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pata_at91: SMC settings calculation bugfixes, support for t6z and IORDY

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* New code correctly calculates SMC registers values, adjusts calculated
  to admissible ranges, enlarges cycles when required and converts values
  into SMC's format.
* Support for TDF cycles (ATA t6z) and IORDY line added.
* Eliminate need in the initial_timing structure.
* Code cleanup.

Signed-off-by: Igor Plyatov <plyatov@gmail.com>
Signed-off-by: Jeff Garzik <jgarzik@pobox.com>
This commit is contained in:
Igor Plyatov 2011-05-12 22:15:51 +04:00 committed by Jeff Garzik
parent af649a1b56
commit 0144261fa6
1 changed files with 193 additions and 94 deletions
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287
drivers/ata/pata_at91.c
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@ -3,6 +3,7 @@
* with CompactFlash interface in True IDE mode
*
* Copyright (C) 2009 Matyukevich Sergey
* 2011 Igor Plyatov
*
* Based on:
* * generic platform driver by Paul Mundt: drivers/ata/pata_platform.c
@ -31,38 +32,150 @@
#include <mach/board.h>
#include <mach/gpio.h>
#define DRV_NAME "pata_at91"
#define DRV_VERSION "0.3"
#define DRV_NAME "pata_at91"
#define DRV_VERSION "0.2"
#define CF_IDE_OFFSET 0x00c00000
#define CF_ALT_IDE_OFFSET 0x00e00000
#define CF_IDE_RES_SIZE 0x08
#define NCS_RD_PULSE_LIMIT 0x3f /* maximal value for pulse bitfields */
#define CF_IDE_OFFSET 0x00c00000
#define CF_ALT_IDE_OFFSET 0x00e00000
#define CF_IDE_RES_SIZE 0x08
#define CS_PULSE_MAXIMUM 319
#define ER_SMC_CALC 1
#define ER_SMC_RECALC 2
struct at91_ide_info {
unsigned long mode;
unsigned int cs;
struct clk *mck;
void __iomem *ide_addr;
void __iomem *alt_addr;
};
static const struct ata_timing initial_timing = {
.mode = XFER_PIO_0,
.setup = 70,
.act8b = 290,
.rec8b = 240,
.cyc8b = 600,
.active = 165,
.recover = 150,
.dmack_hold = 0,
.cycle = 600,
.udma = 0
/**
* struct smc_range - range of valid values for SMC register.
*/
struct smc_range {
int min;
int max;
};
/**
* adjust_smc_value - adjust value for one of SMC registers.
* @value: adjusted value
* @range: array of SMC ranges with valid values
* @size: SMC ranges array size
*
* This returns the difference between input and output value or negative
* in case of invalid input value.
* If negative returned, then output value = maximal possible from ranges.
*/
static int adjust_smc_value(int *value, struct smc_range *range, int size)
{
int maximum = (range + size - 1)->max;
int remainder;
do {
if (*value < range->min) {
remainder = range->min - *value;
*value = range->min; /* nearest valid value */
return remainder;
} else if ((range->min <= *value) && (*value <= range->max))
return 0;
range++;
} while (--size);
*value = maximum;
return -1; /* invalid value */
}
/**
* calc_smc_vals - calculate SMC register values
* @dev: ATA device
* @setup: SMC_SETUP register value
* @pulse: SMC_PULSE register value
* @cycle: SMC_CYCLE register value
*
* This returns negative in case of invalid values for SMC registers:
* -ER_SMC_RECALC - recalculation required for SMC values,
* -ER_SMC_CALC - calculation failed (invalid input values).
*
* SMC use special coding scheme, see "Coding and Range of Timing
* Parameters" table from AT91SAM9 datasheets.
*
* SMC_SETUP = 128*setup[5] + setup[4:0]
* SMC_PULSE = 256*pulse[6] + pulse[5:0]
* SMC_CYCLE = 256*cycle[8:7] + cycle[6:0]
*/
static int calc_smc_vals(struct device *dev,
int *setup, int *pulse, int *cycle, int *cs_pulse)
{
int ret_val;
int err = 0;
struct smc_range range_setup[] = { /* SMC_SETUP valid values */
{.min = 0, .max = 31}, /* first range */
{.min = 128, .max = 159} /* second range */
};
struct smc_range range_pulse[] = { /* SMC_PULSE valid values */
{.min = 0, .max = 63}, /* first range */
{.min = 256, .max = 319} /* second range */
};
struct smc_range range_cycle[] = { /* SMC_CYCLE valid values */
{.min = 0, .max = 127}, /* first range */
{.min = 256, .max = 383}, /* second range */
{.min = 512, .max = 639}, /* third range */
{.min = 768, .max = 895} /* fourth range */
};
ret_val = adjust_smc_value(setup, range_setup, ARRAY_SIZE(range_setup));
if (ret_val < 0)
dev_warn(dev, "maximal SMC Setup value\n");
else
*cycle += ret_val;
ret_val = adjust_smc_value(pulse, range_pulse, ARRAY_SIZE(range_pulse));
if (ret_val < 0)
dev_warn(dev, "maximal SMC Pulse value\n");
else
*cycle += ret_val;
ret_val = adjust_smc_value(cycle, range_cycle, ARRAY_SIZE(range_cycle));
if (ret_val < 0)
dev_warn(dev, "maximal SMC Cycle value\n");
*cs_pulse = *cycle;
if (*cs_pulse > CS_PULSE_MAXIMUM) {
dev_err(dev, "unable to calculate valid SMC settings\n");
return -ER_SMC_CALC;
}
ret_val = adjust_smc_value(cs_pulse, range_pulse,
ARRAY_SIZE(range_pulse));
if (ret_val < 0) {
dev_warn(dev, "maximal SMC CS Pulse value\n");
} else if (ret_val != 0) {
*cycle = *cs_pulse;
dev_warn(dev, "SMC Cycle extended\n");
err = -ER_SMC_RECALC;
}
return err;
}
/**
* to_smc_format - convert values into SMC format
* @setup: SETUP value of SMC Setup Register
* @pulse: PULSE value of SMC Pulse Register
* @cycle: CYCLE value of SMC Cycle Register
* @cs_pulse: NCS_PULSE value of SMC Pulse Register
*/
static void to_smc_format(int *setup, int *pulse, int *cycle, int *cs_pulse)
{
*setup = (*setup & 0x1f) | ((*setup & 0x80) >> 2);
*pulse = (*pulse & 0x3f) | ((*pulse & 0x100) >> 2);
*cycle = (*cycle & 0x7f) | ((*cycle & 0x300) >> 1);
*cs_pulse = (*cs_pulse & 0x3f) | ((*cs_pulse & 0x100) >> 2);
}
static unsigned long calc_mck_cycles(unsigned long ns, unsigned long mck_hz)
{
unsigned long mul;
@ -80,85 +193,77 @@ static unsigned long calc_mck_cycles(unsigned long ns, unsigned long mck_hz)
return (ns * mul + 65536) >> 16; /* rounding */
}
static void set_smc_mode(struct at91_ide_info *info)
{
at91_sys_write(AT91_SMC_MODE(info->cs), info->mode);
return;
}
static void set_smc_timing(struct device *dev,
/**
* set_smc_timing - SMC timings setup.
* @dev: device
* @info: AT91 IDE info
* @ata: ATA timings
*
* Its assumed that write timings are same as read timings,
* cs_setup = 0 and cs_pulse = cycle.
*/
static void set_smc_timing(struct device *dev, struct ata_device *adev,
struct at91_ide_info *info, const struct ata_timing *ata)
{
unsigned long read_cycle, write_cycle, active, recover;
unsigned long nrd_setup, nrd_pulse, nrd_recover;
unsigned long nwe_setup, nwe_pulse;
unsigned long ncs_write_setup, ncs_write_pulse;
unsigned long ncs_read_setup, ncs_read_pulse;
unsigned long mck_hz;
read_cycle = ata->cyc8b;
nrd_setup = ata->setup;
nrd_pulse = ata->act8b;
nrd_recover = ata->rec8b;
int ret = 0;
int use_iordy;
unsigned int t6z; /* data tristate time in ns */
unsigned int cycle; /* SMC Cycle width in MCK ticks */
unsigned int setup; /* SMC Setup width in MCK ticks */
unsigned int pulse; /* CFIOR and CFIOW pulse width in MCK ticks */
unsigned int cs_setup = 0;/* CS4 or CS5 setup width in MCK ticks */
unsigned int cs_pulse; /* CS4 or CS5 pulse width in MCK ticks*/
unsigned int tdf_cycles; /* SMC TDF MCK ticks */
unsigned long mck_hz; /* MCK frequency in Hz */
t6z = (ata->mode < XFER_PIO_5) ? 30 : 20;
mck_hz = clk_get_rate(info->mck);
cycle = calc_mck_cycles(ata->cyc8b, mck_hz);
setup = calc_mck_cycles(ata->setup, mck_hz);
pulse = calc_mck_cycles(ata->act8b, mck_hz);
tdf_cycles = calc_mck_cycles(t6z, mck_hz);
read_cycle = calc_mck_cycles(read_cycle, mck_hz);
nrd_setup = calc_mck_cycles(nrd_setup, mck_hz);
nrd_pulse = calc_mck_cycles(nrd_pulse, mck_hz);
nrd_recover = calc_mck_cycles(nrd_recover, mck_hz);
do {
ret = calc_smc_vals(dev, &setup, &pulse, &cycle, &cs_pulse);
} while (ret == -ER_SMC_RECALC);
active = nrd_setup + nrd_pulse;
recover = read_cycle - active;
if (ret == -ER_SMC_CALC)
dev_err(dev, "Interface may not operate correctly\n");
/* Need at least two cycles recovery */
if (recover < 2)
read_cycle = active + 2;
dev_dbg(dev, "SMC Setup=%u, Pulse=%u, Cycle=%u, CS Pulse=%u\n",
setup, pulse, cycle, cs_pulse);
to_smc_format(&setup, &pulse, &cycle, &cs_pulse);
/* disable or enable waiting for IORDY signal */
use_iordy = ata_pio_need_iordy(adev);
if (use_iordy)
info->mode |= AT91_SMC_EXNWMODE_READY;
/* (CS0, CS1, DIR, OE) <= (CFCE1, CFCE2, CFRNW, NCSX) timings */
ncs_read_setup = 1;
ncs_read_pulse = read_cycle - 2;
if (ncs_read_pulse > NCS_RD_PULSE_LIMIT) {
ncs_read_pulse = NCS_RD_PULSE_LIMIT;
dev_warn(dev, "ncs_read_pulse limited to maximal value %lu\n",
ncs_read_pulse);
if (tdf_cycles > 15) {
tdf_cycles = 15;
dev_warn(dev, "maximal SMC TDF Cycles value\n");
}
/* Write timings same as read timings */
write_cycle = read_cycle;
nwe_setup = nrd_setup;
nwe_pulse = nrd_pulse;
ncs_write_setup = ncs_read_setup;
ncs_write_pulse = ncs_read_pulse;
dev_dbg(dev, "ATA timings: nrd_setup = %lu nrd_pulse = %lu nrd_cycle = %lu\n",
nrd_setup, nrd_pulse, read_cycle);
dev_dbg(dev, "ATA timings: nwe_setup = %lu nwe_pulse = %lu nwe_cycle = %lu\n",
nwe_setup, nwe_pulse, write_cycle);
dev_dbg(dev, "ATA timings: ncs_read_setup = %lu ncs_read_pulse = %lu\n",
ncs_read_setup, ncs_read_pulse);
dev_dbg(dev, "ATA timings: ncs_write_setup = %lu ncs_write_pulse = %lu\n",
ncs_write_setup, ncs_write_pulse);
dev_dbg(dev, "Use IORDY=%u, TDF Cycles=%u\n", use_iordy, tdf_cycles);
info->mode |= AT91_SMC_TDF_(tdf_cycles);
/* write SMC Setup Register */
at91_sys_write(AT91_SMC_SETUP(info->cs),
AT91_SMC_NWESETUP_(nwe_setup) |
AT91_SMC_NRDSETUP_(nrd_setup) |
AT91_SMC_NCS_WRSETUP_(ncs_write_setup) |
AT91_SMC_NCS_RDSETUP_(ncs_read_setup));
AT91_SMC_NWESETUP_(setup) |
AT91_SMC_NRDSETUP_(setup) |
AT91_SMC_NCS_WRSETUP_(cs_setup) |
AT91_SMC_NCS_RDSETUP_(cs_setup));
/* write SMC Pulse Register */
at91_sys_write(AT91_SMC_PULSE(info->cs),
AT91_SMC_NWEPULSE_(nwe_pulse) |
AT91_SMC_NRDPULSE_(nrd_pulse) |
AT91_SMC_NCS_WRPULSE_(ncs_write_pulse) |
AT91_SMC_NCS_RDPULSE_(ncs_read_pulse));
AT91_SMC_NWEPULSE_(pulse) |
AT91_SMC_NRDPULSE_(pulse) |
AT91_SMC_NCS_WRPULSE_(cs_pulse) |
AT91_SMC_NCS_RDPULSE_(cs_pulse));
/* write SMC Cycle Register */
at91_sys_write(AT91_SMC_CYCLE(info->cs),
AT91_SMC_NWECYCLE_(write_cycle) |
AT91_SMC_NRDCYCLE_(read_cycle));
return;
AT91_SMC_NWECYCLE_(cycle) |
AT91_SMC_NRDCYCLE_(cycle));
/* write SMC Mode Register*/
at91_sys_write(AT91_SMC_MODE(info->cs), info->mode);
}
static void pata_at91_set_piomode(struct ata_port *ap, struct ata_device *adev)
@ -172,15 +277,9 @@ static void pata_at91_set_piomode(struct ata_port *ap, struct ata_device *adev)
if (ret) {
dev_warn(ap->dev, "Failed to compute ATA timing %d, "
"set PIO_0 timing\n", ret);
set_smc_timing(ap->dev, info, &initial_timing);
} else {
set_smc_timing(ap->dev, info, &timing);
timing = *ata_timing_find_mode(XFER_PIO_0);
}
/* Setup SMC mode */
set_smc_mode(info);
return;
set_smc_timing(ap->dev, adev, info, &timing);
}
static unsigned int pata_at91_data_xfer_noirq(struct ata_device *dev,
@ -346,7 +445,7 @@ static int __devexit pata_at91_remove(struct platform_device *pdev)
static struct platform_driver pata_at91_driver = {
.probe = pata_at91_probe,
.remove = __devexit_p(pata_at91_remove),
.driver = {
.driver = {
.name = DRV_NAME,
.owner = THIS_MODULE,
},