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|
/*
* Copyright (c) 2016, NVIDIA CORPORATION. All rights reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
* DEALINGS IN THE SOFTWARE.
*/
/*
* Secure boot is the process by which NVIDIA-signed firmware is loaded into
* some of the falcons of a GPU. For production devices this is the only way
* for the firmware to access useful (but sensitive) registers.
*
* A Falcon microprocessor supporting advanced security modes can run in one of
* three modes:
*
* - Non-secure (NS). In this mode, functionality is similar to Falcon
* architectures before security modes were introduced (pre-Maxwell), but
* capability is restricted. In particular, certain registers may be
* inaccessible for reads and/or writes, and physical memory access may be
* disabled (on certain Falcon instances). This is the only possible mode that
* can be used if you don't have microcode cryptographically signed by NVIDIA.
*
* - Heavy Secure (HS). In this mode, the microprocessor is a black box - it's
* not possible to read or write any Falcon internal state or Falcon registers
* from outside the Falcon (for example, from the host system). The only way
* to enable this mode is by loading microcode that has been signed by NVIDIA.
* (The loading process involves tagging the IMEM block as secure, writing the
* signature into a Falcon register, and starting execution. The hardware will
* validate the signature, and if valid, grant HS privileges.)
*
* - Light Secure (LS). In this mode, the microprocessor has more privileges
* than NS but fewer than HS. Some of the microprocessor state is visible to
* host software to ease debugging. The only way to enable this mode is by HS
* microcode enabling LS mode. Some privileges available to HS mode are not
* available here. LS mode is introduced in GM20x.
*
* Secure boot consists in temporarily switching a HS-capable falcon (typically
* PMU) into HS mode in order to validate the LS firmwares of managed falcons,
* load them, and switch managed falcons into LS mode. Once secure boot
* completes, no falcon remains in HS mode.
*
* Secure boot requires a write-protected memory region (WPR) which can only be
* written by the secure falcon. On dGPU, the driver sets up the WPR region in
* video memory. On Tegra, it is set up by the bootloader and its location and
* size written into memory controller registers.
*
* The secure boot process takes place as follows:
*
* 1) A LS blob is constructed that contains all the LS firmwares we want to
* load, along with their signatures and bootloaders.
*
* 2) A HS blob (also called ACR) is created that contains the signed HS
* firmware in charge of loading the LS firmwares into their respective
* falcons.
*
* 3) The HS blob is loaded (via its own bootloader) and executed on the
* HS-capable falcon. It authenticates itself, switches the secure falcon to
* HS mode and setup the WPR region around the LS blob (dGPU) or copies the
* LS blob into the WPR region (Tegra).
*
* 4) The LS blob is now secure from all external tampering. The HS falcon
* checks the signatures of the LS firmwares and, if valid, switches the
* managed falcons to LS mode and makes them ready to run the LS firmware.
*
* 5) The managed falcons remain in LS mode and can be started.
*
*/
#include "priv.h"
#include <core/gpuobj.h>
#include <core/firmware.h>
#include <subdev/fb.h>
enum {
FALCON_DMAIDX_UCODE = 0,
FALCON_DMAIDX_VIRT = 1,
FALCON_DMAIDX_PHYS_VID = 2,
FALCON_DMAIDX_PHYS_SYS_COH = 3,
FALCON_DMAIDX_PHYS_SYS_NCOH = 4,
};
/**
* struct fw_bin_header - header of firmware files
* @bin_magic: always 0x3b1d14f0
* @bin_ver: version of the bin format
* @bin_size: entire image size including this header
* @header_offset: offset of the firmware/bootloader header in the file
* @data_offset: offset of the firmware/bootloader payload in the file
* @data_size: size of the payload
*
* This header is located at the beginning of the HS firmware and HS bootloader
* files, to describe where the headers and data can be found.
*/
struct fw_bin_header {
u32 bin_magic;
u32 bin_ver;
u32 bin_size;
u32 header_offset;
u32 data_offset;
u32 data_size;
};
/**
* struct fw_bl_desc - firmware bootloader descriptor
* @start_tag: starting tag of bootloader
* @desc_dmem_load_off: DMEM offset of flcn_bl_dmem_desc
* @code_off: offset of code section
* @code_size: size of code section
* @data_off: offset of data section
* @data_size: size of data section
*
* This structure is embedded in bootloader firmware files at to describe the
* IMEM and DMEM layout expected by the bootloader.
*/
struct fw_bl_desc {
u32 start_tag;
u32 dmem_load_off;
u32 code_off;
u32 code_size;
u32 data_off;
u32 data_size;
};
/*
*
* LS blob structures
*
*/
/**
* struct lsf_ucode_desc - LS falcon signatures
* @prd_keys: signature to use when the GPU is in production mode
* @dgb_keys: signature to use when the GPU is in debug mode
* @b_prd_present: whether the production key is present
* @b_dgb_present: whether the debug key is present
* @falcon_id: ID of the falcon the ucode applies to
*
* Directly loaded from a signature file.
*/
struct lsf_ucode_desc {
u8 prd_keys[2][16];
u8 dbg_keys[2][16];
u32 b_prd_present;
u32 b_dbg_present;
u32 falcon_id;
};
/**
* struct lsf_lsb_header - LS firmware header
* @signature: signature to verify the firmware against
* @ucode_off: offset of the ucode blob in the WPR region. The ucode
* blob contains the bootloader, code and data of the
* LS falcon
* @ucode_size: size of the ucode blob, including bootloader
* @data_size: size of the ucode blob data
* @bl_code_size: size of the bootloader code
* @bl_imem_off: offset in imem of the bootloader
* @bl_data_off: offset of the bootloader data in WPR region
* @bl_data_size: size of the bootloader data
* @app_code_off: offset of the app code relative to ucode_off
* @app_code_size: size of the app code
* @app_data_off: offset of the app data relative to ucode_off
* @app_data_size: size of the app data
* @flags: flags for the secure bootloader
*
* This structure is written into the WPR region for each managed falcon. Each
* instance is referenced by the lsb_offset member of the corresponding
* lsf_wpr_header.
*/
struct lsf_lsb_header {
struct lsf_ucode_desc signature;
u32 ucode_off;
u32 ucode_size;
u32 data_size;
u32 bl_code_size;
u32 bl_imem_off;
u32 bl_data_off;
u32 bl_data_size;
u32 app_code_off;
u32 app_code_size;
u32 app_data_off;
u32 app_data_size;
u32 flags;
#define LSF_FLAG_LOAD_CODE_AT_0 1
#define LSF_FLAG_DMACTL_REQ_CTX 4
#define LSF_FLAG_FORCE_PRIV_LOAD 8
};
/**
* struct lsf_wpr_header - LS blob WPR Header
* @falcon_id: LS falcon ID
* @lsb_offset: offset of the lsb_lsf_header in the WPR region
* @bootstrap_owner: secure falcon reponsible for bootstrapping the LS falcon
* @lazy_bootstrap: skip bootstrapping by ACR
* @status: bootstrapping status
*
* An array of these is written at the beginning of the WPR region, one for
* each managed falcon. The array is terminated by an instance which falcon_id
* is LSF_FALCON_ID_INVALID.
*/
struct lsf_wpr_header {
u32 falcon_id;
u32 lsb_offset;
u32 bootstrap_owner;
u32 lazy_bootstrap;
u32 status;
#define LSF_IMAGE_STATUS_NONE 0
#define LSF_IMAGE_STATUS_COPY 1
#define LSF_IMAGE_STATUS_VALIDATION_CODE_FAILED 2
#define LSF_IMAGE_STATUS_VALIDATION_DATA_FAILED 3
#define LSF_IMAGE_STATUS_VALIDATION_DONE 4
#define LSF_IMAGE_STATUS_VALIDATION_SKIPPED 5
#define LSF_IMAGE_STATUS_BOOTSTRAP_READY 6
};
/**
* struct ls_ucode_img_desc - descriptor of firmware image
* @descriptor_size: size of this descriptor
* @image_size: size of the whole image
* @bootloader_start_offset: start offset of the bootloader in ucode image
* @bootloader_size: size of the bootloader
* @bootloader_imem_offset: start off set of the bootloader in IMEM
* @bootloader_entry_point: entry point of the bootloader in IMEM
* @app_start_offset: start offset of the LS firmware
* @app_size: size of the LS firmware's code and data
* @app_imem_offset: offset of the app in IMEM
* @app_imem_entry: entry point of the app in IMEM
* @app_dmem_offset: offset of the data in DMEM
* @app_resident_code_offset: offset of app code from app_start_offset
* @app_resident_code_size: size of the code
* @app_resident_data_offset: offset of data from app_start_offset
* @app_resident_data_size: size of data
*
* A firmware image contains the code, data, and bootloader of a given LS
* falcon in a single blob. This structure describes where everything is.
*
* This can be generated from a (bootloader, code, data) set if they have
* been loaded separately, or come directly from a file.
*/
struct ls_ucode_img_desc {
u32 descriptor_size;
u32 image_size;
u32 tools_version;
u32 app_version;
char date[64];
u32 bootloader_start_offset;
u32 bootloader_size;
u32 bootloader_imem_offset;
u32 bootloader_entry_point;
u32 app_start_offset;
u32 app_size;
u32 app_imem_offset;
u32 app_imem_entry;
u32 app_dmem_offset;
u32 app_resident_code_offset;
u32 app_resident_code_size;
u32 app_resident_data_offset;
u32 app_resident_data_size;
u32 nb_overlays;
struct {u32 start; u32 size; } load_ovl[64];
u32 compressed;
};
/**
* struct ls_ucode_img - temporary storage for loaded LS firmwares
* @node: to link within lsf_ucode_mgr
* @falcon_id: ID of the falcon this LS firmware is for
* @ucode_desc: loaded or generated map of ucode_data
* @ucode_header: header of the firmware
* @ucode_data: firmware payload (code and data)
* @ucode_size: size in bytes of data in ucode_data
* @wpr_header: WPR header to be written to the LS blob
* @lsb_header: LSB header to be written to the LS blob
*
* Preparing the WPR LS blob requires information about all the LS firmwares
* (size, etc) to be known. This structure contains all the data of one LS
* firmware.
*/
struct ls_ucode_img {
struct list_head node;
enum nvkm_secboot_falcon falcon_id;
struct ls_ucode_img_desc ucode_desc;
u32 *ucode_header;
u8 *ucode_data;
u32 ucode_size;
struct lsf_wpr_header wpr_header;
struct lsf_lsb_header lsb_header;
};
/**
* struct ls_ucode_mgr - manager for all LS falcon firmwares
* @count: number of managed LS falcons
* @wpr_size: size of the required WPR region in bytes
* @img_list: linked list of lsf_ucode_img
*/
struct ls_ucode_mgr {
u16 count;
u32 wpr_size;
struct list_head img_list;
};
/*
*
* HS blob structures
*
*/
/**
* struct hsf_fw_header - HS firmware descriptor
* @sig_dbg_offset: offset of the debug signature
* @sig_dbg_size: size of the debug signature
* @sig_prod_offset: offset of the production signature
* @sig_prod_size: size of the production signature
* @patch_loc: offset of the offset (sic) of where the signature is
* @patch_sig: offset of the offset (sic) to add to sig_*_offset
* @hdr_offset: offset of the load header (see struct hs_load_header)
* @hdr_size: size of above header
*
* This structure is embedded in the HS firmware image at
* hs_bin_hdr.header_offset.
*/
struct hsf_fw_header {
u32 sig_dbg_offset;
u32 sig_dbg_size;
u32 sig_prod_offset;
u32 sig_prod_size;
u32 patch_loc;
u32 patch_sig;
u32 hdr_offset;
u32 hdr_size;
};
/**
* struct hsf_load_header - HS firmware load header
*/
struct hsf_load_header {
u32 non_sec_code_off;
u32 non_sec_code_size;
u32 data_dma_base;
u32 data_size;
u32 num_apps;
struct {
u32 sec_code_off;
u32 sec_code_size;
} app[0];
};
/**
* Convenience function to duplicate a firmware file in memory and check that
* it has the required minimum size.
*/
static void *
gm200_secboot_load_firmware(struct nvkm_subdev *subdev, const char *name,
size_t min_size)
{
const struct firmware *fw;
void *blob;
int ret;
ret = nvkm_firmware_get(subdev->device, name, &fw);
if (ret)
return ERR_PTR(ret);
if (fw->size < min_size) {
nvkm_error(subdev, "%s is smaller than expected size %zu\n",
name, min_size);
nvkm_firmware_put(fw);
return ERR_PTR(-EINVAL);
}
blob = kmemdup(fw->data, fw->size, GFP_KERNEL);
nvkm_firmware_put(fw);
if (!blob)
return ERR_PTR(-ENOMEM);
return blob;
}
/*
* Low-secure blob creation
*/
#define BL_DESC_BLK_SIZE 256
/**
* Build a ucode image and descriptor from provided bootloader, code and data.
*
* @bl: bootloader image, including 16-bytes descriptor
* @code: LS firmware code segment
* @data: LS firmware data segment
* @desc: ucode descriptor to be written
*
* Return: allocated ucode image with corresponding descriptor information. desc
* is also updated to contain the right offsets within returned image.
*/
static void *
ls_ucode_img_build(const struct firmware *bl, const struct firmware *code,
const struct firmware *data, struct ls_ucode_img_desc *desc)
{
struct fw_bin_header *bin_hdr = (void *)bl->data;
struct fw_bl_desc *bl_desc = (void *)bl->data + bin_hdr->header_offset;
void *bl_data = (void *)bl->data + bin_hdr->data_offset;
u32 pos = 0;
void *image;
desc->bootloader_start_offset = pos;
desc->bootloader_size = ALIGN(bl_desc->code_size, sizeof(u32));
desc->bootloader_imem_offset = bl_desc->start_tag * 256;
desc->bootloader_entry_point = bl_desc->start_tag * 256;
pos = ALIGN(pos + desc->bootloader_size, BL_DESC_BLK_SIZE);
desc->app_start_offset = pos;
desc->app_size = ALIGN(code->size, BL_DESC_BLK_SIZE) +
ALIGN(data->size, BL_DESC_BLK_SIZE);
desc->app_imem_offset = 0;
desc->app_imem_entry = 0;
desc->app_dmem_offset = 0;
desc->app_resident_code_offset = 0;
desc->app_resident_code_size = ALIGN(code->size, BL_DESC_BLK_SIZE);
pos = ALIGN(pos + desc->app_resident_code_size, BL_DESC_BLK_SIZE);
desc->app_resident_data_offset = pos - desc->app_start_offset;
desc->app_resident_data_size = ALIGN(data->size, BL_DESC_BLK_SIZE);
desc->image_size = ALIGN(bl_desc->code_size, BL_DESC_BLK_SIZE) +
desc->app_size;
image = kzalloc(desc->image_size, GFP_KERNEL);
if (!image)
return ERR_PTR(-ENOMEM);
memcpy(image + desc->bootloader_start_offset, bl_data,
bl_desc->code_size);
memcpy(image + desc->app_start_offset, code->data, code->size);
memcpy(image + desc->app_start_offset + desc->app_resident_data_offset,
data->data, data->size);
return image;
}
/**
* ls_ucode_img_load_generic() - load and prepare a LS ucode image
*
* Load the LS microcode, bootloader and signature and pack them into a single
* blob. Also generate the corresponding ucode descriptor.
*/
static int
ls_ucode_img_load_generic(struct nvkm_subdev *subdev,
struct ls_ucode_img *img, const char *falcon_name,
const u32 falcon_id)
{
const struct firmware *bl, *code, *data;
struct lsf_ucode_desc *lsf_desc;
char f[64];
int ret;
img->ucode_header = NULL;
snprintf(f, sizeof(f), "gr/%s_bl", falcon_name);
ret = nvkm_firmware_get(subdev->device, f, &bl);
if (ret)
goto error;
snprintf(f, sizeof(f), "gr/%s_inst", falcon_name);
ret = nvkm_firmware_get(subdev->device, f, &code);
if (ret)
goto free_bl;
snprintf(f, sizeof(f), "gr/%s_data", falcon_name);
ret = nvkm_firmware_get(subdev->device, f, &data);
if (ret)
goto free_inst;
img->ucode_data = ls_ucode_img_build(bl, code, data,
&img->ucode_desc);
if (IS_ERR(img->ucode_data)) {
ret = PTR_ERR(img->ucode_data);
goto free_data;
}
img->ucode_size = img->ucode_desc.image_size;
snprintf(f, sizeof(f), "gr/%s_sig", falcon_name);
lsf_desc = gm200_secboot_load_firmware(subdev, f, sizeof(*lsf_desc));
if (IS_ERR(lsf_desc)) {
ret = PTR_ERR(lsf_desc);
goto free_image;
}
/* not needed? the signature should already have the right value */
lsf_desc->falcon_id = falcon_id;
memcpy(&img->lsb_header.signature, lsf_desc, sizeof(*lsf_desc));
img->falcon_id = lsf_desc->falcon_id;
kfree(lsf_desc);
/* success path - only free requested firmware files */
goto free_data;
free_image:
kfree(img->ucode_data);
free_data:
nvkm_firmware_put(data);
free_inst:
nvkm_firmware_put(code);
free_bl:
nvkm_firmware_put(bl);
error:
return ret;
}
typedef int (*lsf_load_func)(struct nvkm_subdev *, struct ls_ucode_img *);
static int
ls_ucode_img_load_fecs(struct nvkm_subdev *subdev, struct ls_ucode_img *img)
{
return ls_ucode_img_load_generic(subdev, img, "fecs",
NVKM_SECBOOT_FALCON_FECS);
}
static int
ls_ucode_img_load_gpccs(struct nvkm_subdev *subdev, struct ls_ucode_img *img)
{
return ls_ucode_img_load_generic(subdev, img, "gpccs",
NVKM_SECBOOT_FALCON_GPCCS);
}
/**
* ls_ucode_img_load() - create a lsf_ucode_img and load it
*/
static struct ls_ucode_img *
ls_ucode_img_load(struct nvkm_subdev *subdev, lsf_load_func load_func)
{
struct ls_ucode_img *img;
int ret;
img = kzalloc(sizeof(*img), GFP_KERNEL);
if (!img)
return ERR_PTR(-ENOMEM);
ret = load_func(subdev, img);
if (ret) {
kfree(img);
return ERR_PTR(ret);
}
return img;
}
static const lsf_load_func lsf_load_funcs[] = {
[NVKM_SECBOOT_FALCON_END] = NULL, /* reserve enough space */
[NVKM_SECBOOT_FALCON_FECS] = ls_ucode_img_load_fecs,
[NVKM_SECBOOT_FALCON_GPCCS] = ls_ucode_img_load_gpccs,
};
/**
* ls_ucode_img_populate_bl_desc() - populate a DMEM BL descriptor for LS image
* @img: ucode image to generate against
* @desc: descriptor to populate
* @sb: secure boot state to use for base addresses
*
* Populate the DMEM BL descriptor with the information contained in a
* ls_ucode_desc.
*
*/
static void
ls_ucode_img_populate_bl_desc(struct ls_ucode_img *img, u64 wpr_addr,
struct gm200_flcn_bl_desc *desc)
{
struct ls_ucode_img_desc *pdesc = &img->ucode_desc;
u64 addr_base;
addr_base = wpr_addr + img->lsb_header.ucode_off +
pdesc->app_start_offset;
memset(desc, 0, sizeof(*desc));
desc->ctx_dma = FALCON_DMAIDX_UCODE;
desc->code_dma_base.lo = lower_32_bits(
(addr_base + pdesc->app_resident_code_offset));
desc->code_dma_base.hi = upper_32_bits(
(addr_base + pdesc->app_resident_code_offset));
desc->non_sec_code_size = pdesc->app_resident_code_size;
desc->data_dma_base.lo = lower_32_bits(
(addr_base + pdesc->app_resident_data_offset));
desc->data_dma_base.hi = upper_32_bits(
(addr_base + pdesc->app_resident_data_offset));
desc->data_size = pdesc->app_resident_data_size;
desc->code_entry_point = pdesc->app_imem_entry;
}
#define LSF_LSB_HEADER_ALIGN 256
#define LSF_BL_DATA_ALIGN 256
#define LSF_BL_DATA_SIZE_ALIGN 256
#define LSF_BL_CODE_SIZE_ALIGN 256
#define LSF_UCODE_DATA_ALIGN 4096
/**
* ls_ucode_img_fill_headers - fill the WPR and LSB headers of an image
* @gsb: secure boot device used
* @img: image to generate for
* @offset: offset in the WPR region where this image starts
*
* Allocate space in the WPR area from offset and write the WPR and LSB headers
* accordingly.
*
* Return: offset at the end of this image.
*/
static u32
ls_ucode_img_fill_headers(struct gm200_secboot *gsb, struct ls_ucode_img *img,
u32 offset)
{
struct lsf_wpr_header *whdr = &img->wpr_header;
struct lsf_lsb_header *lhdr = &img->lsb_header;
struct ls_ucode_img_desc *desc = &img->ucode_desc;
if (img->ucode_header) {
nvkm_fatal(&gsb->base.subdev,
"images withough loader are not supported yet!\n");
return offset;
}
/* Fill WPR header */
whdr->falcon_id = img->falcon_id;
whdr->bootstrap_owner = gsb->base.func->boot_falcon;
whdr->status = LSF_IMAGE_STATUS_COPY;
/* Align, save off, and include an LSB header size */
offset = ALIGN(offset, LSF_LSB_HEADER_ALIGN);
whdr->lsb_offset = offset;
offset += sizeof(struct lsf_lsb_header);
/*
* Align, save off, and include the original (static) ucode
* image size
*/
offset = ALIGN(offset, LSF_UCODE_DATA_ALIGN);
lhdr->ucode_off = offset;
offset += img->ucode_size;
/*
* For falcons that use a boot loader (BL), we append a loader
* desc structure on the end of the ucode image and consider
* this the boot loader data. The host will then copy the loader
* desc args to this space within the WPR region (before locking
* down) and the HS bin will then copy them to DMEM 0 for the
* loader.
*/
lhdr->bl_code_size = ALIGN(desc->bootloader_size,
LSF_BL_CODE_SIZE_ALIGN);
lhdr->ucode_size = ALIGN(desc->app_resident_data_offset,
LSF_BL_CODE_SIZE_ALIGN) + lhdr->bl_code_size;
lhdr->data_size = ALIGN(desc->app_size, LSF_BL_CODE_SIZE_ALIGN) +
lhdr->bl_code_size - lhdr->ucode_size;
/*
* Though the BL is located at 0th offset of the image, the VA
* is different to make sure that it doesn't collide the actual
* OS VA range
*/
lhdr->bl_imem_off = desc->bootloader_imem_offset;
lhdr->app_code_off = desc->app_start_offset +
desc->app_resident_code_offset;
lhdr->app_code_size = desc->app_resident_code_size;
lhdr->app_data_off = desc->app_start_offset +
desc->app_resident_data_offset;
lhdr->app_data_size = desc->app_resident_data_size;
lhdr->flags = 0;
if (img->falcon_id == gsb->base.func->boot_falcon)
lhdr->flags = LSF_FLAG_DMACTL_REQ_CTX;
/* GPCCS will be loaded using PRI */
if (img->falcon_id == NVKM_SECBOOT_FALCON_GPCCS)
lhdr->flags |= LSF_FLAG_FORCE_PRIV_LOAD;
/* Align (size bloat) and save off BL descriptor size */
lhdr->bl_data_size = ALIGN(sizeof(struct gm200_flcn_bl_desc),
LSF_BL_DATA_SIZE_ALIGN);
/*
* Align, save off, and include the additional BL data
*/
offset = ALIGN(offset, LSF_BL_DATA_ALIGN);
lhdr->bl_data_off = offset;
offset += lhdr->bl_data_size;
return offset;
}
static void
ls_ucode_mgr_init(struct ls_ucode_mgr *mgr)
{
memset(mgr, 0, sizeof(*mgr));
INIT_LIST_HEAD(&mgr->img_list);
}
static void
ls_ucode_mgr_cleanup(struct ls_ucode_mgr *mgr)
{
struct ls_ucode_img *img, *t;
list_for_each_entry_safe(img, t, &mgr->img_list, node) {
kfree(img->ucode_data);
kfree(img->ucode_header);
kfree(img);
}
}
static void
ls_ucode_mgr_add_img(struct ls_ucode_mgr *mgr, struct ls_ucode_img *img)
{
mgr->count++;
list_add_tail(&img->node, &mgr->img_list);
}
/**
* ls_ucode_mgr_fill_headers - fill WPR and LSB headers of all managed images
*/
static void
ls_ucode_mgr_fill_headers(struct gm200_secboot *gsb, struct ls_ucode_mgr *mgr)
{
struct ls_ucode_img *img;
u32 offset;
/*
* Start with an array of WPR headers at the base of the WPR.
* The expectation here is that the secure falcon will do a single DMA
* read of this array and cache it internally so it's ok to pack these.
* Also, we add 1 to the falcon count to indicate the end of the array.
*/
offset = sizeof(struct lsf_wpr_header) * (mgr->count + 1);
/*
* Walk the managed falcons, accounting for the LSB structs
* as well as the ucode images.
*/
list_for_each_entry(img, &mgr->img_list, node) {
offset = ls_ucode_img_fill_headers(gsb, img, offset);
}
mgr->wpr_size = offset;
}
/**
* ls_ucode_mgr_write_wpr - write the WPR blob contents
*/
static int
ls_ucode_mgr_write_wpr(struct gm200_secboot *gsb, struct ls_ucode_mgr *mgr,
struct nvkm_gpuobj *wpr_blob)
{
struct ls_ucode_img *img;
u32 pos = 0;
nvkm_kmap(wpr_blob);
list_for_each_entry(img, &mgr->img_list, node) {
nvkm_gpuobj_memcpy_to(wpr_blob, pos, &img->wpr_header,
sizeof(img->wpr_header));
nvkm_gpuobj_memcpy_to(wpr_blob, img->wpr_header.lsb_offset,
&img->lsb_header, sizeof(img->lsb_header));
/* Generate and write BL descriptor */
if (!img->ucode_header) {
u8 desc[gsb->func->bl_desc_size];
struct gm200_flcn_bl_desc gdesc;
ls_ucode_img_populate_bl_desc(img, gsb->wpr_addr,
&gdesc);
gsb->func->fixup_bl_desc(&gdesc, &desc);
nvkm_gpuobj_memcpy_to(wpr_blob,
img->lsb_header.bl_data_off,
&desc, gsb->func->bl_desc_size);
}
/* Copy ucode */
nvkm_gpuobj_memcpy_to(wpr_blob, img->lsb_header.ucode_off,
img->ucode_data, img->ucode_size);
pos += sizeof(img->wpr_header);
}
nvkm_wo32(wpr_blob, pos, NVKM_SECBOOT_FALCON_INVALID);
nvkm_done(wpr_blob);
return 0;
}
/* Both size and address of WPR need to be 128K-aligned */
#define WPR_ALIGNMENT 0x20000
/**
* gm200_secboot_prepare_ls_blob() - prepare the LS blob
*
* For each securely managed falcon, load the FW, signatures and bootloaders and
* prepare a ucode blob. Then, compute the offsets in the WPR region for each
* blob, and finally write the headers and ucode blobs into a GPU object that
* will be copied into the WPR region by the HS firmware.
*/
static int
gm200_secboot_prepare_ls_blob(struct gm200_secboot *gsb)
{
struct nvkm_secboot *sb = &gsb->base;
struct nvkm_device *device = sb->subdev.device;
struct ls_ucode_mgr mgr;
int falcon_id;
int ret;
ls_ucode_mgr_init(&mgr);
/* Load all LS blobs */
for_each_set_bit(falcon_id, &gsb->base.func->managed_falcons,
NVKM_SECBOOT_FALCON_END) {
struct ls_ucode_img *img;
img = ls_ucode_img_load(&sb->subdev, lsf_load_funcs[falcon_id]);
if (IS_ERR(img)) {
ret = PTR_ERR(img);
goto cleanup;
}
ls_ucode_mgr_add_img(&mgr, img);
}
/*
* Fill the WPR and LSF headers with the right offsets and compute
* required WPR size
*/
ls_ucode_mgr_fill_headers(gsb, &mgr);
mgr.wpr_size = ALIGN(mgr.wpr_size, WPR_ALIGNMENT);
/* Allocate GPU object that will contain the WPR region */
ret = nvkm_gpuobj_new(device, mgr.wpr_size, WPR_ALIGNMENT, false, NULL,
&gsb->ls_blob);
if (ret)
goto cleanup;
nvkm_debug(&sb->subdev, "%d managed LS falcons, WPR size is %d bytes\n",
mgr.count, mgr.wpr_size);
/* If WPR address and size are not fixed, set them to fit the LS blob */
if (!gsb->wpr_size) {
gsb->wpr_addr = gsb->ls_blob->addr;
gsb->wpr_size = gsb->ls_blob->size;
}
/* Write LS blob */
ret = ls_ucode_mgr_write_wpr(gsb, &mgr, gsb->ls_blob);
if (ret)
nvkm_gpuobj_del(&gsb->ls_blob);
cleanup:
ls_ucode_mgr_cleanup(&mgr);
return ret;
}
/*
* High-secure blob creation
*/
/**
* gm200_secboot_hsf_patch_signature() - patch HS blob with correct signature
*/
static void
gm200_secboot_hsf_patch_signature(struct gm200_secboot *gsb, void *acr_image)
{
struct nvkm_secboot *sb = &gsb->base;
struct fw_bin_header *hsbin_hdr = acr_image;
struct hsf_fw_header *fw_hdr = acr_image + hsbin_hdr->header_offset;
void *hs_data = acr_image + hsbin_hdr->data_offset;
void *sig;
u32 sig_size;
/* Falcon in debug or production mode? */
if ((nvkm_rd32(sb->subdev.device, sb->base + 0xc08) >> 20) & 0x1) {
sig = acr_image + fw_hdr->sig_dbg_offset;
sig_size = fw_hdr->sig_dbg_size;
} else {
sig = acr_image + fw_hdr->sig_prod_offset;
sig_size = fw_hdr->sig_prod_size;
}
/* Patch signature */
memcpy(hs_data + fw_hdr->patch_loc, sig + fw_hdr->patch_sig, sig_size);
}
/**
* gm200_secboot_populate_hsf_bl_desc() - populate BL descriptor for HS image
*/
static void
gm200_secboot_populate_hsf_bl_desc(void *acr_image,
struct gm200_flcn_bl_desc *bl_desc)
{
struct fw_bin_header *hsbin_hdr = acr_image;
struct hsf_fw_header *fw_hdr = acr_image + hsbin_hdr->header_offset;
struct hsf_load_header *load_hdr = acr_image + fw_hdr->hdr_offset;
/*
* Descriptor for the bootloader that will load the ACR image into
* IMEM/DMEM memory.
*/
fw_hdr = acr_image + hsbin_hdr->header_offset;
load_hdr = acr_image + fw_hdr->hdr_offset;
memset(bl_desc, 0, sizeof(*bl_desc));
bl_desc->ctx_dma = FALCON_DMAIDX_VIRT;
bl_desc->non_sec_code_off = load_hdr->non_sec_code_off;
bl_desc->non_sec_code_size = load_hdr->non_sec_code_size;
bl_desc->sec_code_off = load_hdr->app[0].sec_code_off;
bl_desc->sec_code_size = load_hdr->app[0].sec_code_size;
bl_desc->code_entry_point = 0;
/*
* We need to set code_dma_base to the virtual address of the acr_blob,
* and add this address to data_dma_base before writing it into DMEM
*/
bl_desc->code_dma_base.lo = 0;
bl_desc->data_dma_base.lo = load_hdr->data_dma_base;
bl_desc->data_size = load_hdr->data_size;
}
/**
* gm200_secboot_prepare_hs_blob - load and prepare a HS blob and BL descriptor
*
* @gsb secure boot instance to prepare for
* @fw name of the HS firmware to load
* @blob pointer to gpuobj that will be allocated to receive the HS FW payload
* @bl_desc pointer to the BL descriptor to write for this firmware
* @patch whether we should patch the HS descriptor (only for HS loaders)
*/
static int
gm200_secboot_prepare_hs_blob(struct gm200_secboot *gsb, const char *fw,
struct nvkm_gpuobj **blob,
struct gm200_flcn_bl_desc *bl_desc, bool patch)
{
struct nvkm_subdev *subdev = &gsb->base.subdev;
void *acr_image;
struct fw_bin_header *hsbin_hdr;
struct hsf_fw_header *fw_hdr;
void *acr_data;
struct hsf_load_header *load_hdr;
struct hsflcn_acr_desc *desc;
int ret;
acr_image = gm200_secboot_load_firmware(subdev, fw, 0);
if (IS_ERR(acr_image))
return PTR_ERR(acr_image);
hsbin_hdr = acr_image;
/* Patch signature */
gm200_secboot_hsf_patch_signature(gsb, acr_image);
acr_data = acr_image + hsbin_hdr->data_offset;
/* Patch descriptor? */
if (patch) {
fw_hdr = acr_image + hsbin_hdr->header_offset;
load_hdr = acr_image + fw_hdr->hdr_offset;
desc = acr_data + load_hdr->data_dma_base;
gsb->func->fixup_hs_desc(gsb, desc);
}
/* Generate HS BL descriptor */
gm200_secboot_populate_hsf_bl_desc(acr_image, bl_desc);
/* Create ACR blob and copy HS data to it */
ret = nvkm_gpuobj_new(subdev->device, ALIGN(hsbin_hdr->data_size, 256),
0x1000, false, NULL, blob);
if (ret)
goto cleanup;
nvkm_kmap(*blob);
nvkm_gpuobj_memcpy_to(*blob, 0, acr_data, hsbin_hdr->data_size);
nvkm_done(*blob);
cleanup:
kfree(acr_image);
return ret;
}
/*
* High-secure bootloader blob creation
*/
static int
gm200_secboot_prepare_hsbl_blob(struct gm200_secboot *gsb)
{
struct nvkm_subdev *subdev = &gsb->base.subdev;
gsb->hsbl_blob = gm200_secboot_load_firmware(subdev, "acr/bl", 0);
if (IS_ERR(gsb->hsbl_blob)) {
int ret = PTR_ERR(gsb->hsbl_blob);
gsb->hsbl_blob = NULL;
return ret;
}
return 0;
}
/**
* gm20x_secboot_prepare_blobs - load blobs common to all GM20X GPUs.
*
* This includes the LS blob, HS ucode loading blob, and HS bootloader.
*
* The HS ucode unload blob is only used on dGPU.
*/
int
gm20x_secboot_prepare_blobs(struct gm200_secboot *gsb)
{
int ret;
/* Load and prepare the managed falcon's firmwares */
if (!gsb->ls_blob) {
ret = gm200_secboot_prepare_ls_blob(gsb);
if (ret)
return ret;
}
/* Load the HS firmware that will load the LS firmwares */
if (!gsb->acr_load_blob) {
ret = gm200_secboot_prepare_hs_blob(gsb, "acr/ucode_load",
&gsb->acr_load_blob,
&gsb->acr_load_bl_desc, true);
if (ret)
return ret;
}
/* Load the HS firmware bootloader */
if (!gsb->hsbl_blob) {
ret = gm200_secboot_prepare_hsbl_blob(gsb);
if (ret)
return ret;
}
return 0;
}
static int
gm200_secboot_prepare_blobs(struct gm200_secboot *gsb)
{
int ret;
ret = gm20x_secboot_prepare_blobs(gsb);
if (ret)
return ret;
/* dGPU only: load the HS firmware that unprotects the WPR region */
if (!gsb->acr_unload_blob) {
ret = gm200_secboot_prepare_hs_blob(gsb, "acr/ucode_unload",
&gsb->acr_unload_blob,
&gsb->acr_unload_bl_desc, false);
if (ret)
return ret;
}
return 0;
}
static int
gm200_secboot_blobs_ready(struct gm200_secboot *gsb)
{
struct nvkm_subdev *subdev = &gsb->base.subdev;
int ret;
/* firmware already loaded, nothing to do... */
if (gsb->firmware_ok)
return 0;
ret = gsb->func->prepare_blobs(gsb);
if (ret) {
nvkm_error(subdev, "failed to load secure firmware\n");
return ret;
}
gsb->firmware_ok = true;
return 0;
}
/*
* Secure Boot Execution
*/
/**
* gm200_secboot_load_hs_bl() - load HS bootloader into DMEM and IMEM
*/
static void
gm200_secboot_load_hs_bl(struct gm200_secboot *gsb, void *data, u32 data_size)
{
struct nvkm_device *device = gsb->base.subdev.device;
struct fw_bin_header *hdr = gsb->hsbl_blob;
struct fw_bl_desc *hsbl_desc = gsb->hsbl_blob + hdr->header_offset;
void *blob_data = gsb->hsbl_blob + hdr->data_offset;
void *hsbl_code = blob_data + hsbl_desc->code_off;
void *hsbl_data = blob_data + hsbl_desc->data_off;
u32 code_size = ALIGN(hsbl_desc->code_size, 256);
const u32 base = gsb->base.base;
u32 blk;
u32 tag;
int i;
/*
* Copy HS bootloader data
*/
nvkm_wr32(device, base + 0x1c0, (0x00000000 | (0x1 << 24)));
for (i = 0; i < hsbl_desc->data_size / 4; i++)
nvkm_wr32(device, base + 0x1c4, ((u32 *)hsbl_data)[i]);
/*
* Copy HS bootloader interface structure where the HS descriptor
* expects it to be
*/
nvkm_wr32(device, base + 0x1c0,
(hsbl_desc->dmem_load_off | (0x1 << 24)));
for (i = 0; i < data_size / 4; i++)
nvkm_wr32(device, base + 0x1c4, ((u32 *)data)[i]);
/* Copy HS bootloader code to end of IMEM */
blk = (nvkm_rd32(device, base + 0x108) & 0x1ff) - (code_size >> 8);
tag = hsbl_desc->start_tag;
nvkm_wr32(device, base + 0x180, ((blk & 0xff) << 8) | (0x1 << 24));
for (i = 0; i < code_size / 4; i++) {
/* write new tag every 256B */
if ((i & 0x3f) == 0) {
nvkm_wr32(device, base + 0x188, tag & 0xffff);
tag++;
}
nvkm_wr32(device, base + 0x184, ((u32 *)hsbl_code)[i]);
}
nvkm_wr32(device, base + 0x188, 0);
}
/**
* gm200_secboot_setup_falcon() - set up the secure falcon for secure boot
*/
static int
gm200_secboot_setup_falcon(struct gm200_secboot *gsb)
{
struct nvkm_device *device = gsb->base.subdev.device;
struct fw_bin_header *hdr = gsb->hsbl_blob;
struct fw_bl_desc *hsbl_desc = gsb->hsbl_blob + hdr->header_offset;
/* virtual start address for boot vector */
u32 virt_addr = hsbl_desc->start_tag << 8;
const u32 base = gsb->base.base;
const u32 reg_base = base + 0xe00;
u32 inst_loc;
int ret;
ret = nvkm_secboot_falcon_reset(&gsb->base);
if (ret)
return ret;
/* setup apertures - virtual */
nvkm_wr32(device, reg_base + 4 * (FALCON_DMAIDX_UCODE), 0x4);
nvkm_wr32(device, reg_base + 4 * (FALCON_DMAIDX_VIRT), 0x0);
/* setup apertures - physical */
nvkm_wr32(device, reg_base + 4 * (FALCON_DMAIDX_PHYS_VID), 0x4);
nvkm_wr32(device, reg_base + 4 * (FALCON_DMAIDX_PHYS_SYS_COH),
0x4 | 0x1);
nvkm_wr32(device, reg_base + 4 * (FALCON_DMAIDX_PHYS_SYS_NCOH),
0x4 | 0x2);
/* Set context */
if (nvkm_memory_target(gsb->inst->memory) == NVKM_MEM_TARGET_VRAM)
inst_loc = 0x0; /* FB */
else
inst_loc = 0x3; /* Non-coherent sysmem */
nvkm_mask(device, base + 0x048, 0x1, 0x1);
nvkm_wr32(device, base + 0x480,
((gsb->inst->addr >> 12) & 0xfffffff) |
(inst_loc << 28) | (1 << 30));
/* Set boot vector to code's starting virtual address */
nvkm_wr32(device, base + 0x104, virt_addr);
return 0;
}
/**
* gm200_secboot_run_hs_blob() - run the given high-secure blob
*/
static int
gm200_secboot_run_hs_blob(struct gm200_secboot *gsb, struct nvkm_gpuobj *blob,
struct gm200_flcn_bl_desc *desc)
{
struct nvkm_vma vma;
u64 vma_addr;
const u32 bl_desc_size = gsb->func->bl_desc_size;
u8 bl_desc[bl_desc_size];
int ret;
/* Map the HS firmware so the HS bootloader can see it */
ret = nvkm_gpuobj_map(blob, gsb->vm, NV_MEM_ACCESS_RW, &vma);
if (ret)
return ret;
/* Add the mapping address to the DMA bases */
vma_addr = flcn64_to_u64(desc->code_dma_base) + vma.offset;
desc->code_dma_base.lo = lower_32_bits(vma_addr);
desc->code_dma_base.hi = upper_32_bits(vma_addr);
vma_addr = flcn64_to_u64(desc->data_dma_base) + vma.offset;
desc->data_dma_base.lo = lower_32_bits(vma_addr);
desc->data_dma_base.hi = upper_32_bits(vma_addr);
/* Fixup the BL header */
gsb->func->fixup_bl_desc(desc, &bl_desc);
/* Reset the falcon and make it ready to run the HS bootloader */
ret = gm200_secboot_setup_falcon(gsb);
if (ret)
goto done;
/* Load the HS bootloader into the falcon's IMEM/DMEM */
gm200_secboot_load_hs_bl(gsb, &bl_desc, bl_desc_size);
/* Start the HS bootloader */
ret = nvkm_secboot_falcon_run(&gsb->base);
if (ret)
goto done;
done:
/* Restore the original DMA addresses */
vma_addr = flcn64_to_u64(desc->code_dma_base) - vma.offset;
desc->code_dma_base.lo = lower_32_bits(vma_addr);
desc->code_dma_base.hi = upper_32_bits(vma_addr);
vma_addr = flcn64_to_u64(desc->data_dma_base) - vma.offset;
desc->data_dma_base.lo = lower_32_bits(vma_addr);
desc->data_dma_base.hi = upper_32_bits(vma_addr);
/* We don't need the ACR firmware anymore */
nvkm_gpuobj_unmap(&vma);
return ret;
}
/*
* gm200_secboot_reset() - execute secure boot from the prepared state
*
* Load the HS bootloader and ask the falcon to run it. This will in turn
* load the HS firmware and run it, so once the falcon stops all the managed
* falcons should have their LS firmware loaded and be ready to run.
*/
int
gm200_secboot_reset(struct nvkm_secboot *sb, enum nvkm_secboot_falcon falcon)
{
struct gm200_secboot *gsb = gm200_secboot(sb);
int ret;
/* Make sure all blobs are ready */
ret = gm200_secboot_blobs_ready(gsb);
if (ret)
return ret;
/*
* Dummy GM200 implementation: perform secure boot each time we are
* called on FECS. Since only FECS and GPCCS are managed and started
* together, this ought to be safe.
*
* Once we have proper PMU firmware and support, this will be changed
* to a proper call to the PMU method.
*/
if (falcon != NVKM_SECBOOT_FALCON_FECS)
goto end;
/* If WPR is set and we have an unload blob, run it to unlock WPR */
if (gsb->acr_unload_blob &&
gsb->falcon_state[NVKM_SECBOOT_FALCON_FECS] != NON_SECURE) {
ret = gm200_secboot_run_hs_blob(gsb, gsb->acr_unload_blob,
&gsb->acr_unload_bl_desc);
if (ret)
return ret;
}
/* Reload all managed falcons */
ret = gm200_secboot_run_hs_blob(gsb, gsb->acr_load_blob,
&gsb->acr_load_bl_desc);
if (ret)
return ret;
end:
gsb->falcon_state[falcon] = RESET;
return 0;
}
int
gm200_secboot_start(struct nvkm_secboot *sb, enum nvkm_secboot_falcon falcon)
{
struct gm200_secboot *gsb = gm200_secboot(sb);
int base;
switch (falcon) {
case NVKM_SECBOOT_FALCON_FECS:
base = 0x409000;
break;
case NVKM_SECBOOT_FALCON_GPCCS:
base = 0x41a000;
break;
default:
nvkm_error(&sb->subdev, "cannot start unhandled falcon!\n");
return -EINVAL;
}
nvkm_wr32(sb->subdev.device, base + 0x130, 0x00000002);
gsb->falcon_state[falcon] = RUNNING;
return 0;
}
int
gm200_secboot_init(struct nvkm_secboot *sb)
{
struct gm200_secboot *gsb = gm200_secboot(sb);
struct nvkm_device *device = sb->subdev.device;
struct nvkm_vm *vm;
const u64 vm_area_len = 600 * 1024;
int ret;
/* Allocate instance block and VM */
ret = nvkm_gpuobj_new(device, 0x1000, 0, true, NULL, &gsb->inst);
if (ret)
return ret;
ret = nvkm_gpuobj_new(device, 0x8000, 0, true, NULL, &gsb->pgd);
if (ret)
return ret;
ret = nvkm_vm_new(device, 0, vm_area_len, 0, NULL, &vm);
if (ret)
return ret;
atomic_inc(&vm->engref[NVKM_SUBDEV_PMU]);
ret = nvkm_vm_ref(vm, &gsb->vm, gsb->pgd);
nvkm_vm_ref(NULL, &vm, NULL);
if (ret)
return ret;
nvkm_kmap(gsb->inst);
nvkm_wo32(gsb->inst, 0x200, lower_32_bits(gsb->pgd->addr));
nvkm_wo32(gsb->inst, 0x204, upper_32_bits(gsb->pgd->addr));
nvkm_wo32(gsb->inst, 0x208, lower_32_bits(vm_area_len - 1));
nvkm_wo32(gsb->inst, 0x20c, upper_32_bits(vm_area_len - 1));
nvkm_done(gsb->inst);
return 0;
}
int
gm200_secboot_fini(struct nvkm_secboot *sb, bool suspend)
{
struct gm200_secboot *gsb = gm200_secboot(sb);
int ret = 0;
int i;
/* Run the unload blob to unprotect the WPR region */
if (gsb->acr_unload_blob &&
gsb->falcon_state[NVKM_SECBOOT_FALCON_FECS] != NON_SECURE)
ret = gm200_secboot_run_hs_blob(gsb, gsb->acr_unload_blob,
&gsb->acr_unload_bl_desc);
for (i = 0; i < NVKM_SECBOOT_FALCON_END; i++)
gsb->falcon_state[i] = NON_SECURE;
return ret;
}
void *
gm200_secboot_dtor(struct nvkm_secboot *sb)
{
struct gm200_secboot *gsb = gm200_secboot(sb);
nvkm_gpuobj_del(&gsb->acr_unload_blob);
kfree(gsb->hsbl_blob);
nvkm_gpuobj_del(&gsb->acr_load_blob);
nvkm_gpuobj_del(&gsb->ls_blob);
nvkm_vm_ref(NULL, &gsb->vm, gsb->pgd);
nvkm_gpuobj_del(&gsb->pgd);
nvkm_gpuobj_del(&gsb->inst);
return gsb;
}
static const struct nvkm_secboot_func
gm200_secboot = {
.dtor = gm200_secboot_dtor,
.init = gm200_secboot_init,
.fini = gm200_secboot_fini,
.reset = gm200_secboot_reset,
.start = gm200_secboot_start,
.managed_falcons = BIT(NVKM_SECBOOT_FALCON_FECS) |
BIT(NVKM_SECBOOT_FALCON_GPCCS),
.boot_falcon = NVKM_SECBOOT_FALCON_PMU,
};
/**
* gm200_fixup_bl_desc - just copy the BL descriptor
*
* Use the GM200 descriptor format by default.
*/
static void
gm200_secboot_fixup_bl_desc(const struct gm200_flcn_bl_desc *desc, void *ret)
{
memcpy(ret, desc, sizeof(*desc));
}
static void
gm200_secboot_fixup_hs_desc(struct gm200_secboot *gsb,
struct hsflcn_acr_desc *desc)
{
desc->ucode_blob_base = gsb->ls_blob->addr;
desc->ucode_blob_size = gsb->ls_blob->size;
desc->wpr_offset = 0;
/* WPR region information for the HS binary to set up */
desc->wpr_region_id = 1;
desc->regions.no_regions = 1;
desc->regions.region_props[0].region_id = 1;
desc->regions.region_props[0].start_addr = gsb->wpr_addr >> 8;
desc->regions.region_props[0].end_addr =
(gsb->wpr_addr + gsb->wpr_size) >> 8;
}
static const struct gm200_secboot_func
gm200_secboot_func = {
.bl_desc_size = sizeof(struct gm200_flcn_bl_desc),
.fixup_bl_desc = gm200_secboot_fixup_bl_desc,
.fixup_hs_desc = gm200_secboot_fixup_hs_desc,
.prepare_blobs = gm200_secboot_prepare_blobs,
};
int
gm200_secboot_new(struct nvkm_device *device, int index,
struct nvkm_secboot **psb)
{
int ret;
struct gm200_secboot *gsb;
gsb = kzalloc(sizeof(*gsb), GFP_KERNEL);
if (!gsb) {
psb = NULL;
return -ENOMEM;
}
*psb = &gsb->base;
ret = nvkm_secboot_ctor(&gm200_secboot, device, index, &gsb->base);
if (ret)
return ret;
gsb->func = &gm200_secboot_func;
return 0;
}
MODULE_FIRMWARE("nvidia/gm200/acr/bl.bin");
MODULE_FIRMWARE("nvidia/gm200/acr/ucode_load.bin");
MODULE_FIRMWARE("nvidia/gm200/acr/ucode_unload.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/fecs_bl.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/fecs_inst.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/fecs_data.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/fecs_sig.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/gpccs_bl.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/gpccs_inst.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/gpccs_data.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/gpccs_sig.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/sw_ctx.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/sw_nonctx.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/sw_bundle_init.bin");
MODULE_FIRMWARE("nvidia/gm200/gr/sw_method_init.bin");
MODULE_FIRMWARE("nvidia/gm204/acr/bl.bin");
MODULE_FIRMWARE("nvidia/gm204/acr/ucode_load.bin");
MODULE_FIRMWARE("nvidia/gm204/acr/ucode_unload.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/fecs_bl.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/fecs_inst.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/fecs_data.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/fecs_sig.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/gpccs_bl.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/gpccs_inst.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/gpccs_data.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/gpccs_sig.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/sw_ctx.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/sw_nonctx.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/sw_bundle_init.bin");
MODULE_FIRMWARE("nvidia/gm204/gr/sw_method_init.bin");
MODULE_FIRMWARE("nvidia/gm206/acr/bl.bin");
MODULE_FIRMWARE("nvidia/gm206/acr/ucode_load.bin");
MODULE_FIRMWARE("nvidia/gm206/acr/ucode_unload.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/fecs_bl.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/fecs_inst.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/fecs_data.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/fecs_sig.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/gpccs_bl.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/gpccs_inst.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/gpccs_data.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/gpccs_sig.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/sw_ctx.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/sw_nonctx.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/sw_bundle_init.bin");
MODULE_FIRMWARE("nvidia/gm206/gr/sw_method_init.bin");
MODULE_FIRMWARE("nvidia/gp100/acr/bl.bin");
MODULE_FIRMWARE("nvidia/gp100/acr/ucode_load.bin");
MODULE_FIRMWARE("nvidia/gp100/acr/ucode_unload.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/fecs_bl.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/fecs_inst.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/fecs_data.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/fecs_sig.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/gpccs_bl.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/gpccs_inst.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/gpccs_data.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/gpccs_sig.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/sw_ctx.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/sw_nonctx.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/sw_bundle_init.bin");
MODULE_FIRMWARE("nvidia/gp100/gr/sw_method_init.bin");
|