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openwrt-xburst/target/linux/atheros-2.6/files/arch/mips/atheros/ar5312.c

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/*
* This file is subject to the terms and conditions of the GNU General Public
* License. See the file "COPYING" in the main directory of this archive
* for more details.
*
* Copyright (C) 2003 Atheros Communications, Inc., All Rights Reserved.
* Copyright (C) 2006 FON Technology, SL.
* Copyright (C) 2006 Imre Kaloz <kaloz@openwrt.org>
* Copyright (C) 2006 Felix Fietkau <nbd@openwrt.org>
*/
/*
* Platform devices for Atheros SoCs
*/
#include <linux/autoconf.h>
#include <linux/init.h>
#include <linux/module.h>
#include <linux/types.h>
#include <linux/string.h>
#include <linux/mtd/physmap.h>
#include <linux/platform_device.h>
#include <linux/kernel.h>
#include <linux/reboot.h>
#include <asm/bootinfo.h>
#include <asm/reboot.h>
#include <asm/time.h>
#include <asm/irq.h>
#include <asm/io.h>
#include "ar531x.h"
#define NO_PHY 0x1f
static int is_5312 = 0;
static struct platform_device *ar5312_devs[5];
static struct resource ar5312_eth0_res[] = {
{
.name = "eth0_membase",
.flags = IORESOURCE_MEM,
.start = KSEG1ADDR(AR531X_ENET0),
.end = KSEG1ADDR(AR531X_ENET0 + 0x2000),
},
{
.name = "eth0_irq",
.flags = IORESOURCE_IRQ,
.start = AR5312_IRQ_ENET0_INTRS,
.end = AR5312_IRQ_ENET0_INTRS,
},
};
static struct ar531x_eth ar5312_eth0_data = {
.phy = NO_PHY,
.mac = 0,
.reset_base = AR531X_RESET,
.reset_mac = AR531X_RESET_ENET0,
.reset_phy = AR531X_RESET_EPHY0,
.phy_base = KSEG1ADDR(AR531X_ENET0),
};
static struct resource ar5312_eth1_res[] = {
{
.name = "eth1_membase",
.flags = IORESOURCE_MEM,
.start = KSEG1ADDR(AR531X_ENET1),
.end = KSEG1ADDR(AR531X_ENET1 + 0x2000),
},
{
.name = "eth1_irq",
.flags = IORESOURCE_IRQ,
.start = AR5312_IRQ_ENET1_INTRS,
.end = AR5312_IRQ_ENET1_INTRS,
},
};
static struct ar531x_eth ar5312_eth1_data = {
.phy = NO_PHY,
.mac = 1,
.reset_base = AR531X_RESET,
.reset_mac = AR531X_RESET_ENET1,
.reset_phy = AR531X_RESET_EPHY1,
.phy_base = KSEG1ADDR(AR531X_ENET1),
};
static struct platform_device ar5312_eth[] = {
{
.id = 0,
.name = "ar531x-eth",
.dev.platform_data = &ar5312_eth0_data,
.resource = ar5312_eth0_res,
.num_resources = ARRAY_SIZE(ar5312_eth0_res)
},
{
.id = 1,
.name = "ar531x-eth",
.dev.platform_data = &ar5312_eth1_data,
.resource = ar5312_eth1_res,
.num_resources = ARRAY_SIZE(ar5312_eth1_res)
},
};
/*
* AR2312/3 ethernet uses the PHY of ENET0, but the MAC
* of ENET1. Atheros calls it 'twisted' for a reason :)
*/
static struct resource ar231x_eth0_res[] = {
{
.name = "eth0_membase",
.flags = IORESOURCE_MEM,
.start = KSEG1ADDR(AR531X_ENET1),
.end = KSEG1ADDR(AR531X_ENET1 + 0x2000),
},
{
.name = "eth0_irq",
.flags = IORESOURCE_IRQ,
.start = AR5312_IRQ_ENET1_INTRS,
.end = AR5312_IRQ_ENET1_INTRS,
},
};
static struct ar531x_eth ar231x_eth0_data = {
.phy = 1,
.mac = 1,
.reset_base = AR531X_RESET,
.reset_mac = AR531X_RESET_ENET1,
.reset_phy = AR531X_RESET_EPHY1,
.phy_base = KSEG1ADDR(AR531X_ENET0),
};
static struct platform_device ar231x_eth0 = {
.id = 0,
.name = "ar531x-eth",
.dev.platform_data = &ar231x_eth0_data,
.resource = ar231x_eth0_res,
.num_resources = ARRAY_SIZE(ar231x_eth0_res)
};
static struct platform_device ar5312_wmac[] = {
{
.id = 0,
.name = "ar531x-wmac",
},
{
.id = 1,
.name = "ar531x-wmac",
},
};
static struct physmap_flash_data ar5312_flash_data = {
.width = 2,
};
static struct resource ar5312_flash_resource = {
.start = AR531X_FLASH,
.end = AR531X_FLASH + 0x400000 - 1,
.flags = IORESOURCE_MEM,
};
static struct platform_device ar5312_physmap_flash = {
.name = "physmap-flash",
.id = 0,
.dev = {
.platform_data = &ar5312_flash_data,
},
.num_resources = 1,
.resource = &ar5312_flash_resource,
};
/*
* NB: This mapping size is larger than the actual flash size,
* but this shouldn't be a problem here, because the flash
* will simply be mapped multiple times.
*/
static char __init *ar5312_flash_limit(void)
{
u32 ctl;
/*
* Configure flash bank 0.
* Assume 8M window size. Flash will be aliased if it's smaller
*/
ctl = FLASHCTL_E |
FLASHCTL_AC_8M |
FLASHCTL_RBLE |
(0x01 << FLASHCTL_IDCY_S) |
(0x07 << FLASHCTL_WST1_S) |
(0x07 << FLASHCTL_WST2_S) |
(sysRegRead(AR531X_FLASHCTL0) & FLASHCTL_MW);
sysRegWrite(AR531X_FLASHCTL0, ctl);
/* Disable other flash banks */
sysRegWrite(AR531X_FLASHCTL1,
sysRegRead(AR531X_FLASHCTL1) & ~(FLASHCTL_E | FLASHCTL_AC));
sysRegWrite(AR531X_FLASHCTL2,
sysRegRead(AR531X_FLASHCTL2) & ~(FLASHCTL_E | FLASHCTL_AC));
return (char *) KSEG1ADDR(AR531X_FLASH + 0x800000);
}
static struct ar531x_config __init *init_wmac(int unit)
{
struct ar531x_config *config;
config = (struct ar531x_config *) kzalloc(sizeof(struct ar531x_config), GFP_KERNEL);
config->board = board_config;
config->radio = radio_config;
config->unit = unit;
config->tag = (u_int16_t) ((sysRegRead(AR531X_REV) >> AR531X_REV_WMAC_MIN_S) & AR531X_REV_CHIP);
return config;
}
int __init ar5312_init_devices(void)
{
struct ar531x_boarddata *bcfg;
char *radio, *c;
int dev = 0;
uint32_t fctl = 0;
if (!is_5312)
return 0;
/* Locate board/radio config data */
ar531x_find_config(ar5312_flash_limit());
bcfg = (struct ar531x_boarddata *) board_config;
/*
* Chip IDs and hardware detection for some Atheros
* models are really broken!
*
* Atheros uses a disabled WMAC0 and Silicon ID of AR5312
* as indication for AR2312, which is otherwise
* indistinguishable from the real AR5312.
*/
if (radio_config) {
radio = radio_config + AR531X_RADIO_MASK_OFF;
if ((*((u32 *) radio) & AR531X_RADIO0_MASK) == 0)
bcfg->config |= BD_ISCASPER;
} else
radio = NULL;
/* AR2313 has CPU minor rev. 10 */
if ((current_cpu_data.processor_id & 0xff) == 0x0a)
mips_machtype = MACH_ATHEROS_AR2313;
/* AR2312 shares the same Silicon ID as AR5312 */
else if (bcfg->config & BD_ISCASPER)
mips_machtype = MACH_ATHEROS_AR2312;
/* Everything else is probably AR5312 or compatible */
else
mips_machtype = MACH_ATHEROS_AR5312;
ar5312_eth0_data.board_config = board_config;
ar5312_eth1_data.board_config = board_config;
/* fixup flash width */
fctl = sysRegRead(AR531X_FLASHCTL) & FLASHCTL_MW;
switch (fctl) {
case FLASHCTL_MWx16:
ar5312_flash_data.width = 2;
break;
case FLASHCTL_MWx8:
default:
ar5312_flash_data.width = 1;
break;
}
ar5312_devs[dev++] = &ar5312_physmap_flash;
if (!memcmp(bcfg->enet0Mac, "\xff\xff\xff\xff\xff\xff", 6))
memcpy(bcfg->enet0Mac, bcfg->enet1Mac, 6);
if (memcmp(bcfg->enet0Mac, bcfg->enet1Mac, 6) == 0) {
/* ENET0 and ENET1 have the same mac.
* Increment the one from ENET1 */
c = bcfg->enet1Mac + 5;
while ((c >= (char *) bcfg->enet1Mac) && !(++(*c)))
c--;
}
switch(mips_machtype) {
case MACH_ATHEROS_AR5312:
ar5312_eth0_data.macaddr = bcfg->enet0Mac;
ar5312_eth1_data.macaddr = bcfg->enet1Mac;
ar5312_devs[dev++] = &ar5312_eth[0];
ar5312_devs[dev++] = &ar5312_eth[1];
break;
case MACH_ATHEROS_AR2312:
case MACH_ATHEROS_AR2313:
ar231x_eth0_data.macaddr = bcfg->enet0Mac;
ar5312_devs[dev++] = &ar231x_eth0;
ar5312_flash_data.width = 1;
break;
}
if (radio) {
if (mips_machtype == MACH_ATHEROS_AR5312) {
if (*((u32 *) radio) & AR531X_RADIO0_MASK) {
ar5312_wmac[0].dev.platform_data = init_wmac(0);
ar5312_devs[dev++] = &ar5312_wmac[0];
}
}
if (*((u32 *) radio) & AR531X_RADIO1_MASK) {
ar5312_wmac[1].dev.platform_data = init_wmac(1);
ar5312_devs[dev++] = &ar5312_wmac[1];
}
}
return platform_add_devices(ar5312_devs, dev);
}
/*
* Called when an interrupt is received, this function
* determines exactly which interrupt it was, and it
* invokes the appropriate handler.
*
* Implicitly, we also define interrupt priority by
* choosing which to dispatch first.
*/
asmlinkage void ar5312_irq_dispatch(void)
{
int pending = read_c0_status() & read_c0_cause();
if (pending & CAUSEF_IP2)
do_IRQ(AR5312_IRQ_WLAN0_INTRS);
else if (pending & CAUSEF_IP3)
do_IRQ(AR5312_IRQ_ENET0_INTRS);
else if (pending & CAUSEF_IP4)
do_IRQ(AR5312_IRQ_ENET1_INTRS);
else if (pending & CAUSEF_IP5)
do_IRQ(AR5312_IRQ_WLAN1_INTRS);
else if (pending & CAUSEF_IP6) {
unsigned int ar531x_misc_intrs = sysRegRead(AR531X_ISR) & sysRegRead(AR531X_IMR);
if (ar531x_misc_intrs & AR531X_ISR_TIMER) {
do_IRQ(AR531X_MISC_IRQ_TIMER);
(void)sysRegRead(AR531X_TIMER);
} else if (ar531x_misc_intrs & AR531X_ISR_AHBPROC)
do_IRQ(AR531X_MISC_IRQ_AHB_PROC);
else if ((ar531x_misc_intrs & AR531X_ISR_UART0))
do_IRQ(AR531X_MISC_IRQ_UART0);
else if (ar531x_misc_intrs & AR531X_ISR_WD)
do_IRQ(AR531X_MISC_IRQ_WATCHDOG);
else
do_IRQ(AR531X_MISC_IRQ_NONE);
} else if (pending & CAUSEF_IP7) {
do_IRQ(AR531X_IRQ_CPU_CLOCK);
}
else
do_IRQ(AR531X_IRQ_NONE);
}
static void ar5312_halt(void)
{
while (1);
}
static void ar5312_power_off(void)
{
ar5312_halt();
}
static void ar5312_restart(char *command)
{
/* reset the system */
for(;;) sysRegWrite(AR531X_RESET, AR531X_RESET_SYSTEM);
}
/*
* This table is indexed by bits 5..4 of the CLOCKCTL1 register
* to determine the predevisor value.
*/
static int __initdata CLOCKCTL1_PREDIVIDE_TABLE[4] = {
1,
2,
4,
5
};
static unsigned int __init ar5312_cpu_frequency(void)
{
unsigned int result;
unsigned int predivide_mask, predivide_shift;
unsigned int multiplier_mask, multiplier_shift;
unsigned int clockCtl1, preDivideSelect, preDivisor, multiplier;
unsigned int doubler_mask;
unsigned int wisoc_revision;
/* Trust the bootrom's idea of cpu frequency. */
if ((result = sysRegRead(AR5312_SCRATCH)))
return result;
wisoc_revision = (sysRegRead(AR531X_REV) & AR531X_REV_MAJ) >> AR531X_REV_MAJ_S;
if (wisoc_revision == AR531X_REV_MAJ_AR2313) {
predivide_mask = AR2313_CLOCKCTL1_PREDIVIDE_MASK;
predivide_shift = AR2313_CLOCKCTL1_PREDIVIDE_SHIFT;
multiplier_mask = AR2313_CLOCKCTL1_MULTIPLIER_MASK;
multiplier_shift = AR2313_CLOCKCTL1_MULTIPLIER_SHIFT;
doubler_mask = AR2313_CLOCKCTL1_DOUBLER_MASK;
} else { /* AR5312 and AR2312 */
predivide_mask = AR5312_CLOCKCTL1_PREDIVIDE_MASK;
predivide_shift = AR5312_CLOCKCTL1_PREDIVIDE_SHIFT;
multiplier_mask = AR5312_CLOCKCTL1_MULTIPLIER_MASK;
multiplier_shift = AR5312_CLOCKCTL1_MULTIPLIER_SHIFT;
doubler_mask = AR5312_CLOCKCTL1_DOUBLER_MASK;
}
/*
* Clocking is derived from a fixed 40MHz input clock.
*
* cpuFreq = InputClock * MULT (where MULT is PLL multiplier)
* sysFreq = cpuFreq / 4 (used for APB clock, serial,
* flash, Timer, Watchdog Timer)
*
* cntFreq = cpuFreq / 2 (use for CPU count/compare)
*
* So, for example, with a PLL multiplier of 5, we have
*
* cpuFreq = 200MHz
* sysFreq = 50MHz
* cntFreq = 100MHz
*
* We compute the CPU frequency, based on PLL settings.
*/
clockCtl1 = sysRegRead(AR5312_CLOCKCTL1);
preDivideSelect = (clockCtl1 & predivide_mask) >> predivide_shift;
preDivisor = CLOCKCTL1_PREDIVIDE_TABLE[preDivideSelect];
multiplier = (clockCtl1 & multiplier_mask) >> multiplier_shift;
if (clockCtl1 & doubler_mask) {
multiplier = multiplier << 1;
}
return (40000000 / preDivisor) * multiplier;
}
static inline int ar5312_sys_frequency(void)
{
return ar5312_cpu_frequency() / 4;
}
static void __init ar5312_time_init(void)
{
mips_hpt_frequency = ar5312_cpu_frequency() / 2;
}
/* Enable the specified AR531X_MISC_IRQ interrupt */
static void
ar5312_misc_intr_enable(unsigned int irq)
{
unsigned int imr;
imr = sysRegRead(AR531X_IMR);
imr |= (1 << (irq - AR531X_MISC_IRQ_BASE - 1));
sysRegWrite(AR531X_IMR, imr);
sysRegRead(AR531X_IMR); /* flush write buffer */
}
/* Disable the specified AR531X_MISC_IRQ interrupt */
static void
ar5312_misc_intr_disable(unsigned int irq)
{
unsigned int imr;
imr = sysRegRead(AR531X_IMR);
imr &= ~(1 << (irq - AR531X_MISC_IRQ_BASE - 1));
sysRegWrite(AR531X_IMR, imr);
sysRegRead(AR531X_IMR); /* flush write buffer */
}
/* Turn on the specified AR531X_MISC_IRQ interrupt */
static unsigned int
ar5312_misc_intr_startup(unsigned int irq)
{
ar5312_misc_intr_enable(irq);
return 0;
}
/* Turn off the specified AR531X_MISC_IRQ interrupt */
static void
ar5312_misc_intr_shutdown(unsigned int irq)
{
ar5312_misc_intr_disable(irq);
}
static void
ar5312_misc_intr_ack(unsigned int irq)
{
ar5312_misc_intr_disable(irq);
}
static void
ar5312_misc_intr_end(unsigned int irq)
{
if (!(irq_desc[irq].status & (IRQ_DISABLED | IRQ_INPROGRESS)))
ar5312_misc_intr_enable(irq);
}
static struct irq_chip ar5312_misc_intr_controller = {
.typename = "AR5312 misc",
.startup = ar5312_misc_intr_startup,
.shutdown = ar5312_misc_intr_shutdown,
.enable = ar5312_misc_intr_enable,
.disable = ar5312_misc_intr_disable,
.ack = ar5312_misc_intr_ack,
.end = ar5312_misc_intr_end,
};
static irqreturn_t ar5312_ahb_proc_handler(int cpl, void *dev_id)
{
u32 proc1 = sysRegRead(AR531X_PROC1);
u32 procAddr = sysRegRead(AR531X_PROCADDR); /* clears error state */
u32 dma1 = sysRegRead(AR531X_DMA1);
u32 dmaAddr = sysRegRead(AR531X_DMAADDR); /* clears error state */
printk("AHB interrupt: PROCADDR=0x%8.8x PROC1=0x%8.8x DMAADDR=0x%8.8x DMA1=0x%8.8x\n",
procAddr, proc1, dmaAddr, dma1);
machine_restart("AHB error"); /* Catastrophic failure */
return IRQ_HANDLED;
}
static struct irqaction ar5312_ahb_proc_interrupt = {
.handler = ar5312_ahb_proc_handler,
.flags = SA_INTERRUPT,
.name = "ar5312_ahb_proc_interrupt",
};
static struct irqaction cascade = {
.handler = no_action,
.flags = SA_INTERRUPT,
.name = "cascade",
};
void __init ar5312_misc_intr_init(int irq_base)
{
int i;
for (i = irq_base; i < irq_base + AR531X_MISC_IRQ_COUNT; i++) {
irq_desc[i].status = IRQ_DISABLED;
irq_desc[i].action = NULL;
irq_desc[i].depth = 1;
irq_desc[i].chip = &ar5312_misc_intr_controller;
}
setup_irq(AR531X_MISC_IRQ_AHB_PROC, &ar5312_ahb_proc_interrupt);
setup_irq(AR5312_IRQ_MISC_INTRS, &cascade);
}
void __init ar5312_prom_init(void)
{
u32 memsize, memcfg, bank0AC, bank1AC;
is_5312 = 1;
/* Detect memory size */
memcfg = sysRegRead(AR531X_MEM_CFG1);
bank0AC = (memcfg & MEM_CFG1_AC0) >> MEM_CFG1_AC0_S;
bank1AC = (memcfg & MEM_CFG1_AC1) >> MEM_CFG1_AC1_S;
memsize = (bank0AC ? (1 << (bank0AC+1)) : 0)
+ (bank1AC ? (1 << (bank1AC+1)) : 0);
memsize <<= 20;
add_memory_region(0, memsize, BOOT_MEM_RAM);
/* Initialize it to AR5312 for now. Real detection will be done
* in ar5312_init_devices() */
mips_machtype = MACH_ATHEROS_AR5312;
}
void __init ar5312_plat_setup(void)
{
/* Clear any lingering AHB errors */
sysRegRead(AR531X_PROCADDR);
sysRegRead(AR531X_DMAADDR);
sysRegWrite(AR531X_WD_CTRL, AR531X_WD_CTRL_IGNORE_EXPIRATION);
board_time_init = ar5312_time_init;
_machine_restart = ar5312_restart;
_machine_halt = ar5312_halt;
pm_power_off = ar5312_power_off;
serial_setup(KSEG1ADDR(AR531X_UART0), ar5312_sys_frequency());
}
arch_initcall(ar5312_init_devices);