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accel/ivpu: Implement firmware parsing and booting

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Read, parse and boot VPU firmware image.

Co-developed-by: Andrzej Kacprowski <andrzej.kacprowski@linux.intel.com>
Signed-off-by: Andrzej Kacprowski <andrzej.kacprowski@linux.intel.com>
Co-developed-by: Krystian Pradzynski <krystian.pradzynski@linux.intel.com>
Signed-off-by: Krystian Pradzynski <krystian.pradzynski@linux.intel.com>
Signed-off-by: Jacek Lawrynowicz <jacek.lawrynowicz@linux.intel.com>
Reviewed-by: Oded Gabbay <ogabbay@kernel.org>
Reviewed-by: Jeffrey Hugo <quic_jhugo@quicinc.com>
Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
Link: https://patchwork.freedesktop.org/patch/msgid/20230117092723.60441-6-jacek.lawrynowicz@linux.intel.com
This commit is contained in:
Jacek Lawrynowicz 2023-01-17 10:27:21 +01:00 committed by Daniel Vetter
parent 5d7422cfb4
commit 02d5b0aacd
8 changed files with 979 additions and 1 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

1
drivers/accel/ivpu/Makefile
View File

@ -3,6 +3,7 @@
intel_vpu-y := \
ivpu_drv.o \
ivpu_fw.o \
ivpu_gem.o \
ivpu_hw_mtl.o \
ivpu_ipc.o \

131
drivers/accel/ivpu/ivpu_drv.c
View File

@ -14,10 +14,13 @@
#include <drm/drm_ioctl.h>
#include <drm/drm_prime.h>
#include "vpu_boot_api.h"
#include "ivpu_drv.h"
#include "ivpu_fw.h"
#include "ivpu_gem.h"
#include "ivpu_hw.h"
#include "ivpu_ipc.h"
#include "ivpu_jsm_msg.h"
#include "ivpu_mmu.h"
#include "ivpu_mmu_context.h"
@ -32,6 +35,10 @@ int ivpu_dbg_mask;
module_param_named(dbg_mask, ivpu_dbg_mask, int, 0644);
MODULE_PARM_DESC(dbg_mask, "Driver debug mask. See IVPU_DBG_* macros.");
int ivpu_test_mode;
module_param_named_unsafe(test_mode, ivpu_test_mode, int, 0644);
MODULE_PARM_DESC(test_mode, "Test mode: 0 - normal operation, 1 - fw unit test, 2 - null hw");
u8 ivpu_pll_min_ratio;
module_param_named(pll_min_ratio, ivpu_pll_min_ratio, byte, 0644);
MODULE_PARM_DESC(pll_min_ratio, "Minimum PLL ratio used to set VPU frequency");
@ -129,6 +136,28 @@ static int ivpu_get_param_ioctl(struct drm_device *dev, void *data, struct drm_f
case DRM_IVPU_PARAM_CONTEXT_ID:
args->value = file_priv->ctx.id;
break;
case DRM_IVPU_PARAM_FW_API_VERSION:
if (args->index < VPU_FW_API_VER_NUM) {
struct vpu_firmware_header *fw_hdr;
fw_hdr = (struct vpu_firmware_header *)vdev->fw->file->data;
args->value = fw_hdr->api_version[args->index];
} else {
ret = -EINVAL;
}
break;
case DRM_IVPU_PARAM_ENGINE_HEARTBEAT:
ret = ivpu_jsm_get_heartbeat(vdev, args->index, &args->value);
break;
case DRM_IVPU_PARAM_UNIQUE_INFERENCE_ID:
args->value = (u64)atomic64_inc_return(&vdev->unique_id_counter);
break;
case DRM_IVPU_PARAM_TILE_CONFIG:
args->value = vdev->hw->tile_fuse;
break;
case DRM_IVPU_PARAM_SKU:
args->value = vdev->hw->sku;
break;
default:
ret = -EINVAL;
break;
@ -225,11 +254,85 @@ static const struct drm_ioctl_desc ivpu_drm_ioctls[] = {
DRM_IOCTL_DEF_DRV(IVPU_BO_INFO, ivpu_bo_info_ioctl, 0),
};
static int ivpu_wait_for_ready(struct ivpu_device *vdev)
{
struct ivpu_ipc_consumer cons;
struct ivpu_ipc_hdr ipc_hdr;
unsigned long timeout;
int ret;
if (ivpu_test_mode == IVPU_TEST_MODE_FW_TEST)
return 0;
ivpu_ipc_consumer_add(vdev, &cons, IVPU_IPC_CHAN_BOOT_MSG);
timeout = jiffies + msecs_to_jiffies(vdev->timeout.boot);
while (1) {
ret = ivpu_ipc_irq_handler(vdev);
if (ret)
break;
ret = ivpu_ipc_receive(vdev, &cons, &ipc_hdr, NULL, 0);
if (ret != -ETIMEDOUT || time_after_eq(jiffies, timeout))
break;
cond_resched();
}
ivpu_ipc_consumer_del(vdev, &cons);
if (!ret && ipc_hdr.data_addr != IVPU_IPC_BOOT_MSG_DATA_ADDR) {
ivpu_err(vdev, "Invalid VPU ready message: 0x%x\n",
ipc_hdr.data_addr);
return -EIO;
}
if (!ret)
ivpu_info(vdev, "VPU ready message received successfully\n");
else
ivpu_hw_diagnose_failure(vdev);
return ret;
}
/**
* ivpu_boot() - Start VPU firmware
* @vdev: VPU device
*
* This function is paired with ivpu_shutdown() but it doesn't power up the
* VPU because power up has to be called very early in ivpu_probe().
*/
int ivpu_boot(struct ivpu_device *vdev)
{
int ret;
/* Update boot params located at first 4KB of FW memory */
ivpu_fw_boot_params_setup(vdev, vdev->fw->mem->kvaddr);
ret = ivpu_hw_boot_fw(vdev);
if (ret) {
ivpu_err(vdev, "Failed to start the firmware: %d\n", ret);
return ret;
}
ret = ivpu_wait_for_ready(vdev);
if (ret) {
ivpu_err(vdev, "Failed to boot the firmware: %d\n", ret);
return ret;
}
ivpu_hw_irq_clear(vdev);
enable_irq(vdev->irq);
ivpu_hw_irq_enable(vdev);
ivpu_ipc_enable(vdev);
return 0;
}
int ivpu_shutdown(struct ivpu_device *vdev)
{
int ret;
ivpu_hw_irq_disable(vdev);
disable_irq(vdev->irq);
ivpu_ipc_disable(vdev);
ivpu_mmu_disable(vdev);
@ -341,6 +444,10 @@ static int ivpu_dev_init(struct ivpu_device *vdev)
if (!vdev->mmu)
return -ENOMEM;
vdev->fw = drmm_kzalloc(&vdev->drm, sizeof(*vdev->fw), GFP_KERNEL);
if (!vdev->fw)
return -ENOMEM;
vdev->ipc = drmm_kzalloc(&vdev->drm, sizeof(*vdev->ipc), GFP_KERNEL);
if (!vdev->ipc)
return -ENOMEM;
@ -349,6 +456,7 @@ static int ivpu_dev_init(struct ivpu_device *vdev)
vdev->platform = IVPU_PLATFORM_INVALID;
vdev->context_xa_limit.min = IVPU_GLOBAL_CONTEXT_MMU_SSID + 1;
vdev->context_xa_limit.max = IVPU_CONTEXT_LIMIT;
atomic64_set(&vdev->unique_id_counter, 0);
xa_init_flags(&vdev->context_xa, XA_FLAGS_ALLOC);
ret = ivpu_pci_init(vdev);
@ -389,14 +497,34 @@ static int ivpu_dev_init(struct ivpu_device *vdev)
goto err_mmu_gctx_fini;
}
ret = ivpu_fw_init(vdev);
if (ret) {
ivpu_err(vdev, "Failed to initialize firmware: %d\n", ret);
goto err_mmu_gctx_fini;
}
ret = ivpu_ipc_init(vdev);
if (ret) {
ivpu_err(vdev, "Failed to initialize IPC: %d\n", ret);
goto err_mmu_gctx_fini;
goto err_fw_fini;
}
ret = ivpu_fw_load(vdev);
if (ret) {
ivpu_err(vdev, "Failed to load firmware: %d\n", ret);
goto err_fw_fini;
}
ret = ivpu_boot(vdev);
if (ret) {
ivpu_err(vdev, "Failed to boot: %d\n", ret);
goto err_fw_fini;
}
return 0;
err_fw_fini:
ivpu_fw_fini(vdev);
err_mmu_gctx_fini:
ivpu_mmu_global_context_fini(vdev);
err_power_down:
@ -410,6 +538,7 @@ static void ivpu_dev_fini(struct ivpu_device *vdev)
{
ivpu_shutdown(vdev);
ivpu_ipc_fini(vdev);
ivpu_fw_fini(vdev);
ivpu_mmu_global_context_fini(vdev);
drm_WARN_ON(&vdev->drm, !xa_empty(&vdev->context_xa));

11
drivers/accel/ivpu/ivpu_drv.h
View File

@ -74,6 +74,7 @@ struct ivpu_wa_table {
struct ivpu_hw_info;
struct ivpu_mmu_info;
struct ivpu_fw_info;
struct ivpu_ipc_info;
struct ivpu_device {
@ -86,12 +87,15 @@ struct ivpu_device {
struct ivpu_wa_table wa;
struct ivpu_hw_info *hw;
struct ivpu_mmu_info *mmu;
struct ivpu_fw_info *fw;
struct ivpu_ipc_info *ipc;
struct ivpu_mmu_context gctx;
struct xarray context_xa;
struct xa_limit context_xa_limit;
atomic64_t unique_id_counter;
struct {
int boot;
int jsm;
@ -116,9 +120,16 @@ extern int ivpu_dbg_mask;
extern u8 ivpu_pll_min_ratio;
extern u8 ivpu_pll_max_ratio;
#define IVPU_TEST_MODE_DISABLED 0
#define IVPU_TEST_MODE_FW_TEST 1
#define IVPU_TEST_MODE_NULL_HW 2
extern int ivpu_test_mode;
struct ivpu_file_priv *ivpu_file_priv_get(struct ivpu_file_priv *file_priv);
struct ivpu_file_priv *ivpu_file_priv_get_by_ctx_id(struct ivpu_device *vdev, unsigned long id);
void ivpu_file_priv_put(struct ivpu_file_priv **link);
int ivpu_boot(struct ivpu_device *vdev);
int ivpu_shutdown(struct ivpu_device *vdev);
static inline bool ivpu_is_mtl(struct ivpu_device *vdev)

419
drivers/accel/ivpu/ivpu_fw.c Normal file
View File

@ -0,0 +1,419 @@
// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (C) 2020-2023 Intel Corporation
*/
#include <linux/firmware.h>
#include <linux/highmem.h>
#include <linux/moduleparam.h>
#include <linux/pci.h>
#include "vpu_boot_api.h"
#include "ivpu_drv.h"
#include "ivpu_fw.h"
#include "ivpu_gem.h"
#include "ivpu_hw.h"
#include "ivpu_ipc.h"
#define FW_GLOBAL_MEM_START (2ull * SZ_1G)
#define FW_GLOBAL_MEM_END (3ull * SZ_1G)
#define FW_SHARED_MEM_SIZE SZ_256M /* Must be aligned to FW_SHARED_MEM_ALIGNMENT */
#define FW_SHARED_MEM_ALIGNMENT SZ_128K /* VPU MTRR limitation */
#define FW_RUNTIME_MAX_SIZE SZ_512M
#define FW_SHAVE_NN_MAX_SIZE SZ_2M
#define FW_RUNTIME_MIN_ADDR (FW_GLOBAL_MEM_START)
#define FW_RUNTIME_MAX_ADDR (FW_GLOBAL_MEM_END - FW_SHARED_MEM_SIZE)
#define FW_VERSION_HEADER_SIZE SZ_4K
#define FW_FILE_IMAGE_OFFSET (VPU_FW_HEADER_SIZE + FW_VERSION_HEADER_SIZE)
#define WATCHDOG_MSS_REDIRECT 32
#define WATCHDOG_NCE_REDIRECT 33
#define ADDR_TO_L2_CACHE_CFG(addr) ((addr) >> 31)
#define IVPU_FW_CHECK_API(vdev, fw_hdr, name) ivpu_fw_check_api(vdev, fw_hdr, #name, \
VPU_##name##_API_VER_INDEX, \
VPU_##name##_API_VER_MAJOR, \
VPU_##name##_API_VER_MINOR)
static char *ivpu_firmware;
module_param_named_unsafe(firmware, ivpu_firmware, charp, 0644);
MODULE_PARM_DESC(firmware, "VPU firmware binary in /lib/firmware/..");
static int ivpu_fw_request(struct ivpu_device *vdev)
{
static const char * const fw_names[] = {
"mtl_vpu.bin",
"intel/vpu/mtl_vpu_v0.0.bin"
};
int ret = -ENOENT;
int i;
if (ivpu_firmware)
return request_firmware(&vdev->fw->file, ivpu_firmware, vdev->drm.dev);
for (i = 0; i < ARRAY_SIZE(fw_names); i++) {
ret = firmware_request_nowarn(&vdev->fw->file, fw_names[i], vdev->drm.dev);
if (!ret)
return 0;
}
ivpu_err(vdev, "Failed to request firmware: %d\n", ret);
return ret;
}
static void
ivpu_fw_check_api(struct ivpu_device *vdev, const struct vpu_firmware_header *fw_hdr,
const char *str, int index, u16 expected_major, u16 expected_minor)
{
u16 major = (u16)(fw_hdr->api_version[index] >> 16);
u16 minor = (u16)(fw_hdr->api_version[index]);
if (major != expected_major) {
ivpu_warn(vdev, "Incompatible FW %s API version: %d.%d (expected %d.%d)\n",
str, major, minor, expected_major, expected_minor);
}
ivpu_dbg(vdev, FW_BOOT, "FW %s API version: %d.%d (expected %d.%d)\n",
str, major, minor, expected_major, expected_minor);
}
static int ivpu_fw_parse(struct ivpu_device *vdev)
{
struct ivpu_fw_info *fw = vdev->fw;
const struct vpu_firmware_header *fw_hdr = (const void *)fw->file->data;
u64 runtime_addr, image_load_addr, runtime_size, image_size;
if (fw->file->size <= FW_FILE_IMAGE_OFFSET) {
ivpu_err(vdev, "Firmware file is too small: %zu\n", fw->file->size);
return -EINVAL;
}
if (fw_hdr->header_version != VPU_FW_HEADER_VERSION) {
ivpu_err(vdev, "Invalid firmware header version: %u\n", fw_hdr->header_version);
return -EINVAL;
}
runtime_addr = fw_hdr->boot_params_load_address;
runtime_size = fw_hdr->runtime_size;
image_load_addr = fw_hdr->image_load_address;
image_size = fw_hdr->image_size;
if (runtime_addr < FW_RUNTIME_MIN_ADDR || runtime_addr > FW_RUNTIME_MAX_ADDR) {
ivpu_err(vdev, "Invalid firmware runtime address: 0x%llx\n", runtime_addr);
return -EINVAL;
}
if (runtime_size < fw->file->size || runtime_size > FW_RUNTIME_MAX_SIZE) {
ivpu_err(vdev, "Invalid firmware runtime size: %llu\n", runtime_size);
return -EINVAL;
}
if (FW_FILE_IMAGE_OFFSET + image_size > fw->file->size) {
ivpu_err(vdev, "Invalid image size: %llu\n", image_size);
return -EINVAL;
}
if (image_load_addr < runtime_addr ||
image_load_addr + image_size > runtime_addr + runtime_size) {
ivpu_err(vdev, "Invalid firmware load address size: 0x%llx and size %llu\n",
image_load_addr, image_size);
return -EINVAL;
}
if (fw_hdr->shave_nn_fw_size > FW_SHAVE_NN_MAX_SIZE) {
ivpu_err(vdev, "SHAVE NN firmware is too big: %u\n", fw_hdr->shave_nn_fw_size);
return -EINVAL;
}
if (fw_hdr->entry_point < image_load_addr ||
fw_hdr->entry_point >= image_load_addr + image_size) {
ivpu_err(vdev, "Invalid entry point: 0x%llx\n", fw_hdr->entry_point);
return -EINVAL;
}
fw->runtime_addr = runtime_addr;
fw->runtime_size = runtime_size;
fw->image_load_offset = image_load_addr - runtime_addr;
fw->image_size = image_size;
fw->shave_nn_size = PAGE_ALIGN(fw_hdr->shave_nn_fw_size);
fw->cold_boot_entry_point = fw_hdr->entry_point;
fw->entry_point = fw->cold_boot_entry_point;
ivpu_dbg(vdev, FW_BOOT, "Header version: 0x%x, format 0x%x\n",
fw_hdr->header_version, fw_hdr->image_format);
ivpu_dbg(vdev, FW_BOOT, "Size: file %lu image %u runtime %u shavenn %u\n",
fw->file->size, fw->image_size, fw->runtime_size, fw->shave_nn_size);
ivpu_dbg(vdev, FW_BOOT, "Address: runtime 0x%llx, load 0x%llx, entry point 0x%llx\n",
fw->runtime_addr, image_load_addr, fw->entry_point);
ivpu_dbg(vdev, FW_BOOT, "FW version: %s\n", (char *)fw_hdr + VPU_FW_HEADER_SIZE);
IVPU_FW_CHECK_API(vdev, fw_hdr, BOOT);
IVPU_FW_CHECK_API(vdev, fw_hdr, JSM);
return 0;
}
static void ivpu_fw_release(struct ivpu_device *vdev)
{
release_firmware(vdev->fw->file);
}
static int ivpu_fw_update_global_range(struct ivpu_device *vdev)
{
struct ivpu_fw_info *fw = vdev->fw;
u64 start = ALIGN(fw->runtime_addr + fw->runtime_size, FW_SHARED_MEM_ALIGNMENT);
u64 size = FW_SHARED_MEM_SIZE;
if (start + size > FW_GLOBAL_MEM_END) {
ivpu_err(vdev, "No space for shared region, start %lld, size %lld\n", start, size);
return -EINVAL;
}
ivpu_hw_init_range(&vdev->hw->ranges.global_low, start, size);
return 0;
}
static int ivpu_fw_mem_init(struct ivpu_device *vdev)
{
struct ivpu_fw_info *fw = vdev->fw;
int ret;
ret = ivpu_fw_update_global_range(vdev);
if (ret)
return ret;
fw->mem = ivpu_bo_alloc_internal(vdev, fw->runtime_addr, fw->runtime_size, DRM_IVPU_BO_WC);
if (!fw->mem) {
ivpu_err(vdev, "Failed to allocate firmware runtime memory\n");
return -ENOMEM;
}
if (fw->shave_nn_size) {
fw->mem_shave_nn = ivpu_bo_alloc_internal(vdev, vdev->hw->ranges.global_high.start,
fw->shave_nn_size, DRM_IVPU_BO_UNCACHED);
if (!fw->mem_shave_nn) {
ivpu_err(vdev, "Failed to allocate shavenn buffer\n");
ivpu_bo_free_internal(fw->mem);
return -ENOMEM;
}
}
return 0;
}
static void ivpu_fw_mem_fini(struct ivpu_device *vdev)
{
struct ivpu_fw_info *fw = vdev->fw;
if (fw->mem_shave_nn) {
ivpu_bo_free_internal(fw->mem_shave_nn);
fw->mem_shave_nn = NULL;
}
ivpu_bo_free_internal(fw->mem);
fw->mem = NULL;
}
int ivpu_fw_init(struct ivpu_device *vdev)
{
int ret;
ret = ivpu_fw_request(vdev);
if (ret)
return ret;
ret = ivpu_fw_parse(vdev);
if (ret)
goto err_fw_release;
ret = ivpu_fw_mem_init(vdev);
if (ret)
goto err_fw_release;
return 0;
err_fw_release:
ivpu_fw_release(vdev);
return ret;
}
void ivpu_fw_fini(struct ivpu_device *vdev)
{
ivpu_fw_mem_fini(vdev);
ivpu_fw_release(vdev);
}
int ivpu_fw_load(struct ivpu_device *vdev)
{
struct ivpu_fw_info *fw = vdev->fw;
u64 image_end_offset = fw->image_load_offset + fw->image_size;
memset(fw->mem->kvaddr, 0, fw->image_load_offset);
memcpy(fw->mem->kvaddr + fw->image_load_offset,
fw->file->data + FW_FILE_IMAGE_OFFSET, fw->image_size);
if (IVPU_WA(clear_runtime_mem)) {
u8 *start = fw->mem->kvaddr + image_end_offset;
u64 size = fw->mem->base.size - image_end_offset;
memset(start, 0, size);
}
wmb(); /* Flush WC buffers after writing fw->mem */
return 0;
}
static void ivpu_fw_boot_params_print(struct ivpu_device *vdev, struct vpu_boot_params *boot_params)
{
ivpu_dbg(vdev, FW_BOOT, "boot_params.magic = 0x%x\n",
boot_params->magic);
ivpu_dbg(vdev, FW_BOOT, "boot_params.vpu_id = 0x%x\n",
boot_params->vpu_id);
ivpu_dbg(vdev, FW_BOOT, "boot_params.vpu_count = 0x%x\n",
boot_params->vpu_count);
ivpu_dbg(vdev, FW_BOOT, "boot_params.frequency = %u\n",
boot_params->frequency);
ivpu_dbg(vdev, FW_BOOT, "boot_params.perf_clk_frequency = %u\n",
boot_params->perf_clk_frequency);
ivpu_dbg(vdev, FW_BOOT, "boot_params.ipc_header_area_start = 0x%llx\n",
boot_params->ipc_header_area_start);
ivpu_dbg(vdev, FW_BOOT, "boot_params.ipc_header_area_size = 0x%x\n",
boot_params->ipc_header_area_size);
ivpu_dbg(vdev, FW_BOOT, "boot_params.shared_region_base = 0x%llx\n",
boot_params->shared_region_base);
ivpu_dbg(vdev, FW_BOOT, "boot_params.shared_region_size = 0x%x\n",
boot_params->shared_region_size);
ivpu_dbg(vdev, FW_BOOT, "boot_params.ipc_payload_area_start = 0x%llx\n",
boot_params->ipc_payload_area_start);
ivpu_dbg(vdev, FW_BOOT, "boot_params.ipc_payload_area_size = 0x%x\n",
boot_params->ipc_payload_area_size);
ivpu_dbg(vdev, FW_BOOT, "boot_params.global_aliased_pio_base = 0x%llx\n",
boot_params->global_aliased_pio_base);
ivpu_dbg(vdev, FW_BOOT, "boot_params.global_aliased_pio_size = 0x%x\n",
boot_params->global_aliased_pio_size);
ivpu_dbg(vdev, FW_BOOT, "boot_params.autoconfig = 0x%x\n",
boot_params->autoconfig);
ivpu_dbg(vdev, FW_BOOT, "boot_params.cache_defaults[VPU_BOOT_L2_CACHE_CFG_NN].use = 0x%x\n",
boot_params->cache_defaults[VPU_BOOT_L2_CACHE_CFG_NN].use);
ivpu_dbg(vdev, FW_BOOT, "boot_params.cache_defaults[VPU_BOOT_L2_CACHE_CFG_NN].cfg = 0x%x\n",
boot_params->cache_defaults[VPU_BOOT_L2_CACHE_CFG_NN].cfg);
ivpu_dbg(vdev, FW_BOOT, "boot_params.global_memory_allocator_base = 0x%llx\n",
boot_params->global_memory_allocator_base);
ivpu_dbg(vdev, FW_BOOT, "boot_params.global_memory_allocator_size = 0x%x\n",
boot_params->global_memory_allocator_size);
ivpu_dbg(vdev, FW_BOOT, "boot_params.shave_nn_fw_base = 0x%llx\n",
boot_params->shave_nn_fw_base);
ivpu_dbg(vdev, FW_BOOT, "boot_params.watchdog_irq_mss = 0x%x\n",
boot_params->watchdog_irq_mss);
ivpu_dbg(vdev, FW_BOOT, "boot_params.watchdog_irq_nce = 0x%x\n",
boot_params->watchdog_irq_nce);
ivpu_dbg(vdev, FW_BOOT, "boot_params.host_to_vpu_irq = 0x%x\n",
boot_params->host_to_vpu_irq);
ivpu_dbg(vdev, FW_BOOT, "boot_params.job_done_irq = 0x%x\n",
boot_params->job_done_irq);
ivpu_dbg(vdev, FW_BOOT, "boot_params.host_version_id = 0x%x\n",
boot_params->host_version_id);
ivpu_dbg(vdev, FW_BOOT, "boot_params.si_stepping = 0x%x\n",
boot_params->si_stepping);
ivpu_dbg(vdev, FW_BOOT, "boot_params.device_id = 0x%llx\n",
boot_params->device_id);
ivpu_dbg(vdev, FW_BOOT, "boot_params.feature_exclusion = 0x%llx\n",
boot_params->feature_exclusion);
ivpu_dbg(vdev, FW_BOOT, "boot_params.sku = 0x%llx\n",
boot_params->sku);
ivpu_dbg(vdev, FW_BOOT, "boot_params.min_freq_pll_ratio = 0x%x\n",
boot_params->min_freq_pll_ratio);
ivpu_dbg(vdev, FW_BOOT, "boot_params.pn_freq_pll_ratio = 0x%x\n",
boot_params->pn_freq_pll_ratio);
ivpu_dbg(vdev, FW_BOOT, "boot_params.max_freq_pll_ratio = 0x%x\n",
boot_params->max_freq_pll_ratio);
ivpu_dbg(vdev, FW_BOOT, "boot_params.default_trace_level = 0x%x\n",
boot_params->default_trace_level);
ivpu_dbg(vdev, FW_BOOT, "boot_params.tracing_buff_message_format_mask = 0x%llx\n",
boot_params->tracing_buff_message_format_mask);
ivpu_dbg(vdev, FW_BOOT, "boot_params.trace_destination_mask = 0x%x\n",
boot_params->trace_destination_mask);
ivpu_dbg(vdev, FW_BOOT, "boot_params.trace_hw_component_mask = 0x%llx\n",
boot_params->trace_hw_component_mask);
ivpu_dbg(vdev, FW_BOOT, "boot_params.boot_type = 0x%x\n",
boot_params->boot_type);
ivpu_dbg(vdev, FW_BOOT, "boot_params.punit_telemetry_sram_base = 0x%llx\n",
boot_params->punit_telemetry_sram_base);
ivpu_dbg(vdev, FW_BOOT, "boot_params.punit_telemetry_sram_size = 0x%llx\n",
boot_params->punit_telemetry_sram_size);
ivpu_dbg(vdev, FW_BOOT, "boot_params.vpu_telemetry_enable = 0x%x\n",
boot_params->vpu_telemetry_enable);
}
void ivpu_fw_boot_params_setup(struct ivpu_device *vdev, struct vpu_boot_params *boot_params)
{
struct ivpu_bo *ipc_mem_rx = vdev->ipc->mem_rx;
/* In case of warm boot we only have to reset the entrypoint addr */
if (!ivpu_fw_is_cold_boot(vdev)) {
boot_params->save_restore_ret_address = 0;
return;
}
boot_params->magic = VPU_BOOT_PARAMS_MAGIC;
boot_params->vpu_id = to_pci_dev(vdev->drm.dev)->bus->number;
boot_params->frequency = ivpu_hw_reg_pll_freq_get(vdev);
/*
* Uncached region of VPU address space, covers IPC buffers, job queues
* and log buffers, programmable to L2$ Uncached by VPU MTRR
*/
boot_params->shared_region_base = vdev->hw->ranges.global_low.start;
boot_params->shared_region_size = vdev->hw->ranges.global_low.end -
vdev->hw->ranges.global_low.start;
boot_params->ipc_header_area_start = ipc_mem_rx->vpu_addr;
boot_params->ipc_header_area_size = ipc_mem_rx->base.size / 2;
boot_params->ipc_payload_area_start = ipc_mem_rx->vpu_addr + ipc_mem_rx->base.size / 2;
boot_params->ipc_payload_area_size = ipc_mem_rx->base.size / 2;
boot_params->global_aliased_pio_base =
vdev->hw->ranges.global_aliased_pio.start;
boot_params->global_aliased_pio_size =
ivpu_hw_range_size(&vdev->hw->ranges.global_aliased_pio);
/* Allow configuration for L2C_PAGE_TABLE with boot param value */
boot_params->autoconfig = 1;
/* Enable L2 cache for first 2GB of high memory */
boot_params->cache_defaults[VPU_BOOT_L2_CACHE_CFG_NN].use = 1;
boot_params->cache_defaults[VPU_BOOT_L2_CACHE_CFG_NN].cfg =
ADDR_TO_L2_CACHE_CFG(vdev->hw->ranges.global_high.start);
if (vdev->fw->mem_shave_nn)
boot_params->shave_nn_fw_base = vdev->fw->mem_shave_nn->vpu_addr;
boot_params->watchdog_irq_mss = WATCHDOG_MSS_REDIRECT;
boot_params->watchdog_irq_nce = WATCHDOG_NCE_REDIRECT;
boot_params->si_stepping = ivpu_revision(vdev);
boot_params->device_id = ivpu_device_id(vdev);
boot_params->feature_exclusion = vdev->hw->tile_fuse;
boot_params->sku = vdev->hw->sku;
boot_params->min_freq_pll_ratio = vdev->hw->pll.min_ratio;
boot_params->pn_freq_pll_ratio = vdev->hw->pll.pn_ratio;
boot_params->max_freq_pll_ratio = vdev->hw->pll.max_ratio;
boot_params->punit_telemetry_sram_base = ivpu_hw_reg_telemetry_offset_get(vdev);
boot_params->punit_telemetry_sram_size = ivpu_hw_reg_telemetry_size_get(vdev);
boot_params->vpu_telemetry_enable = ivpu_hw_reg_telemetry_enable_get(vdev);
wmb(); /* Flush WC buffers after writing bootparams */
ivpu_fw_boot_params_print(vdev, boot_params);
}

38
drivers/accel/ivpu/ivpu_fw.h Normal file
View File

@ -0,0 +1,38 @@
/* SPDX-License-Identifier: GPL-2.0-only */
/*
* Copyright (C) 2020-2023 Intel Corporation
*/
#ifndef __IVPU_FW_H__
#define __IVPU_FW_H__
struct ivpu_device;
struct ivpu_bo;
struct vpu_boot_params;
struct ivpu_fw_info {
const struct firmware *file;
struct ivpu_bo *mem;
struct ivpu_bo *mem_shave_nn;
struct ivpu_bo *mem_log_crit;
struct ivpu_bo *mem_log_verb;
u64 runtime_addr;
u32 runtime_size;
u64 image_load_offset;
u32 image_size;
u32 shave_nn_size;
u64 entry_point; /* Cold or warm boot entry point for next boot */
u64 cold_boot_entry_point;
};
int ivpu_fw_init(struct ivpu_device *vdev);
void ivpu_fw_fini(struct ivpu_device *vdev);
int ivpu_fw_load(struct ivpu_device *vdev);
void ivpu_fw_boot_params_setup(struct ivpu_device *vdev, struct vpu_boot_params *bp);
static inline bool ivpu_fw_is_cold_boot(struct ivpu_device *vdev)
{
return vdev->fw->entry_point == vdev->fw->cold_boot_entry_point;
}
#endif /* __IVPU_FW_H__ */

10
drivers/accel/ivpu/ivpu_hw_mtl.c
View File

@ -4,6 +4,7 @@
*/
#include "ivpu_drv.h"
#include "ivpu_fw.h"
#include "ivpu_hw_mtl_reg.h"
#include "ivpu_hw_reg_io.h"
#include "ivpu_hw.h"
@ -588,6 +589,15 @@ static void ivpu_boot_soc_cpu_boot(struct ivpu_device *vdev)
val = REG_CLR_FLD(MTL_VPU_CPU_SS_MSSCPU_CPR_LEON_RT_VEC, IRQI_RESUME0, val);
REGV_WR32(MTL_VPU_CPU_SS_MSSCPU_CPR_LEON_RT_VEC, val);
val = vdev->fw->entry_point >> 9;
REGV_WR32(MTL_VPU_HOST_SS_LOADING_ADDRESS_LO, val);
val = REG_SET_FLD(MTL_VPU_HOST_SS_LOADING_ADDRESS_LO, DONE, val);
REGV_WR32(MTL_VPU_HOST_SS_LOADING_ADDRESS_LO, val);
ivpu_dbg(vdev, PM, "Booting firmware, mode: %s\n",
vdev->fw->entry_point == vdev->fw->cold_boot_entry_point ? "cold boot" : "resume");
}
static int ivpu_boot_d0i3_drive(struct ivpu_device *vdev, bool enable)

349
drivers/accel/ivpu/vpu_boot_api.h Normal file
View File

@ -0,0 +1,349 @@
/* SPDX-License-Identifier: MIT */
/*
* Copyright (C) 2020-2023 Intel Corporation
*/
#ifndef VPU_BOOT_API_H
#define VPU_BOOT_API_H
/*
* =========== FW API version information beginning ================
* The bellow values will be used to construct the version info this way:
* fw_bin_header->api_version[VPU_BOOT_API_VER_ID] = (VPU_BOOT_API_VER_MAJOR << 16) |
* VPU_BOOT_API_VER_MINOR;
* VPU_BOOT_API_VER_PATCH will be ignored. KMD and compatibility is not affected if this changes.
*/
/*
* Major version changes that break backward compatibility.
* Major version must start from 1 and can only be incremented.
*/
#define VPU_BOOT_API_VER_MAJOR 3
/*
* Minor version changes when API backward compatibility is preserved.
* Resets to 0 if Major version is incremented.
*/
#define VPU_BOOT_API_VER_MINOR 12
/*
* API header changed (field names, documentation, formatting) but API itself has not been changed
*/
#define VPU_BOOT_API_VER_PATCH 2
/*
* Index in the API version table
* Must be unique for each API
*/
#define VPU_BOOT_API_VER_INDEX 0
/* ------------ FW API version information end ---------------------*/
#pragma pack(push, 1)
/*
* Firmware image header format
*/
#define VPU_FW_HEADER_SIZE 4096
#define VPU_FW_HEADER_VERSION 0x1
#define VPU_FW_VERSION_SIZE 32
#define VPU_FW_API_VER_NUM 16
struct vpu_firmware_header {
u32 header_version;
u32 image_format;
u64 image_load_address;
u32 image_size;
u64 entry_point;
u8 vpu_version[VPU_FW_VERSION_SIZE];
u32 compression_type;
u64 firmware_version_load_address;
u32 firmware_version_size;
u64 boot_params_load_address;
u32 api_version[VPU_FW_API_VER_NUM];
/* Size of memory require for firmware execution */
u32 runtime_size;
u32 shave_nn_fw_size;
};
/*
* Firmware boot parameters format
*/
#define VPU_BOOT_PLL_COUNT 3
#define VPU_BOOT_PLL_OUT_COUNT 4
/** Values for boot_type field */
#define VPU_BOOT_TYPE_COLDBOOT 0
#define VPU_BOOT_TYPE_WARMBOOT 1
/** Value for magic filed */
#define VPU_BOOT_PARAMS_MAGIC 0x10000
/** VPU scheduling mode. By default, OS scheduling is used. */
#define VPU_SCHEDULING_MODE_OS 0
#define VPU_SCHEDULING_MODE_HW 1
enum VPU_BOOT_L2_CACHE_CFG_TYPE {
VPU_BOOT_L2_CACHE_CFG_UPA = 0,
VPU_BOOT_L2_CACHE_CFG_NN = 1,
VPU_BOOT_L2_CACHE_CFG_NUM = 2
};
/**
* Logging destinations.
*
* Logging output can be directed to different logging destinations. This enum
* defines the list of logging destinations supported by the VPU firmware (NOTE:
* a specific VPU FW binary may support only a subset of such output
* destinations, depending on the target platform and compile options).
*/
enum vpu_trace_destination {
VPU_TRACE_DESTINATION_PIPEPRINT = 0x1,
VPU_TRACE_DESTINATION_VERBOSE_TRACING = 0x2,
VPU_TRACE_DESTINATION_NORTH_PEAK = 0x4,
};
/*
* Processor bit shifts (for loggable HW components).
*/
#define VPU_TRACE_PROC_BIT_ARM 0
#define VPU_TRACE_PROC_BIT_LRT 1
#define VPU_TRACE_PROC_BIT_LNN 2
#define VPU_TRACE_PROC_BIT_SHV_0 3
#define VPU_TRACE_PROC_BIT_SHV_1 4
#define VPU_TRACE_PROC_BIT_SHV_2 5
#define VPU_TRACE_PROC_BIT_SHV_3 6
#define VPU_TRACE_PROC_BIT_SHV_4 7
#define VPU_TRACE_PROC_BIT_SHV_5 8
#define VPU_TRACE_PROC_BIT_SHV_6 9
#define VPU_TRACE_PROC_BIT_SHV_7 10
#define VPU_TRACE_PROC_BIT_SHV_8 11
#define VPU_TRACE_PROC_BIT_SHV_9 12
#define VPU_TRACE_PROC_BIT_SHV_10 13
#define VPU_TRACE_PROC_BIT_SHV_11 14
#define VPU_TRACE_PROC_BIT_SHV_12 15
#define VPU_TRACE_PROC_BIT_SHV_13 16
#define VPU_TRACE_PROC_BIT_SHV_14 17
#define VPU_TRACE_PROC_BIT_SHV_15 18
#define VPU_TRACE_PROC_BIT_ACT_SHV_0 19
#define VPU_TRACE_PROC_BIT_ACT_SHV_1 20
#define VPU_TRACE_PROC_BIT_ACT_SHV_2 21
#define VPU_TRACE_PROC_BIT_ACT_SHV_3 22
#define VPU_TRACE_PROC_NO_OF_HW_DEVS 23
/* KMB HW component IDs are sequential, so define first and last IDs. */
#define VPU_TRACE_PROC_BIT_KMB_FIRST VPU_TRACE_PROC_BIT_LRT
#define VPU_TRACE_PROC_BIT_KMB_LAST VPU_TRACE_PROC_BIT_SHV_15
struct vpu_boot_l2_cache_config {
u8 use;
u8 cfg;
};
struct vpu_warm_boot_section {
u32 src;
u32 dst;
u32 size;
u32 core_id;
u32 is_clear_op;
};
struct vpu_boot_params {
u32 magic;
u32 vpu_id;
u32 vpu_count;
u32 pad0[5];
/* Clock frequencies: 0x20 - 0xFF */
u32 frequency;
u32 pll[VPU_BOOT_PLL_COUNT][VPU_BOOT_PLL_OUT_COUNT];
u32 perf_clk_frequency;
u32 pad1[42];
/* Memory regions: 0x100 - 0x1FF */
u64 ipc_header_area_start;
u32 ipc_header_area_size;
u64 shared_region_base;
u32 shared_region_size;
u64 ipc_payload_area_start;
u32 ipc_payload_area_size;
u64 global_aliased_pio_base;
u32 global_aliased_pio_size;
u32 autoconfig;
struct vpu_boot_l2_cache_config cache_defaults[VPU_BOOT_L2_CACHE_CFG_NUM];
u64 global_memory_allocator_base;
u32 global_memory_allocator_size;
/**
* ShaveNN FW section VPU base address
* On VPU2.7 HW this address must be within 2GB range starting from L2C_PAGE_TABLE base
*/
u64 shave_nn_fw_base;
u64 save_restore_ret_address; /* stores the address of FW's restore entry point */
u32 pad2[43];
/* IRQ re-direct numbers: 0x200 - 0x2FF */
s32 watchdog_irq_mss;
s32 watchdog_irq_nce;
/* ARM -> VPU doorbell interrupt. ARM is notifying VPU of async command or compute job. */
u32 host_to_vpu_irq;
/* VPU -> ARM job done interrupt. VPU is notifying ARM of compute job completion. */
u32 job_done_irq;
/* VPU -> ARM IRQ line to use to request MMU update. */
u32 mmu_update_request_irq;
/* ARM -> VPU IRQ line to use to notify of MMU update completion. */
u32 mmu_update_done_irq;
/* ARM -> VPU IRQ line to use to request power level change. */
u32 set_power_level_irq;
/* VPU -> ARM IRQ line to use to notify of power level change completion. */
u32 set_power_level_done_irq;
/* VPU -> ARM IRQ line to use to notify of VPU idle state change */
u32 set_vpu_idle_update_irq;
/* VPU -> ARM IRQ line to use to request counter reset. */
u32 metric_query_event_irq;
/* ARM -> VPU IRQ line to use to notify of counter reset completion. */
u32 metric_query_event_done_irq;
/* VPU -> ARM IRQ line to use to notify of preemption completion. */
u32 preemption_done_irq;
/* Padding. */
u32 pad3[52];
/* Silicon information: 0x300 - 0x3FF */
u32 host_version_id;
u32 si_stepping;
u64 device_id;
u64 feature_exclusion;
u64 sku;
/** PLL ratio for minimum clock frequency */
u32 min_freq_pll_ratio;
/** PLL ratio for maximum clock frequency */
u32 max_freq_pll_ratio;
/**
* Initial log level threshold (messages with log level severity less than
* the threshold will not be logged); applies to every enabled logging
* destination and loggable HW component. See 'mvLog_t' enum for acceptable
* values.
*/
u32 default_trace_level;
u32 boot_type;
u64 punit_telemetry_sram_base;
u64 punit_telemetry_sram_size;
u32 vpu_telemetry_enable;
u64 crit_tracing_buff_addr;
u32 crit_tracing_buff_size;
u64 verbose_tracing_buff_addr;
u32 verbose_tracing_buff_size;
u64 verbose_tracing_sw_component_mask; /* TO BE REMOVED */
/**
* Mask of destinations to which logging messages are delivered; bitwise OR
* of values defined in vpu_trace_destination enum.
*/
u32 trace_destination_mask;
/**
* Mask of hardware components for which logging is enabled; bitwise OR of
* bits defined by the VPU_TRACE_PROC_BIT_* macros.
*/
u64 trace_hw_component_mask;
/** Mask of trace message formats supported by the driver */
u64 tracing_buff_message_format_mask;
u64 trace_reserved_1[2];
/**
* Period at which the VPU reads the temp sensor values into MMIO, on
* platforms where that is necessary (in ms). 0 to disable reads.
*/
u32 temp_sensor_period_ms;
/** PLL ratio for efficient clock frequency */
u32 pn_freq_pll_ratio;
u32 pad4[28];
/* Warm boot information: 0x400 - 0x43F */
u32 warm_boot_sections_count;
u32 warm_boot_start_address_reference;
u32 warm_boot_section_info_address_offset;
u32 pad5[13];
/* Power States transitions timestamps: 0x440 - 0x46F*/
struct {
/* VPU_IDLE -> VPU_ACTIVE transition initiated timestamp */
u64 vpu_active_state_requested;
/* VPU_IDLE -> VPU_ACTIVE transition completed timestamp */
u64 vpu_active_state_achieved;
/* VPU_ACTIVE -> VPU_IDLE transition initiated timestamp */
u64 vpu_idle_state_requested;
/* VPU_ACTIVE -> VPU_IDLE transition completed timestamp */
u64 vpu_idle_state_achieved;
/* VPU_IDLE -> VPU_STANDBY transition initiated timestamp */
u64 vpu_standby_state_requested;
/* VPU_IDLE -> VPU_STANDBY transition completed timestamp */
u64 vpu_standby_state_achieved;
} power_states_timestamps;
/* VPU scheduling mode. Values defined by VPU_SCHEDULING_MODE_* macros. */
u32 vpu_scheduling_mode;
/* Present call period in milliseconds. */
u32 vpu_focus_present_timer_ms;
/* Unused/reserved: 0x478 - 0xFFF */
u32 pad6[738];
};
/*
* Magic numbers set between host and vpu to detect corruptio of tracing init
*/
#define VPU_TRACING_BUFFER_CANARY (0xCAFECAFE)
/* Tracing buffer message format definitions */
#define VPU_TRACING_FORMAT_STRING 0
#define VPU_TRACING_FORMAT_MIPI 2
/*
* Header of the tracing buffer.
* The below defined header will be stored at the beginning of
* each allocated tracing buffer, followed by a series of 256b
* of ASCII trace message entries.
*/
struct vpu_tracing_buffer_header {
/**
* Magic number set by host to detect corruption
* @see VPU_TRACING_BUFFER_CANARY
*/
u32 host_canary_start;
/* offset from start of buffer for trace entries */
u32 read_index;
u32 pad_to_cache_line_size_0[14];
/* End of first cache line */
/**
* Magic number set by host to detect corruption
* @see VPU_TRACING_BUFFER_CANARY
*/
u32 vpu_canary_start;
/* offset from start of buffer from write start */
u32 write_index;
/* counter for buffer wrapping */
u32 wrap_count;
/* legacy field - do not use */
u32 reserved_0;
/**
* Size of the log buffer include this header (@header_size) and space
* reserved for all messages. If @alignment` is greater that 0 the @Size
* must be multiple of @Alignment.
*/
u32 size;
/* Header version */
u16 header_version;
/* Header size */
u16 header_size;
/*
* Format of the messages in the trace buffer
* 0 - null terminated string
* 1 - size + null terminated string
* 2 - MIPI-SysT encoding
*/
u32 format;
/*
* Message alignment
* 0 - messages are place 1 after another
* n - every message starts and multiple on offset
*/
u32 alignment; /* 64, 128, 256 */
/* Name of the logging entity, i.e "LRT", "LNN", "SHV0", etc */
char name[16];
u32 pad_to_cache_line_size_1[4];
/* End of second cache line */
};
#pragma pack(pop)
#endif

21
include/uapi/drm/ivpu_accel.h
View File

@ -47,6 +47,11 @@ extern "C" {
#define DRM_IVPU_PARAM_CONTEXT_BASE_ADDRESS 5
#define DRM_IVPU_PARAM_CONTEXT_PRIORITY 6
#define DRM_IVPU_PARAM_CONTEXT_ID 7
#define DRM_IVPU_PARAM_FW_API_VERSION 8
#define DRM_IVPU_PARAM_ENGINE_HEARTBEAT 9
#define DRM_IVPU_PARAM_UNIQUE_INFERENCE_ID 10
#define DRM_IVPU_PARAM_TILE_CONFIG 11
#define DRM_IVPU_PARAM_SKU 12
#define DRM_IVPU_PLATFORM_TYPE_SILICON 0
@ -90,6 +95,22 @@ struct drm_ivpu_param {
* %DRM_IVPU_PARAM_CONTEXT_ID:
* Current context ID, always greater than 0 (read-only)
*
* %DRM_IVPU_PARAM_FW_API_VERSION:
* Firmware API version array (read-only)
*
* %DRM_IVPU_PARAM_ENGINE_HEARTBEAT:
* Heartbeat value from an engine (read-only).
* Engine ID (i.e. DRM_IVPU_ENGINE_COMPUTE) is given via index.
*
* %DRM_IVPU_PARAM_UNIQUE_INFERENCE_ID:
* Device-unique inference ID (read-only)
*
* %DRM_IVPU_PARAM_TILE_CONFIG:
* VPU tile configuration (read-only)
*
* %DRM_IVPU_PARAM_SKU:
* VPU SKU ID (read-only)
*
*/
__u32 param;