// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2020 Rockchip Electronics Co. Ltd.
*
* Author: Shunqing Chen <csq@rock-chips.com>
*/
#include <linux/delay.h>
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/soc/rockchip/rk_vendor_storage.h>
#include <linux/slab.h>
#include "rk628.h"
#include "rk628_combrxphy.h"
#include "rk628_cru.h"
#include "rk628_hdmirx.h"
#define INIT_FIFO_STATE 64
#define is_validfs(x) (x == 32000 || \
x == 44100 || \
x == 48000 || \
x == 88200 || \
x == 96000 || \
x == 176400 || \
x == 192000 || \
x == 768000)
struct rk628_audiostate {
u32 hdmirx_aud_clkrate;
u32 fs_audio;
u32 ctsn_flag;
u32 fifo_flag;
int init_state;
int pre_state;
bool fifo_int;
bool audio_enable;
};
struct rk628_audioinfo {
struct delayed_work delayed_work_audio_rate_change;
struct delayed_work delayed_work_audio;
struct mutex *confctl_mutex;
struct rk628 *rk628;
struct rk628_audiostate audio_state;
bool i2s_enabled_default;
bool i2s_enabled;
int debug;
bool fifo_ints_en;
bool ctsn_ints_en;
bool audio_present;
struct device *dev;
};
static int hdcp_load_keys_cb(struct rk628 *rk628, struct rk628_hdcp *hdcp)
{
int size;
u8 hdcp_vendor_data[320];
hdcp->keys = kmalloc(HDCP_KEY_SIZE, GFP_KERNEL);
if (!hdcp->keys)
return -ENOMEM;
hdcp->seeds = kmalloc(HDCP_KEY_SEED_SIZE, GFP_KERNEL);
if (!hdcp->seeds) {
kfree(hdcp->keys);
hdcp->keys = NULL;
return -ENOMEM;
}
size = rk_vendor_read(HDMIRX_HDCP1X_ID, hdcp_vendor_data, 314);
if (size < (HDCP_KEY_SIZE + HDCP_KEY_SEED_SIZE)) {
dev_dbg(rk628->dev, "HDCP: read size %d\n", size);
kfree(hdcp->keys);
hdcp->keys = NULL;
kfree(hdcp->seeds);
hdcp->seeds = NULL;
return -EINVAL;
}
memcpy(hdcp->keys, hdcp_vendor_data, HDCP_KEY_SIZE);
memcpy(hdcp->seeds, hdcp_vendor_data + HDCP_KEY_SIZE,
HDCP_KEY_SEED_SIZE);
return 0;
}
static int rk628_hdmi_hdcp_load_key(struct rk628 *rk628, struct rk628_hdcp *hdcp)
{
int i;
int ret;
struct hdcp_keys *hdcp_keys;
u32 seeds = 0;
if (!hdcp->keys) {
ret = hdcp_load_keys_cb(rk628, hdcp);
if (ret) {
dev_err(rk628->dev, "HDCP: load key failed\n");
return ret;
}
}
hdcp_keys = hdcp->keys;
rk628_i2c_update_bits(rk628, HDMI_RX_HDCP_CTRL,
HDCP_ENABLE_MASK |
HDCP_ENC_EN_MASK,
HDCP_ENABLE(0) |
HDCP_ENC_EN(0));
rk628_i2c_update_bits(rk628, GRF_SYSTEM_CON0,
SW_ADAPTER_I2CSLADR_MASK |
SW_EFUSE_HDCP_EN_MASK,
SW_ADAPTER_I2CSLADR(0) |
SW_EFUSE_HDCP_EN(1));
/* The useful data in ksv should be 5 byte */
for (i = 0; i < KSV_LEN; i++)
rk628_i2c_write(rk628, HDCP_KEY_KSV0 + i * 4,
hdcp_keys->KSV[i]);
for (i = 0; i < HDCP_PRIVATE_KEY_SIZE; i++)
rk628_i2c_write(rk628, HDCP_KEY_DPK0 + i * 4,
hdcp_keys->devicekey[i]);
rk628_i2c_update_bits(rk628, GRF_SYSTEM_CON0,
SW_ADAPTER_I2CSLADR_MASK |
SW_EFUSE_HDCP_EN_MASK,
SW_ADAPTER_I2CSLADR(0) |
SW_EFUSE_HDCP_EN(0));
rk628_i2c_update_bits(rk628, HDMI_RX_HDCP_CTRL,
HDCP_ENABLE_MASK |
HDCP_ENC_EN_MASK,
HDCP_ENABLE(1) |
HDCP_ENC_EN(1));
/* Enable decryption logic */
if (hdcp->seeds) {
seeds = (hdcp->seeds[0] & 0xff) << 8;
seeds |= (hdcp->seeds[1] & 0xff);
}
if (seeds) {
rk628_i2c_update_bits(rk628, HDMI_RX_HDCP_CTRL,
KEY_DECRIPT_ENABLE_MASK,
KEY_DECRIPT_ENABLE(1));
rk628_i2c_write(rk628, HDMI_RX_HDCP_SEED, seeds);
} else {
rk628_i2c_update_bits(rk628, HDMI_RX_HDCP_CTRL,
KEY_DECRIPT_ENABLE_MASK,
KEY_DECRIPT_ENABLE(0));
}
return 0;
}
void rk628_hdmirx_set_hdcp(struct rk628 *rk628, struct rk628_hdcp *hdcp, bool en)
{
dev_dbg(rk628->dev, "%s: %sable\n", __func__, en ? "en" : "dis");
if (en) {
rk628_hdmi_hdcp_load_key(rk628, hdcp);
} else {
rk628_i2c_update_bits(rk628, HDMI_RX_HDCP_CTRL,
HDCP_ENABLE_MASK |
HDCP_ENC_EN_MASK,
HDCP_ENABLE(0) |
HDCP_ENC_EN(0));
}
}
EXPORT_SYMBOL(rk628_hdmirx_set_hdcp);
void rk628_hdmirx_controller_setup(struct rk628 *rk628)
{
rk628_i2c_write(rk628, HDMI_RX_HDMI20_CONTROL, 0x10000f10);
rk628_i2c_write(rk628, HDMI_RX_HDMI_MODE_RECOVER, 0x00000021);
rk628_i2c_write(rk628, HDMI_RX_PDEC_CTRL, 0xbfff8011);
rk628_i2c_write(rk628, HDMI_RX_PDEC_ASP_CTRL, 0x00000040);
rk628_i2c_write(rk628, HDMI_RX_HDMI_RESMPL_CTRL, 0x00000001);
rk628_i2c_write(rk628, HDMI_RX_HDMI_SYNC_CTRL, 0x00000014);
rk628_i2c_write(rk628, HDMI_RX_PDEC_ERR_FILTER, 0x00000008);
rk628_i2c_write(rk628, HDMI_RX_SCDC_I2CCONFIG, 0x01000000);
rk628_i2c_write(rk628, HDMI_RX_SCDC_CONFIG, 0x00000001);
rk628_i2c_write(rk628, HDMI_RX_SCDC_WRDATA0, 0xabcdef01);
rk628_i2c_write(rk628, HDMI_RX_CHLOCK_CONFIG, 0x0030c15c);
rk628_i2c_write(rk628, HDMI_RX_HDMI_ERROR_PROTECT, 0x000d0c98);
rk628_i2c_write(rk628, HDMI_RX_MD_HCTRL1, 0x00000010);
rk628_i2c_write(rk628, HDMI_RX_MD_HCTRL2, 0x00001738);
rk628_i2c_write(rk628, HDMI_RX_MD_VCTRL, 0x00000002);
rk628_i2c_write(rk628, HDMI_RX_MD_VTH, 0x0000073a);
rk628_i2c_write(rk628, HDMI_RX_MD_IL_POL, 0x00000004);
rk628_i2c_write(rk628, HDMI_RX_PDEC_ACRM_CTRL, 0x00000000);
rk628_i2c_write(rk628, HDMI_RX_HDMI_DCM_CTRL, 0x00040414);
rk628_i2c_write(rk628, HDMI_RX_HDMI_CKM_EVLTM, 0x00103e70);
rk628_i2c_write(rk628, HDMI_RX_HDMI_CKM_F, 0x0c1c0b54);
rk628_i2c_write(rk628, HDMI_RX_HDMI_RESMPL_CTRL, 0x00000001);
rk628_i2c_update_bits(rk628, HDMI_RX_HDCP_SETTINGS,
HDMI_RESERVED_MASK |
FAST_I2C_MASK |
ONE_DOT_ONE_MASK |
FAST_REAUTH_MASK,
HDMI_RESERVED(1) |
FAST_I2C(0) |
ONE_DOT_ONE(0) |
FAST_REAUTH(0));
}
EXPORT_SYMBOL(rk628_hdmirx_controller_setup);
static void rk628_hdmirx_audio_fifo_init(struct rk628_audioinfo *aif)
{
dev_dbg(aif->dev, "%s initial fifo\n", __func__);
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_ICLR, 0x1f);
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_CTRL, 0x10001);
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_CTRL, 0x10000);
aif->audio_state.pre_state = aif->audio_state.init_state = INIT_FIFO_STATE*4;
}
static void rk628_hdmirx_audio_fifo_initd(struct rk628_audioinfo *aif)
{
dev_dbg(aif->dev, "%s double initial fifo\n", __func__);
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_ICLR, 0x1f);
rk628_i2c_update_bits(aif->rk628, HDMI_RX_AUD_FIFO_TH,
AFIF_TH_START_MASK,
AFIF_TH_START(192));
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_CTRL, 0x10001);
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_CTRL, 0x10000);
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_CTRL, 0x10001);
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_CTRL, 0x10000);
rk628_i2c_update_bits(aif->rk628, HDMI_RX_AUD_FIFO_TH,
AFIF_TH_START_MASK,
AFIF_TH_START(INIT_FIFO_STATE));
aif->audio_state.pre_state = aif->audio_state.init_state = INIT_FIFO_STATE*4;
}
static u32 _rk628_hdmirx_audio_fs(struct rk628_audioinfo *aif)
{
u64 tmdsclk = 0;
u32 clkrate = 0, cts_decoded = 0, n_decoded = 0, fs_audio = 0;
/* fout=128*fs=ftmds*N/CTS */
rk628_i2c_read(aif->rk628, HDMI_RX_HDMI_CKM_RESULT, &clkrate);
clkrate = clkrate & 0xffff;
/* tmdsclk = (clkrate/1000) * 49500000 */
tmdsclk = clkrate * (49500000 / 1000);
rk628_i2c_read(aif->rk628, HDMI_RX_PDEC_ACR_CTS, &cts_decoded);
rk628_i2c_read(aif->rk628, HDMI_RX_PDEC_ACR_N, &n_decoded);
if (cts_decoded != 0) {
fs_audio = div_u64((tmdsclk * n_decoded), cts_decoded);
fs_audio /= 128;
fs_audio = div_u64(fs_audio + 50, 100);
fs_audio *= 100;
}
dev_dbg(aif->dev,
"%s: clkrate:%u tmdsclk:%llu, n_decoded:%u, cts_decoded:%u, fs_audio:%u\n",
__func__, clkrate, tmdsclk, n_decoded, cts_decoded, fs_audio);
if (!is_validfs(fs_audio))
fs_audio = 0;
return fs_audio;
}
static void rk628_hdmirx_audio_clk_set_rate(struct rk628_audioinfo *aif, u32 rate)
{
dev_dbg(aif->dev, "%s: %u to %u\n",
__func__, aif->audio_state.hdmirx_aud_clkrate, rate);
rk628_clk_set_rate(aif->rk628, CGU_CLK_HDMIRX_AUD, rate);
aif->audio_state.hdmirx_aud_clkrate = rate;
}
static void rk628_hdmirx_audio_clk_inc_rate(struct rk628_audioinfo *aif, int dis)
{
u32 hdmirx_aud_clkrate = aif->audio_state.hdmirx_aud_clkrate + dis;
dev_dbg(aif->dev, "%s: %u to %u\n",
__func__, aif->audio_state.hdmirx_aud_clkrate, hdmirx_aud_clkrate);
rk628_clk_set_rate(aif->rk628, CGU_CLK_HDMIRX_AUD, hdmirx_aud_clkrate);
aif->audio_state.hdmirx_aud_clkrate = hdmirx_aud_clkrate;
}
static void rk628_hdmirx_audio_set_fs(struct rk628_audioinfo *aif, u32 fs_audio)
{
u32 hdmirx_aud_clkrate_t = fs_audio*128;
dev_dbg(aif->dev, "%s: %u to %u with fs %u\n", __func__,
aif->audio_state.hdmirx_aud_clkrate, hdmirx_aud_clkrate_t,
fs_audio);
rk628_clk_set_rate(aif->rk628, CGU_CLK_HDMIRX_AUD, hdmirx_aud_clkrate_t);
aif->audio_state.hdmirx_aud_clkrate = hdmirx_aud_clkrate_t;
aif->audio_state.fs_audio = fs_audio;
}
static void rk628_hdmirx_audio_enable(struct rk628_audioinfo *aif)
{
u32 fifo_ints;
rk628_i2c_read(aif->rk628, HDMI_RX_AUD_FIFO_ISTS, &fifo_ints);
dev_dbg(aif->dev, "%s fifo ints %#x\n", __func__, fifo_ints);
if ((fifo_ints & 0x18) == 0x18)
rk628_hdmirx_audio_fifo_initd(aif);
else if (fifo_ints & 0x18)
rk628_hdmirx_audio_fifo_init(aif);
rk628_i2c_update_bits(aif->rk628, HDMI_RX_DMI_DISABLE_IF,
AUD_ENABLE_MASK, AUD_ENABLE(1));
aif->audio_state.audio_enable = true;
aif->fifo_ints_en = true;
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_IEN_SET,
AFIF_OVERFL_ISTS | AFIF_UNDERFL_ISTS);
}
static void rk628_csi_delayed_work_audio(struct work_struct *work)
{
struct delayed_work *dwork = to_delayed_work(work);
struct rk628_audioinfo *aif = container_of(dwork, struct rk628_audioinfo,
delayed_work_audio);
struct rk628_audiostate *audio_state = &aif->audio_state;
u32 fs_audio;
int cur_state, init_state, pre_state;
init_state = audio_state->init_state;
pre_state = audio_state->pre_state;
fs_audio = _rk628_hdmirx_audio_fs(aif);
if (!is_validfs(fs_audio)) {
dev_dbg(aif->dev, "%s: no supported fs(%u)\n", __func__, fs_audio);
goto exit;
}
if (!audio_state->audio_enable) {
rk628_hdmirx_audio_set_fs(aif, fs_audio);
rk628_hdmirx_audio_enable(aif);
goto exit;
}
if (abs(fs_audio - audio_state->fs_audio) > 1000)
rk628_hdmirx_audio_set_fs(aif, fs_audio);
rk628_i2c_read(aif->rk628, HDMI_RX_AUD_FIFO_FILLSTS1, &cur_state);
dev_dbg(aif->dev, "%s: HDMI_RX_AUD_FIFO_FILLSTS1:%#x, single offset:%d, total offset:%d\n",
__func__, cur_state, cur_state - pre_state, cur_state - init_state);
if (cur_state != 0)
aif->audio_present = true;
else
aif->audio_present = false;
if ((cur_state - init_state) > 16 && (cur_state - pre_state) > 0)
rk628_hdmirx_audio_clk_inc_rate(aif, 10);
else if ((cur_state != 0) && (cur_state - init_state) < -16 && (cur_state - pre_state) < 0)
rk628_hdmirx_audio_clk_inc_rate(aif, -10);
audio_state->pre_state = cur_state;
exit:
schedule_delayed_work(&aif->delayed_work_audio, msecs_to_jiffies(1000));
}
static void rk628_csi_delayed_work_audio_rate_change(struct work_struct *work)
{
u32 fifo_fillsts;
u32 fs_audio;
struct delayed_work *dwork = to_delayed_work(work);
struct rk628_audioinfo *aif = container_of(dwork, struct rk628_audioinfo,
delayed_work_audio_rate_change);
mutex_lock(aif->confctl_mutex);
fs_audio = _rk628_hdmirx_audio_fs(aif);
dev_dbg(aif->dev, "%s get audio fs %u\n", __func__, fs_audio);
if (aif->audio_state.ctsn_flag == (ACR_N_CHG_ICLR | ACR_CTS_CHG_ICLR)) {
aif->audio_state.ctsn_flag = 0;
if (is_validfs(fs_audio)) {
rk628_hdmirx_audio_set_fs(aif, fs_audio);
/* We start audio work after recieveing cts n interrupt */
rk628_hdmirx_audio_enable(aif);
} else {
dev_dbg(aif->dev, "%s invalid fs when ctsn updating\n", __func__);
}
schedule_delayed_work(&aif->delayed_work_audio, msecs_to_jiffies(1000));
}
if (aif->audio_state.fifo_int) {
aif->audio_state.fifo_int = false;
if (is_validfs(fs_audio))
rk628_hdmirx_audio_set_fs(aif, fs_audio);
rk628_i2c_read(aif->rk628, HDMI_RX_AUD_FIFO_FILLSTS1, &fifo_fillsts);
if (!fifo_fillsts) {
dev_dbg(aif->dev, "%s underflow after overflow\n", __func__);
rk628_hdmirx_audio_fifo_initd(aif);
} else {
dev_dbg(aif->dev, "%s overflow after underflow\n", __func__);
rk628_hdmirx_audio_fifo_initd(aif);
}
}
mutex_unlock(aif->confctl_mutex);
}
HAUDINFO rk628_hdmirx_audioinfo_alloc(struct device *dev,
struct mutex *confctl_mutex,
struct rk628 *rk628,
bool en)
{
struct rk628_audioinfo *aif;
aif = devm_kzalloc(dev, sizeof(*aif), GFP_KERNEL);
if (!aif)
return NULL;
INIT_DELAYED_WORK(&aif->delayed_work_audio_rate_change,
rk628_csi_delayed_work_audio_rate_change);
INIT_DELAYED_WORK(&aif->delayed_work_audio,
rk628_csi_delayed_work_audio);
aif->confctl_mutex = confctl_mutex;
aif->rk628 = rk628;
aif->i2s_enabled_default = en;
aif->dev = dev;
return aif;
}
EXPORT_SYMBOL(rk628_hdmirx_audioinfo_alloc);
void rk628_hdmirx_audio_cancel_work_audio(HAUDINFO info, bool sync)
{
struct rk628_audioinfo *aif = (struct rk628_audioinfo *)info;
if (sync)
cancel_delayed_work_sync(&aif->delayed_work_audio);
else
cancel_delayed_work(&aif->delayed_work_audio);
}
EXPORT_SYMBOL(rk628_hdmirx_audio_cancel_work_audio);
void rk628_hdmirx_audio_cancel_work_rate_change(HAUDINFO info, bool sync)
{
struct rk628_audioinfo *aif = (struct rk628_audioinfo *)info;
if (sync)
cancel_delayed_work_sync(&aif->delayed_work_audio_rate_change);
else
cancel_delayed_work(&aif->delayed_work_audio_rate_change);
}
EXPORT_SYMBOL(rk628_hdmirx_audio_cancel_work_rate_change);
void rk628_hdmirx_audio_destroy(HAUDINFO info)
{
struct rk628_audioinfo *aif = (struct rk628_audioinfo *)info;
if (!aif)
return;
rk628_hdmirx_audio_cancel_work_audio(aif, true);
rk628_hdmirx_audio_cancel_work_rate_change(aif, true);
aif->confctl_mutex = NULL;
aif->rk628 = NULL;
}
EXPORT_SYMBOL(rk628_hdmirx_audio_destroy);
bool rk628_hdmirx_audio_present(HAUDINFO info)
{
struct rk628_audioinfo *aif = (struct rk628_audioinfo *)info;
if (!aif)
return false;
return aif->audio_present;
}
EXPORT_SYMBOL(rk628_hdmirx_audio_present);
int rk628_hdmirx_audio_fs(HAUDINFO info)
{
struct rk628_audioinfo *aif = (struct rk628_audioinfo *)info;
if (!aif)
return 0;
return aif->audio_state.fs_audio;
}
EXPORT_SYMBOL(rk628_hdmirx_audio_fs);
void rk628_hdmirx_audio_i2s_ctrl(HAUDINFO info, bool enable)
{
struct rk628_audioinfo *aif = (struct rk628_audioinfo *)info;
if (enable == aif->i2s_enabled)
return;
if (enable) {
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_SAO_CTRL,
I2S_LPCM_BPCUV(0) |
I2S_32_16(1));
} else {
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_SAO_CTRL,
I2S_LPCM_BPCUV(0) |
I2S_32_16(1) |
I2S_ENABLE_BITS(0x3f));
}
aif->i2s_enabled = enable;
}
EXPORT_SYMBOL(rk628_hdmirx_audio_i2s_ctrl);
void rk628_hdmirx_audio_setup(HAUDINFO info)
{
struct rk628_audioinfo *aif = (struct rk628_audioinfo *)info;
u32 audio_pll_n, audio_pll_cts;
dev_dbg(aif->dev, "%s: setup audio\n", __func__);
audio_pll_n = 5644;
audio_pll_cts = 148500;
aif->audio_state.ctsn_flag = 0;
aif->audio_state.fs_audio = 0;
aif->audio_state.pre_state = 0;
aif->audio_state.init_state = INIT_FIFO_STATE*4;
aif->audio_state.fifo_int = false;
aif->audio_state.audio_enable = false;
aif->fifo_ints_en = false;
aif->ctsn_ints_en = false;
aif->i2s_enabled = false;
rk628_hdmirx_audio_clk_set_rate(aif, 5644800);
/* manual aud CTS */
rk628_i2c_write(aif->rk628, HDMI_RX_AUDPLL_GEN_CTS, audio_pll_cts);
/* manual aud N */
rk628_i2c_write(aif->rk628, HDMI_RX_AUDPLL_GEN_N, audio_pll_n);
/* aud CTS N en manual */
rk628_i2c_update_bits(aif->rk628, HDMI_RX_AUD_CLK_CTRL,
CTS_N_REF_MASK, CTS_N_REF(1));
/* aud pll ctrl */
rk628_i2c_update_bits(aif->rk628, HDMI_RX_AUD_PLL_CTRL,
PLL_LOCK_TOGGLE_DIV_MASK, PLL_LOCK_TOGGLE_DIV(0));
rk628_i2c_update_bits(aif->rk628, HDMI_RX_AUD_FIFO_TH,
AFIF_TH_START_MASK |
AFIF_TH_MAX_MASK |
AFIF_TH_MIN_MASK,
AFIF_TH_START(64) |
AFIF_TH_MAX(8) |
AFIF_TH_MIN(8));
/* AUTO_VMUTE */
rk628_i2c_update_bits(aif->rk628, HDMI_RX_AUD_FIFO_CTRL,
AFIF_SUBPACKET_DESEL_MASK |
AFIF_SUBPACKETS_MASK,
AFIF_SUBPACKET_DESEL(0) |
AFIF_SUBPACKETS(1));
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_SAO_CTRL,
I2S_LPCM_BPCUV(0) |
I2S_32_16(1)|
(aif->i2s_enabled_default ? 0 : I2S_ENABLE_BITS(0x3f)));
aif->i2s_enabled = aif->i2s_enabled_default;
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_MUTE_CTRL,
APPLY_INT_MUTE(0) |
APORT_SHDW_CTRL(3) |
AUTO_ACLK_MUTE(2) |
AUD_MUTE_SPEED(1) |
AUD_AVMUTE_EN(1) |
AUD_MUTE_SEL(0) |
AUD_MUTE_MODE(1));
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_PAO_CTRL,
PAO_RATE(0));
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_CHEXTR_CTRL,
AUD_LAYOUT_CTRL(1));
aif->ctsn_ints_en = true;
rk628_i2c_write(aif->rk628, HDMI_RX_PDEC_IEN_SET, ACR_N_CHG_ICLR | ACR_CTS_CHG_ICLR);
/* audio detect */
rk628_i2c_write(aif->rk628, HDMI_RX_PDEC_AUDIODET_CTRL,
AUDIODET_THRESHOLD(0));
}
EXPORT_SYMBOL(rk628_hdmirx_audio_setup);
bool rk628_audio_fifoints_enabled(HAUDINFO info)
{
return ((struct rk628_audioinfo *)info)->fifo_ints_en;
}
EXPORT_SYMBOL(rk628_audio_fifoints_enabled);
bool rk628_audio_ctsnints_enabled(HAUDINFO info)
{
return ((struct rk628_audioinfo *)info)->ctsn_ints_en;
}
EXPORT_SYMBOL(rk628_audio_ctsnints_enabled);
void rk628_csi_isr_ctsn(HAUDINFO info, u32 pdec_ints)
{
struct rk628_audioinfo *aif = (struct rk628_audioinfo *)info;
u32 ctsn_mask = ACR_N_CHG_ICLR | ACR_CTS_CHG_ICLR;
dev_dbg(aif->dev, "%s: pdec_ints:%#x\n", __func__, pdec_ints);
/* cts & n both need update but maybe come diff int */
if (pdec_ints & ACR_N_CHG_ICLR)
aif->audio_state.ctsn_flag |= ACR_N_CHG_ICLR;
if (pdec_ints & ACR_CTS_CHG_ICLR)
aif->audio_state.ctsn_flag |= ACR_CTS_CHG_ICLR;
if (aif->audio_state.ctsn_flag == ctsn_mask) {
dev_dbg(aif->dev, "%s: ctsn updated, disable ctsn int\n", __func__);
rk628_i2c_write(aif->rk628, HDMI_RX_PDEC_IEN_CLR, ctsn_mask);
aif->ctsn_ints_en = false;
schedule_delayed_work(&aif->delayed_work_audio_rate_change, 0);
}
rk628_i2c_write(aif->rk628, HDMI_RX_PDEC_ICLR, pdec_ints & ctsn_mask);
}
EXPORT_SYMBOL(rk628_csi_isr_ctsn);
void rk628_csi_isr_fifoints(HAUDINFO info, u32 fifo_ints)
{
struct rk628_audioinfo *aif = (struct rk628_audioinfo *)info;
u32 fifo_mask = AFIF_OVERFL_ISTS | AFIF_UNDERFL_ISTS;
dev_dbg(aif->dev, "%s: fifo_ints:%#x\n", __func__, fifo_ints);
/* cts & n both need update but maybe come diff int */
if (fifo_ints & AFIF_OVERFL_ISTS) {
dev_dbg(aif->dev, "%s: Audio FIFO overflow\n", __func__);
aif->audio_state.fifo_flag |= AFIF_OVERFL_ISTS;
}
if (fifo_ints & AFIF_UNDERFL_ISTS) {
dev_dbg(aif->dev, "%s: Audio FIFO underflow\n", __func__);
aif->audio_state.fifo_flag |= AFIF_UNDERFL_ISTS;
}
if (aif->audio_state.fifo_flag == fifo_mask) {
aif->audio_state.fifo_int = true;
aif->audio_state.fifo_flag = 0;
schedule_delayed_work(&aif->delayed_work_audio_rate_change, 0);
}
rk628_i2c_write(aif->rk628, HDMI_RX_AUD_FIFO_ICLR, fifo_ints & fifo_mask);
}
EXPORT_SYMBOL(rk628_csi_isr_fifoints);
int rk628_is_avi_ready(struct rk628 *rk628, bool avi_rcv_rdy)
{
u8 i;
u32 val, avi_pb = 0;
u8 cnt = 0, max_cnt = 2;
u32 hdcp_ctrl_val = 0;
rk628_i2c_read(rk628, HDMI_RX_HDCP_CTRL, &val);
if ((val & HDCP_ENABLE_MASK))
max_cnt = 5;
for (i = 0; i < 100; i++) {
rk628_i2c_read(rk628, HDMI_RX_PDEC_AVI_PB, &val);
dev_info(rk628->dev, "%s PDEC_AVI_PB:%#x, avi_rcv_rdy:%d\n",
__func__, val, avi_rcv_rdy);
if (i > 30 && !(hdcp_ctrl_val & 0x400)) {
rk628_i2c_read(rk628, HDMI_RX_HDCP_CTRL, &hdcp_ctrl_val);
/* force hdcp avmute */
hdcp_ctrl_val |= 0x400;
rk628_i2c_write(rk628, HDMI_RX_HDCP_CTRL, hdcp_ctrl_val);
}
if (val && val == avi_pb && avi_rcv_rdy) {
if (++cnt >= max_cnt)
break;
} else {
cnt = 0;
avi_pb = val;
}
msleep(30);
}
if (cnt < max_cnt)
return 0;
return 1;
}
EXPORT_SYMBOL(rk628_is_avi_ready);
Orange Pi5 kernel
Deprecated Linux kernel 5.10.110 for OrangePi 5/5B/5+ boards
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