm_resume,
.recover = a5xx_recover,
.submit = a5xx_submit,
.flush = a5xx_flush,
.active_ring = a5xx_active_ring,
.irq = a5xx_irq,
.destroy = a5xx_destroy,
#if defined(CONFIG_DEBUG_FS) || defined(CONFIG_DEV_COREDUMP)
.show = a5xx_show,
#endif
#if defined(CONFIG_DEBUG_FS)
.debugfs_init = a5xx_debugfs_init,
#endif
.gpu_busy = a5xx_gpu_busy,
.gpu_state_get = a5xx_gpu_state_get,
.gpu_state_put = a5xx_gpu_state_put,
},
.get_timestamp = a5xx_get_timestamp,
};
static void check_speed_bin(struct device *dev)
{
struct nvmem_cell *cell;
u32 bin, val;
cell = nvmem_cell_get(dev, "speed_bin");
/* If a nvmem cell isn't defined, nothing to do */
if (IS_ERR(cell))
return;
bin = *((u32 *) nvmem_cell_read(cell, NULL));
nvmem_cell_put(cell);
val = (1 << bin);
dev_pm_opp_set_supported_hw(dev, &val, 1);
}
struct msm_gpu *a5xx_gpu_init(struct drm_device *dev)
{
struct msm_drm_private *priv = dev->dev_private;
struct platform_device *pdev = priv->gpu_pdev;
struct a5xx_gpu *a5xx_gpu = NULL;
struct adreno_gpu *adreno_gpu;
struct msm_gpu *gpu;
int ret;
if (!pdev) {
dev_err(dev->dev, "No A5XX device is defined\n");
return ERR_PTR(-ENXIO);
}
a5xx_gpu = kzalloc(sizeof(*a5xx_gpu), GFP_KERNEL);
if (!a5xx_gpu)
return ERR_PTR(-ENOMEM);
adreno_gpu = &a5xx_gpu->base;
gpu = &adreno_gpu->base;
adreno_gpu->registers = a5xx_registers;
adreno_gpu->reg_offsets = a5xx_register_offsets;
a5xx_gpu->lm_leakage = 0x4E001A;
check_speed_bin(&pdev->dev);
ret = adreno_gpu_init(dev, pdev, adreno_gpu, &funcs, 4);
if (ret) {
a5xx_destroy(&(a5xx_gpu->base.base));
return ERR_PTR(ret);
}
if (gpu->aspace)
msm_mmu_set_fault_handler(gpu->aspace->mmu, gpu, a5xx_fault_handler);
/* Set up the preemption specific bits and pieces for each ringbuffer */
a5xx_preempt_init(gpu);
return gpu;
}