linux_dsm_epyc7002/drivers/misc/mei/hdcp/mei_hdcp.c
Dave Airlie 14ee642c2a Features:
- Engine discovery query (Tvrtko)
 - Support for DP YCbCr4:2:0 outputs (Gwan-gyeong)
 - HDCP revocation support, refactoring (Ramalingam)
 - Remove DRM_AUTH from IOCTLs which also have DRM_RENDER_ALLOW (Christian König)
 - Asynchronous display power disabling (Imre)
 - Perma-pin uC firmware and re-enable global reset (Fernando)
 - GTT remapping for display, for bigger fb size and stride (Ville)
 - Enable pipe HDR mode on ICL if only HDR planes are used (Ville)
 - Kconfig to tweak the busyspin durations for i915_wait_request (Chris)
 - Allow multiple user handles to the same VM (Chris)
 - GT/GEM runtime pm improvements using wakerefs (Chris)
 - Gen 4&5 render context support (Chris)
 - Allow userspace to clone contexts on creation (Chris)
 - SINGLE_TIMELINE flags for context creation (Chris)
 - Allow specification of parallel execbuf (Chris)
 
 Refactoring:
 - Header refactoring (Jani)
 - Move GraphicsTechnology files under gt/ (Chris)
 - Sideband code refactoring (Chris)
 
 Fixes:
 - ICL DSI state readout and checker fixes (Vandita)
 - GLK DSI picture corruption fix (Stanislav)
 - HDMI deep color fixes (Clinton, Aditya)
 - Fix driver unbinding from a device in use (Janusz)
 - Fix clock gating with pipe scaling (Radhakrishna)
 - Disable broken FBC on GLK (Daniel Drake)
 - Miscellaneous GuC fixes (Michal)
 - Fix MG PHY DP register programming (Imre)
 - Add missing combo PHY lane power setup (Imre)
 - Workarounds for early ICL VBT issues (Imre)
 - Fix fastset vs. pfit on/off on HSW EDP transcoder (Ville)
 - Add readout and state check for pch_pfit.force_thru (Ville)
 - Miscellaneous display fixes and refactoring (Ville)
 - Display workaround fixes (Ville)
 - Enable audio even if ELD is bogus (Ville)
 - Fix use-after-free in reporting create.size (Chris)
 - Sideband fixes to avoid BYT hard lockups (Chris)
 - Workaround fixes and improvements (Chris)
 
 Maintainer shortcomings:
 - Failure to adequately describe and give credit for all changes (Jani)
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Merge tag 'drm-intel-next-2019-05-24' of git://anongit.freedesktop.org/drm/drm-intel into drm-next

Features:
- Engine discovery query (Tvrtko)
- Support for DP YCbCr4:2:0 outputs (Gwan-gyeong)
- HDCP revocation support, refactoring (Ramalingam)
- Remove DRM_AUTH from IOCTLs which also have DRM_RENDER_ALLOW (Christian König)
- Asynchronous display power disabling (Imre)
- Perma-pin uC firmware and re-enable global reset (Fernando)
- GTT remapping for display, for bigger fb size and stride (Ville)
- Enable pipe HDR mode on ICL if only HDR planes are used (Ville)
- Kconfig to tweak the busyspin durations for i915_wait_request (Chris)
- Allow multiple user handles to the same VM (Chris)
- GT/GEM runtime pm improvements using wakerefs (Chris)
- Gen 4&5 render context support (Chris)
- Allow userspace to clone contexts on creation (Chris)
- SINGLE_TIMELINE flags for context creation (Chris)
- Allow specification of parallel execbuf (Chris)

Refactoring:
- Header refactoring (Jani)
- Move GraphicsTechnology files under gt/ (Chris)
- Sideband code refactoring (Chris)

Fixes:
- ICL DSI state readout and checker fixes (Vandita)
- GLK DSI picture corruption fix (Stanislav)
- HDMI deep color fixes (Clinton, Aditya)
- Fix driver unbinding from a device in use (Janusz)
- Fix clock gating with pipe scaling (Radhakrishna)
- Disable broken FBC on GLK (Daniel Drake)
- Miscellaneous GuC fixes (Michal)
- Fix MG PHY DP register programming (Imre)
- Add missing combo PHY lane power setup (Imre)
- Workarounds for early ICL VBT issues (Imre)
- Fix fastset vs. pfit on/off on HSW EDP transcoder (Ville)
- Add readout and state check for pch_pfit.force_thru (Ville)
- Miscellaneous display fixes and refactoring (Ville)
- Display workaround fixes (Ville)
- Enable audio even if ELD is bogus (Ville)
- Fix use-after-free in reporting create.size (Chris)
- Sideband fixes to avoid BYT hard lockups (Chris)
- Workaround fixes and improvements (Chris)

Maintainer shortcomings:
- Failure to adequately describe and give credit for all changes (Jani)

Signed-off-by: Dave Airlie <airlied@redhat.com>

From: Jani Nikula <jani.nikula@intel.com>
Link: https://patchwork.freedesktop.org/patch/msgid/87sgt3n45z.fsf@intel.com
2019-05-28 09:26:52 +10:00

850 lines
24 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Copyright © 2019 Intel Corporation
*
* Mei_hdcp.c: HDCP client driver for mei bus
*
* Author:
* Ramalingam C <ramalingam.c@intel.com>
*/
/**
* DOC: MEI_HDCP Client Driver
*
* This is a client driver to the mei_bus to make the HDCP2.2 services of
* ME FW available for the interested consumers like I915.
*
* This module will act as a translation layer between HDCP protocol
* implementor(I915) and ME FW by translating HDCP2.2 authentication
* messages to ME FW command payloads and vice versa.
*/
#include <linux/module.h>
#include <linux/slab.h>
#include <linux/uuid.h>
#include <linux/mei_cl_bus.h>
#include <linux/component.h>
#include <drm/drm_connector.h>
#include <drm/i915_component.h>
#include <drm/i915_mei_hdcp_interface.h>
#include "mei_hdcp.h"
static inline u8 mei_get_ddi_index(enum port port)
{
switch (port) {
case PORT_A:
return MEI_DDI_A;
case PORT_B ... PORT_F:
return (u8)port;
default:
return MEI_DDI_INVALID_PORT;
}
}
/**
* mei_hdcp_initiate_session() - Initiate a Wired HDCP2.2 Tx Session in ME FW
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
* @ake_data: AKE_Init msg output.
*
* Return: 0 on Success, <0 on Failure.
*/
static int
mei_hdcp_initiate_session(struct device *dev, struct hdcp_port_data *data,
struct hdcp2_ake_init *ake_data)
{
struct wired_cmd_initiate_hdcp2_session_in session_init_in = { { 0 } };
struct wired_cmd_initiate_hdcp2_session_out
session_init_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !data || !ake_data)
return -EINVAL;
cldev = to_mei_cl_device(dev);
session_init_in.header.api_version = HDCP_API_VERSION;
session_init_in.header.command_id = WIRED_INITIATE_HDCP2_SESSION;
session_init_in.header.status = ME_HDCP_STATUS_SUCCESS;
session_init_in.header.buffer_len =
WIRED_CMD_BUF_LEN_INITIATE_HDCP2_SESSION_IN;
session_init_in.port.integrated_port_type = data->port_type;
session_init_in.port.physical_port = mei_get_ddi_index(data->port);
session_init_in.protocol = data->protocol;
byte = mei_cldev_send(cldev, (u8 *)&session_init_in,
sizeof(session_init_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&session_init_out,
sizeof(session_init_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (session_init_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X Failed. Status: 0x%X\n",
WIRED_INITIATE_HDCP2_SESSION,
session_init_out.header.status);
return -EIO;
}
ake_data->msg_id = HDCP_2_2_AKE_INIT;
ake_data->tx_caps = session_init_out.tx_caps;
memcpy(ake_data->r_tx, session_init_out.r_tx, HDCP_2_2_RTX_LEN);
return 0;
}
/**
* mei_hdcp_verify_receiver_cert_prepare_km() - Verify the Receiver Certificate
* AKE_Send_Cert and prepare AKE_Stored_Km/AKE_No_Stored_Km
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
* @rx_cert: AKE_Send_Cert for verification
* @km_stored: Pairing status flag output
* @ek_pub_km: AKE_Stored_Km/AKE_No_Stored_Km output msg
* @msg_sz : size of AKE_XXXXX_Km output msg
*
* Return: 0 on Success, <0 on Failure
*/
static int
mei_hdcp_verify_receiver_cert_prepare_km(struct device *dev,
struct hdcp_port_data *data,
struct hdcp2_ake_send_cert *rx_cert,
bool *km_stored,
struct hdcp2_ake_no_stored_km
*ek_pub_km,
size_t *msg_sz)
{
struct wired_cmd_verify_receiver_cert_in verify_rxcert_in = { { 0 } };
struct wired_cmd_verify_receiver_cert_out verify_rxcert_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !data || !rx_cert || !km_stored || !ek_pub_km || !msg_sz)
return -EINVAL;
cldev = to_mei_cl_device(dev);
verify_rxcert_in.header.api_version = HDCP_API_VERSION;
verify_rxcert_in.header.command_id = WIRED_VERIFY_RECEIVER_CERT;
verify_rxcert_in.header.status = ME_HDCP_STATUS_SUCCESS;
verify_rxcert_in.header.buffer_len =
WIRED_CMD_BUF_LEN_VERIFY_RECEIVER_CERT_IN;
verify_rxcert_in.port.integrated_port_type = data->port_type;
verify_rxcert_in.port.physical_port = mei_get_ddi_index(data->port);
verify_rxcert_in.cert_rx = rx_cert->cert_rx;
memcpy(verify_rxcert_in.r_rx, &rx_cert->r_rx, HDCP_2_2_RRX_LEN);
memcpy(verify_rxcert_in.rx_caps, rx_cert->rx_caps, HDCP_2_2_RXCAPS_LEN);
byte = mei_cldev_send(cldev, (u8 *)&verify_rxcert_in,
sizeof(verify_rxcert_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed: %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&verify_rxcert_out,
sizeof(verify_rxcert_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed: %zd\n", byte);
return byte;
}
if (verify_rxcert_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X Failed. Status: 0x%X\n",
WIRED_VERIFY_RECEIVER_CERT,
verify_rxcert_out.header.status);
return -EIO;
}
*km_stored = !!verify_rxcert_out.km_stored;
if (verify_rxcert_out.km_stored) {
ek_pub_km->msg_id = HDCP_2_2_AKE_STORED_KM;
*msg_sz = sizeof(struct hdcp2_ake_stored_km);
} else {
ek_pub_km->msg_id = HDCP_2_2_AKE_NO_STORED_KM;
*msg_sz = sizeof(struct hdcp2_ake_no_stored_km);
}
memcpy(ek_pub_km->e_kpub_km, &verify_rxcert_out.ekm_buff,
sizeof(verify_rxcert_out.ekm_buff));
return 0;
}
/**
* mei_hdcp_verify_hprime() - Verify AKE_Send_H_prime at ME FW.
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
* @rx_hprime: AKE_Send_H_prime msg for ME FW verification
*
* Return: 0 on Success, <0 on Failure
*/
static int
mei_hdcp_verify_hprime(struct device *dev, struct hdcp_port_data *data,
struct hdcp2_ake_send_hprime *rx_hprime)
{
struct wired_cmd_ake_send_hprime_in send_hprime_in = { { 0 } };
struct wired_cmd_ake_send_hprime_out send_hprime_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !data || !rx_hprime)
return -EINVAL;
cldev = to_mei_cl_device(dev);
send_hprime_in.header.api_version = HDCP_API_VERSION;
send_hprime_in.header.command_id = WIRED_AKE_SEND_HPRIME;
send_hprime_in.header.status = ME_HDCP_STATUS_SUCCESS;
send_hprime_in.header.buffer_len = WIRED_CMD_BUF_LEN_AKE_SEND_HPRIME_IN;
send_hprime_in.port.integrated_port_type = data->port_type;
send_hprime_in.port.physical_port = mei_get_ddi_index(data->port);
memcpy(send_hprime_in.h_prime, rx_hprime->h_prime,
HDCP_2_2_H_PRIME_LEN);
byte = mei_cldev_send(cldev, (u8 *)&send_hprime_in,
sizeof(send_hprime_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&send_hprime_out,
sizeof(send_hprime_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (send_hprime_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X Failed. Status: 0x%X\n",
WIRED_AKE_SEND_HPRIME, send_hprime_out.header.status);
return -EIO;
}
return 0;
}
/**
* mei_hdcp_store_pairing_info() - Store pairing info received at ME FW
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
* @pairing_info: AKE_Send_Pairing_Info msg input to ME FW
*
* Return: 0 on Success, <0 on Failure
*/
static int
mei_hdcp_store_pairing_info(struct device *dev, struct hdcp_port_data *data,
struct hdcp2_ake_send_pairing_info *pairing_info)
{
struct wired_cmd_ake_send_pairing_info_in pairing_info_in = { { 0 } };
struct wired_cmd_ake_send_pairing_info_out pairing_info_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !data || !pairing_info)
return -EINVAL;
cldev = to_mei_cl_device(dev);
pairing_info_in.header.api_version = HDCP_API_VERSION;
pairing_info_in.header.command_id = WIRED_AKE_SEND_PAIRING_INFO;
pairing_info_in.header.status = ME_HDCP_STATUS_SUCCESS;
pairing_info_in.header.buffer_len =
WIRED_CMD_BUF_LEN_SEND_PAIRING_INFO_IN;
pairing_info_in.port.integrated_port_type = data->port_type;
pairing_info_in.port.physical_port = mei_get_ddi_index(data->port);
memcpy(pairing_info_in.e_kh_km, pairing_info->e_kh_km,
HDCP_2_2_E_KH_KM_LEN);
byte = mei_cldev_send(cldev, (u8 *)&pairing_info_in,
sizeof(pairing_info_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&pairing_info_out,
sizeof(pairing_info_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (pairing_info_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X failed. Status: 0x%X\n",
WIRED_AKE_SEND_PAIRING_INFO,
pairing_info_out.header.status);
return -EIO;
}
return 0;
}
/**
* mei_hdcp_initiate_locality_check() - Prepare LC_Init
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
* @lc_init_data: LC_Init msg output
*
* Return: 0 on Success, <0 on Failure
*/
static int
mei_hdcp_initiate_locality_check(struct device *dev,
struct hdcp_port_data *data,
struct hdcp2_lc_init *lc_init_data)
{
struct wired_cmd_init_locality_check_in lc_init_in = { { 0 } };
struct wired_cmd_init_locality_check_out lc_init_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !data || !lc_init_data)
return -EINVAL;
cldev = to_mei_cl_device(dev);
lc_init_in.header.api_version = HDCP_API_VERSION;
lc_init_in.header.command_id = WIRED_INIT_LOCALITY_CHECK;
lc_init_in.header.status = ME_HDCP_STATUS_SUCCESS;
lc_init_in.header.buffer_len = WIRED_CMD_BUF_LEN_INIT_LOCALITY_CHECK_IN;
lc_init_in.port.integrated_port_type = data->port_type;
lc_init_in.port.physical_port = mei_get_ddi_index(data->port);
byte = mei_cldev_send(cldev, (u8 *)&lc_init_in, sizeof(lc_init_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&lc_init_out, sizeof(lc_init_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (lc_init_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X Failed. status: 0x%X\n",
WIRED_INIT_LOCALITY_CHECK, lc_init_out.header.status);
return -EIO;
}
lc_init_data->msg_id = HDCP_2_2_LC_INIT;
memcpy(lc_init_data->r_n, lc_init_out.r_n, HDCP_2_2_RN_LEN);
return 0;
}
/**
* mei_hdcp_verify_lprime() - Verify lprime.
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
* @rx_lprime: LC_Send_L_prime msg for ME FW verification
*
* Return: 0 on Success, <0 on Failure
*/
static int
mei_hdcp_verify_lprime(struct device *dev, struct hdcp_port_data *data,
struct hdcp2_lc_send_lprime *rx_lprime)
{
struct wired_cmd_validate_locality_in verify_lprime_in = { { 0 } };
struct wired_cmd_validate_locality_out verify_lprime_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !data || !rx_lprime)
return -EINVAL;
cldev = to_mei_cl_device(dev);
verify_lprime_in.header.api_version = HDCP_API_VERSION;
verify_lprime_in.header.command_id = WIRED_VALIDATE_LOCALITY;
verify_lprime_in.header.status = ME_HDCP_STATUS_SUCCESS;
verify_lprime_in.header.buffer_len =
WIRED_CMD_BUF_LEN_VALIDATE_LOCALITY_IN;
verify_lprime_in.port.integrated_port_type = data->port_type;
verify_lprime_in.port.physical_port = mei_get_ddi_index(data->port);
memcpy(verify_lprime_in.l_prime, rx_lprime->l_prime,
HDCP_2_2_L_PRIME_LEN);
byte = mei_cldev_send(cldev, (u8 *)&verify_lprime_in,
sizeof(verify_lprime_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&verify_lprime_out,
sizeof(verify_lprime_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (verify_lprime_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X failed. status: 0x%X\n",
WIRED_VALIDATE_LOCALITY,
verify_lprime_out.header.status);
return -EIO;
}
return 0;
}
/**
* mei_hdcp_get_session_key() - Prepare SKE_Send_Eks.
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
* @ske_data: SKE_Send_Eks msg output from ME FW.
*
* Return: 0 on Success, <0 on Failure
*/
static int mei_hdcp_get_session_key(struct device *dev,
struct hdcp_port_data *data,
struct hdcp2_ske_send_eks *ske_data)
{
struct wired_cmd_get_session_key_in get_skey_in = { { 0 } };
struct wired_cmd_get_session_key_out get_skey_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !data || !ske_data)
return -EINVAL;
cldev = to_mei_cl_device(dev);
get_skey_in.header.api_version = HDCP_API_VERSION;
get_skey_in.header.command_id = WIRED_GET_SESSION_KEY;
get_skey_in.header.status = ME_HDCP_STATUS_SUCCESS;
get_skey_in.header.buffer_len = WIRED_CMD_BUF_LEN_GET_SESSION_KEY_IN;
get_skey_in.port.integrated_port_type = data->port_type;
get_skey_in.port.physical_port = mei_get_ddi_index(data->port);
byte = mei_cldev_send(cldev, (u8 *)&get_skey_in, sizeof(get_skey_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&get_skey_out, sizeof(get_skey_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (get_skey_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X failed. status: 0x%X\n",
WIRED_GET_SESSION_KEY, get_skey_out.header.status);
return -EIO;
}
ske_data->msg_id = HDCP_2_2_SKE_SEND_EKS;
memcpy(ske_data->e_dkey_ks, get_skey_out.e_dkey_ks,
HDCP_2_2_E_DKEY_KS_LEN);
memcpy(ske_data->riv, get_skey_out.r_iv, HDCP_2_2_RIV_LEN);
return 0;
}
/**
* mei_hdcp_repeater_check_flow_prepare_ack() - Validate the Downstream topology
* and prepare rep_ack.
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
* @rep_topology: Receiver ID List to be validated
* @rep_send_ack : repeater ack from ME FW.
*
* Return: 0 on Success, <0 on Failure
*/
static int
mei_hdcp_repeater_check_flow_prepare_ack(struct device *dev,
struct hdcp_port_data *data,
struct hdcp2_rep_send_receiverid_list
*rep_topology,
struct hdcp2_rep_send_ack
*rep_send_ack)
{
struct wired_cmd_verify_repeater_in verify_repeater_in = { { 0 } };
struct wired_cmd_verify_repeater_out verify_repeater_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !rep_topology || !rep_send_ack || !data)
return -EINVAL;
cldev = to_mei_cl_device(dev);
verify_repeater_in.header.api_version = HDCP_API_VERSION;
verify_repeater_in.header.command_id = WIRED_VERIFY_REPEATER;
verify_repeater_in.header.status = ME_HDCP_STATUS_SUCCESS;
verify_repeater_in.header.buffer_len =
WIRED_CMD_BUF_LEN_VERIFY_REPEATER_IN;
verify_repeater_in.port.integrated_port_type = data->port_type;
verify_repeater_in.port.physical_port = mei_get_ddi_index(data->port);
memcpy(verify_repeater_in.rx_info, rep_topology->rx_info,
HDCP_2_2_RXINFO_LEN);
memcpy(verify_repeater_in.seq_num_v, rep_topology->seq_num_v,
HDCP_2_2_SEQ_NUM_LEN);
memcpy(verify_repeater_in.v_prime, rep_topology->v_prime,
HDCP_2_2_V_PRIME_HALF_LEN);
memcpy(verify_repeater_in.receiver_ids, rep_topology->receiver_ids,
HDCP_2_2_RECEIVER_IDS_MAX_LEN);
byte = mei_cldev_send(cldev, (u8 *)&verify_repeater_in,
sizeof(verify_repeater_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&verify_repeater_out,
sizeof(verify_repeater_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (verify_repeater_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X failed. status: 0x%X\n",
WIRED_VERIFY_REPEATER,
verify_repeater_out.header.status);
return -EIO;
}
memcpy(rep_send_ack->v, verify_repeater_out.v,
HDCP_2_2_V_PRIME_HALF_LEN);
rep_send_ack->msg_id = HDCP_2_2_REP_SEND_ACK;
return 0;
}
/**
* mei_hdcp_verify_mprime() - Verify mprime.
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
* @stream_ready: RepeaterAuth_Stream_Ready msg for ME FW verification.
*
* Return: 0 on Success, <0 on Failure
*/
static int mei_hdcp_verify_mprime(struct device *dev,
struct hdcp_port_data *data,
struct hdcp2_rep_stream_ready *stream_ready)
{
struct wired_cmd_repeater_auth_stream_req_in
verify_mprime_in = { { 0 } };
struct wired_cmd_repeater_auth_stream_req_out
verify_mprime_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !stream_ready || !data)
return -EINVAL;
cldev = to_mei_cl_device(dev);
verify_mprime_in.header.api_version = HDCP_API_VERSION;
verify_mprime_in.header.command_id = WIRED_REPEATER_AUTH_STREAM_REQ;
verify_mprime_in.header.status = ME_HDCP_STATUS_SUCCESS;
verify_mprime_in.header.buffer_len =
WIRED_CMD_BUF_LEN_REPEATER_AUTH_STREAM_REQ_MIN_IN;
verify_mprime_in.port.integrated_port_type = data->port_type;
verify_mprime_in.port.physical_port = mei_get_ddi_index(data->port);
memcpy(verify_mprime_in.m_prime, stream_ready->m_prime,
HDCP_2_2_MPRIME_LEN);
drm_hdcp_cpu_to_be24(verify_mprime_in.seq_num_m, data->seq_num_m);
memcpy(verify_mprime_in.streams, data->streams,
(data->k * sizeof(struct hdcp2_streamid_type)));
verify_mprime_in.k = cpu_to_be16(data->k);
byte = mei_cldev_send(cldev, (u8 *)&verify_mprime_in,
sizeof(verify_mprime_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&verify_mprime_out,
sizeof(verify_mprime_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (verify_mprime_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X failed. status: 0x%X\n",
WIRED_REPEATER_AUTH_STREAM_REQ,
verify_mprime_out.header.status);
return -EIO;
}
return 0;
}
/**
* mei_hdcp_enable_authentication() - Mark a port as authenticated
* through ME FW
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
*
* Return: 0 on Success, <0 on Failure
*/
static int mei_hdcp_enable_authentication(struct device *dev,
struct hdcp_port_data *data)
{
struct wired_cmd_enable_auth_in enable_auth_in = { { 0 } };
struct wired_cmd_enable_auth_out enable_auth_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !data)
return -EINVAL;
cldev = to_mei_cl_device(dev);
enable_auth_in.header.api_version = HDCP_API_VERSION;
enable_auth_in.header.command_id = WIRED_ENABLE_AUTH;
enable_auth_in.header.status = ME_HDCP_STATUS_SUCCESS;
enable_auth_in.header.buffer_len = WIRED_CMD_BUF_LEN_ENABLE_AUTH_IN;
enable_auth_in.port.integrated_port_type = data->port_type;
enable_auth_in.port.physical_port = mei_get_ddi_index(data->port);
enable_auth_in.stream_type = data->streams[0].stream_type;
byte = mei_cldev_send(cldev, (u8 *)&enable_auth_in,
sizeof(enable_auth_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&enable_auth_out,
sizeof(enable_auth_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (enable_auth_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "ME cmd 0x%08X failed. status: 0x%X\n",
WIRED_ENABLE_AUTH, enable_auth_out.header.status);
return -EIO;
}
return 0;
}
/**
* mei_hdcp_close_session() - Close the Wired HDCP Tx session of ME FW per port.
* This also disables the authenticated state of the port.
* @dev: device corresponding to the mei_cl_device
* @data: Intel HW specific hdcp data
*
* Return: 0 on Success, <0 on Failure
*/
static int
mei_hdcp_close_session(struct device *dev, struct hdcp_port_data *data)
{
struct wired_cmd_close_session_in session_close_in = { { 0 } };
struct wired_cmd_close_session_out session_close_out = { { 0 } };
struct mei_cl_device *cldev;
ssize_t byte;
if (!dev || !data)
return -EINVAL;
cldev = to_mei_cl_device(dev);
session_close_in.header.api_version = HDCP_API_VERSION;
session_close_in.header.command_id = WIRED_CLOSE_SESSION;
session_close_in.header.status = ME_HDCP_STATUS_SUCCESS;
session_close_in.header.buffer_len =
WIRED_CMD_BUF_LEN_CLOSE_SESSION_IN;
session_close_in.port.integrated_port_type = data->port_type;
session_close_in.port.physical_port = mei_get_ddi_index(data->port);
byte = mei_cldev_send(cldev, (u8 *)&session_close_in,
sizeof(session_close_in));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_send failed. %zd\n", byte);
return byte;
}
byte = mei_cldev_recv(cldev, (u8 *)&session_close_out,
sizeof(session_close_out));
if (byte < 0) {
dev_dbg(dev, "mei_cldev_recv failed. %zd\n", byte);
return byte;
}
if (session_close_out.header.status != ME_HDCP_STATUS_SUCCESS) {
dev_dbg(dev, "Session Close Failed. status: 0x%X\n",
session_close_out.header.status);
return -EIO;
}
return 0;
}
static const struct i915_hdcp_component_ops mei_hdcp_ops = {
.owner = THIS_MODULE,
.initiate_hdcp2_session = mei_hdcp_initiate_session,
.verify_receiver_cert_prepare_km =
mei_hdcp_verify_receiver_cert_prepare_km,
.verify_hprime = mei_hdcp_verify_hprime,
.store_pairing_info = mei_hdcp_store_pairing_info,
.initiate_locality_check = mei_hdcp_initiate_locality_check,
.verify_lprime = mei_hdcp_verify_lprime,
.get_session_key = mei_hdcp_get_session_key,
.repeater_check_flow_prepare_ack =
mei_hdcp_repeater_check_flow_prepare_ack,
.verify_mprime = mei_hdcp_verify_mprime,
.enable_hdcp_authentication = mei_hdcp_enable_authentication,
.close_hdcp_session = mei_hdcp_close_session,
};
static int mei_component_master_bind(struct device *dev)
{
struct mei_cl_device *cldev = to_mei_cl_device(dev);
struct i915_hdcp_comp_master *comp_master =
mei_cldev_get_drvdata(cldev);
int ret;
dev_dbg(dev, "%s\n", __func__);
comp_master->ops = &mei_hdcp_ops;
comp_master->mei_dev = dev;
ret = component_bind_all(dev, comp_master);
if (ret < 0)
return ret;
return 0;
}
static void mei_component_master_unbind(struct device *dev)
{
struct mei_cl_device *cldev = to_mei_cl_device(dev);
struct i915_hdcp_comp_master *comp_master =
mei_cldev_get_drvdata(cldev);
dev_dbg(dev, "%s\n", __func__);
component_unbind_all(dev, comp_master);
}
static const struct component_master_ops mei_component_master_ops = {
.bind = mei_component_master_bind,
.unbind = mei_component_master_unbind,
};
static int mei_hdcp_component_match(struct device *dev, int subcomponent,
void *data)
{
return !strcmp(dev->driver->name, "i915") &&
subcomponent == I915_COMPONENT_HDCP;
}
static int mei_hdcp_probe(struct mei_cl_device *cldev,
const struct mei_cl_device_id *id)
{
struct i915_hdcp_comp_master *comp_master;
struct component_match *master_match;
int ret;
ret = mei_cldev_enable(cldev);
if (ret < 0) {
dev_err(&cldev->dev, "mei_cldev_enable Failed. %d\n", ret);
goto enable_err_exit;
}
comp_master = kzalloc(sizeof(*comp_master), GFP_KERNEL);
if (!comp_master) {
ret = -ENOMEM;
goto err_exit;
}
master_match = NULL;
component_match_add_typed(&cldev->dev, &master_match,
mei_hdcp_component_match, comp_master);
if (IS_ERR_OR_NULL(master_match)) {
ret = -ENOMEM;
goto err_exit;
}
mei_cldev_set_drvdata(cldev, comp_master);
ret = component_master_add_with_match(&cldev->dev,
&mei_component_master_ops,
master_match);
if (ret < 0) {
dev_err(&cldev->dev, "Master comp add failed %d\n", ret);
goto err_exit;
}
return 0;
err_exit:
mei_cldev_set_drvdata(cldev, NULL);
kfree(comp_master);
mei_cldev_disable(cldev);
enable_err_exit:
return ret;
}
static int mei_hdcp_remove(struct mei_cl_device *cldev)
{
struct i915_hdcp_comp_master *comp_master =
mei_cldev_get_drvdata(cldev);
component_master_del(&cldev->dev, &mei_component_master_ops);
kfree(comp_master);
mei_cldev_set_drvdata(cldev, NULL);
return mei_cldev_disable(cldev);
}
#define MEI_UUID_HDCP GUID_INIT(0xB638AB7E, 0x94E2, 0x4EA2, 0xA5, \
0x52, 0xD1, 0xC5, 0x4B, 0x62, 0x7F, 0x04)
static struct mei_cl_device_id mei_hdcp_tbl[] = {
{ .uuid = MEI_UUID_HDCP, .version = MEI_CL_VERSION_ANY },
{ }
};
MODULE_DEVICE_TABLE(mei, mei_hdcp_tbl);
static struct mei_cl_driver mei_hdcp_driver = {
.id_table = mei_hdcp_tbl,
.name = KBUILD_MODNAME,
.probe = mei_hdcp_probe,
.remove = mei_hdcp_remove,
};
module_mei_cl_driver(mei_hdcp_driver);
MODULE_AUTHOR("Intel Corporation");
MODULE_LICENSE("GPL");
MODULE_DESCRIPTION("MEI HDCP");