linux_dsm_epyc7002/arch/arm/mach-omap2/vc.c
Linus Torvalds 825f4e0271 ARM: SoC updates for 3.16 (part 1)
A quite large set of SoC updates this cycle. In no particular order:
 
 - Multi-cluster power management for Samsung Exynos, adding support for
   big.LITTLE CPU switching on EXYNOS5
 - SMP support for Marvell Armada 375 and 38x
 - SMP rework on Allwinner A31
 - Xilinx Zynq support for SOC_BUS, big endian
 - Marvell orion5x platform cleanup, modernizing the implementation and
   moving to DT.
 - _Finally_ moving Samsung Exynos over to support MULTIPLATFORM, so
   that their platform can be enabled in the same kernel binary as most
   of the other v7 platforms in the tree. \o/ The work isn't quite complete,
   there's some driver fixes still needed, but the basics now work.
 
 New SoC support added:
 - Freescale i.MX6SX
 - LSI Axxia AXM55xx SoCs
 - Samsung EXYNOS 3250, 5260, 5410, 5420 and 5800
 - STi STIH407
 
 Plus a large set of various smaller updates for different platforms. I'm
 probably missing some important one here.
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Merge tag 'soc-for-3.16' of git://git.kernel.org/pub/scm/linux/kernel/git/arm/arm-soc into next

Pull part one of ARM SoC updates from Olof Johansson:
 "A quite large set of SoC updates this cycle.  In no particular order:

   - Multi-cluster power management for Samsung Exynos, adding support
     for big.LITTLE CPU switching on EXYNOS5

   - SMP support for Marvell Armada 375 and 38x

   - SMP rework on Allwinner A31

   - Xilinx Zynq support for SOC_BUS, big endian

   - Marvell orion5x platform cleanup, modernizing the implementation
     and moving to DT.

   - _Finally_ moving Samsung Exynos over to support MULTIPLATFORM, so
     that their platform can be enabled in the same kernel binary as
     most of the other v7 platforms in the tree.  \o/

     The work isn't quite complete, there's some driver fixes still
     needed, but the basics now work.

  New SoC support added:

   - Freescale i.MX6SX

   - LSI Axxia AXM55xx SoCs

   - Samsung EXYNOS 3250, 5260, 5410, 5420 and 5800

   - STi STIH407

  plus a large set of various smaller updates for different platforms.
  I'm probably missing some important one here"

* tag 'soc-for-3.16' of git://git.kernel.org/pub/scm/linux/kernel/git/arm/arm-soc: (281 commits)
  ARM: exynos: don't run exynos4 l2x0 setup on other platforms
  ARM: exynos: Fix "allmodconfig" build errors in mcpm and hotplug
  ARM: EXYNOS: mcpm rename the power_down_finish
  ARM: EXYNOS: Enable mcpm for dual-cluster exynos5800 SoC
  ARM: EXYNOS: Enable multi-platform build support
  ARM: EXYNOS: Consolidate Kconfig entries
  ARM: EXYNOS: Add support for EXYNOS5410 SoC
  ARM: EXYNOS: Support secondary CPU boot of Exynos3250
  ARM: EXYNOS: Add Exynos3250 SoC ID
  ARM: EXYNOS: Add 5800 SoC support
  ARM: EXYNOS: initial board support for exynos5260 SoC
  clk: exynos5410: register clocks using common clock framework
  ARM: debug: qcom: add UART addresses to Kconfig help for APQ8084
  ARM: sunxi: allow building without reset controller
  Documentation: devicetree: arm: sort enable-method entries
  ARM: rockchip: convert smp bringup to CPU_METHOD_OF_DECLARE
  clk: exynos5250: Add missing sysmmu clocks for DISP and ISP blocks
  ARM: dts: axxia: Add reset controller
  power: reset: Add Axxia system reset driver
  ARM: axxia: Adding defconfig for AXM55xx
  ...
2014-06-02 16:15:12 -07:00

840 lines
23 KiB
C

/*
* OMAP Voltage Controller (VC) interface
*
* Copyright (C) 2011 Texas Instruments, Inc.
*
* This file is licensed under the terms of the GNU General Public
* License version 2. This program is licensed "as is" without any
* warranty of any kind, whether express or implied.
*/
#include <linux/kernel.h>
#include <linux/delay.h>
#include <linux/init.h>
#include <linux/bug.h>
#include <linux/io.h>
#include <asm/div64.h>
#include "iomap.h"
#include "soc.h"
#include "voltage.h"
#include "vc.h"
#include "prm-regbits-34xx.h"
#include "prm-regbits-44xx.h"
#include "prm44xx.h"
#include "pm.h"
#include "scrm44xx.h"
#include "control.h"
/**
* struct omap_vc_channel_cfg - describe the cfg_channel bitfield
* @sa: bit for slave address
* @rav: bit for voltage configuration register
* @rac: bit for command configuration register
* @racen: enable bit for RAC
* @cmd: bit for command value set selection
*
* Channel configuration bits, common for OMAP3+
* OMAP3 register: PRM_VC_CH_CONF
* OMAP4 register: PRM_VC_CFG_CHANNEL
* OMAP5 register: PRM_VC_SMPS_<voltdm>_CONFIG
*/
struct omap_vc_channel_cfg {
u8 sa;
u8 rav;
u8 rac;
u8 racen;
u8 cmd;
};
static struct omap_vc_channel_cfg vc_default_channel_cfg = {
.sa = BIT(0),
.rav = BIT(1),
.rac = BIT(2),
.racen = BIT(3),
.cmd = BIT(4),
};
/*
* On OMAP3+, all VC channels have the above default bitfield
* configuration, except the OMAP4 MPU channel. This appears
* to be a freak accident as every other VC channel has the
* default configuration, thus creating a mutant channel config.
*/
static struct omap_vc_channel_cfg vc_mutant_channel_cfg = {
.sa = BIT(0),
.rav = BIT(2),
.rac = BIT(3),
.racen = BIT(4),
.cmd = BIT(1),
};
static struct omap_vc_channel_cfg *vc_cfg_bits;
/* Default I2C trace length on pcb, 6.3cm. Used for capacitance calculations. */
static u32 sr_i2c_pcb_length = 63;
#define CFG_CHANNEL_MASK 0x1f
/**
* omap_vc_config_channel - configure VC channel to PMIC mappings
* @voltdm: pointer to voltagdomain defining the desired VC channel
*
* Configures the VC channel to PMIC mappings for the following
* PMIC settings
* - i2c slave address (SA)
* - voltage configuration address (RAV)
* - command configuration address (RAC) and enable bit (RACEN)
* - command values for ON, ONLP, RET and OFF (CMD)
*
* This function currently only allows flexible configuration of the
* non-default channel. Starting with OMAP4, there are more than 2
* channels, with one defined as the default (on OMAP4, it's MPU.)
* Only the non-default channel can be configured.
*/
static int omap_vc_config_channel(struct voltagedomain *voltdm)
{
struct omap_vc_channel *vc = voltdm->vc;
/*
* For default channel, the only configurable bit is RACEN.
* All others must stay at zero (see function comment above.)
*/
if (vc->flags & OMAP_VC_CHANNEL_DEFAULT)
vc->cfg_channel &= vc_cfg_bits->racen;
voltdm->rmw(CFG_CHANNEL_MASK << vc->cfg_channel_sa_shift,
vc->cfg_channel << vc->cfg_channel_sa_shift,
vc->cfg_channel_reg);
return 0;
}
/* Voltage scale and accessory APIs */
int omap_vc_pre_scale(struct voltagedomain *voltdm,
unsigned long target_volt,
u8 *target_vsel, u8 *current_vsel)
{
struct omap_vc_channel *vc = voltdm->vc;
u32 vc_cmdval;
/* Check if sufficient pmic info is available for this vdd */
if (!voltdm->pmic) {
pr_err("%s: Insufficient pmic info to scale the vdd_%s\n",
__func__, voltdm->name);
return -EINVAL;
}
if (!voltdm->pmic->uv_to_vsel) {
pr_err("%s: PMIC function to convert voltage in uV to vsel not registered. Hence unable to scale voltage for vdd_%s\n",
__func__, voltdm->name);
return -ENODATA;
}
if (!voltdm->read || !voltdm->write) {
pr_err("%s: No read/write API for accessing vdd_%s regs\n",
__func__, voltdm->name);
return -EINVAL;
}
*target_vsel = voltdm->pmic->uv_to_vsel(target_volt);
*current_vsel = voltdm->pmic->uv_to_vsel(voltdm->nominal_volt);
/* Setting the ON voltage to the new target voltage */
vc_cmdval = voltdm->read(vc->cmdval_reg);
vc_cmdval &= ~vc->common->cmd_on_mask;
vc_cmdval |= (*target_vsel << vc->common->cmd_on_shift);
voltdm->write(vc_cmdval, vc->cmdval_reg);
voltdm->vc_param->on = target_volt;
omap_vp_update_errorgain(voltdm, target_volt);
return 0;
}
void omap_vc_post_scale(struct voltagedomain *voltdm,
unsigned long target_volt,
u8 target_vsel, u8 current_vsel)
{
u32 smps_steps = 0, smps_delay = 0;
smps_steps = abs(target_vsel - current_vsel);
/* SMPS slew rate / step size. 2us added as buffer. */
smps_delay = ((smps_steps * voltdm->pmic->step_size) /
voltdm->pmic->slew_rate) + 2;
udelay(smps_delay);
}
/* vc_bypass_scale - VC bypass method of voltage scaling */
int omap_vc_bypass_scale(struct voltagedomain *voltdm,
unsigned long target_volt)
{
struct omap_vc_channel *vc = voltdm->vc;
u32 loop_cnt = 0, retries_cnt = 0;
u32 vc_valid, vc_bypass_val_reg, vc_bypass_value;
u8 target_vsel, current_vsel;
int ret;
ret = omap_vc_pre_scale(voltdm, target_volt, &target_vsel, &current_vsel);
if (ret)
return ret;
vc_valid = vc->common->valid;
vc_bypass_val_reg = vc->common->bypass_val_reg;
vc_bypass_value = (target_vsel << vc->common->data_shift) |
(vc->volt_reg_addr << vc->common->regaddr_shift) |
(vc->i2c_slave_addr << vc->common->slaveaddr_shift);
voltdm->write(vc_bypass_value, vc_bypass_val_reg);
voltdm->write(vc_bypass_value | vc_valid, vc_bypass_val_reg);
vc_bypass_value = voltdm->read(vc_bypass_val_reg);
/*
* Loop till the bypass command is acknowledged from the SMPS.
* NOTE: This is legacy code. The loop count and retry count needs
* to be revisited.
*/
while (!(vc_bypass_value & vc_valid)) {
loop_cnt++;
if (retries_cnt > 10) {
pr_warning("%s: Retry count exceeded\n", __func__);
return -ETIMEDOUT;
}
if (loop_cnt > 50) {
retries_cnt++;
loop_cnt = 0;
udelay(10);
}
vc_bypass_value = voltdm->read(vc_bypass_val_reg);
}
omap_vc_post_scale(voltdm, target_volt, target_vsel, current_vsel);
return 0;
}
/* Convert microsecond value to number of 32kHz clock cycles */
static inline u32 omap_usec_to_32k(u32 usec)
{
return DIV_ROUND_UP_ULL(32768ULL * (u64)usec, 1000000ULL);
}
struct omap3_vc_timings {
u32 voltsetup1;
u32 voltsetup2;
};
struct omap3_vc {
struct voltagedomain *vd;
u32 voltctrl;
u32 voltsetup1;
u32 voltsetup2;
struct omap3_vc_timings timings[2];
};
static struct omap3_vc vc;
void omap3_vc_set_pmic_signaling(int core_next_state)
{
struct voltagedomain *vd = vc.vd;
struct omap3_vc_timings *c = vc.timings;
u32 voltctrl, voltsetup1, voltsetup2;
voltctrl = vc.voltctrl;
voltsetup1 = vc.voltsetup1;
voltsetup2 = vc.voltsetup2;
switch (core_next_state) {
case PWRDM_POWER_OFF:
voltctrl &= ~(OMAP3430_PRM_VOLTCTRL_AUTO_RET |
OMAP3430_PRM_VOLTCTRL_AUTO_SLEEP);
voltctrl |= OMAP3430_PRM_VOLTCTRL_AUTO_OFF;
if (voltctrl & OMAP3430_PRM_VOLTCTRL_SEL_OFF)
voltsetup2 = c->voltsetup2;
else
voltsetup1 = c->voltsetup1;
break;
case PWRDM_POWER_RET:
default:
c++;
voltctrl &= ~(OMAP3430_PRM_VOLTCTRL_AUTO_OFF |
OMAP3430_PRM_VOLTCTRL_AUTO_SLEEP);
voltctrl |= OMAP3430_PRM_VOLTCTRL_AUTO_RET;
voltsetup1 = c->voltsetup1;
break;
}
if (voltctrl != vc.voltctrl) {
vd->write(voltctrl, OMAP3_PRM_VOLTCTRL_OFFSET);
vc.voltctrl = voltctrl;
}
if (voltsetup1 != vc.voltsetup1) {
vd->write(c->voltsetup1,
OMAP3_PRM_VOLTSETUP1_OFFSET);
vc.voltsetup1 = voltsetup1;
}
if (voltsetup2 != vc.voltsetup2) {
vd->write(c->voltsetup2,
OMAP3_PRM_VOLTSETUP2_OFFSET);
vc.voltsetup2 = voltsetup2;
}
}
#define PRM_POLCTRL_TWL_MASK (OMAP3430_PRM_POLCTRL_CLKREQ_POL | \
OMAP3430_PRM_POLCTRL_CLKREQ_POL)
#define PRM_POLCTRL_TWL_VAL OMAP3430_PRM_POLCTRL_CLKREQ_POL
/*
* Configure signal polarity for sys_clkreq and sys_off_mode pins
* as the default values are wrong and can cause the system to hang
* if any twl4030 scripts are loaded.
*/
static void __init omap3_vc_init_pmic_signaling(struct voltagedomain *voltdm)
{
u32 val;
if (vc.vd)
return;
vc.vd = voltdm;
val = voltdm->read(OMAP3_PRM_POLCTRL_OFFSET);
if (!(val & OMAP3430_PRM_POLCTRL_CLKREQ_POL) ||
(val & OMAP3430_PRM_POLCTRL_CLKREQ_POL)) {
val |= OMAP3430_PRM_POLCTRL_CLKREQ_POL;
val &= ~OMAP3430_PRM_POLCTRL_OFFMODE_POL;
pr_debug("PM: fixing sys_clkreq and sys_off_mode polarity to 0x%x\n",
val);
voltdm->write(val, OMAP3_PRM_POLCTRL_OFFSET);
}
/*
* By default let's use I2C4 signaling for retention idle
* and sys_off_mode pin signaling for off idle. This way we
* have sys_clk_req pin go down for retention and both
* sys_clk_req and sys_off_mode pins will go down for off
* idle. And we can also scale voltages to zero for off-idle.
* Note that no actual voltage scaling during off-idle will
* happen unless the board specific twl4030 PMIC scripts are
* loaded.
*/
val = voltdm->read(OMAP3_PRM_VOLTCTRL_OFFSET);
if (!(val & OMAP3430_PRM_VOLTCTRL_SEL_OFF)) {
val |= OMAP3430_PRM_VOLTCTRL_SEL_OFF;
pr_debug("PM: setting voltctrl sys_off_mode signaling to 0x%x\n",
val);
voltdm->write(val, OMAP3_PRM_VOLTCTRL_OFFSET);
}
vc.voltctrl = val;
omap3_vc_set_pmic_signaling(PWRDM_POWER_ON);
}
static void omap3_init_voltsetup1(struct voltagedomain *voltdm,
struct omap3_vc_timings *c, u32 idle)
{
unsigned long val;
val = (voltdm->vc_param->on - idle) / voltdm->pmic->slew_rate;
val *= voltdm->sys_clk.rate / 8 / 1000000 + 1;
val <<= __ffs(voltdm->vfsm->voltsetup_mask);
c->voltsetup1 &= ~voltdm->vfsm->voltsetup_mask;
c->voltsetup1 |= val;
}
/**
* omap3_set_i2c_timings - sets i2c sleep timings for a channel
* @voltdm: channel to configure
* @off_mode: select whether retention or off mode values used
*
* Calculates and sets up voltage controller to use I2C based
* voltage scaling for sleep modes. This can be used for either off mode
* or retention. Off mode has additionally an option to use sys_off_mode
* pad, which uses a global signal to program the whole power IC to
* off-mode.
*
* Note that pmic is not controlling the voltage scaling during
* retention signaled over I2C4, so we can keep voltsetup2 as 0.
* And the oscillator is not shut off over I2C4, so no need to
* set clksetup.
*/
static void omap3_set_i2c_timings(struct voltagedomain *voltdm)
{
struct omap3_vc_timings *c = vc.timings;
/* Configure PRWDM_POWER_OFF over I2C4 */
omap3_init_voltsetup1(voltdm, c, voltdm->vc_param->off);
c++;
/* Configure PRWDM_POWER_RET over I2C4 */
omap3_init_voltsetup1(voltdm, c, voltdm->vc_param->ret);
}
/**
* omap3_set_off_timings - sets off-mode timings for a channel
* @voltdm: channel to configure
*
* Calculates and sets up off-mode timings for a channel. Off-mode
* can use either I2C based voltage scaling, or alternatively
* sys_off_mode pad can be used to send a global command to power IC.n,
* sys_off_mode has the additional benefit that voltages can be
* scaled to zero volt level with TWL4030 / TWL5030, I2C can only
* scale to 600mV.
*
* Note that omap is not controlling the voltage scaling during
* off idle signaled by sys_off_mode, so we can keep voltsetup1
* as 0.
*/
static void omap3_set_off_timings(struct voltagedomain *voltdm)
{
struct omap3_vc_timings *c = vc.timings;
u32 tstart, tshut, clksetup, voltoffset;
if (c->voltsetup2)
return;
omap_pm_get_oscillator(&tstart, &tshut);
if (tstart == ULONG_MAX) {
pr_debug("PM: oscillator start-up time not initialized, using 10ms\n");
clksetup = omap_usec_to_32k(10000);
} else {
clksetup = omap_usec_to_32k(tstart);
}
/*
* For twl4030 errata 27, we need to allow minimum ~488.32 us wait to
* switch from HFCLKIN to internal oscillator. That means timings
* have voltoffset fixed to 0xa in rounded up 32 KiHz cycles. And
* that means we can calculate the value based on the oscillator
* start-up time since voltoffset2 = clksetup - voltoffset.
*/
voltoffset = omap_usec_to_32k(488);
c->voltsetup2 = clksetup - voltoffset;
voltdm->write(clksetup, OMAP3_PRM_CLKSETUP_OFFSET);
voltdm->write(voltoffset, OMAP3_PRM_VOLTOFFSET_OFFSET);
}
static void __init omap3_vc_init_channel(struct voltagedomain *voltdm)
{
omap3_vc_init_pmic_signaling(voltdm);
omap3_set_off_timings(voltdm);
omap3_set_i2c_timings(voltdm);
}
/**
* omap4_calc_volt_ramp - calculates voltage ramping delays on omap4
* @voltdm: channel to calculate values for
* @voltage_diff: voltage difference in microvolts
*
* Calculates voltage ramp prescaler + counter values for a voltage
* difference on omap4. Returns a field value suitable for writing to
* VOLTSETUP register for a channel in following format:
* bits[8:9] prescaler ... bits[0:5] counter. See OMAP4 TRM for reference.
*/
static u32 omap4_calc_volt_ramp(struct voltagedomain *voltdm, u32 voltage_diff)
{
u32 prescaler;
u32 cycles;
u32 time;
time = voltage_diff / voltdm->pmic->slew_rate;
cycles = voltdm->sys_clk.rate / 1000 * time / 1000;
cycles /= 64;
prescaler = 0;
/* shift to next prescaler until no overflow */
/* scale for div 256 = 64 * 4 */
if (cycles > 63) {
cycles /= 4;
prescaler++;
}
/* scale for div 512 = 256 * 2 */
if (cycles > 63) {
cycles /= 2;
prescaler++;
}
/* scale for div 2048 = 512 * 4 */
if (cycles > 63) {
cycles /= 4;
prescaler++;
}
/* check for overflow => invalid ramp time */
if (cycles > 63) {
pr_warn("%s: invalid setuptime for vdd_%s\n", __func__,
voltdm->name);
return 0;
}
cycles++;
return (prescaler << OMAP4430_RAMP_UP_PRESCAL_SHIFT) |
(cycles << OMAP4430_RAMP_UP_COUNT_SHIFT);
}
/**
* omap4_usec_to_val_scrm - convert microsecond value to SCRM module bitfield
* @usec: microseconds
* @shift: number of bits to shift left
* @mask: bitfield mask
*
* Converts microsecond value to OMAP4 SCRM bitfield. Bitfield is
* shifted to requested position, and checked agains the mask value.
* If larger, forced to the max value of the field (i.e. the mask itself.)
* Returns the SCRM bitfield value.
*/
static u32 omap4_usec_to_val_scrm(u32 usec, int shift, u32 mask)
{
u32 val;
val = omap_usec_to_32k(usec) << shift;
/* Check for overflow, if yes, force to max value */
if (val > mask)
val = mask;
return val;
}
/**
* omap4_set_timings - set voltage ramp timings for a channel
* @voltdm: channel to configure
* @off_mode: whether off-mode values are used
*
* Calculates and sets the voltage ramp up / down values for a channel.
*/
static void omap4_set_timings(struct voltagedomain *voltdm, bool off_mode)
{
u32 val;
u32 ramp;
int offset;
u32 tstart, tshut;
if (off_mode) {
ramp = omap4_calc_volt_ramp(voltdm,
voltdm->vc_param->on - voltdm->vc_param->off);
offset = voltdm->vfsm->voltsetup_off_reg;
} else {
ramp = omap4_calc_volt_ramp(voltdm,
voltdm->vc_param->on - voltdm->vc_param->ret);
offset = voltdm->vfsm->voltsetup_reg;
}
if (!ramp)
return;
val = voltdm->read(offset);
val |= ramp << OMAP4430_RAMP_DOWN_COUNT_SHIFT;
val |= ramp << OMAP4430_RAMP_UP_COUNT_SHIFT;
voltdm->write(val, offset);
omap_pm_get_oscillator(&tstart, &tshut);
val = omap4_usec_to_val_scrm(tstart, OMAP4_SETUPTIME_SHIFT,
OMAP4_SETUPTIME_MASK);
val |= omap4_usec_to_val_scrm(tshut, OMAP4_DOWNTIME_SHIFT,
OMAP4_DOWNTIME_MASK);
writel_relaxed(val, OMAP4_SCRM_CLKSETUPTIME);
}
/* OMAP4 specific voltage init functions */
static void __init omap4_vc_init_channel(struct voltagedomain *voltdm)
{
omap4_set_timings(voltdm, true);
omap4_set_timings(voltdm, false);
}
struct i2c_init_data {
u8 loadbits;
u8 load;
u8 hsscll_38_4;
u8 hsscll_26;
u8 hsscll_19_2;
u8 hsscll_16_8;
u8 hsscll_12;
};
static const __initdata struct i2c_init_data omap4_i2c_timing_data[] = {
{
.load = 50,
.loadbits = 0x3,
.hsscll_38_4 = 13,
.hsscll_26 = 11,
.hsscll_19_2 = 9,
.hsscll_16_8 = 9,
.hsscll_12 = 8,
},
{
.load = 25,
.loadbits = 0x2,
.hsscll_38_4 = 13,
.hsscll_26 = 11,
.hsscll_19_2 = 9,
.hsscll_16_8 = 9,
.hsscll_12 = 8,
},
{
.load = 12,
.loadbits = 0x1,
.hsscll_38_4 = 11,
.hsscll_26 = 10,
.hsscll_19_2 = 9,
.hsscll_16_8 = 9,
.hsscll_12 = 8,
},
{
.load = 0,
.loadbits = 0x0,
.hsscll_38_4 = 12,
.hsscll_26 = 10,
.hsscll_19_2 = 9,
.hsscll_16_8 = 8,
.hsscll_12 = 8,
},
};
/**
* omap4_vc_i2c_timing_init - sets up board I2C timing parameters
* @voltdm: voltagedomain pointer to get data from
*
* Use PMIC + board supplied settings for calculating the total I2C
* channel capacitance and set the timing parameters based on this.
* Pre-calculated values are provided in data tables, as it is not
* too straightforward to calculate these runtime.
*/
static void __init omap4_vc_i2c_timing_init(struct voltagedomain *voltdm)
{
u32 capacitance;
u32 val;
u16 hsscll;
const struct i2c_init_data *i2c_data;
if (!voltdm->pmic->i2c_high_speed) {
pr_warn("%s: only high speed supported!\n", __func__);
return;
}
/* PCB trace capacitance, 0.125pF / mm => mm / 8 */
capacitance = DIV_ROUND_UP(sr_i2c_pcb_length, 8);
/* OMAP pad capacitance */
capacitance += 4;
/* PMIC pad capacitance */
capacitance += voltdm->pmic->i2c_pad_load;
/* Search for capacitance match in the table */
i2c_data = omap4_i2c_timing_data;
while (i2c_data->load > capacitance)
i2c_data++;
/* Select proper values based on sysclk frequency */
switch (voltdm->sys_clk.rate) {
case 38400000:
hsscll = i2c_data->hsscll_38_4;
break;
case 26000000:
hsscll = i2c_data->hsscll_26;
break;
case 19200000:
hsscll = i2c_data->hsscll_19_2;
break;
case 16800000:
hsscll = i2c_data->hsscll_16_8;
break;
case 12000000:
hsscll = i2c_data->hsscll_12;
break;
default:
pr_warn("%s: unsupported sysclk rate: %d!\n", __func__,
voltdm->sys_clk.rate);
return;
}
/* Loadbits define pull setup for the I2C channels */
val = i2c_data->loadbits << 25 | i2c_data->loadbits << 29;
/* Write to SYSCTRL_PADCONF_WKUP_CTRL_I2C_2 to setup I2C pull */
writel_relaxed(val, OMAP2_L4_IO_ADDRESS(OMAP4_CTRL_MODULE_PAD_WKUP +
OMAP4_CTRL_MODULE_PAD_WKUP_CONTROL_I2C_2));
/* HSSCLH can always be zero */
val = hsscll << OMAP4430_HSSCLL_SHIFT;
val |= (0x28 << OMAP4430_SCLL_SHIFT | 0x2c << OMAP4430_SCLH_SHIFT);
/* Write setup times to I2C config register */
voltdm->write(val, OMAP4_PRM_VC_CFG_I2C_CLK_OFFSET);
}
/**
* omap_vc_i2c_init - initialize I2C interface to PMIC
* @voltdm: voltage domain containing VC data
*
* Use PMIC supplied settings for I2C high-speed mode and
* master code (if set) and program the VC I2C configuration
* register.
*
* The VC I2C configuration is common to all VC channels,
* so this function only configures I2C for the first VC
* channel registers. All other VC channels will use the
* same configuration.
*/
static void __init omap_vc_i2c_init(struct voltagedomain *voltdm)
{
struct omap_vc_channel *vc = voltdm->vc;
static bool initialized;
static bool i2c_high_speed;
u8 mcode;
if (initialized) {
if (voltdm->pmic->i2c_high_speed != i2c_high_speed)
pr_warn("%s: I2C config for vdd_%s does not match other channels (%u).\n",
__func__, voltdm->name, i2c_high_speed);
return;
}
i2c_high_speed = voltdm->pmic->i2c_high_speed;
if (i2c_high_speed)
voltdm->rmw(vc->common->i2c_cfg_hsen_mask,
vc->common->i2c_cfg_hsen_mask,
vc->common->i2c_cfg_reg);
mcode = voltdm->pmic->i2c_mcode;
if (mcode)
voltdm->rmw(vc->common->i2c_mcode_mask,
mcode << __ffs(vc->common->i2c_mcode_mask),
vc->common->i2c_cfg_reg);
if (cpu_is_omap44xx())
omap4_vc_i2c_timing_init(voltdm);
initialized = true;
}
/**
* omap_vc_calc_vsel - calculate vsel value for a channel
* @voltdm: channel to calculate value for
* @uvolt: microvolt value to convert to vsel
*
* Converts a microvolt value to vsel value for the used PMIC.
* This checks whether the microvolt value is out of bounds, and
* adjusts the value accordingly. If unsupported value detected,
* warning is thrown.
*/
static u8 omap_vc_calc_vsel(struct voltagedomain *voltdm, u32 uvolt)
{
if (voltdm->pmic->vddmin > uvolt)
uvolt = voltdm->pmic->vddmin;
if (voltdm->pmic->vddmax < uvolt) {
WARN(1, "%s: voltage not supported by pmic: %u vs max %u\n",
__func__, uvolt, voltdm->pmic->vddmax);
/* Lets try maximum value anyway */
uvolt = voltdm->pmic->vddmax;
}
return voltdm->pmic->uv_to_vsel(uvolt);
}
#ifdef CONFIG_PM
/**
* omap_pm_setup_sr_i2c_pcb_length - set length of SR I2C traces on PCB
* @mm: length of the PCB trace in millimetres
*
* Sets the PCB trace length for the I2C channel. By default uses 63mm.
* This is needed for properly calculating the capacitance value for
* the PCB trace, and for setting the SR I2C channel timing parameters.
*/
void __init omap_pm_setup_sr_i2c_pcb_length(u32 mm)
{
sr_i2c_pcb_length = mm;
}
#endif
void __init omap_vc_init_channel(struct voltagedomain *voltdm)
{
struct omap_vc_channel *vc = voltdm->vc;
u8 on_vsel, onlp_vsel, ret_vsel, off_vsel;
u32 val;
if (!voltdm->pmic || !voltdm->pmic->uv_to_vsel) {
pr_err("%s: No PMIC info for vdd_%s\n", __func__, voltdm->name);
return;
}
if (!voltdm->read || !voltdm->write) {
pr_err("%s: No read/write API for accessing vdd_%s regs\n",
__func__, voltdm->name);
return;
}
vc->cfg_channel = 0;
if (vc->flags & OMAP_VC_CHANNEL_CFG_MUTANT)
vc_cfg_bits = &vc_mutant_channel_cfg;
else
vc_cfg_bits = &vc_default_channel_cfg;
/* get PMIC/board specific settings */
vc->i2c_slave_addr = voltdm->pmic->i2c_slave_addr;
vc->volt_reg_addr = voltdm->pmic->volt_reg_addr;
vc->cmd_reg_addr = voltdm->pmic->cmd_reg_addr;
/* Configure the i2c slave address for this VC */
voltdm->rmw(vc->smps_sa_mask,
vc->i2c_slave_addr << __ffs(vc->smps_sa_mask),
vc->smps_sa_reg);
vc->cfg_channel |= vc_cfg_bits->sa;
/*
* Configure the PMIC register addresses.
*/
voltdm->rmw(vc->smps_volra_mask,
vc->volt_reg_addr << __ffs(vc->smps_volra_mask),
vc->smps_volra_reg);
vc->cfg_channel |= vc_cfg_bits->rav;
if (vc->cmd_reg_addr) {
voltdm->rmw(vc->smps_cmdra_mask,
vc->cmd_reg_addr << __ffs(vc->smps_cmdra_mask),
vc->smps_cmdra_reg);
vc->cfg_channel |= vc_cfg_bits->rac;
}
if (vc->cmd_reg_addr == vc->volt_reg_addr)
vc->cfg_channel |= vc_cfg_bits->racen;
/* Set up the on, inactive, retention and off voltage */
on_vsel = omap_vc_calc_vsel(voltdm, voltdm->vc_param->on);
onlp_vsel = omap_vc_calc_vsel(voltdm, voltdm->vc_param->onlp);
ret_vsel = omap_vc_calc_vsel(voltdm, voltdm->vc_param->ret);
off_vsel = omap_vc_calc_vsel(voltdm, voltdm->vc_param->off);
val = ((on_vsel << vc->common->cmd_on_shift) |
(onlp_vsel << vc->common->cmd_onlp_shift) |
(ret_vsel << vc->common->cmd_ret_shift) |
(off_vsel << vc->common->cmd_off_shift));
voltdm->write(val, vc->cmdval_reg);
vc->cfg_channel |= vc_cfg_bits->cmd;
/* Channel configuration */
omap_vc_config_channel(voltdm);
omap_vc_i2c_init(voltdm);
if (cpu_is_omap34xx())
omap3_vc_init_channel(voltdm);
else if (cpu_is_omap44xx())
omap4_vc_init_channel(voltdm);
}