kernel/drivers/gpu/drm/amd/display/modules/hdcp/hdcp_ddc.c

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2024-07-22 17:22:30 +08:00
/*
* Copyright 2019 Advanced Micro Devices, Inc.
*
* 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 COPYRIGHT HOLDER(S) OR AUTHOR(S) 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.
*
* Authors: AMD
*
*/
#include "hdcp.h"
#define MIN(a, b) ((a) < (b) ? (a) : (b))
#define HDCP_I2C_ADDR 0x3a /* 0x74 >> 1*/
#define KSV_READ_SIZE 0xf /* 0x6803b - 0x6802c */
#define HDCP_MAX_AUX_TRANSACTION_SIZE 16
#define DP_CP_IRQ (1 << 2)
enum mod_hdcp_ddc_message_id {
MOD_HDCP_MESSAGE_ID_INVALID = -1,
/* HDCP 1.4 */
MOD_HDCP_MESSAGE_ID_READ_BKSV = 0,
MOD_HDCP_MESSAGE_ID_READ_RI_R0,
MOD_HDCP_MESSAGE_ID_WRITE_AKSV,
MOD_HDCP_MESSAGE_ID_WRITE_AINFO,
MOD_HDCP_MESSAGE_ID_WRITE_AN,
MOD_HDCP_MESSAGE_ID_READ_VH_X,
MOD_HDCP_MESSAGE_ID_READ_VH_0,
MOD_HDCP_MESSAGE_ID_READ_VH_1,
MOD_HDCP_MESSAGE_ID_READ_VH_2,
MOD_HDCP_MESSAGE_ID_READ_VH_3,
MOD_HDCP_MESSAGE_ID_READ_VH_4,
MOD_HDCP_MESSAGE_ID_READ_BCAPS,
MOD_HDCP_MESSAGE_ID_READ_BSTATUS,
MOD_HDCP_MESSAGE_ID_READ_KSV_FIFO,
MOD_HDCP_MESSAGE_ID_READ_BINFO,
/* HDCP 2.2 */
MOD_HDCP_MESSAGE_ID_HDCP2VERSION,
MOD_HDCP_MESSAGE_ID_RX_CAPS,
MOD_HDCP_MESSAGE_ID_WRITE_AKE_INIT,
MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_CERT,
MOD_HDCP_MESSAGE_ID_WRITE_AKE_NO_STORED_KM,
MOD_HDCP_MESSAGE_ID_WRITE_AKE_STORED_KM,
MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_H_PRIME,
MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_PAIRING_INFO,
MOD_HDCP_MESSAGE_ID_WRITE_LC_INIT,
MOD_HDCP_MESSAGE_ID_READ_LC_SEND_L_PRIME,
MOD_HDCP_MESSAGE_ID_WRITE_SKE_SEND_EKS,
MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_SEND_RECEIVERID_LIST,
MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_SEND_RECEIVERID_LIST_PART2,
MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_SEND_ACK,
MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_STREAM_MANAGE,
MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_STREAM_READY,
MOD_HDCP_MESSAGE_ID_READ_RXSTATUS,
MOD_HDCP_MESSAGE_ID_WRITE_CONTENT_STREAM_TYPE,
MOD_HDCP_MESSAGE_ID_MAX
};
static const uint8_t hdcp_i2c_offsets[] = {
[MOD_HDCP_MESSAGE_ID_READ_BKSV] = 0x0,
[MOD_HDCP_MESSAGE_ID_READ_RI_R0] = 0x8,
[MOD_HDCP_MESSAGE_ID_WRITE_AKSV] = 0x10,
[MOD_HDCP_MESSAGE_ID_WRITE_AINFO] = 0x15,
[MOD_HDCP_MESSAGE_ID_WRITE_AN] = 0x18,
[MOD_HDCP_MESSAGE_ID_READ_VH_X] = 0x20,
[MOD_HDCP_MESSAGE_ID_READ_VH_0] = 0x20,
[MOD_HDCP_MESSAGE_ID_READ_VH_1] = 0x24,
[MOD_HDCP_MESSAGE_ID_READ_VH_2] = 0x28,
[MOD_HDCP_MESSAGE_ID_READ_VH_3] = 0x2C,
[MOD_HDCP_MESSAGE_ID_READ_VH_4] = 0x30,
[MOD_HDCP_MESSAGE_ID_READ_BCAPS] = 0x40,
[MOD_HDCP_MESSAGE_ID_READ_BSTATUS] = 0x41,
[MOD_HDCP_MESSAGE_ID_READ_KSV_FIFO] = 0x43,
[MOD_HDCP_MESSAGE_ID_READ_BINFO] = 0xFF,
[MOD_HDCP_MESSAGE_ID_HDCP2VERSION] = 0x50,
[MOD_HDCP_MESSAGE_ID_WRITE_AKE_INIT] = 0x60,
[MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_CERT] = 0x80,
[MOD_HDCP_MESSAGE_ID_WRITE_AKE_NO_STORED_KM] = 0x60,
[MOD_HDCP_MESSAGE_ID_WRITE_AKE_STORED_KM] = 0x60,
[MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_H_PRIME] = 0x80,
[MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_PAIRING_INFO] = 0x80,
[MOD_HDCP_MESSAGE_ID_WRITE_LC_INIT] = 0x60,
[MOD_HDCP_MESSAGE_ID_READ_LC_SEND_L_PRIME] = 0x80,
[MOD_HDCP_MESSAGE_ID_WRITE_SKE_SEND_EKS] = 0x60,
[MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_SEND_RECEIVERID_LIST] = 0x80,
[MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_SEND_RECEIVERID_LIST_PART2] = 0x80,
[MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_SEND_ACK] = 0x60,
[MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_STREAM_MANAGE] = 0x60,
[MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_STREAM_READY] = 0x80,
[MOD_HDCP_MESSAGE_ID_READ_RXSTATUS] = 0x70,
[MOD_HDCP_MESSAGE_ID_WRITE_CONTENT_STREAM_TYPE] = 0x0
};
static const uint32_t hdcp_dpcd_addrs[] = {
[MOD_HDCP_MESSAGE_ID_READ_BKSV] = 0x68000,
[MOD_HDCP_MESSAGE_ID_READ_RI_R0] = 0x68005,
[MOD_HDCP_MESSAGE_ID_WRITE_AKSV] = 0x68007,
[MOD_HDCP_MESSAGE_ID_WRITE_AINFO] = 0x6803B,
[MOD_HDCP_MESSAGE_ID_WRITE_AN] = 0x6800c,
[MOD_HDCP_MESSAGE_ID_READ_VH_X] = 0x68014,
[MOD_HDCP_MESSAGE_ID_READ_VH_0] = 0x68014,
[MOD_HDCP_MESSAGE_ID_READ_VH_1] = 0x68018,
[MOD_HDCP_MESSAGE_ID_READ_VH_2] = 0x6801c,
[MOD_HDCP_MESSAGE_ID_READ_VH_3] = 0x68020,
[MOD_HDCP_MESSAGE_ID_READ_VH_4] = 0x68024,
[MOD_HDCP_MESSAGE_ID_READ_BCAPS] = 0x68028,
[MOD_HDCP_MESSAGE_ID_READ_BSTATUS] = 0x68029,
[MOD_HDCP_MESSAGE_ID_READ_KSV_FIFO] = 0x6802c,
[MOD_HDCP_MESSAGE_ID_READ_BINFO] = 0x6802a,
[MOD_HDCP_MESSAGE_ID_RX_CAPS] = 0x6921d,
[MOD_HDCP_MESSAGE_ID_WRITE_AKE_INIT] = 0x69000,
[MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_CERT] = 0x6900b,
[MOD_HDCP_MESSAGE_ID_WRITE_AKE_NO_STORED_KM] = 0x69220,
[MOD_HDCP_MESSAGE_ID_WRITE_AKE_STORED_KM] = 0x692a0,
[MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_H_PRIME] = 0x692c0,
[MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_PAIRING_INFO] = 0x692e0,
[MOD_HDCP_MESSAGE_ID_WRITE_LC_INIT] = 0x692f0,
[MOD_HDCP_MESSAGE_ID_READ_LC_SEND_L_PRIME] = 0x692f8,
[MOD_HDCP_MESSAGE_ID_WRITE_SKE_SEND_EKS] = 0x69318,
[MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_SEND_RECEIVERID_LIST] = 0x69330,
[MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_SEND_RECEIVERID_LIST_PART2] = 0x69340,
[MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_SEND_ACK] = 0x693e0,
[MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_STREAM_MANAGE] = 0x693f0,
[MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_STREAM_READY] = 0x69473,
[MOD_HDCP_MESSAGE_ID_READ_RXSTATUS] = 0x69493,
[MOD_HDCP_MESSAGE_ID_WRITE_CONTENT_STREAM_TYPE] = 0x69494
};
static enum mod_hdcp_status read(struct mod_hdcp *hdcp,
enum mod_hdcp_ddc_message_id msg_id,
uint8_t *buf,
uint32_t buf_len)
{
bool success = true;
uint32_t cur_size = 0;
uint32_t data_offset = 0;
if (msg_id == MOD_HDCP_MESSAGE_ID_INVALID) {
return MOD_HDCP_STATUS_DDC_FAILURE;
}
if (is_dp_hdcp(hdcp)) {
while (buf_len > 0) {
cur_size = MIN(buf_len, HDCP_MAX_AUX_TRANSACTION_SIZE);
success = hdcp->config.ddc.funcs.read_dpcd(hdcp->config.ddc.handle,
hdcp_dpcd_addrs[msg_id] + data_offset,
buf + data_offset,
cur_size);
if (!success)
break;
buf_len -= cur_size;
data_offset += cur_size;
}
} else {
success = hdcp->config.ddc.funcs.read_i2c(
hdcp->config.ddc.handle,
HDCP_I2C_ADDR,
hdcp_i2c_offsets[msg_id],
buf,
(uint32_t)buf_len);
}
return success ? MOD_HDCP_STATUS_SUCCESS : MOD_HDCP_STATUS_DDC_FAILURE;
}
static enum mod_hdcp_status read_repeatedly(struct mod_hdcp *hdcp,
enum mod_hdcp_ddc_message_id msg_id,
uint8_t *buf,
uint32_t buf_len,
uint8_t read_size)
{
enum mod_hdcp_status status = MOD_HDCP_STATUS_DDC_FAILURE;
uint32_t cur_size = 0;
uint32_t data_offset = 0;
while (buf_len > 0) {
cur_size = MIN(buf_len, read_size);
status = read(hdcp, msg_id, buf + data_offset, cur_size);
if (status != MOD_HDCP_STATUS_SUCCESS)
break;
buf_len -= cur_size;
data_offset += cur_size;
}
return status;
}
static enum mod_hdcp_status write(struct mod_hdcp *hdcp,
enum mod_hdcp_ddc_message_id msg_id,
uint8_t *buf,
uint32_t buf_len)
{
bool success = true;
uint32_t cur_size = 0;
uint32_t data_offset = 0;
if (msg_id == MOD_HDCP_MESSAGE_ID_INVALID) {
return MOD_HDCP_STATUS_DDC_FAILURE;
}
if (is_dp_hdcp(hdcp)) {
while (buf_len > 0) {
cur_size = MIN(buf_len, HDCP_MAX_AUX_TRANSACTION_SIZE);
success = hdcp->config.ddc.funcs.write_dpcd(
hdcp->config.ddc.handle,
hdcp_dpcd_addrs[msg_id] + data_offset,
buf + data_offset,
cur_size);
if (!success)
break;
buf_len -= cur_size;
data_offset += cur_size;
}
} else {
hdcp->buf[0] = hdcp_i2c_offsets[msg_id];
memmove(&hdcp->buf[1], buf, buf_len);
success = hdcp->config.ddc.funcs.write_i2c(
hdcp->config.ddc.handle,
HDCP_I2C_ADDR,
hdcp->buf,
(uint32_t)(buf_len+1));
}
return success ? MOD_HDCP_STATUS_SUCCESS : MOD_HDCP_STATUS_DDC_FAILURE;
}
enum mod_hdcp_status mod_hdcp_read_bksv(struct mod_hdcp *hdcp)
{
return read(hdcp, MOD_HDCP_MESSAGE_ID_READ_BKSV,
hdcp->auth.msg.hdcp1.bksv,
sizeof(hdcp->auth.msg.hdcp1.bksv));
}
enum mod_hdcp_status mod_hdcp_read_bcaps(struct mod_hdcp *hdcp)
{
return read(hdcp, MOD_HDCP_MESSAGE_ID_READ_BCAPS,
&hdcp->auth.msg.hdcp1.bcaps,
sizeof(hdcp->auth.msg.hdcp1.bcaps));
}
enum mod_hdcp_status mod_hdcp_read_bstatus(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_BSTATUS,
(uint8_t *)&hdcp->auth.msg.hdcp1.bstatus,
1);
else
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_BSTATUS,
(uint8_t *)&hdcp->auth.msg.hdcp1.bstatus,
sizeof(hdcp->auth.msg.hdcp1.bstatus));
return status;
}
enum mod_hdcp_status mod_hdcp_read_r0p(struct mod_hdcp *hdcp)
{
return read(hdcp, MOD_HDCP_MESSAGE_ID_READ_RI_R0,
(uint8_t *)&hdcp->auth.msg.hdcp1.r0p,
sizeof(hdcp->auth.msg.hdcp1.r0p));
}
/* special case, reading repeatedly at the same address, don't use read() */
enum mod_hdcp_status mod_hdcp_read_ksvlist(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = read_repeatedly(hdcp, MOD_HDCP_MESSAGE_ID_READ_KSV_FIFO,
hdcp->auth.msg.hdcp1.ksvlist,
hdcp->auth.msg.hdcp1.ksvlist_size,
KSV_READ_SIZE);
else
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_KSV_FIFO,
(uint8_t *)&hdcp->auth.msg.hdcp1.ksvlist,
hdcp->auth.msg.hdcp1.ksvlist_size);
return status;
}
enum mod_hdcp_status mod_hdcp_read_vp(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_VH_0,
&hdcp->auth.msg.hdcp1.vp[0], 4);
if (status != MOD_HDCP_STATUS_SUCCESS)
goto out;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_VH_1,
&hdcp->auth.msg.hdcp1.vp[4], 4);
if (status != MOD_HDCP_STATUS_SUCCESS)
goto out;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_VH_2,
&hdcp->auth.msg.hdcp1.vp[8], 4);
if (status != MOD_HDCP_STATUS_SUCCESS)
goto out;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_VH_3,
&hdcp->auth.msg.hdcp1.vp[12], 4);
if (status != MOD_HDCP_STATUS_SUCCESS)
goto out;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_VH_4,
&hdcp->auth.msg.hdcp1.vp[16], 4);
out:
return status;
}
enum mod_hdcp_status mod_hdcp_read_binfo(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_BINFO,
(uint8_t *)&hdcp->auth.msg.hdcp1.binfo_dp,
sizeof(hdcp->auth.msg.hdcp1.binfo_dp));
else
status = MOD_HDCP_STATUS_INVALID_OPERATION;
return status;
}
enum mod_hdcp_status mod_hdcp_write_aksv(struct mod_hdcp *hdcp)
{
return write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_AKSV,
hdcp->auth.msg.hdcp1.aksv,
sizeof(hdcp->auth.msg.hdcp1.aksv));
}
enum mod_hdcp_status mod_hdcp_write_ainfo(struct mod_hdcp *hdcp)
{
return write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_AINFO,
&hdcp->auth.msg.hdcp1.ainfo,
sizeof(hdcp->auth.msg.hdcp1.ainfo));
}
enum mod_hdcp_status mod_hdcp_write_an(struct mod_hdcp *hdcp)
{
return write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_AN,
hdcp->auth.msg.hdcp1.an,
sizeof(hdcp->auth.msg.hdcp1.an));
}
enum mod_hdcp_status mod_hdcp_read_hdcp2version(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = MOD_HDCP_STATUS_INVALID_OPERATION;
else
status = read(hdcp, MOD_HDCP_MESSAGE_ID_HDCP2VERSION,
&hdcp->auth.msg.hdcp2.hdcp2version_hdmi,
sizeof(hdcp->auth.msg.hdcp2.hdcp2version_hdmi));
return status;
}
enum mod_hdcp_status mod_hdcp_read_rxcaps(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (!is_dp_hdcp(hdcp))
status = MOD_HDCP_STATUS_INVALID_OPERATION;
else
status = read(hdcp, MOD_HDCP_MESSAGE_ID_RX_CAPS,
hdcp->auth.msg.hdcp2.rxcaps_dp,
sizeof(hdcp->auth.msg.hdcp2.rxcaps_dp));
return status;
}
enum mod_hdcp_status mod_hdcp_read_rxstatus(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp)) {
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_RXSTATUS,
&hdcp->auth.msg.hdcp2.rxstatus_dp,
1);
} else {
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_RXSTATUS,
(uint8_t *)&hdcp->auth.msg.hdcp2.rxstatus,
sizeof(hdcp->auth.msg.hdcp2.rxstatus));
}
return status;
}
enum mod_hdcp_status mod_hdcp_read_ake_cert(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp)) {
hdcp->auth.msg.hdcp2.ake_cert[0] = HDCP_2_2_AKE_SEND_CERT;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_CERT,
hdcp->auth.msg.hdcp2.ake_cert+1,
sizeof(hdcp->auth.msg.hdcp2.ake_cert)-1);
} else {
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_CERT,
hdcp->auth.msg.hdcp2.ake_cert,
sizeof(hdcp->auth.msg.hdcp2.ake_cert));
}
return status;
}
enum mod_hdcp_status mod_hdcp_read_h_prime(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp)) {
hdcp->auth.msg.hdcp2.ake_h_prime[0] = HDCP_2_2_AKE_SEND_HPRIME;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_H_PRIME,
hdcp->auth.msg.hdcp2.ake_h_prime+1,
sizeof(hdcp->auth.msg.hdcp2.ake_h_prime)-1);
} else {
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_H_PRIME,
hdcp->auth.msg.hdcp2.ake_h_prime,
sizeof(hdcp->auth.msg.hdcp2.ake_h_prime));
}
return status;
}
enum mod_hdcp_status mod_hdcp_read_pairing_info(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp)) {
hdcp->auth.msg.hdcp2.ake_pairing_info[0] = HDCP_2_2_AKE_SEND_PAIRING_INFO;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_PAIRING_INFO,
hdcp->auth.msg.hdcp2.ake_pairing_info+1,
sizeof(hdcp->auth.msg.hdcp2.ake_pairing_info)-1);
} else {
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_AKE_SEND_PAIRING_INFO,
hdcp->auth.msg.hdcp2.ake_pairing_info,
sizeof(hdcp->auth.msg.hdcp2.ake_pairing_info));
}
return status;
}
enum mod_hdcp_status mod_hdcp_read_l_prime(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp)) {
hdcp->auth.msg.hdcp2.lc_l_prime[0] = HDCP_2_2_LC_SEND_LPRIME;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_LC_SEND_L_PRIME,
hdcp->auth.msg.hdcp2.lc_l_prime+1,
sizeof(hdcp->auth.msg.hdcp2.lc_l_prime)-1);
} else {
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_LC_SEND_L_PRIME,
hdcp->auth.msg.hdcp2.lc_l_prime,
sizeof(hdcp->auth.msg.hdcp2.lc_l_prime));
}
return status;
}
enum mod_hdcp_status mod_hdcp_read_rx_id_list(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status = MOD_HDCP_STATUS_SUCCESS;
if (is_dp_hdcp(hdcp)) {
uint32_t device_count = 0;
uint32_t rx_id_list_size = 0;
uint32_t bytes_read = 0;
hdcp->auth.msg.hdcp2.rx_id_list[0] = HDCP_2_2_REP_SEND_RECVID_LIST;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_SEND_RECEIVERID_LIST,
hdcp->auth.msg.hdcp2.rx_id_list+1,
HDCP_MAX_AUX_TRANSACTION_SIZE);
if (status == MOD_HDCP_STATUS_SUCCESS) {
bytes_read = HDCP_MAX_AUX_TRANSACTION_SIZE;
device_count = HDCP_2_2_DEV_COUNT_LO(hdcp->auth.msg.hdcp2.rx_id_list[2]) +
(HDCP_2_2_DEV_COUNT_HI(hdcp->auth.msg.hdcp2.rx_id_list[1]) << 4);
rx_id_list_size = MIN((21 + 5 * device_count),
(sizeof(hdcp->auth.msg.hdcp2.rx_id_list) - 1));
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_SEND_RECEIVERID_LIST_PART2,
hdcp->auth.msg.hdcp2.rx_id_list + 1 + bytes_read,
(rx_id_list_size - 1) / HDCP_MAX_AUX_TRANSACTION_SIZE * HDCP_MAX_AUX_TRANSACTION_SIZE);
}
} else {
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_SEND_RECEIVERID_LIST,
hdcp->auth.msg.hdcp2.rx_id_list,
hdcp->auth.msg.hdcp2.rx_id_list_size);
}
return status;
}
enum mod_hdcp_status mod_hdcp_read_stream_ready(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp)) {
hdcp->auth.msg.hdcp2.repeater_auth_stream_ready[0] = HDCP_2_2_REP_STREAM_READY;
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_STREAM_READY,
hdcp->auth.msg.hdcp2.repeater_auth_stream_ready+1,
sizeof(hdcp->auth.msg.hdcp2.repeater_auth_stream_ready)-1);
} else {
status = read(hdcp, MOD_HDCP_MESSAGE_ID_READ_REPEATER_AUTH_STREAM_READY,
hdcp->auth.msg.hdcp2.repeater_auth_stream_ready,
sizeof(hdcp->auth.msg.hdcp2.repeater_auth_stream_ready));
}
return status;
}
enum mod_hdcp_status mod_hdcp_write_ake_init(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_AKE_INIT,
hdcp->auth.msg.hdcp2.ake_init+1,
sizeof(hdcp->auth.msg.hdcp2.ake_init)-1);
else
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_AKE_INIT,
hdcp->auth.msg.hdcp2.ake_init,
sizeof(hdcp->auth.msg.hdcp2.ake_init));
return status;
}
enum mod_hdcp_status mod_hdcp_write_no_stored_km(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_AKE_NO_STORED_KM,
hdcp->auth.msg.hdcp2.ake_no_stored_km+1,
sizeof(hdcp->auth.msg.hdcp2.ake_no_stored_km)-1);
else
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_AKE_NO_STORED_KM,
hdcp->auth.msg.hdcp2.ake_no_stored_km,
sizeof(hdcp->auth.msg.hdcp2.ake_no_stored_km));
return status;
}
enum mod_hdcp_status mod_hdcp_write_stored_km(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_AKE_STORED_KM,
hdcp->auth.msg.hdcp2.ake_stored_km+1,
sizeof(hdcp->auth.msg.hdcp2.ake_stored_km)-1);
else
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_AKE_STORED_KM,
hdcp->auth.msg.hdcp2.ake_stored_km,
sizeof(hdcp->auth.msg.hdcp2.ake_stored_km));
return status;
}
enum mod_hdcp_status mod_hdcp_write_lc_init(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_LC_INIT,
hdcp->auth.msg.hdcp2.lc_init+1,
sizeof(hdcp->auth.msg.hdcp2.lc_init)-1);
else
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_LC_INIT,
hdcp->auth.msg.hdcp2.lc_init,
sizeof(hdcp->auth.msg.hdcp2.lc_init));
return status;
}
enum mod_hdcp_status mod_hdcp_write_eks(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = write(hdcp,
MOD_HDCP_MESSAGE_ID_WRITE_SKE_SEND_EKS,
hdcp->auth.msg.hdcp2.ske_eks+1,
sizeof(hdcp->auth.msg.hdcp2.ske_eks)-1);
else
status = write(hdcp,
MOD_HDCP_MESSAGE_ID_WRITE_SKE_SEND_EKS,
hdcp->auth.msg.hdcp2.ske_eks,
sizeof(hdcp->auth.msg.hdcp2.ske_eks));
return status;
}
enum mod_hdcp_status mod_hdcp_write_repeater_auth_ack(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_SEND_ACK,
hdcp->auth.msg.hdcp2.repeater_auth_ack+1,
sizeof(hdcp->auth.msg.hdcp2.repeater_auth_ack)-1);
else
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_SEND_ACK,
hdcp->auth.msg.hdcp2.repeater_auth_ack,
sizeof(hdcp->auth.msg.hdcp2.repeater_auth_ack));
return status;
}
enum mod_hdcp_status mod_hdcp_write_stream_manage(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = write(hdcp,
MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_STREAM_MANAGE,
hdcp->auth.msg.hdcp2.repeater_auth_stream_manage+1,
hdcp->auth.msg.hdcp2.stream_manage_size-1);
else
status = write(hdcp,
MOD_HDCP_MESSAGE_ID_WRITE_REPEATER_AUTH_STREAM_MANAGE,
hdcp->auth.msg.hdcp2.repeater_auth_stream_manage,
hdcp->auth.msg.hdcp2.stream_manage_size);
return status;
}
enum mod_hdcp_status mod_hdcp_write_content_type(struct mod_hdcp *hdcp)
{
enum mod_hdcp_status status;
if (is_dp_hdcp(hdcp))
status = write(hdcp, MOD_HDCP_MESSAGE_ID_WRITE_CONTENT_STREAM_TYPE,
hdcp->auth.msg.hdcp2.content_stream_type_dp+1,
sizeof(hdcp->auth.msg.hdcp2.content_stream_type_dp)-1);
else
status = MOD_HDCP_STATUS_INVALID_OPERATION;
return status;
}
enum mod_hdcp_status mod_hdcp_clear_cp_irq_status(struct mod_hdcp *hdcp)
{
uint8_t clear_cp_irq_bit = DP_CP_IRQ;
uint32_t size = 1;
if (is_dp_hdcp(hdcp)) {
uint32_t cp_irq_addrs = (hdcp->connection.link.dp.rev >= 0x14)
? DP_DEVICE_SERVICE_IRQ_VECTOR_ESI0:DP_DEVICE_SERVICE_IRQ_VECTOR;
return hdcp->config.ddc.funcs.write_dpcd(hdcp->config.ddc.handle, cp_irq_addrs,
&clear_cp_irq_bit, size) ? MOD_HDCP_STATUS_SUCCESS : MOD_HDCP_STATUS_DDC_FAILURE;
}
return MOD_HDCP_STATUS_INVALID_OPERATION;
}