mirrors/linux-stable
1
0
Fork 0
mirror of https://git.kernel.org/pub/scm/linux/kernel/git/stable/linux.git synced 2024-10-05 16:37:50 +00:00
Code Issues Releases Wiki Activity
linux-stable/drivers/phy/broadcom/phy-brcm-sata.c
Florian Fainelli 0ed41b3388 phy: brcm-sata: Correct MDIO operations for 40nm platforms 
The logic to write to MDIO registers on 40nm platforms was wrong
because it would use the port number as an offset from the base address
rather than the bank address of the PHY. This is hardly noticeable
because the only programming we do is enabling SSC or not, which is not
really causing an observable functional change.

Correct that mistake by passing down the struct brcm_sata_port structure
down to the brcm_sata_mdio_wr() and brcm_sata_mdio_rd() functions and do
the proper offsetting for 28nm, respectively 40nm platforms from there.
This means that brcm_sata_pcb_base() is now useless and is therefore
removed.

Fixes: c1602a1a0f ("phy: phy_brcmstb_sata: add support for MIPS-based platforms")
Signed-off-by: Florian Fainelli <f.fainelli@gmail.com>
Signed-off-by: Kishon Vijay Abraham I <kishon@ti.com>
2020-02-21 14:01:47 +05:30

832 lines
22 KiB
C
Raw Blame History

// SPDX-License-Identifier: GPL-2.0-or-later
/*
* Broadcom SATA3 AHCI Controller PHY Driver
*
* Copyright (C) 2016 Broadcom
*/
#include <linux/delay.h>
#include <linux/device.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <linux/io.h>
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/of.h>
#include <linux/phy/phy.h>
#include <linux/platform_device.h>
#define SATA_PCB_BANK_OFFSET 0x23c
#define SATA_PCB_REG_OFFSET(ofs) ((ofs) * 4)
#define MAX_PORTS 2
/* Register offset between PHYs in PCB space */
#define SATA_PCB_REG_28NM_SPACE_SIZE 0x1000
/* The older SATA PHY registers duplicated per port registers within the map,
* rather than having a separate map per port.
*/
#define SATA_PCB_REG_40NM_SPACE_SIZE 0x10
/* Register offset between PHYs in PHY control space */
#define SATA_PHY_CTRL_REG_28NM_SPACE_SIZE 0x8
enum brcm_sata_phy_version {
BRCM_SATA_PHY_STB_16NM,
BRCM_SATA_PHY_STB_28NM,
BRCM_SATA_PHY_STB_40NM,
BRCM_SATA_PHY_IPROC_NS2,
BRCM_SATA_PHY_IPROC_NSP,
BRCM_SATA_PHY_IPROC_SR,
BRCM_SATA_PHY_DSL_28NM,
};
enum brcm_sata_phy_rxaeq_mode {
RXAEQ_MODE_OFF = 0,
RXAEQ_MODE_AUTO,
RXAEQ_MODE_MANUAL,
};
static enum brcm_sata_phy_rxaeq_mode rxaeq_to_val(const char *m)
{
if (!strcmp(m, "auto"))
return RXAEQ_MODE_AUTO;
else if (!strcmp(m, "manual"))
return RXAEQ_MODE_MANUAL;
else
return RXAEQ_MODE_OFF;
}
struct brcm_sata_port {
int portnum;
struct phy *phy;
struct brcm_sata_phy *phy_priv;
bool ssc_en;
enum brcm_sata_phy_rxaeq_mode rxaeq_mode;
u32 rxaeq_val;
};
struct brcm_sata_phy {
struct device *dev;
void __iomem *phy_base;
void __iomem *ctrl_base;
enum brcm_sata_phy_version version;
struct brcm_sata_port phys[MAX_PORTS];
};
enum sata_phy_regs {
BLOCK0_REG_BANK = 0x000,
BLOCK0_XGXSSTATUS = 0x81,
BLOCK0_XGXSSTATUS_PLL_LOCK = BIT(12),
BLOCK0_SPARE = 0x8d,
BLOCK0_SPARE_OOB_CLK_SEL_MASK = 0x3,
BLOCK0_SPARE_OOB_CLK_SEL_REFBY2 = 0x1,
PLL_REG_BANK_0 = 0x050,
PLL_REG_BANK_0_PLLCONTROL_0 = 0x81,
PLLCONTROL_0_FREQ_DET_RESTART = BIT(13),
PLLCONTROL_0_FREQ_MONITOR = BIT(12),
PLLCONTROL_0_SEQ_START = BIT(15),
PLL_CAP_CHARGE_TIME = 0x83,
PLL_VCO_CAL_THRESH = 0x84,
PLL_CAP_CONTROL = 0x85,
PLL_FREQ_DET_TIME = 0x86,
PLL_ACTRL2 = 0x8b,
PLL_ACTRL2_SELDIV_MASK = 0x1f,
PLL_ACTRL2_SELDIV_SHIFT = 9,
PLL_ACTRL6 = 0x86,
PLL1_REG_BANK = 0x060,
PLL1_ACTRL2 = 0x82,
PLL1_ACTRL3 = 0x83,
PLL1_ACTRL4 = 0x84,
PLL1_ACTRL5 = 0x85,
PLL1_ACTRL6 = 0x86,
PLL1_ACTRL7 = 0x87,
PLL1_ACTRL8 = 0x88,
TX_REG_BANK = 0x070,
TX_ACTRL0 = 0x80,
TX_ACTRL0_TXPOL_FLIP = BIT(6),
TX_ACTRL5 = 0x85,
TX_ACTRL5_SSC_EN = BIT(11),
AEQRX_REG_BANK_0 = 0xd0,
AEQ_CONTROL1 = 0x81,
AEQ_CONTROL1_ENABLE = BIT(2),
AEQ_CONTROL1_FREEZE = BIT(3),
AEQ_FRC_EQ = 0x83,
AEQ_FRC_EQ_FORCE = BIT(0),
AEQ_FRC_EQ_FORCE_VAL = BIT(1),
AEQ_RFZ_FRC_VAL = BIT(8),
AEQRX_REG_BANK_1 = 0xe0,
AEQRX_SLCAL0_CTRL0 = 0x82,
AEQRX_SLCAL1_CTRL0 = 0x86,
OOB_REG_BANK = 0x150,
OOB1_REG_BANK = 0x160,
OOB_CTRL1 = 0x80,
OOB_CTRL1_BURST_MAX_MASK = 0xf,
OOB_CTRL1_BURST_MAX_SHIFT = 12,
OOB_CTRL1_BURST_MIN_MASK = 0xf,
OOB_CTRL1_BURST_MIN_SHIFT = 8,
OOB_CTRL1_WAKE_IDLE_MAX_MASK = 0xf,
OOB_CTRL1_WAKE_IDLE_MAX_SHIFT = 4,
OOB_CTRL1_WAKE_IDLE_MIN_MASK = 0xf,
OOB_CTRL1_WAKE_IDLE_MIN_SHIFT = 0,
OOB_CTRL2 = 0x81,
OOB_CTRL2_SEL_ENA_SHIFT = 15,
OOB_CTRL2_SEL_ENA_RC_SHIFT = 14,
OOB_CTRL2_RESET_IDLE_MAX_MASK = 0x3f,
OOB_CTRL2_RESET_IDLE_MAX_SHIFT = 8,
OOB_CTRL2_BURST_CNT_MASK = 0x3,
OOB_CTRL2_BURST_CNT_SHIFT = 6,
OOB_CTRL2_RESET_IDLE_MIN_MASK = 0x3f,
OOB_CTRL2_RESET_IDLE_MIN_SHIFT = 0,
TXPMD_REG_BANK = 0x1a0,
TXPMD_CONTROL1 = 0x81,
TXPMD_CONTROL1_TX_SSC_EN_FRC = BIT(0),
TXPMD_CONTROL1_TX_SSC_EN_FRC_VAL = BIT(1),
TXPMD_TX_FREQ_CTRL_CONTROL1 = 0x82,
TXPMD_TX_FREQ_CTRL_CONTROL2 = 0x83,
TXPMD_TX_FREQ_CTRL_CONTROL2_FMIN_MASK = 0x3ff,
TXPMD_TX_FREQ_CTRL_CONTROL3 = 0x84,
TXPMD_TX_FREQ_CTRL_CONTROL3_FMAX_MASK = 0x3ff,
RXPMD_REG_BANK = 0x1c0,
RXPMD_RX_CDR_CONTROL1 = 0x81,
RXPMD_RX_PPM_VAL_MASK = 0x1ff,
RXPMD_RXPMD_EN_FRC = BIT(12),
RXPMD_RXPMD_EN_FRC_VAL = BIT(13),
RXPMD_RX_CDR_CDR_PROP_BW = 0x82,
RXPMD_G_CDR_PROP_BW_MASK = 0x7,
RXPMD_G1_CDR_PROP_BW_SHIFT = 0,
RXPMD_G2_CDR_PROP_BW_SHIFT = 3,
RXPMD_G3_CDR_PROB_BW_SHIFT = 6,
RXPMD_RX_CDR_CDR_ACQ_INTEG_BW = 0x83,
RXPMD_G_CDR_ACQ_INT_BW_MASK = 0x7,
RXPMD_G1_CDR_ACQ_INT_BW_SHIFT = 0,
RXPMD_G2_CDR_ACQ_INT_BW_SHIFT = 3,
RXPMD_G3_CDR_ACQ_INT_BW_SHIFT = 6,
RXPMD_RX_CDR_CDR_LOCK_INTEG_BW = 0x84,
RXPMD_G_CDR_LOCK_INT_BW_MASK = 0x7,
RXPMD_G1_CDR_LOCK_INT_BW_SHIFT = 0,
RXPMD_G2_CDR_LOCK_INT_BW_SHIFT = 3,
RXPMD_G3_CDR_LOCK_INT_BW_SHIFT = 6,
RXPMD_RX_FREQ_MON_CONTROL1 = 0x87,
RXPMD_MON_CORRECT_EN = BIT(8),
RXPMD_MON_MARGIN_VAL_MASK = 0xff,
};
enum sata_phy_ctrl_regs {
PHY_CTRL_1 = 0x0,
PHY_CTRL_1_RESET = BIT(0),
};
static inline void __iomem *brcm_sata_ctrl_base(struct brcm_sata_port *port)
{
struct brcm_sata_phy *priv = port->phy_priv;
u32 size = 0;
switch (priv->version) {
case BRCM_SATA_PHY_IPROC_NS2:
size = SATA_PHY_CTRL_REG_28NM_SPACE_SIZE;
break;
default:
dev_err(priv->dev, "invalid phy version\n");
break;
}
return priv->ctrl_base + (port->portnum * size);
}
static void brcm_sata_phy_wr(struct brcm_sata_port *port, u32 bank,
u32 ofs, u32 msk, u32 value)
{
struct brcm_sata_phy *priv = port->phy_priv;
void __iomem *pcb_base = priv->phy_base;
u32 tmp;
if (priv->version == BRCM_SATA_PHY_STB_40NM)
bank += (port->portnum * SATA_PCB_REG_40NM_SPACE_SIZE);
else
pcb_base += (port->portnum * SATA_PCB_REG_28NM_SPACE_SIZE);
writel(bank, pcb_base + SATA_PCB_BANK_OFFSET);
tmp = readl(pcb_base + SATA_PCB_REG_OFFSET(ofs));
tmp = (tmp & msk) | value;
writel(tmp, pcb_base + SATA_PCB_REG_OFFSET(ofs));
}
static u32 brcm_sata_phy_rd(struct brcm_sata_port *port, u32 bank, u32 ofs)
{
struct brcm_sata_phy *priv = port->phy_priv;
void __iomem *pcb_base = priv->phy_base;
if (priv->version == BRCM_SATA_PHY_STB_40NM)
bank += (port->portnum * SATA_PCB_REG_40NM_SPACE_SIZE);
else
pcb_base += (port->portnum * SATA_PCB_REG_28NM_SPACE_SIZE);
writel(bank, pcb_base + SATA_PCB_BANK_OFFSET);
return readl(pcb_base + SATA_PCB_REG_OFFSET(ofs));
}
/* These defaults were characterized by H/W group */
#define STB_FMIN_VAL_DEFAULT 0x3df
#define STB_FMAX_VAL_DEFAULT 0x3df
#define STB_FMAX_VAL_SSC 0x83
static void brcm_stb_sata_ssc_init(struct brcm_sata_port *port)
{
struct brcm_sata_phy *priv = port->phy_priv;
u32 tmp;
/* override the TX spread spectrum setting */
tmp = TXPMD_CONTROL1_TX_SSC_EN_FRC_VAL | TXPMD_CONTROL1_TX_SSC_EN_FRC;
brcm_sata_phy_wr(port, TXPMD_REG_BANK, TXPMD_CONTROL1, ~tmp, tmp);
/* set fixed min freq */
brcm_sata_phy_wr(port, TXPMD_REG_BANK, TXPMD_TX_FREQ_CTRL_CONTROL2,
~TXPMD_TX_FREQ_CTRL_CONTROL2_FMIN_MASK,
STB_FMIN_VAL_DEFAULT);
/* set fixed max freq depending on SSC config */
if (port->ssc_en) {
dev_info(priv->dev, "enabling SSC on port%d\n", port->portnum);
tmp = STB_FMAX_VAL_SSC;
} else {
tmp = STB_FMAX_VAL_DEFAULT;
}
brcm_sata_phy_wr(port, TXPMD_REG_BANK, TXPMD_TX_FREQ_CTRL_CONTROL3,
~TXPMD_TX_FREQ_CTRL_CONTROL3_FMAX_MASK, tmp);
}
#define AEQ_FRC_EQ_VAL_SHIFT 2
#define AEQ_FRC_EQ_VAL_MASK 0x3f
static int brcm_stb_sata_rxaeq_init(struct brcm_sata_port *port)
{
u32 tmp = 0, reg = 0;
switch (port->rxaeq_mode) {
case RXAEQ_MODE_OFF:
return 0;
case RXAEQ_MODE_AUTO:
reg = AEQ_CONTROL1;
tmp = AEQ_CONTROL1_ENABLE | AEQ_CONTROL1_FREEZE;
break;
case RXAEQ_MODE_MANUAL:
reg = AEQ_FRC_EQ;
tmp = AEQ_FRC_EQ_FORCE | AEQ_FRC_EQ_FORCE_VAL;
if (port->rxaeq_val > AEQ_FRC_EQ_VAL_MASK)
return -EINVAL;
tmp |= port->rxaeq_val << AEQ_FRC_EQ_VAL_SHIFT;
break;
}
brcm_sata_phy_wr(port, AEQRX_REG_BANK_0, reg, ~tmp, tmp);
brcm_sata_phy_wr(port, AEQRX_REG_BANK_1, reg, ~tmp, tmp);
return 0;
}
static int brcm_stb_sata_init(struct brcm_sata_port *port)
{
brcm_stb_sata_ssc_init(port);
return brcm_stb_sata_rxaeq_init(port);
}
static int brcm_stb_sata_16nm_ssc_init(struct brcm_sata_port *port)
{
u32 tmp, value;
/* Reduce CP tail current to 1/16th of its default value */
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL6, 0, 0x141);
/* Turn off CP tail current boost */
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL8, 0, 0xc006);
/* Set a specific AEQ equalizer value */
tmp = AEQ_FRC_EQ_FORCE_VAL | AEQ_FRC_EQ_FORCE;
brcm_sata_phy_wr(port, AEQRX_REG_BANK_0, AEQ_FRC_EQ,
~(tmp | AEQ_RFZ_FRC_VAL |
AEQ_FRC_EQ_VAL_MASK << AEQ_FRC_EQ_VAL_SHIFT),
tmp | 32 << AEQ_FRC_EQ_VAL_SHIFT);
/* Set RX PPM val center frequency */
if (port->ssc_en)
value = 0x52;
else
value = 0;
brcm_sata_phy_wr(port, RXPMD_REG_BANK, RXPMD_RX_CDR_CONTROL1,
~RXPMD_RX_PPM_VAL_MASK, value);
/* Set proportional loop bandwith Gen1/2/3 */
tmp = RXPMD_G_CDR_PROP_BW_MASK << RXPMD_G1_CDR_PROP_BW_SHIFT |
RXPMD_G_CDR_PROP_BW_MASK << RXPMD_G2_CDR_PROP_BW_SHIFT |
RXPMD_G_CDR_PROP_BW_MASK << RXPMD_G3_CDR_PROB_BW_SHIFT;
if (port->ssc_en)
value = 2 << RXPMD_G1_CDR_PROP_BW_SHIFT |
2 << RXPMD_G2_CDR_PROP_BW_SHIFT |
2 << RXPMD_G3_CDR_PROB_BW_SHIFT;
else
value = 1 << RXPMD_G1_CDR_PROP_BW_SHIFT |
1 << RXPMD_G2_CDR_PROP_BW_SHIFT |
1 << RXPMD_G3_CDR_PROB_BW_SHIFT;
brcm_sata_phy_wr(port, RXPMD_REG_BANK, RXPMD_RX_CDR_CDR_PROP_BW, ~tmp,
value);
/* Set CDR integral loop acquisition bandwidth for Gen1/2/3 */
tmp = RXPMD_G_CDR_ACQ_INT_BW_MASK << RXPMD_G1_CDR_ACQ_INT_BW_SHIFT |
RXPMD_G_CDR_ACQ_INT_BW_MASK << RXPMD_G2_CDR_ACQ_INT_BW_SHIFT |
RXPMD_G_CDR_ACQ_INT_BW_MASK << RXPMD_G3_CDR_ACQ_INT_BW_SHIFT;
if (port->ssc_en)
value = 1 << RXPMD_G1_CDR_ACQ_INT_BW_SHIFT |
1 << RXPMD_G2_CDR_ACQ_INT_BW_SHIFT |
1 << RXPMD_G3_CDR_ACQ_INT_BW_SHIFT;
else
value = 0;
brcm_sata_phy_wr(port, RXPMD_REG_BANK, RXPMD_RX_CDR_CDR_ACQ_INTEG_BW,
~tmp, value);
/* Set CDR integral loop locking bandwidth to 1 for Gen 1/2/3 */
tmp = RXPMD_G_CDR_LOCK_INT_BW_MASK << RXPMD_G1_CDR_LOCK_INT_BW_SHIFT |
RXPMD_G_CDR_LOCK_INT_BW_MASK << RXPMD_G2_CDR_LOCK_INT_BW_SHIFT |
RXPMD_G_CDR_LOCK_INT_BW_MASK << RXPMD_G3_CDR_LOCK_INT_BW_SHIFT;
if (port->ssc_en)
value = 1 << RXPMD_G1_CDR_LOCK_INT_BW_SHIFT |
1 << RXPMD_G2_CDR_LOCK_INT_BW_SHIFT |
1 << RXPMD_G3_CDR_LOCK_INT_BW_SHIFT;
else
value = 0;
brcm_sata_phy_wr(port, RXPMD_REG_BANK, RXPMD_RX_CDR_CDR_LOCK_INTEG_BW,
~tmp, value);
/* Set no guard band and clamp CDR */
tmp = RXPMD_MON_CORRECT_EN | RXPMD_MON_MARGIN_VAL_MASK;
if (port->ssc_en)
value = 0x51;
else
value = 0;
brcm_sata_phy_wr(port, RXPMD_REG_BANK, RXPMD_RX_FREQ_MON_CONTROL1,
~tmp, RXPMD_MON_CORRECT_EN | value);
/* Turn on/off SSC */
brcm_sata_phy_wr(port, TX_REG_BANK, TX_ACTRL5, ~TX_ACTRL5_SSC_EN,
port->ssc_en ? TX_ACTRL5_SSC_EN : 0);
return 0;
}
static int brcm_stb_sata_16nm_init(struct brcm_sata_port *port)
{
return brcm_stb_sata_16nm_ssc_init(port);
}
/* NS2 SATA PLL1 defaults were characterized by H/W group */
#define NS2_PLL1_ACTRL2_MAGIC 0x1df8
#define NS2_PLL1_ACTRL3_MAGIC 0x2b00
#define NS2_PLL1_ACTRL4_MAGIC 0x8824
static int brcm_ns2_sata_init(struct brcm_sata_port *port)
{
int try;
unsigned int val;
void __iomem *ctrl_base = brcm_sata_ctrl_base(port);
struct device *dev = port->phy_priv->dev;
/* Configure OOB control */
val = 0x0;
val |= (0xc << OOB_CTRL1_BURST_MAX_SHIFT);
val |= (0x4 << OOB_CTRL1_BURST_MIN_SHIFT);
val |= (0x9 << OOB_CTRL1_WAKE_IDLE_MAX_SHIFT);
val |= (0x3 << OOB_CTRL1_WAKE_IDLE_MIN_SHIFT);
brcm_sata_phy_wr(port, OOB_REG_BANK, OOB_CTRL1, 0x0, val);
val = 0x0;
val |= (0x1b << OOB_CTRL2_RESET_IDLE_MAX_SHIFT);
val |= (0x2 << OOB_CTRL2_BURST_CNT_SHIFT);
val |= (0x9 << OOB_CTRL2_RESET_IDLE_MIN_SHIFT);
brcm_sata_phy_wr(port, OOB_REG_BANK, OOB_CTRL2, 0x0, val);
/* Configure PHY PLL register bank 1 */
val = NS2_PLL1_ACTRL2_MAGIC;
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL2, 0x0, val);
val = NS2_PLL1_ACTRL3_MAGIC;
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL3, 0x0, val);
val = NS2_PLL1_ACTRL4_MAGIC;
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL4, 0x0, val);
/* Configure PHY BLOCK0 register bank */
/* Set oob_clk_sel to refclk/2 */
brcm_sata_phy_wr(port, BLOCK0_REG_BANK, BLOCK0_SPARE,
~BLOCK0_SPARE_OOB_CLK_SEL_MASK,
BLOCK0_SPARE_OOB_CLK_SEL_REFBY2);
/* Strobe PHY reset using PHY control register */
writel(PHY_CTRL_1_RESET, ctrl_base + PHY_CTRL_1);
mdelay(1);
writel(0x0, ctrl_base + PHY_CTRL_1);
mdelay(1);
/* Wait for PHY PLL lock by polling pll_lock bit */
try = 50;
while (try) {
val = brcm_sata_phy_rd(port, BLOCK0_REG_BANK,
BLOCK0_XGXSSTATUS);
if (val & BLOCK0_XGXSSTATUS_PLL_LOCK)
break;
msleep(20);
try--;
}
if (!try) {
/* PLL did not lock; give up */
dev_err(dev, "port%d PLL did not lock\n", port->portnum);
return -ETIMEDOUT;
}
dev_dbg(dev, "port%d initialized\n", port->portnum);
return 0;
}
static int brcm_nsp_sata_init(struct brcm_sata_port *port)
{
struct device *dev = port->phy_priv->dev;
unsigned int oob_bank;
unsigned int val, try;
/* Configure OOB control */
if (port->portnum == 0)
oob_bank = OOB_REG_BANK;
else if (port->portnum == 1)
oob_bank = OOB1_REG_BANK;
else
return -EINVAL;
val = 0x0;
val |= (0x0f << OOB_CTRL1_BURST_MAX_SHIFT);
val |= (0x06 << OOB_CTRL1_BURST_MIN_SHIFT);
val |= (0x0f << OOB_CTRL1_WAKE_IDLE_MAX_SHIFT);
val |= (0x06 << OOB_CTRL1_WAKE_IDLE_MIN_SHIFT);
brcm_sata_phy_wr(port, oob_bank, OOB_CTRL1, 0x0, val);
val = 0x0;
val |= (0x2e << OOB_CTRL2_RESET_IDLE_MAX_SHIFT);
val |= (0x02 << OOB_CTRL2_BURST_CNT_SHIFT);
val |= (0x16 << OOB_CTRL2_RESET_IDLE_MIN_SHIFT);
brcm_sata_phy_wr(port, oob_bank, OOB_CTRL2, 0x0, val);
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_ACTRL2,
~(PLL_ACTRL2_SELDIV_MASK << PLL_ACTRL2_SELDIV_SHIFT),
0x0c << PLL_ACTRL2_SELDIV_SHIFT);
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_CAP_CONTROL,
0xff0, 0x4f0);
val = PLLCONTROL_0_FREQ_DET_RESTART | PLLCONTROL_0_FREQ_MONITOR;
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_REG_BANK_0_PLLCONTROL_0,
~val, val);
val = PLLCONTROL_0_SEQ_START;
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_REG_BANK_0_PLLCONTROL_0,
~val, 0);
mdelay(10);
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_REG_BANK_0_PLLCONTROL_0,
~val, val);
/* Wait for pll_seq_done bit */
try = 50;
while (--try) {
val = brcm_sata_phy_rd(port, BLOCK0_REG_BANK,
BLOCK0_XGXSSTATUS);
if (val & BLOCK0_XGXSSTATUS_PLL_LOCK)
break;
msleep(20);
}
if (!try) {
/* PLL did not lock; give up */
dev_err(dev, "port%d PLL did not lock\n", port->portnum);
return -ETIMEDOUT;
}
dev_dbg(dev, "port%d initialized\n", port->portnum);
return 0;
}
/* SR PHY PLL0 registers */
#define SR_PLL0_ACTRL6_MAGIC 0xa
/* SR PHY PLL1 registers */
#define SR_PLL1_ACTRL2_MAGIC 0x32
#define SR_PLL1_ACTRL3_MAGIC 0x2
#define SR_PLL1_ACTRL4_MAGIC 0x3e8
static int brcm_sr_sata_init(struct brcm_sata_port *port)
{
struct device *dev = port->phy_priv->dev;
unsigned int val, try;
/* Configure PHY PLL register bank 1 */
val = SR_PLL1_ACTRL2_MAGIC;
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL2, 0x0, val);
val = SR_PLL1_ACTRL3_MAGIC;
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL3, 0x0, val);
val = SR_PLL1_ACTRL4_MAGIC;
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL4, 0x0, val);
/* Configure PHY PLL register bank 0 */
val = SR_PLL0_ACTRL6_MAGIC;
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_ACTRL6, 0x0, val);
/* Wait for PHY PLL lock by polling pll_lock bit */
try = 50;
do {
val = brcm_sata_phy_rd(port, BLOCK0_REG_BANK,
BLOCK0_XGXSSTATUS);
if (val & BLOCK0_XGXSSTATUS_PLL_LOCK)
break;
msleep(20);
try--;
} while (try);
if ((val & BLOCK0_XGXSSTATUS_PLL_LOCK) == 0) {
/* PLL did not lock; give up */
dev_err(dev, "port%d PLL did not lock\n", port->portnum);
return -ETIMEDOUT;
}
/* Invert Tx polarity */
brcm_sata_phy_wr(port, TX_REG_BANK, TX_ACTRL0,
~TX_ACTRL0_TXPOL_FLIP, TX_ACTRL0_TXPOL_FLIP);
/* Configure OOB control to handle 100MHz reference clock */
val = ((0xc << OOB_CTRL1_BURST_MAX_SHIFT) |
(0x4 << OOB_CTRL1_BURST_MIN_SHIFT) |
(0x8 << OOB_CTRL1_WAKE_IDLE_MAX_SHIFT) |
(0x3 << OOB_CTRL1_WAKE_IDLE_MIN_SHIFT));
brcm_sata_phy_wr(port, OOB_REG_BANK, OOB_CTRL1, 0x0, val);
val = ((0x1b << OOB_CTRL2_RESET_IDLE_MAX_SHIFT) |
(0x2 << OOB_CTRL2_BURST_CNT_SHIFT) |
(0x9 << OOB_CTRL2_RESET_IDLE_MIN_SHIFT));
brcm_sata_phy_wr(port, OOB_REG_BANK, OOB_CTRL2, 0x0, val);
return 0;
}
static int brcm_dsl_sata_init(struct brcm_sata_port *port)
{
struct device *dev = port->phy_priv->dev;
unsigned int try;
u32 tmp;
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL7, 0, 0x873);
brcm_sata_phy_wr(port, PLL1_REG_BANK, PLL1_ACTRL6, 0, 0xc000);
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_REG_BANK_0_PLLCONTROL_0,
0, 0x3089);
usleep_range(1000, 2000);
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_REG_BANK_0_PLLCONTROL_0,
0, 0x3088);
usleep_range(1000, 2000);
brcm_sata_phy_wr(port, AEQRX_REG_BANK_1, AEQRX_SLCAL0_CTRL0,
0, 0x3000);
brcm_sata_phy_wr(port, AEQRX_REG_BANK_1, AEQRX_SLCAL1_CTRL0,
0, 0x3000);
usleep_range(1000, 2000);
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_CAP_CHARGE_TIME, 0, 0x32);
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_VCO_CAL_THRESH, 0, 0xa);
brcm_sata_phy_wr(port, PLL_REG_BANK_0, PLL_FREQ_DET_TIME, 0, 0x64);
usleep_range(1000, 2000);
/* Acquire PLL lock */
try = 50;
while (try) {
tmp = brcm_sata_phy_rd(port, BLOCK0_REG_BANK,
BLOCK0_XGXSSTATUS);
if (tmp & BLOCK0_XGXSSTATUS_PLL_LOCK)
break;
msleep(20);
try--;
};
if (!try) {
/* PLL did not lock; give up */
dev_err(dev, "port%d PLL did not lock\n", port->portnum);
return -ETIMEDOUT;
}
dev_dbg(dev, "port%d initialized\n", port->portnum);
return 0;
}
static int brcm_sata_phy_init(struct phy *phy)
{
int rc;
struct brcm_sata_port *port = phy_get_drvdata(phy);
switch (port->phy_priv->version) {
case BRCM_SATA_PHY_STB_16NM:
rc = brcm_stb_sata_16nm_init(port);
break;
case BRCM_SATA_PHY_STB_28NM:
case BRCM_SATA_PHY_STB_40NM:
rc = brcm_stb_sata_init(port);
break;
case BRCM_SATA_PHY_IPROC_NS2:
rc = brcm_ns2_sata_init(port);
break;
case BRCM_SATA_PHY_IPROC_NSP:
rc = brcm_nsp_sata_init(port);
break;
case BRCM_SATA_PHY_IPROC_SR:
rc = brcm_sr_sata_init(port);
break;
case BRCM_SATA_PHY_DSL_28NM:
rc = brcm_dsl_sata_init(port);
break;
default:
rc = -ENODEV;
}
return rc;
}
static void brcm_stb_sata_calibrate(struct brcm_sata_port *port)
{
u32 tmp = BIT(8);
brcm_sata_phy_wr(port, RXPMD_REG_BANK, RXPMD_RX_FREQ_MON_CONTROL1,
~tmp, tmp);
}
static int brcm_sata_phy_calibrate(struct phy *phy)
{
struct brcm_sata_port *port = phy_get_drvdata(phy);
int rc = -EOPNOTSUPP;
switch (port->phy_priv->version) {
case BRCM_SATA_PHY_STB_28NM:
case BRCM_SATA_PHY_STB_40NM:
brcm_stb_sata_calibrate(port);
rc = 0;
break;
default:
break;
}
return rc;
}
static const struct phy_ops phy_ops = {
.init = brcm_sata_phy_init,
.calibrate = brcm_sata_phy_calibrate,
.owner = THIS_MODULE,
};
static const struct of_device_id brcm_sata_phy_of_match[] = {
{ .compatible = "brcm,bcm7216-sata-phy",
.data = (void *)BRCM_SATA_PHY_STB_16NM },
{ .compatible = "brcm,bcm7445-sata-phy",
.data = (void *)BRCM_SATA_PHY_STB_28NM },
{ .compatible = "brcm,bcm7425-sata-phy",
.data = (void *)BRCM_SATA_PHY_STB_40NM },
{ .compatible = "brcm,iproc-ns2-sata-phy",
.data = (void *)BRCM_SATA_PHY_IPROC_NS2 },
{ .compatible = "brcm,iproc-nsp-sata-phy",
.data = (void *)BRCM_SATA_PHY_IPROC_NSP },
{ .compatible = "brcm,iproc-sr-sata-phy",
.data = (void *)BRCM_SATA_PHY_IPROC_SR },
{ .compatible = "brcm,bcm63138-sata-phy",
.data = (void *)BRCM_SATA_PHY_DSL_28NM },
{},
};
MODULE_DEVICE_TABLE(of, brcm_sata_phy_of_match);
static int brcm_sata_phy_probe(struct platform_device *pdev)
{
const char *rxaeq_mode;
struct device *dev = &pdev->dev;
struct device_node *dn = dev->of_node, *child;
const struct of_device_id *of_id;
struct brcm_sata_phy *priv;
struct resource *res;
struct phy_provider *provider;
int ret, count = 0;
if (of_get_child_count(dn) == 0)
return -ENODEV;
priv = devm_kzalloc(dev, sizeof(*priv), GFP_KERNEL);
if (!priv)
return -ENOMEM;
dev_set_drvdata(dev, priv);
priv->dev = dev;
res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "phy");
priv->phy_base = devm_ioremap_resource(dev, res);
if (IS_ERR(priv->phy_base))
return PTR_ERR(priv->phy_base);
of_id = of_match_node(brcm_sata_phy_of_match, dn);
if (of_id)
priv->version = (enum brcm_sata_phy_version)of_id->data;
else
priv->version = BRCM_SATA_PHY_STB_28NM;
if (priv->version == BRCM_SATA_PHY_IPROC_NS2) {
res = platform_get_resource_byname(pdev, IORESOURCE_MEM,
"phy-ctrl");
priv->ctrl_base = devm_ioremap_resource(dev, res);
if (IS_ERR(priv->ctrl_base))
return PTR_ERR(priv->ctrl_base);
}
for_each_available_child_of_node(dn, child) {
unsigned int id;
struct brcm_sata_port *port;
if (of_property_read_u32(child, "reg", &id)) {
dev_err(dev, "missing reg property in node %pOFn\n",
child);
ret = -EINVAL;
goto put_child;
}
if (id >= MAX_PORTS) {
dev_err(dev, "invalid reg: %u\n", id);
ret = -EINVAL;
goto put_child;
}
if (priv->phys[id].phy) {
dev_err(dev, "already registered port %u\n", id);
ret = -EINVAL;
goto put_child;
}
port = &priv->phys[id];
port->portnum = id;
port->phy_priv = priv;
port->phy = devm_phy_create(dev, child, &phy_ops);
port->rxaeq_mode = RXAEQ_MODE_OFF;
if (!of_property_read_string(child, "brcm,rxaeq-mode",
&rxaeq_mode))
port->rxaeq_mode = rxaeq_to_val(rxaeq_mode);
if (port->rxaeq_mode == RXAEQ_MODE_MANUAL)
of_property_read_u32(child, "brcm,rxaeq-value",
&port->rxaeq_val);
port->ssc_en = of_property_read_bool(child, "brcm,enable-ssc");
if (IS_ERR(port->phy)) {
dev_err(dev, "failed to create PHY\n");
ret = PTR_ERR(port->phy);
goto put_child;
}
phy_set_drvdata(port->phy, port);
count++;
}
provider = devm_of_phy_provider_register(dev, of_phy_simple_xlate);
if (IS_ERR(provider)) {
dev_err(dev, "could not register PHY provider\n");
return PTR_ERR(provider);
}
dev_info(dev, "registered %d port(s)\n", count);
return 0;
put_child:
of_node_put(child);
return ret;
}
static struct platform_driver brcm_sata_phy_driver = {
.probe = brcm_sata_phy_probe,
.driver = {
.of_match_table = brcm_sata_phy_of_match,
.name = "brcm-sata-phy",
}
};
module_platform_driver(brcm_sata_phy_driver);
MODULE_DESCRIPTION("Broadcom SATA PHY driver");
MODULE_LICENSE("GPL");
MODULE_AUTHOR("Marc Carino");
MODULE_AUTHOR("Brian Norris");
MODULE_ALIAS("platform:phy-brcm-sata");
Reference in a new issue View git blame Copy permalink