// SPDX-License-Identifier: GPL-2.0 /* * Copyright (C) 2019 Intel Corporation. * * Authors: * Ramalingam C */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "drm_internal.h" static struct hdcp_srm { u32 revoked_ksv_cnt; u8 *revoked_ksv_list; /* Mutex to protect above struct member */ struct mutex mutex; } *srm_data; static inline void drm_hdcp_print_ksv(const u8 *ksv) { DRM_DEBUG("\t%#02x, %#02x, %#02x, %#02x, %#02x\n", ksv[0], ksv[1], ksv[2], ksv[3], ksv[4]); } static u32 drm_hdcp_get_revoked_ksv_count(const u8 *buf, u32 vrls_length) { u32 parsed_bytes = 0, ksv_count = 0, vrl_ksv_cnt, vrl_sz; while (parsed_bytes < vrls_length) { vrl_ksv_cnt = *buf; ksv_count += vrl_ksv_cnt; vrl_sz = (vrl_ksv_cnt * DRM_HDCP_KSV_LEN) + 1; buf += vrl_sz; parsed_bytes += vrl_sz; } /* * When vrls are not valid, ksvs are not considered. * Hence SRM will be discarded. */ if (parsed_bytes != vrls_length) ksv_count = 0; return ksv_count; } static u32 drm_hdcp_get_revoked_ksvs(const u8 *buf, u8 *revoked_ksv_list, u32 vrls_length) { u32 parsed_bytes = 0, ksv_count = 0; u32 vrl_ksv_cnt, vrl_ksv_sz, vrl_idx = 0; do { vrl_ksv_cnt = *buf; vrl_ksv_sz = vrl_ksv_cnt * DRM_HDCP_KSV_LEN; buf++; DRM_DEBUG("vrl: %d, Revoked KSVs: %d\n", vrl_idx++, vrl_ksv_cnt); memcpy(revoked_ksv_list, buf, vrl_ksv_sz); ksv_count += vrl_ksv_cnt; revoked_ksv_list += vrl_ksv_sz; buf += vrl_ksv_sz; parsed_bytes += (vrl_ksv_sz + 1); } while (parsed_bytes < vrls_length); return ksv_count; } static inline u32 get_vrl_length(const u8 *buf) { return drm_hdcp_be24_to_cpu(buf); } static int drm_hdcp_parse_hdcp1_srm(const u8 *buf, size_t count) { struct hdcp_srm_header *header; u32 vrl_length, ksv_count; if (count < (sizeof(struct hdcp_srm_header) + DRM_HDCP_1_4_VRL_LENGTH_SIZE + DRM_HDCP_1_4_DCP_SIG_SIZE)) { DRM_ERROR("Invalid blob length\n"); return -EINVAL; } header = (struct hdcp_srm_header *)buf; DRM_DEBUG("SRM ID: 0x%x, SRM Ver: 0x%x, SRM Gen No: 0x%x\n", header->srm_id, be16_to_cpu(header->srm_version), header->srm_gen_no); WARN_ON(header->reserved); buf = buf + sizeof(*header); vrl_length = get_vrl_length(buf); if (count < (sizeof(struct hdcp_srm_header) + vrl_length) || vrl_length < (DRM_HDCP_1_4_VRL_LENGTH_SIZE + DRM_HDCP_1_4_DCP_SIG_SIZE)) { DRM_ERROR("Invalid blob length or vrl length\n"); return -EINVAL; } /* Length of the all vrls combined */ vrl_length -= (DRM_HDCP_1_4_VRL_LENGTH_SIZE + DRM_HDCP_1_4_DCP_SIG_SIZE); if (!vrl_length) { DRM_ERROR("No vrl found\n"); return -EINVAL; } buf += DRM_HDCP_1_4_VRL_LENGTH_SIZE; ksv_count = drm_hdcp_get_revoked_ksv_count(buf, vrl_length); if (!ksv_count) { DRM_DEBUG("Revoked KSV count is 0\n"); return count; } kfree(srm_data->revoked_ksv_list); srm_data->revoked_ksv_list = kcalloc(ksv_count, DRM_HDCP_KSV_LEN, GFP_KERNEL); if (!srm_data->revoked_ksv_list) { DRM_ERROR("Out of Memory\n"); return -ENOMEM; } if (drm_hdcp_get_revoked_ksvs(buf, srm_data->revoked_ksv_list, vrl_length) != ksv_count) { srm_data->revoked_ksv_cnt = 0; kfree(srm_data->revoked_ksv_list); return -EINVAL; } srm_data->revoked_ksv_cnt = ksv_count; return count; } static int drm_hdcp_parse_hdcp2_srm(const u8 *buf, size_t count) { struct hdcp_srm_header *header; u32 vrl_length, ksv_count, ksv_sz; if (count < (sizeof(struct hdcp_srm_header) + DRM_HDCP_2_VRL_LENGTH_SIZE + DRM_HDCP_2_DCP_SIG_SIZE)) { DRM_ERROR("Invalid blob length\n"); return -EINVAL; } header = (struct hdcp_srm_header *)buf; DRM_DEBUG("SRM ID: 0x%x, SRM Ver: 0x%x, SRM Gen No: 0x%x\n", header->srm_id & DRM_HDCP_SRM_ID_MASK, be16_to_cpu(header->srm_version), header->srm_gen_no); if (header->reserved) return -EINVAL; buf = buf + sizeof(*header); vrl_length = get_vrl_length(buf); if (count < (sizeof(struct hdcp_srm_header) + vrl_length) || vrl_length < (DRM_HDCP_2_VRL_LENGTH_SIZE + DRM_HDCP_2_DCP_SIG_SIZE)) { DRM_ERROR("Invalid blob length or vrl length\n"); return -EINVAL; } /* Length of the all vrls combined */ vrl_length -= (DRM_HDCP_2_VRL_LENGTH_SIZE + DRM_HDCP_2_DCP_SIG_SIZE); if (!vrl_length) { DRM_ERROR("No vrl found\n"); return -EINVAL; } buf += DRM_HDCP_2_VRL_LENGTH_SIZE; ksv_count = (*buf << 2) | DRM_HDCP_2_KSV_COUNT_2_LSBITS(*(buf + 1)); if (!ksv_count) { DRM_DEBUG("Revoked KSV count is 0\n"); return count; } kfree(srm_data->revoked_ksv_list); srm_data->revoked_ksv_list = kcalloc(ksv_count, DRM_HDCP_KSV_LEN, GFP_KERNEL); if (!srm_data->revoked_ksv_list) { DRM_ERROR("Out of Memory\n"); return -ENOMEM; } ksv_sz = ksv_count * DRM_HDCP_KSV_LEN; buf += DRM_HDCP_2_NO_OF_DEV_PLUS_RESERVED_SZ; DRM_DEBUG("Revoked KSVs: %d\n", ksv_count); memcpy(srm_data->revoked_ksv_list, buf, ksv_sz); srm_data->revoked_ksv_cnt = ksv_count; return count; } static inline bool is_srm_version_hdcp1(const u8 *buf) { return *buf == (u8)(DRM_HDCP_1_4_SRM_ID << 4); } static inline bool is_srm_version_hdcp2(const u8 *buf) { return *buf == (u8)(DRM_HDCP_2_SRM_ID << 4 | DRM_HDCP_2_INDICATOR); } static void drm_hdcp_srm_update(const u8 *buf, size_t count) { if (count < sizeof(struct hdcp_srm_header)) return; if (is_srm_version_hdcp1(buf)) drm_hdcp_parse_hdcp1_srm(buf, count); else if (is_srm_version_hdcp2(buf)) drm_hdcp_parse_hdcp2_srm(buf, count); } static void drm_hdcp_request_srm(struct drm_device *drm_dev) { char fw_name[36] = "display_hdcp_srm.bin"; const struct firmware *fw; int ret; ret = request_firmware_direct(&fw, (const char *)fw_name, drm_dev->dev); if (ret < 0) goto exit; if (fw->size && fw->data) drm_hdcp_srm_update(fw->data, fw->size); exit: release_firmware(fw); } /** * drm_hdcp_check_ksvs_revoked - Check the revoked status of the IDs * * @drm_dev: drm_device for which HDCP revocation check is requested * @ksvs: List of KSVs (HDCP receiver IDs) * @ksv_count: KSV count passed in through @ksvs * * This function reads the HDCP System renewability Message(SRM Table) * from userspace as a firmware and parses it for the revoked HDCP * KSVs(Receiver IDs) detected by DCP LLC. Once the revoked KSVs are known, * revoked state of the KSVs in the list passed in by display drivers are * decided and response is sent. * * SRM should be presented in the name of "display_hdcp_srm.bin". * * Format of the SRM table, that userspace needs to write into the binary file, * is defined at: * 1. Renewability chapter on 55th page of HDCP 1.4 specification * https://www.digital-cp.com/sites/default/files/specifications/HDCP%20Specification%20Rev1_4_Secure.pdf * 2. Renewability chapter on 63rd page of HDCP 2.2 specification * https://www.digital-cp.com/sites/default/files/specifications/HDCP%20on%20HDMI%20Specification%20Rev2_2_Final1.pdf * * Returns: * TRUE on any of the KSV is revoked, else FALSE. */ bool drm_hdcp_check_ksvs_revoked(struct drm_device *drm_dev, u8 *ksvs, u32 ksv_count) { u32 rev_ksv_cnt, cnt, i, j; u8 *rev_ksv_list; if (!srm_data) return false; mutex_lock(&srm_data->mutex); drm_hdcp_request_srm(drm_dev); rev_ksv_cnt = srm_data->revoked_ksv_cnt; rev_ksv_list = srm_data->revoked_ksv_list; /* If the Revoked ksv list is empty */ if (!rev_ksv_cnt || !rev_ksv_list) { mutex_unlock(&srm_data->mutex); return false; } for (cnt = 0; cnt < ksv_count; cnt++) { rev_ksv_list = srm_data->revoked_ksv_list; for (i = 0; i < rev_ksv_cnt; i++) { for (j = 0; j < DRM_HDCP_KSV_LEN; j++) if (ksvs[j] != rev_ksv_list[j]) { break; } else if (j == (DRM_HDCP_KSV_LEN - 1)) { DRM_DEBUG("Revoked KSV is "); drm_hdcp_print_ksv(ksvs); mutex_unlock(&srm_data->mutex); return true; } /* Move the offset to next KSV in the revoked list */ rev_ksv_list += DRM_HDCP_KSV_LEN; } /* Iterate to next ksv_offset */ ksvs += DRM_HDCP_KSV_LEN; } mutex_unlock(&srm_data->mutex); return false; } EXPORT_SYMBOL_GPL(drm_hdcp_check_ksvs_revoked); int drm_setup_hdcp_srm(struct class *drm_class) { srm_data = kzalloc(sizeof(*srm_data), GFP_KERNEL); if (!srm_data) return -ENOMEM; mutex_init(&srm_data->mutex); return 0; } void drm_teardown_hdcp_srm(struct class *drm_class) { if (srm_data) { kfree(srm_data->revoked_ksv_list); kfree(srm_data); } } static struct drm_prop_enum_list drm_cp_enum_list[] = { { DRM_MODE_CONTENT_PROTECTION_UNDESIRED, "Undesired" }, { DRM_MODE_CONTENT_PROTECTION_DESIRED, "Desired" }, { DRM_MODE_CONTENT_PROTECTION_ENABLED, "Enabled" }, }; DRM_ENUM_NAME_FN(drm_get_content_protection_name, drm_cp_enum_list) static struct drm_prop_enum_list drm_hdcp_content_type_enum_list[] = { { DRM_MODE_HDCP_CONTENT_TYPE0, "HDCP Type0" }, { DRM_MODE_HDCP_CONTENT_TYPE1, "HDCP Type1" }, }; DRM_ENUM_NAME_FN(drm_get_hdcp_content_type_name, drm_hdcp_content_type_enum_list) /** * drm_connector_attach_content_protection_property - attach content protection * property * * @connector: connector to attach CP property on. * @hdcp_content_type: is HDCP Content Type property needed for connector * * This is used to add support for content protection on select connectors. * Content Protection is intentionally vague to allow for different underlying * technologies, however it is most implemented by HDCP. * * When hdcp_content_type is true enum property called HDCP Content Type is * created (if it is not already) and attached to the connector. * * This property is used for sending the protected content's stream type * from userspace to kernel on selected connectors. Protected content provider * will decide their type of their content and declare the same to kernel. * * Content type will be used during the HDCP 2.2 authentication. * Content type will be set to &drm_connector_state.hdcp_content_type. * * The content protection will be set to &drm_connector_state.content_protection * * When kernel triggered content protection state change like DESIRED->ENABLED * and ENABLED->DESIRED, will use drm_hdcp_update_content_protection() to update * the content protection state of a connector. * * Returns: * Zero on success, negative errno on failure. */ int drm_connector_attach_content_protection_property( struct drm_connector *connector, bool hdcp_content_type) { struct drm_device *dev = connector->dev; struct drm_property *prop = dev->mode_config.content_protection_property; if (!prop) prop = drm_property_create_enum(dev, 0, "Content Protection", drm_cp_enum_list, ARRAY_SIZE(drm_cp_enum_list)); if (!prop) return -ENOMEM; drm_object_attach_property(&connector->base, prop, DRM_MODE_CONTENT_PROTECTION_UNDESIRED); dev->mode_config.content_protection_property = prop; if (!hdcp_content_type) return 0; prop = dev->mode_config.hdcp_content_type_property; if (!prop) prop = drm_property_create_enum(dev, 0, "HDCP Content Type", drm_hdcp_content_type_enum_list, ARRAY_SIZE( drm_hdcp_content_type_enum_list)); if (!prop) return -ENOMEM; drm_object_attach_property(&connector->base, prop, DRM_MODE_HDCP_CONTENT_TYPE0); dev->mode_config.hdcp_content_type_property = prop; return 0; } EXPORT_SYMBOL(drm_connector_attach_content_protection_property); /** * drm_hdcp_update_content_protection - Updates the content protection state * of a connector * * @connector: drm_connector on which content protection state needs an update * @val: New state of the content protection property * * This function can be used by display drivers, to update the kernel triggered * content protection state changes of a drm_connector such as DESIRED->ENABLED * and ENABLED->DESIRED. No uevent for DESIRED->UNDESIRED or ENABLED->UNDESIRED, * as userspace is triggering such state change and kernel performs it without * fail.This function update the new state of the property into the connector's * state and generate an uevent to notify the userspace. */ void drm_hdcp_update_content_protection(struct drm_connector *connector, u64 val) { struct drm_device *dev = connector->dev; struct drm_connector_state *state = connector->state; WARN_ON(!drm_modeset_is_locked(&dev->mode_config.connection_mutex)); if (state->content_protection == val) return; state->content_protection = val; drm_sysfs_connector_status_event(connector, dev->mode_config.content_protection_property); } EXPORT_SYMBOL(drm_hdcp_update_content_protection);