rockbox/firmware/target/arm/pnx0101/system-pnx0101.c
Tomasz Malesinski 026032f06d PNX0101: new register names and polishing support for Clock Generation Unit
git-svn-id: svn://svn.rockbox.org/rockbox/trunk@14792 a1c6a512-1295-4272-9138-f99709370657
2007-09-20 22:13:48 +00:00

310 lines
8.2 KiB
C

/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id: $
*
* Copyright (C) 2007 by Tomasz Malesinski
*
* All files in this archive are subject to the GNU General Public License.
* See the file COPYING in the source tree root for full license agreement.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include <stdlib.h>
#include "pnx0101.h"
#include "system.h"
static struct
{
unsigned char freq;
unsigned char sys_mult;
unsigned char sys_div;
}
perf_modes[3] ICONST_ATTR =
{
{12, 4, 4},
{48, 4, 1},
{60, 5, 1}
};
static int performance_mode, bus_divider;
static void cgu_set_sel_stage_input(int clock, int input)
{
int s = CGU.base_ssr[clock];
if (s & 1)
CGU.base_fs2[clock] = input;
else
CGU.base_fs1[clock] = input;
CGU.base_scr[clock] = (s & 3) ^ 3;
}
static void cgu_reset_sel_stage_clocks(int first_esr, int n_esr,
int first_div, int n_div)
{
int i;
for (i = 0; i < n_esr; i++)
CGU.clk_esr[first_esr + i] = 0;
for (i = 0; i < n_div; i++)
CGU.base_fdc[first_div + i] = 0;
}
static void cgu_configure_div(int div, int n, int m)
{
int msub, madd, div_size, max_n;
unsigned long cfg;
if (n == m)
{
CGU.base_fdc[div] = CGU.base_fdc[div] & ~1;
return;
}
msub = -n;
madd = m - n;
div_size = (div == PNX0101_HIPREC_FDC) ? 10 : 8;
max_n = 1 << div_size;
while ((madd << 1) < max_n && (msub << 1) >= -max_n)
{
madd <<= 1;
msub <<= 1;
}
cfg = (((msub << div_size) | madd) << 3) | 4;
CGU.base_fdc[div] = CGU.base_fdc[div] & ~1;
CGU.base_fdc[div] = cfg | 2;
CGU.base_fdc[div] = cfg;
CGU.base_fdc[div] = cfg | 1;
}
static void cgu_connect_div_to_clock(int rel_div, int esr)
{
CGU.clk_esr[esr] = (rel_div << 1) | 1;
}
static void cgu_enable_clock(int clock)
{
CGU.clk_pcr[clock] |= 1;
}
static void cgu_start_sel_stage_dividers(int bcr)
{
CGU.base_bcr[bcr] = 1;
}
/* Convert a pointer that points to IRAM (0x4xxxx) to a pointer that
points to the uncached page (0x0xxxx) that is also mapped to IRAM. */
static inline void *noncached(void *p)
{
return (void *)(((unsigned long)p) & 0xffff);
}
/* To avoid SRAM accesses while changing memory controller settings we
run this routine from uncached copy of IRAM. All times are in CPU
cycles. At CPU frequencies lower than 60 MHz we could use faster
settings, but since DMA may access SRAM at any time, changing
memory timings together with CPU frequency would be tricky. */
static void do_set_mem_timings(void) ICODE_ATTR;
static void do_set_mem_timings(void)
{
int old_irq = set_irq_level(HIGHEST_IRQ_LEVEL);
while ((EMC.status & 3) != 0);
EMC.control = 5;
EMCSTATIC0.waitrd = 6;
EMCSTATIC0.waitwr = 5;
EMCSTATIC1.waitrd = 5;
EMCSTATIC1.waitwr = 4; /* OF uses 5 here */
EMCSTATIC2.waitrd = 4;
EMCSTATIC2.waitwr = 3;
EMCSTATIC0.waitoen = 1;
EMCSTATIC1.waitoen = 1;
EMCSTATIC2.waitoen = 1;
/* Enable write buffers for SRAM. */
#ifndef DEBUG
EMCSTATIC1.config = 0x80081;
#endif
EMC.control = 1;
set_irq_level(old_irq);
}
static void emc_set_mem_timings(void)
{
void (*f)(void) = noncached(do_set_mem_timings);
(*f)();
}
static void cgu_set_sys_mult(int i)
{
cgu_set_sel_stage_input(PNX0101_SEL_STAGE_SYS, PNX0101_MAIN_CLOCK_FAST);
cgu_set_sel_stage_input(PNX0101_SEL_STAGE_APB3, PNX0101_MAIN_CLOCK_FAST);
PLL.lppdn = 1;
PLL.lpfin = 1;
PLL.lpmbyp = 0;
PLL.lpdbyp = 0;
PLL.lppsel = 1;
PLL.lpmsel = i - 1;
PLL.lppdn = 0;
while (!PLL.lplock);
cgu_configure_div(PNX0101_FIRST_DIV_SYS + 1, 1, (i == 5) ? 15 : 12);
cgu_connect_div_to_clock(1, 0x11);
cgu_enable_clock(0x11);
cgu_start_sel_stage_dividers(PNX0101_BCR_SYS);
cgu_set_sel_stage_input(PNX0101_SEL_STAGE_SYS,
PNX0101_MAIN_CLOCK_MAIN_PLL);
cgu_set_sel_stage_input(PNX0101_SEL_STAGE_APB3,
PNX0101_MAIN_CLOCK_MAIN_PLL);
}
static void pnx0101_set_performance_mode(int mode)
{
int old = performance_mode;
if (perf_modes[old].sys_mult != perf_modes[mode].sys_mult)
cgu_set_sys_mult(perf_modes[mode].sys_mult);
if (perf_modes[old].sys_div != perf_modes[mode].sys_div)
cgu_configure_div(bus_divider, 1, perf_modes[mode].sys_div);
performance_mode = mode;
}
static void pnx0101_init_clocks(void)
{
bus_divider = PNX0101_FIRST_DIV_SYS + (CGU.clk_esr[0] >> 1);
performance_mode = 0;
emc_set_mem_timings();
pnx0101_set_performance_mode(2);
cgu_set_sel_stage_input(PNX0101_SEL_STAGE_APB1,
PNX0101_MAIN_CLOCK_FAST);
cgu_reset_sel_stage_clocks(PNX0101_FIRST_ESR_APB1, PNX0101_N_ESR_APB1,
PNX0101_FIRST_DIV_APB1, PNX0101_N_DIV_APB1);
cgu_configure_div(PNX0101_FIRST_DIV_APB1, 1, 4);
cgu_connect_div_to_clock(0, PNX0101_ESR_APB1);
cgu_connect_div_to_clock(0, PNX0101_ESR_T0);
cgu_connect_div_to_clock(0, PNX0101_ESR_T1);
cgu_connect_div_to_clock(0, PNX0101_ESR_I2C);
cgu_enable_clock(PNX0101_CLOCK_APB1);
cgu_enable_clock(PNX0101_CLOCK_T0);
cgu_enable_clock(PNX0101_CLOCK_T1);
cgu_enable_clock(PNX0101_CLOCK_I2C);
}
#ifdef HAVE_ADJUSTABLE_CPU_FREQ
void set_cpu_frequency(long frequency)
{
switch (frequency)
{
case CPUFREQ_MAX:
pnx0101_set_performance_mode(2);
cpu_frequency = CPUFREQ_MAX;
break;
case CPUFREQ_NORMAL:
pnx0101_set_performance_mode(1);
cpu_frequency = CPUFREQ_NORMAL;
break;
case CPUFREQ_DEFAULT:
default:
pnx0101_set_performance_mode(0);
cpu_frequency = CPUFREQ_DEFAULT;
break;
}
}
#endif
interrupt_handler_t interrupt_vector[0x1d] __attribute__ ((section(".idata")));
#define IRQ_READ(reg, dest) \
do { unsigned long v2; \
do { \
dest = (reg); \
v2 = (reg); \
} while ((dest != v2)); \
} while (0);
#define IRQ_WRITE_WAIT(reg, val, cond) \
do { unsigned long v, v2; \
do { \
(reg) = (val); \
v = (reg); \
v2 = (reg); \
} while ((v != v2) || !(cond)); \
} while (0);
static void undefined_int(void)
{
}
void irq(void)
{
unsigned long n;
IRQ_READ(INTVECTOR[0], n)
(*(interrupt_vector[n >> 3]))();
}
void fiq(void)
{
}
void irq_enable_int(int n)
{
IRQ_WRITE_WAIT(INTREQ[n], INTREQ_WEENABLE | INTREQ_ENABLE, v & 0x10000);
}
void irq_disable_int(int n)
{
IRQ_WRITE_WAIT(INTREQ[n], INTREQ_WEENABLE, (v & 0x10000) == 0);
}
void irq_set_int_handler(int n, interrupt_handler_t handler)
{
interrupt_vector[n] = handler;
}
void system_init(void)
{
int i;
/* turn off watchdog */
(*(volatile unsigned long *)0x80002804) = 0;
/*
IRQ_WRITE_WAIT(INTVECTOR[0], 0, v == 0);
IRQ_WRITE_WAIT(INTVECTOR[1], 0, v == 0);
IRQ_WRITE_WAIT(INTPRIOMASK[0], 0, v == 0);
IRQ_WRITE_WAIT(INTPRIOMASK[1], 0, v == 0);
*/
for (i = 1; i <= 0x1c; i++)
{
IRQ_WRITE_WAIT(INTREQ[i],
INTREQ_WEPRIO | INTREQ_WETARGET |
INTREQ_WEENABLE | INTREQ_WEACTVLO | 1,
(v & 0x3010f) == 1);
IRQ_WRITE_WAIT(INTREQ[i], INTREQ_WEENABLE, (v & 0x10000) == 0);
IRQ_WRITE_WAIT(INTREQ[i], INTREQ_WEPRIO | 1, (v & 0xf) == 1);
interrupt_vector[i] = undefined_int;
}
interrupt_vector[0] = undefined_int;
pnx0101_init_clocks();
}
void system_reboot(void)
{
(*(volatile unsigned long *)0x80002804) = 1;
while (1);
}
int system_memory_guard(int newmode)
{
(void)newmode;
return 0;
}