};
-/*
- *
- * 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
* it has the required minimum size.
*/
static void *
-gm200_secboot_load_firmware(struct nvkm_subdev *subdev, const char *name,
+gm200_secboot_load_firmware(const struct nvkm_subdev *subdev, const char *name,
size_t min_size)
{
const struct firmware *fw;
* blob. Also generate the corresponding ucode descriptor.
*/
static int
-ls_ucode_img_load_generic(struct nvkm_subdev *subdev,
+ls_ucode_img_load_generic(const struct nvkm_subdev *subdev,
struct ls_ucode_img *img, const char *falcon_name,
const u32 falcon_id)
{
return ret;
}
-typedef int (*lsf_load_func)(struct nvkm_subdev *, struct ls_ucode_img *);
+typedef int (*lsf_load_func)(const struct nvkm_subdev *, struct ls_ucode_img *);
-static int
-ls_ucode_img_load_fecs(struct nvkm_subdev *subdev, struct ls_ucode_img *img)
+int
+gm200_ls_load_fecs(const 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)
+int
+gm200_ls_load_gpccs(const struct nvkm_subdev *subdev, struct ls_ucode_img *img)
{
return ls_ucode_img_load_generic(subdev, img, "gpccs",
NVKM_SECBOOT_FALCON_GPCCS);
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
+ * gm200_secboot_ls_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
*
*/
static void
-ls_ucode_img_populate_bl_desc(struct ls_ucode_img *img, u64 wpr_addr,
- struct gm200_flcn_bl_desc *desc)
+gm200_secboot_ls_bl_desc(const struct ls_ucode_img *img, u64 wpr_addr,
+ void *_desc)
{
- struct ls_ucode_img_desc *pdesc = &img->ucode_desc;
+ struct gm200_flcn_bl_desc *desc = _desc;
+ const struct ls_ucode_img_desc *pdesc = &img->ucode_desc;
u64 addr_base;
addr_base = wpr_addr + img->lsb_header.ucode_off +
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;
+ const struct secboot_ls_single_func *func =
+ (*gsb->ls_func)[img->falcon_id];
if (img->ucode_header) {
nvkm_fatal(&gsb->base.subdev,
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 and save off BL descriptor size */
+ lhdr->bl_data_size = ALIGN(func->bl_desc_size, LSF_BL_DATA_SIZE_ALIGN);
+
/*
* Align, save off, and include the additional BL data
*/
/* Generate and write BL descriptor */
if (!img->ucode_header) {
- u8 desc[gsb->func->bl_desc_size];
- struct gm200_flcn_bl_desc gdesc;
+ const struct secboot_ls_single_func *ls_func =
+ (*gsb->ls_func)[img->falcon_id];
+ u8 gdesc[ls_func->bl_desc_size];
+
+ ls_func->generate_bl_desc(img, gsb->acr_wpr_addr,
+ &gdesc);
- ls_ucode_img_populate_bl_desc(img, gsb->acr_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);
+ &gdesc, ls_func->bl_desc_size);
}
/* Copy ucode */
ls_ucode_mgr_init(&mgr);
/* Load all LS blobs */
- for_each_set_bit(falcon_id, &gsb->base.func->managed_falcons,
+ for_each_set_bit(falcon_id, &sb->func->managed_falcons,
NVKM_SECBOOT_FALCON_END) {
struct ls_ucode_img *img;
- img = ls_ucode_img_load(&sb->subdev, lsf_load_funcs[falcon_id]);
+ img = ls_ucode_img_load(&sb->subdev,
+ (*gsb->ls_func)[falcon_id]->load);
if (IS_ERR(img)) {
ret = PTR_ERR(img);
return ret;
}
+static const secboot_ls_func
+gm200_ls_func = {
+ [NVKM_SECBOOT_FALCON_FECS] = &(struct secboot_ls_single_func) {
+ .load = gm200_ls_load_fecs,
+ .generate_bl_desc = gm200_secboot_ls_bl_desc,
+ .bl_desc_size = sizeof(struct gm200_flcn_bl_desc),
+ },
+ [NVKM_SECBOOT_FALCON_GPCCS] = &(struct secboot_ls_single_func) {
+ .load = gm200_ls_load_gpccs,
+ .generate_bl_desc = gm200_secboot_ls_bl_desc,
+ .bl_desc_size = sizeof(struct gm200_flcn_bl_desc),
+ },
+};
+
/*
* High-secure blob creation
*/
return ret;
gsb->func = &gm200_secboot_func;
+ gsb->ls_func = &gm200_ls_func;
return 0;
}
int nvkm_secboot_ctor(const struct nvkm_secboot_func *, struct nvkm_device *,
int index, struct nvkm_secboot *);
+/*
+ *
+ * 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 flcn_u64 {
u32 lo;
u32 hi;
u32 data_size;
};
+/**
+ * struct secboot_ls_single_func - manages a single LS firmware
+ *
+ * @load: load the external firmware into a ls_ucode_img
+ * @generate_bl_desc: function called on a block of bl_desc_size to generate the
+ * proper bootloader descriptor for this LS firmware
+ * @bl_desc_size: size of the bootloader descriptor
+ */
+struct secboot_ls_single_func {
+ int (*load)(const struct nvkm_subdev *, struct ls_ucode_img *);
+ void (*generate_bl_desc)(const struct ls_ucode_img *, u64, void *);
+ u32 bl_desc_size;
+};
+
+/**
+ * typedef secboot_ls_func - manages all the LS firmwares for this ACR
+ */
+typedef const struct secboot_ls_single_func *
+secboot_ls_func[NVKM_SECBOOT_FALCON_END];
+
+int gm200_ls_load_fecs(const struct nvkm_subdev *, struct ls_ucode_img *);
+int gm200_ls_load_gpccs(const struct nvkm_subdev *, struct ls_ucode_img *);
+
/**
* Contains the whole secure boot state, allowing it to be performed as needed
* @wpr_addr: physical address of the WPR region
struct gm200_secboot {
struct nvkm_secboot base;
const struct gm200_secboot_func *func;
+ const secboot_ls_func *ls_func;
/*
* Address and size of the fixed WPR region, if any. On Tegra this