linux_dsm_epyc7002/drivers/phy/cadence/phy-cadence-dp.c
Scott Telford c8b427edc7 phy: Add driver for Cadence MHDP DisplayPort SD0801 PHY
Add driver for the Cadence SD0801 "Torrent" PHY used with the Cadence MHDP
DisplayPort Tx controller.

Integration with the MHDP driver will be the subject of another commit.

Signed-off-by: Scott Telford <stelford@cadence.com>
Signed-off-by: Kishon Vijay Abraham I <kishon@ti.com>
2018-09-10 14:25:44 +05:30

542 lines
16 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* Cadence MHDP DisplayPort SD0801 PHY driver.
*
* Copyright 2018 Cadence Design Systems, Inc.
*
*/
#include <linux/delay.h>
#include <linux/err.h>
#include <linux/io.h>
#include <linux/iopoll.h>
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/of_device.h>
#include <linux/phy/phy.h>
#include <linux/platform_device.h>
#define DEFAULT_NUM_LANES 2
#define MAX_NUM_LANES 4
#define DEFAULT_MAX_BIT_RATE 8100 /* in Mbps */
#define POLL_TIMEOUT_US 2000
#define LANE_MASK 0x7
/*
* register offsets from DPTX PHY register block base (i.e MHDP
* register base + 0x30a00)
*/
#define PHY_AUX_CONFIG 0x00
#define PHY_AUX_CTRL 0x04
#define PHY_RESET 0x20
#define PHY_PMA_XCVR_PLLCLK_EN 0x24
#define PHY_PMA_XCVR_PLLCLK_EN_ACK 0x28
#define PHY_PMA_XCVR_POWER_STATE_REQ 0x2c
#define PHY_POWER_STATE_LN_0 0x0000
#define PHY_POWER_STATE_LN_1 0x0008
#define PHY_POWER_STATE_LN_2 0x0010
#define PHY_POWER_STATE_LN_3 0x0018
#define PHY_PMA_XCVR_POWER_STATE_ACK 0x30
#define PHY_PMA_CMN_READY 0x34
#define PHY_PMA_XCVR_TX_VMARGIN 0x38
#define PHY_PMA_XCVR_TX_DEEMPH 0x3c
/*
* register offsets from SD0801 PHY register block base (i.e MHDP
* register base + 0x500000)
*/
#define CMN_SSM_BANDGAP_TMR 0x00084
#define CMN_SSM_BIAS_TMR 0x00088
#define CMN_PLLSM0_PLLPRE_TMR 0x000a8
#define CMN_PLLSM0_PLLLOCK_TMR 0x000b0
#define CMN_PLLSM1_PLLPRE_TMR 0x000c8
#define CMN_PLLSM1_PLLLOCK_TMR 0x000d0
#define CMN_BGCAL_INIT_TMR 0x00190
#define CMN_BGCAL_ITER_TMR 0x00194
#define CMN_IBCAL_INIT_TMR 0x001d0
#define CMN_PLL0_VCOCAL_INIT_TMR 0x00210
#define CMN_PLL0_VCOCAL_ITER_TMR 0x00214
#define CMN_PLL0_VCOCAL_REFTIM_START 0x00218
#define CMN_PLL0_VCOCAL_PLLCNT_START 0x00220
#define CMN_PLL0_INTDIV_M0 0x00240
#define CMN_PLL0_FRACDIVL_M0 0x00244
#define CMN_PLL0_FRACDIVH_M0 0x00248
#define CMN_PLL0_HIGH_THR_M0 0x0024c
#define CMN_PLL0_DSM_DIAG_M0 0x00250
#define CMN_PLL0_LOCK_PLLCNT_START 0x00278
#define CMN_PLL1_VCOCAL_INIT_TMR 0x00310
#define CMN_PLL1_VCOCAL_ITER_TMR 0x00314
#define CMN_PLL1_DSM_DIAG_M0 0x00350
#define CMN_TXPUCAL_INIT_TMR 0x00410
#define CMN_TXPUCAL_ITER_TMR 0x00414
#define CMN_TXPDCAL_INIT_TMR 0x00430
#define CMN_TXPDCAL_ITER_TMR 0x00434
#define CMN_RXCAL_INIT_TMR 0x00450
#define CMN_RXCAL_ITER_TMR 0x00454
#define CMN_SD_CAL_INIT_TMR 0x00490
#define CMN_SD_CAL_ITER_TMR 0x00494
#define CMN_SD_CAL_REFTIM_START 0x00498
#define CMN_SD_CAL_PLLCNT_START 0x004a0
#define CMN_PDIAG_PLL0_CTRL_M0 0x00680
#define CMN_PDIAG_PLL0_CLK_SEL_M0 0x00684
#define CMN_PDIAG_PLL0_CP_PADJ_M0 0x00690
#define CMN_PDIAG_PLL0_CP_IADJ_M0 0x00694
#define CMN_PDIAG_PLL0_FILT_PADJ_M0 0x00698
#define CMN_PDIAG_PLL0_CP_PADJ_M1 0x006d0
#define CMN_PDIAG_PLL0_CP_IADJ_M1 0x006d4
#define CMN_PDIAG_PLL1_CLK_SEL_M0 0x00704
#define XCVR_DIAG_PLLDRC_CTRL 0x10394
#define XCVR_DIAG_HSCLK_SEL 0x10398
#define XCVR_DIAG_HSCLK_DIV 0x1039c
#define TX_PSC_A0 0x10400
#define TX_PSC_A1 0x10404
#define TX_PSC_A2 0x10408
#define TX_PSC_A3 0x1040c
#define RX_PSC_A0 0x20000
#define RX_PSC_A1 0x20004
#define RX_PSC_A2 0x20008
#define RX_PSC_A3 0x2000c
#define PHY_PLL_CFG 0x30038
struct cdns_dp_phy {
void __iomem *base; /* DPTX registers base */
void __iomem *sd_base; /* SD0801 registers base */
u32 num_lanes; /* Number of lanes to use */
u32 max_bit_rate; /* Maximum link bit rate to use (in Mbps) */
struct device *dev;
};
static int cdns_dp_phy_init(struct phy *phy);
static void cdns_dp_phy_run(struct cdns_dp_phy *cdns_phy);
static void cdns_dp_phy_wait_pma_cmn_ready(struct cdns_dp_phy *cdns_phy);
static void cdns_dp_phy_pma_cfg(struct cdns_dp_phy *cdns_phy);
static void cdns_dp_phy_pma_cmn_cfg_25mhz(struct cdns_dp_phy *cdns_phy);
static void cdns_dp_phy_pma_lane_cfg(struct cdns_dp_phy *cdns_phy,
unsigned int lane);
static void cdns_dp_phy_pma_cmn_vco_cfg_25mhz(struct cdns_dp_phy *cdns_phy);
static void cdns_dp_phy_pma_cmn_rate(struct cdns_dp_phy *cdns_phy);
static void cdns_dp_phy_write_field(struct cdns_dp_phy *cdns_phy,
unsigned int offset,
unsigned char start_bit,
unsigned char num_bits,
unsigned int val);
static const struct phy_ops cdns_dp_phy_ops = {
.init = cdns_dp_phy_init,
.owner = THIS_MODULE,
};
static int cdns_dp_phy_init(struct phy *phy)
{
unsigned char lane_bits;
struct cdns_dp_phy *cdns_phy = phy_get_drvdata(phy);
writel(0x0003, cdns_phy->base + PHY_AUX_CTRL); /* enable AUX */
/* PHY PMA registers configuration function */
cdns_dp_phy_pma_cfg(cdns_phy);
/*
* Set lines power state to A0
* Set lines pll clk enable to 0
*/
cdns_dp_phy_write_field(cdns_phy, PHY_PMA_XCVR_POWER_STATE_REQ,
PHY_POWER_STATE_LN_0, 6, 0x0000);
if (cdns_phy->num_lanes >= 2) {
cdns_dp_phy_write_field(cdns_phy,
PHY_PMA_XCVR_POWER_STATE_REQ,
PHY_POWER_STATE_LN_1, 6, 0x0000);
if (cdns_phy->num_lanes == 4) {
cdns_dp_phy_write_field(cdns_phy,
PHY_PMA_XCVR_POWER_STATE_REQ,
PHY_POWER_STATE_LN_2, 6, 0);
cdns_dp_phy_write_field(cdns_phy,
PHY_PMA_XCVR_POWER_STATE_REQ,
PHY_POWER_STATE_LN_3, 6, 0);
}
}
cdns_dp_phy_write_field(cdns_phy, PHY_PMA_XCVR_PLLCLK_EN,
0, 1, 0x0000);
if (cdns_phy->num_lanes >= 2) {
cdns_dp_phy_write_field(cdns_phy, PHY_PMA_XCVR_PLLCLK_EN,
1, 1, 0x0000);
if (cdns_phy->num_lanes == 4) {
cdns_dp_phy_write_field(cdns_phy,
PHY_PMA_XCVR_PLLCLK_EN,
2, 1, 0x0000);
cdns_dp_phy_write_field(cdns_phy,
PHY_PMA_XCVR_PLLCLK_EN,
3, 1, 0x0000);
}
}
/*
* release phy_l0*_reset_n and pma_tx_elec_idle_ln_* based on
* used lanes
*/
lane_bits = (1 << cdns_phy->num_lanes) - 1;
writel(((0xF & ~lane_bits) << 4) | (0xF & lane_bits),
cdns_phy->base + PHY_RESET);
/* release pma_xcvr_pllclk_en_ln_*, only for the master lane */
writel(0x0001, cdns_phy->base + PHY_PMA_XCVR_PLLCLK_EN);
/* PHY PMA registers configuration functions */
cdns_dp_phy_pma_cmn_vco_cfg_25mhz(cdns_phy);
cdns_dp_phy_pma_cmn_rate(cdns_phy);
/* take out of reset */
cdns_dp_phy_write_field(cdns_phy, PHY_RESET, 8, 1, 1);
cdns_dp_phy_wait_pma_cmn_ready(cdns_phy);
cdns_dp_phy_run(cdns_phy);
return 0;
}
static void cdns_dp_phy_wait_pma_cmn_ready(struct cdns_dp_phy *cdns_phy)
{
unsigned int reg;
int ret;
ret = readl_poll_timeout(cdns_phy->base + PHY_PMA_CMN_READY, reg,
reg & 1, 0, 500);
if (ret == -ETIMEDOUT)
dev_err(cdns_phy->dev,
"timeout waiting for PMA common ready\n");
}
static void cdns_dp_phy_pma_cfg(struct cdns_dp_phy *cdns_phy)
{
unsigned int i;
/* PMA common configuration */
cdns_dp_phy_pma_cmn_cfg_25mhz(cdns_phy);
/* PMA lane configuration to deal with multi-link operation */
for (i = 0; i < cdns_phy->num_lanes; i++)
cdns_dp_phy_pma_lane_cfg(cdns_phy, i);
}
static void cdns_dp_phy_pma_cmn_cfg_25mhz(struct cdns_dp_phy *cdns_phy)
{
/* refclock registers - assumes 25 MHz refclock */
writel(0x0019, cdns_phy->sd_base + CMN_SSM_BIAS_TMR);
writel(0x0032, cdns_phy->sd_base + CMN_PLLSM0_PLLPRE_TMR);
writel(0x00D1, cdns_phy->sd_base + CMN_PLLSM0_PLLLOCK_TMR);
writel(0x0032, cdns_phy->sd_base + CMN_PLLSM1_PLLPRE_TMR);
writel(0x00D1, cdns_phy->sd_base + CMN_PLLSM1_PLLLOCK_TMR);
writel(0x007D, cdns_phy->sd_base + CMN_BGCAL_INIT_TMR);
writel(0x007D, cdns_phy->sd_base + CMN_BGCAL_ITER_TMR);
writel(0x0019, cdns_phy->sd_base + CMN_IBCAL_INIT_TMR);
writel(0x001E, cdns_phy->sd_base + CMN_TXPUCAL_INIT_TMR);
writel(0x0006, cdns_phy->sd_base + CMN_TXPUCAL_ITER_TMR);
writel(0x001E, cdns_phy->sd_base + CMN_TXPDCAL_INIT_TMR);
writel(0x0006, cdns_phy->sd_base + CMN_TXPDCAL_ITER_TMR);
writel(0x02EE, cdns_phy->sd_base + CMN_RXCAL_INIT_TMR);
writel(0x0006, cdns_phy->sd_base + CMN_RXCAL_ITER_TMR);
writel(0x0002, cdns_phy->sd_base + CMN_SD_CAL_INIT_TMR);
writel(0x0002, cdns_phy->sd_base + CMN_SD_CAL_ITER_TMR);
writel(0x000E, cdns_phy->sd_base + CMN_SD_CAL_REFTIM_START);
writel(0x012B, cdns_phy->sd_base + CMN_SD_CAL_PLLCNT_START);
/* PLL registers */
writel(0x0409, cdns_phy->sd_base + CMN_PDIAG_PLL0_CP_PADJ_M0);
writel(0x1001, cdns_phy->sd_base + CMN_PDIAG_PLL0_CP_IADJ_M0);
writel(0x0F08, cdns_phy->sd_base + CMN_PDIAG_PLL0_FILT_PADJ_M0);
writel(0x0004, cdns_phy->sd_base + CMN_PLL0_DSM_DIAG_M0);
writel(0x00FA, cdns_phy->sd_base + CMN_PLL0_VCOCAL_INIT_TMR);
writel(0x0004, cdns_phy->sd_base + CMN_PLL0_VCOCAL_ITER_TMR);
writel(0x00FA, cdns_phy->sd_base + CMN_PLL1_VCOCAL_INIT_TMR);
writel(0x0004, cdns_phy->sd_base + CMN_PLL1_VCOCAL_ITER_TMR);
writel(0x0318, cdns_phy->sd_base + CMN_PLL0_VCOCAL_REFTIM_START);
}
static void cdns_dp_phy_pma_cmn_vco_cfg_25mhz(struct cdns_dp_phy *cdns_phy)
{
/* Assumes 25 MHz refclock */
switch (cdns_phy->max_bit_rate) {
/* Setting VCO for 10.8GHz */
case 2700:
case 5400:
writel(0x01B0, cdns_phy->sd_base + CMN_PLL0_INTDIV_M0);
writel(0x0000, cdns_phy->sd_base + CMN_PLL0_FRACDIVL_M0);
writel(0x0002, cdns_phy->sd_base + CMN_PLL0_FRACDIVH_M0);
writel(0x0120, cdns_phy->sd_base + CMN_PLL0_HIGH_THR_M0);
break;
/* Setting VCO for 9.72GHz */
case 2430:
case 3240:
writel(0x0184, cdns_phy->sd_base + CMN_PLL0_INTDIV_M0);
writel(0xCCCD, cdns_phy->sd_base + CMN_PLL0_FRACDIVL_M0);
writel(0x0002, cdns_phy->sd_base + CMN_PLL0_FRACDIVH_M0);
writel(0x0104, cdns_phy->sd_base + CMN_PLL0_HIGH_THR_M0);
break;
/* Setting VCO for 8.64GHz */
case 2160:
case 4320:
writel(0x0159, cdns_phy->sd_base + CMN_PLL0_INTDIV_M0);
writel(0x999A, cdns_phy->sd_base + CMN_PLL0_FRACDIVL_M0);
writel(0x0002, cdns_phy->sd_base + CMN_PLL0_FRACDIVH_M0);
writel(0x00E7, cdns_phy->sd_base + CMN_PLL0_HIGH_THR_M0);
break;
/* Setting VCO for 8.1GHz */
case 8100:
writel(0x0144, cdns_phy->sd_base + CMN_PLL0_INTDIV_M0);
writel(0x0000, cdns_phy->sd_base + CMN_PLL0_FRACDIVL_M0);
writel(0x0002, cdns_phy->sd_base + CMN_PLL0_FRACDIVH_M0);
writel(0x00D8, cdns_phy->sd_base + CMN_PLL0_HIGH_THR_M0);
break;
}
writel(0x0002, cdns_phy->sd_base + CMN_PDIAG_PLL0_CTRL_M0);
writel(0x0318, cdns_phy->sd_base + CMN_PLL0_VCOCAL_PLLCNT_START);
}
static void cdns_dp_phy_pma_cmn_rate(struct cdns_dp_phy *cdns_phy)
{
unsigned int clk_sel_val = 0;
unsigned int hsclk_div_val = 0;
unsigned int i;
/* 16'h0000 for single DP link configuration */
writel(0x0000, cdns_phy->sd_base + PHY_PLL_CFG);
switch (cdns_phy->max_bit_rate) {
case 1620:
clk_sel_val = 0x0f01;
hsclk_div_val = 2;
break;
case 2160:
case 2430:
case 2700:
clk_sel_val = 0x0701;
hsclk_div_val = 1;
break;
case 3240:
clk_sel_val = 0x0b00;
hsclk_div_val = 2;
break;
case 4320:
case 5400:
clk_sel_val = 0x0301;
hsclk_div_val = 0;
break;
case 8100:
clk_sel_val = 0x0200;
hsclk_div_val = 0;
break;
}
writel(clk_sel_val, cdns_phy->sd_base + CMN_PDIAG_PLL0_CLK_SEL_M0);
/* PMA lane configuration to deal with multi-link operation */
for (i = 0; i < cdns_phy->num_lanes; i++) {
writel(hsclk_div_val,
cdns_phy->sd_base + (XCVR_DIAG_HSCLK_DIV | (i<<11)));
}
}
static void cdns_dp_phy_pma_lane_cfg(struct cdns_dp_phy *cdns_phy,
unsigned int lane)
{
unsigned int lane_bits = (lane & LANE_MASK) << 11;
/* Writing Tx/Rx Power State Controllers registers */
writel(0x00FB, cdns_phy->sd_base + (TX_PSC_A0 | lane_bits));
writel(0x04AA, cdns_phy->sd_base + (TX_PSC_A2 | lane_bits));
writel(0x04AA, cdns_phy->sd_base + (TX_PSC_A3 | lane_bits));
writel(0x0000, cdns_phy->sd_base + (RX_PSC_A0 | lane_bits));
writel(0x0000, cdns_phy->sd_base + (RX_PSC_A2 | lane_bits));
writel(0x0000, cdns_phy->sd_base + (RX_PSC_A3 | lane_bits));
writel(0x0001, cdns_phy->sd_base + (XCVR_DIAG_PLLDRC_CTRL | lane_bits));
writel(0x0000, cdns_phy->sd_base + (XCVR_DIAG_HSCLK_SEL | lane_bits));
}
static void cdns_dp_phy_run(struct cdns_dp_phy *cdns_phy)
{
unsigned int read_val;
u32 write_val1 = 0;
u32 write_val2 = 0;
u32 mask = 0;
int ret;
/*
* waiting for ACK of pma_xcvr_pllclk_en_ln_*, only for the
* master lane
*/
ret = readl_poll_timeout(cdns_phy->base + PHY_PMA_XCVR_PLLCLK_EN_ACK,
read_val, read_val & 1, 0, POLL_TIMEOUT_US);
if (ret == -ETIMEDOUT)
dev_err(cdns_phy->dev,
"timeout waiting for link PLL clock enable ack\n");
ndelay(100);
switch (cdns_phy->num_lanes) {
case 1: /* lane 0 */
write_val1 = 0x00000004;
write_val2 = 0x00000001;
mask = 0x0000003f;
break;
case 2: /* lane 0-1 */
write_val1 = 0x00000404;
write_val2 = 0x00000101;
mask = 0x00003f3f;
break;
case 4: /* lane 0-3 */
write_val1 = 0x04040404;
write_val2 = 0x01010101;
mask = 0x3f3f3f3f;
break;
}
writel(write_val1, cdns_phy->base + PHY_PMA_XCVR_POWER_STATE_REQ);
ret = readl_poll_timeout(cdns_phy->base + PHY_PMA_XCVR_POWER_STATE_ACK,
read_val, (read_val & mask) == write_val1, 0,
POLL_TIMEOUT_US);
if (ret == -ETIMEDOUT)
dev_err(cdns_phy->dev,
"timeout waiting for link power state ack\n");
writel(0, cdns_phy->base + PHY_PMA_XCVR_POWER_STATE_REQ);
ndelay(100);
writel(write_val2, cdns_phy->base + PHY_PMA_XCVR_POWER_STATE_REQ);
ret = readl_poll_timeout(cdns_phy->base + PHY_PMA_XCVR_POWER_STATE_ACK,
read_val, (read_val & mask) == write_val2, 0,
POLL_TIMEOUT_US);
if (ret == -ETIMEDOUT)
dev_err(cdns_phy->dev,
"timeout waiting for link power state ack\n");
writel(0, cdns_phy->base + PHY_PMA_XCVR_POWER_STATE_REQ);
ndelay(100);
}
static void cdns_dp_phy_write_field(struct cdns_dp_phy *cdns_phy,
unsigned int offset,
unsigned char start_bit,
unsigned char num_bits,
unsigned int val)
{
unsigned int read_val;
read_val = readl(cdns_phy->base + offset);
writel(((val << start_bit) | (read_val & ~(((1 << num_bits) - 1) <<
start_bit))), cdns_phy->base + offset);
}
static int cdns_dp_phy_probe(struct platform_device *pdev)
{
struct resource *regs;
struct cdns_dp_phy *cdns_phy;
struct device *dev = &pdev->dev;
struct phy_provider *phy_provider;
struct phy *phy;
int err;
cdns_phy = devm_kzalloc(dev, sizeof(*cdns_phy), GFP_KERNEL);
if (!cdns_phy)
return -ENOMEM;
cdns_phy->dev = &pdev->dev;
phy = devm_phy_create(dev, NULL, &cdns_dp_phy_ops);
if (IS_ERR(phy)) {
dev_err(dev, "failed to create DisplayPort PHY\n");
return PTR_ERR(phy);
}
regs = platform_get_resource(pdev, IORESOURCE_MEM, 0);
cdns_phy->base = devm_ioremap_resource(&pdev->dev, regs);
if (IS_ERR(cdns_phy->base))
return PTR_ERR(cdns_phy->base);
regs = platform_get_resource(pdev, IORESOURCE_MEM, 1);
cdns_phy->sd_base = devm_ioremap_resource(&pdev->dev, regs);
if (IS_ERR(cdns_phy->sd_base))
return PTR_ERR(cdns_phy->sd_base);
err = device_property_read_u32(dev, "num_lanes",
&(cdns_phy->num_lanes));
if (err)
cdns_phy->num_lanes = DEFAULT_NUM_LANES;
switch (cdns_phy->num_lanes) {
case 1:
case 2:
case 4:
/* valid number of lanes */
break;
default:
dev_err(dev, "unsupported number of lanes: %d\n",
cdns_phy->num_lanes);
return -EINVAL;
}
err = device_property_read_u32(dev, "max_bit_rate",
&(cdns_phy->max_bit_rate));
if (err)
cdns_phy->max_bit_rate = DEFAULT_MAX_BIT_RATE;
switch (cdns_phy->max_bit_rate) {
case 2160:
case 2430:
case 2700:
case 3240:
case 4320:
case 5400:
case 8100:
/* valid bit rate */
break;
default:
dev_err(dev, "unsupported max bit rate: %dMbps\n",
cdns_phy->max_bit_rate);
return -EINVAL;
}
phy_set_drvdata(phy, cdns_phy);
phy_provider = devm_of_phy_provider_register(dev, of_phy_simple_xlate);
dev_info(dev, "%d lanes, max bit rate %d.%03d Gbps\n",
cdns_phy->num_lanes,
cdns_phy->max_bit_rate / 1000,
cdns_phy->max_bit_rate % 1000);
return PTR_ERR_OR_ZERO(phy_provider);
}
static const struct of_device_id cdns_dp_phy_of_match[] = {
{
.compatible = "cdns,dp-phy"
},
{}
};
MODULE_DEVICE_TABLE(of, cdns_dp_phy_of_match);
static struct platform_driver cdns_dp_phy_driver = {
.probe = cdns_dp_phy_probe,
.driver = {
.name = "cdns-dp-phy",
.of_match_table = cdns_dp_phy_of_match,
}
};
module_platform_driver(cdns_dp_phy_driver);
MODULE_AUTHOR("Cadence Design Systems, Inc.");
MODULE_DESCRIPTION("Cadence MHDP PHY driver");
MODULE_LICENSE("GPL v2");