Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Alexandre Courbot | 1499 | 95.54% | 2 | 66.67% |
Kees Cook | 70 | 4.46% | 1 | 33.33% |
Total | 1569 | 3 |
/* * Copyright (c) 2017, 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. */ #include "acr_r367.h" #include "acr_r361.h" #include <core/gpuobj.h> /* * r367 ACR: new LS signature format requires a rewrite of LS firmware and * blob creation functions. Also the hsflcn_desc layout has changed slightly. */ #define LSF_LSB_DEPMAP_SIZE 11 /** * struct acr_r367_lsf_lsb_header - LS firmware header * * See also struct acr_r352_lsf_lsb_header for documentation. */ struct acr_r367_lsf_lsb_header { /** * LS falcon signatures * @prd_keys: signature to use in production mode * @dgb_keys: signature to use 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 */ struct { u8 prd_keys[2][16]; u8 dbg_keys[2][16]; u32 b_prd_present; u32 b_dbg_present; u32 falcon_id; u32 supports_versioning; u32 version; u32 depmap_count; u8 depmap[LSF_LSB_DEPMAP_SIZE * 2 * 4]; u8 kdf[16]; } 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; }; /** * struct acr_r367_lsf_wpr_header - LS blob WPR Header * * See also struct acr_r352_lsf_wpr_header for documentation. */ struct acr_r367_lsf_wpr_header { u32 falcon_id; u32 lsb_offset; u32 bootstrap_owner; u32 lazy_bootstrap; u32 bin_version; 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 #define LSF_IMAGE_STATUS_REVOCATION_CHECK_FAILED 7 }; /** * struct ls_ucode_img_r367 - ucode image augmented with r367 headers */ struct ls_ucode_img_r367 { struct ls_ucode_img base; struct acr_r367_lsf_wpr_header wpr_header; struct acr_r367_lsf_lsb_header lsb_header; }; #define ls_ucode_img_r367(i) container_of(i, struct ls_ucode_img_r367, base) struct ls_ucode_img * acr_r367_ls_ucode_img_load(const struct acr_r352 *acr, const struct nvkm_secboot *sb, enum nvkm_secboot_falcon falcon_id) { const struct nvkm_subdev *subdev = acr->base.subdev; struct ls_ucode_img_r367 *img; int ret; img = kzalloc(sizeof(*img), GFP_KERNEL); if (!img) return ERR_PTR(-ENOMEM); img->base.falcon_id = falcon_id; ret = acr->func->ls_func[falcon_id]->load(sb, &img->base); if (ret) { kfree(img->base.ucode_data); kfree(img->base.sig); kfree(img); return ERR_PTR(ret); } /* Check that the signature size matches our expectations... */ if (img->base.sig_size != sizeof(img->lsb_header.signature)) { nvkm_error(subdev, "invalid signature size for %s falcon!\n", nvkm_secboot_falcon_name[falcon_id]); return ERR_PTR(-EINVAL); } /* Copy signature to the right place */ memcpy(&img->lsb_header.signature, img->base.sig, img->base.sig_size); /* not needed? the signature should already have the right value */ img->lsb_header.signature.falcon_id = falcon_id; return &img->base; } #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 static u32 acr_r367_ls_img_fill_headers(struct acr_r352 *acr, struct ls_ucode_img_r367 *img, u32 offset) { struct ls_ucode_img *_img = &img->base; struct acr_r367_lsf_wpr_header *whdr = &img->wpr_header; struct acr_r367_lsf_lsb_header *lhdr = &img->lsb_header; struct ls_ucode_img_desc *desc = &_img->ucode_desc; const struct acr_r352_ls_func *func = acr->func->ls_func[_img->falcon_id]; /* Fill WPR header */ whdr->falcon_id = _img->falcon_id; whdr->bootstrap_owner = acr->base.boot_falcon; whdr->bin_version = lhdr->signature.version; whdr->status = LSF_IMAGE_STATUS_COPY; /* Skip bootstrapping falcons started by someone else than ACR */ if (acr->lazy_bootstrap & BIT(_img->falcon_id)) whdr->lazy_bootstrap = 1; /* Align, save off, and include an LSB header size */ offset = ALIGN(offset, LSF_LSB_HEADER_ALIGN); whdr->lsb_offset = offset; offset += sizeof(*lhdr); /* * Align, save off, and include the original (static) ucode * image size */ offset = ALIGN(offset, LSF_UCODE_DATA_ALIGN); _img->ucode_off = 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 = func->lhdr_flags; if (_img->falcon_id == acr->base.boot_falcon) lhdr->flags |= LSF_FLAG_DMACTL_REQ_CTX; /* 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 */ offset = ALIGN(offset, LSF_BL_DATA_ALIGN); lhdr->bl_data_off = offset; offset += lhdr->bl_data_size; return offset; } int acr_r367_ls_fill_headers(struct acr_r352 *acr, struct list_head *imgs) { struct ls_ucode_img_r367 *img; struct list_head *l; u32 count = 0; u32 offset; /* Count the number of images to manage */ list_for_each(l, imgs) count++; /* * 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(img->wpr_header) * (count + 1); /* * Walk the managed falcons, accounting for the LSB structs * as well as the ucode images. */ list_for_each_entry(img, imgs, base.node) { offset = acr_r367_ls_img_fill_headers(acr, img, offset); } return offset; } int acr_r367_ls_write_wpr(struct acr_r352 *acr, struct list_head *imgs, struct nvkm_gpuobj *wpr_blob, u64 wpr_addr) { struct ls_ucode_img *_img; u32 pos = 0; u32 max_desc_size = 0; u8 *gdesc; list_for_each_entry(_img, imgs, node) { const struct acr_r352_ls_func *ls_func = acr->func->ls_func[_img->falcon_id]; max_desc_size = max(max_desc_size, ls_func->bl_desc_size); } gdesc = kmalloc(max_desc_size, GFP_KERNEL); if (!gdesc) return -ENOMEM; nvkm_kmap(wpr_blob); list_for_each_entry(_img, imgs, node) { struct ls_ucode_img_r367 *img = ls_ucode_img_r367(_img); const struct acr_r352_ls_func *ls_func = acr->func->ls_func[_img->falcon_id]; 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 */ memset(gdesc, 0, ls_func->bl_desc_size); ls_func->generate_bl_desc(&acr->base, _img, wpr_addr, gdesc); nvkm_gpuobj_memcpy_to(wpr_blob, img->lsb_header.bl_data_off, gdesc, ls_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); kfree(gdesc); return 0; } struct acr_r367_hsflcn_desc { u8 reserved_dmem[0x200]; u32 signatures[4]; u32 wpr_region_id; u32 wpr_offset; u32 mmu_memory_range; #define FLCN_ACR_MAX_REGIONS 2 struct { u32 no_regions; struct { u32 start_addr; u32 end_addr; u32 region_id; u32 read_mask; u32 write_mask; u32 client_mask; u32 shadow_mem_start_addr; } region_props[FLCN_ACR_MAX_REGIONS]; } regions; u32 ucode_blob_size; u64 ucode_blob_base __aligned(8); struct { u32 vpr_enabled; u32 vpr_start; u32 vpr_end; u32 hdcp_policies; } vpr_desc; }; void acr_r367_fixup_hs_desc(struct acr_r352 *acr, struct nvkm_secboot *sb, void *_desc) { struct acr_r367_hsflcn_desc *desc = _desc; struct nvkm_gpuobj *ls_blob = acr->ls_blob; /* WPR region information if WPR is not fixed */ if (sb->wpr_size == 0) { u64 wpr_start = ls_blob->addr; u64 wpr_end = ls_blob->addr + ls_blob->size; if (acr->func->shadow_blob) wpr_start += ls_blob->size / 2; desc->wpr_region_id = 1; desc->regions.no_regions = 2; desc->regions.region_props[0].start_addr = wpr_start >> 8; desc->regions.region_props[0].end_addr = wpr_end >> 8; desc->regions.region_props[0].region_id = 1; desc->regions.region_props[0].read_mask = 0xf; desc->regions.region_props[0].write_mask = 0xc; desc->regions.region_props[0].client_mask = 0x2; if (acr->func->shadow_blob) desc->regions.region_props[0].shadow_mem_start_addr = ls_blob->addr >> 8; else desc->regions.region_props[0].shadow_mem_start_addr = 0; } else { desc->ucode_blob_base = ls_blob->addr; desc->ucode_blob_size = ls_blob->size; } } const struct acr_r352_func acr_r367_func = { .fixup_hs_desc = acr_r367_fixup_hs_desc, .generate_hs_bl_desc = acr_r361_generate_hs_bl_desc, .hs_bl_desc_size = sizeof(struct acr_r361_flcn_bl_desc), .shadow_blob = true, .ls_ucode_img_load = acr_r367_ls_ucode_img_load, .ls_fill_headers = acr_r367_ls_fill_headers, .ls_write_wpr = acr_r367_ls_write_wpr, .ls_func = { [NVKM_SECBOOT_FALCON_FECS] = &acr_r361_ls_fecs_func, [NVKM_SECBOOT_FALCON_GPCCS] = &acr_r361_ls_gpccs_func, [NVKM_SECBOOT_FALCON_PMU] = &acr_r361_ls_pmu_func, [NVKM_SECBOOT_FALCON_SEC2] = &acr_r361_ls_sec2_func, }, }; struct nvkm_acr * acr_r367_new(enum nvkm_secboot_falcon boot_falcon, unsigned long managed_falcons) { return acr_r352_new_(&acr_r367_func, boot_falcon, managed_falcons); }
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