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linux-next/arch/avr32/mach-at32ap/at32ap7000.c
David Brownell 6b84bbfc71 [AVR32] Initialize dma_mask and dma_coherent_mask
The current at32ap7000 platform devices aren't declared as supporting DMA,
so that layered drivers can't tell whether they need to manage DMA.

This patch makes all those platform devices report that they support DMA.
Most do, but in a few cases this is inappropriate.

Signed-off-by: David Brownell <dbrownell@users.sourceforge.net>
Signed-off-by: Haavard Skinnemoen <hskinnemoen@atmel.com>
2007-06-23 14:53:16 +02:00

1165 lines
29 KiB
C

/*
* Copyright (C) 2005-2006 Atmel Corporation
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*/
#include <linux/clk.h>
#include <linux/fb.h>
#include <linux/init.h>
#include <linux/platform_device.h>
#include <linux/dma-mapping.h>
#include <linux/spi/spi.h>
#include <asm/io.h>
#include <asm/arch/at32ap7000.h>
#include <asm/arch/board.h>
#include <asm/arch/portmux.h>
#include <asm/arch/sm.h>
#include <video/atmel_lcdc.h>
#include "clock.h"
#include "hmatrix.h"
#include "pio.h"
#include "sm.h"
#define PBMEM(base) \
{ \
.start = base, \
.end = base + 0x3ff, \
.flags = IORESOURCE_MEM, \
}
#define IRQ(num) \
{ \
.start = num, \
.end = num, \
.flags = IORESOURCE_IRQ, \
}
#define NAMED_IRQ(num, _name) \
{ \
.start = num, \
.end = num, \
.name = _name, \
.flags = IORESOURCE_IRQ, \
}
/* REVISIT these assume *every* device supports DMA, but several
* don't ... tc, smc, pio, rtc, watchdog, pwm, ps2, and more.
*/
#define DEFINE_DEV(_name, _id) \
static u64 _name##_id##_dma_mask = DMA_32BIT_MASK; \
static struct platform_device _name##_id##_device = { \
.name = #_name, \
.id = _id, \
.dev = { \
.dma_mask = &_name##_id##_dma_mask, \
.coherent_dma_mask = DMA_32BIT_MASK, \
}, \
.resource = _name##_id##_resource, \
.num_resources = ARRAY_SIZE(_name##_id##_resource), \
}
#define DEFINE_DEV_DATA(_name, _id) \
static u64 _name##_id##_dma_mask = DMA_32BIT_MASK; \
static struct platform_device _name##_id##_device = { \
.name = #_name, \
.id = _id, \
.dev = { \
.dma_mask = &_name##_id##_dma_mask, \
.platform_data = &_name##_id##_data, \
.coherent_dma_mask = DMA_32BIT_MASK, \
}, \
.resource = _name##_id##_resource, \
.num_resources = ARRAY_SIZE(_name##_id##_resource), \
}
#define select_peripheral(pin, periph, flags) \
at32_select_periph(GPIO_PIN_##pin, GPIO_##periph, flags)
#define DEV_CLK(_name, devname, bus, _index) \
static struct clk devname##_##_name = { \
.name = #_name, \
.dev = &devname##_device.dev, \
.parent = &bus##_clk, \
.mode = bus##_clk_mode, \
.get_rate = bus##_clk_get_rate, \
.index = _index, \
}
unsigned long at32ap7000_osc_rates[3] = {
[0] = 32768,
/* FIXME: these are ATSTK1002-specific */
[1] = 20000000,
[2] = 12000000,
};
static unsigned long osc_get_rate(struct clk *clk)
{
return at32ap7000_osc_rates[clk->index];
}
static unsigned long pll_get_rate(struct clk *clk, unsigned long control)
{
unsigned long div, mul, rate;
if (!(control & SM_BIT(PLLEN)))
return 0;
div = SM_BFEXT(PLLDIV, control) + 1;
mul = SM_BFEXT(PLLMUL, control) + 1;
rate = clk->parent->get_rate(clk->parent);
rate = (rate + div / 2) / div;
rate *= mul;
return rate;
}
static unsigned long pll0_get_rate(struct clk *clk)
{
u32 control;
control = sm_readl(&system_manager, PM_PLL0);
return pll_get_rate(clk, control);
}
static unsigned long pll1_get_rate(struct clk *clk)
{
u32 control;
control = sm_readl(&system_manager, PM_PLL1);
return pll_get_rate(clk, control);
}
/*
* The AT32AP7000 has five primary clock sources: One 32kHz
* oscillator, two crystal oscillators and two PLLs.
*/
static struct clk osc32k = {
.name = "osc32k",
.get_rate = osc_get_rate,
.users = 1,
.index = 0,
};
static struct clk osc0 = {
.name = "osc0",
.get_rate = osc_get_rate,
.users = 1,
.index = 1,
};
static struct clk osc1 = {
.name = "osc1",
.get_rate = osc_get_rate,
.index = 2,
};
static struct clk pll0 = {
.name = "pll0",
.get_rate = pll0_get_rate,
.parent = &osc0,
};
static struct clk pll1 = {
.name = "pll1",
.get_rate = pll1_get_rate,
.parent = &osc0,
};
/*
* The main clock can be either osc0 or pll0. The boot loader may
* have chosen one for us, so we don't really know which one until we
* have a look at the SM.
*/
static struct clk *main_clock;
/*
* Synchronous clocks are generated from the main clock. The clocks
* must satisfy the constraint
* fCPU >= fHSB >= fPB
* i.e. each clock must not be faster than its parent.
*/
static unsigned long bus_clk_get_rate(struct clk *clk, unsigned int shift)
{
return main_clock->get_rate(main_clock) >> shift;
};
static void cpu_clk_mode(struct clk *clk, int enabled)
{
struct at32_sm *sm = &system_manager;
unsigned long flags;
u32 mask;
spin_lock_irqsave(&sm->lock, flags);
mask = sm_readl(sm, PM_CPU_MASK);
if (enabled)
mask |= 1 << clk->index;
else
mask &= ~(1 << clk->index);
sm_writel(sm, PM_CPU_MASK, mask);
spin_unlock_irqrestore(&sm->lock, flags);
}
static unsigned long cpu_clk_get_rate(struct clk *clk)
{
unsigned long cksel, shift = 0;
cksel = sm_readl(&system_manager, PM_CKSEL);
if (cksel & SM_BIT(CPUDIV))
shift = SM_BFEXT(CPUSEL, cksel) + 1;
return bus_clk_get_rate(clk, shift);
}
static void hsb_clk_mode(struct clk *clk, int enabled)
{
struct at32_sm *sm = &system_manager;
unsigned long flags;
u32 mask;
spin_lock_irqsave(&sm->lock, flags);
mask = sm_readl(sm, PM_HSB_MASK);
if (enabled)
mask |= 1 << clk->index;
else
mask &= ~(1 << clk->index);
sm_writel(sm, PM_HSB_MASK, mask);
spin_unlock_irqrestore(&sm->lock, flags);
}
static unsigned long hsb_clk_get_rate(struct clk *clk)
{
unsigned long cksel, shift = 0;
cksel = sm_readl(&system_manager, PM_CKSEL);
if (cksel & SM_BIT(HSBDIV))
shift = SM_BFEXT(HSBSEL, cksel) + 1;
return bus_clk_get_rate(clk, shift);
}
static void pba_clk_mode(struct clk *clk, int enabled)
{
struct at32_sm *sm = &system_manager;
unsigned long flags;
u32 mask;
spin_lock_irqsave(&sm->lock, flags);
mask = sm_readl(sm, PM_PBA_MASK);
if (enabled)
mask |= 1 << clk->index;
else
mask &= ~(1 << clk->index);
sm_writel(sm, PM_PBA_MASK, mask);
spin_unlock_irqrestore(&sm->lock, flags);
}
static unsigned long pba_clk_get_rate(struct clk *clk)
{
unsigned long cksel, shift = 0;
cksel = sm_readl(&system_manager, PM_CKSEL);
if (cksel & SM_BIT(PBADIV))
shift = SM_BFEXT(PBASEL, cksel) + 1;
return bus_clk_get_rate(clk, shift);
}
static void pbb_clk_mode(struct clk *clk, int enabled)
{
struct at32_sm *sm = &system_manager;
unsigned long flags;
u32 mask;
spin_lock_irqsave(&sm->lock, flags);
mask = sm_readl(sm, PM_PBB_MASK);
if (enabled)
mask |= 1 << clk->index;
else
mask &= ~(1 << clk->index);
sm_writel(sm, PM_PBB_MASK, mask);
spin_unlock_irqrestore(&sm->lock, flags);
}
static unsigned long pbb_clk_get_rate(struct clk *clk)
{
unsigned long cksel, shift = 0;
cksel = sm_readl(&system_manager, PM_CKSEL);
if (cksel & SM_BIT(PBBDIV))
shift = SM_BFEXT(PBBSEL, cksel) + 1;
return bus_clk_get_rate(clk, shift);
}
static struct clk cpu_clk = {
.name = "cpu",
.get_rate = cpu_clk_get_rate,
.users = 1,
};
static struct clk hsb_clk = {
.name = "hsb",
.parent = &cpu_clk,
.get_rate = hsb_clk_get_rate,
};
static struct clk pba_clk = {
.name = "pba",
.parent = &hsb_clk,
.mode = hsb_clk_mode,
.get_rate = pba_clk_get_rate,
.index = 1,
};
static struct clk pbb_clk = {
.name = "pbb",
.parent = &hsb_clk,
.mode = hsb_clk_mode,
.get_rate = pbb_clk_get_rate,
.users = 1,
.index = 2,
};
/* --------------------------------------------------------------------
* Generic Clock operations
* -------------------------------------------------------------------- */
static void genclk_mode(struct clk *clk, int enabled)
{
u32 control;
control = sm_readl(&system_manager, PM_GCCTRL + 4 * clk->index);
if (enabled)
control |= SM_BIT(CEN);
else
control &= ~SM_BIT(CEN);
sm_writel(&system_manager, PM_GCCTRL + 4 * clk->index, control);
}
static unsigned long genclk_get_rate(struct clk *clk)
{
u32 control;
unsigned long div = 1;
control = sm_readl(&system_manager, PM_GCCTRL + 4 * clk->index);
if (control & SM_BIT(DIVEN))
div = 2 * (SM_BFEXT(DIV, control) + 1);
return clk->parent->get_rate(clk->parent) / div;
}
static long genclk_set_rate(struct clk *clk, unsigned long rate, int apply)
{
u32 control;
unsigned long parent_rate, actual_rate, div;
parent_rate = clk->parent->get_rate(clk->parent);
control = sm_readl(&system_manager, PM_GCCTRL + 4 * clk->index);
if (rate > 3 * parent_rate / 4) {
actual_rate = parent_rate;
control &= ~SM_BIT(DIVEN);
} else {
div = (parent_rate + rate) / (2 * rate) - 1;
control = SM_BFINS(DIV, div, control) | SM_BIT(DIVEN);
actual_rate = parent_rate / (2 * (div + 1));
}
printk("clk %s: new rate %lu (actual rate %lu)\n",
clk->name, rate, actual_rate);
if (apply)
sm_writel(&system_manager, PM_GCCTRL + 4 * clk->index,
control);
return actual_rate;
}
int genclk_set_parent(struct clk *clk, struct clk *parent)
{
u32 control;
printk("clk %s: new parent %s (was %s)\n",
clk->name, parent->name, clk->parent->name);
control = sm_readl(&system_manager, PM_GCCTRL + 4 * clk->index);
if (parent == &osc1 || parent == &pll1)
control |= SM_BIT(OSCSEL);
else if (parent == &osc0 || parent == &pll0)
control &= ~SM_BIT(OSCSEL);
else
return -EINVAL;
if (parent == &pll0 || parent == &pll1)
control |= SM_BIT(PLLSEL);
else
control &= ~SM_BIT(PLLSEL);
sm_writel(&system_manager, PM_GCCTRL + 4 * clk->index, control);
clk->parent = parent;
return 0;
}
static void __init genclk_init_parent(struct clk *clk)
{
u32 control;
struct clk *parent;
BUG_ON(clk->index > 7);
control = sm_readl(&system_manager, PM_GCCTRL + 4 * clk->index);
if (control & SM_BIT(OSCSEL))
parent = (control & SM_BIT(PLLSEL)) ? &pll1 : &osc1;
else
parent = (control & SM_BIT(PLLSEL)) ? &pll0 : &osc0;
clk->parent = parent;
}
/* --------------------------------------------------------------------
* System peripherals
* -------------------------------------------------------------------- */
static struct resource sm_resource[] = {
PBMEM(0xfff00000),
NAMED_IRQ(19, "eim"),
NAMED_IRQ(20, "pm"),
NAMED_IRQ(21, "rtc"),
};
struct platform_device at32_sm_device = {
.name = "sm",
.id = 0,
.resource = sm_resource,
.num_resources = ARRAY_SIZE(sm_resource),
};
static struct clk at32_sm_pclk = {
.name = "pclk",
.dev = &at32_sm_device.dev,
.parent = &pbb_clk,
.mode = pbb_clk_mode,
.get_rate = pbb_clk_get_rate,
.users = 1,
.index = 0,
};
static struct resource intc0_resource[] = {
PBMEM(0xfff00400),
};
struct platform_device at32_intc0_device = {
.name = "intc",
.id = 0,
.resource = intc0_resource,
.num_resources = ARRAY_SIZE(intc0_resource),
};
DEV_CLK(pclk, at32_intc0, pbb, 1);
static struct clk ebi_clk = {
.name = "ebi",
.parent = &hsb_clk,
.mode = hsb_clk_mode,
.get_rate = hsb_clk_get_rate,
.users = 1,
};
static struct clk hramc_clk = {
.name = "hramc",
.parent = &hsb_clk,
.mode = hsb_clk_mode,
.get_rate = hsb_clk_get_rate,
.users = 1,
.index = 3,
};
static struct resource smc0_resource[] = {
PBMEM(0xfff03400),
};
DEFINE_DEV(smc, 0);
DEV_CLK(pclk, smc0, pbb, 13);
DEV_CLK(mck, smc0, hsb, 0);
static struct platform_device pdc_device = {
.name = "pdc",
.id = 0,
};
DEV_CLK(hclk, pdc, hsb, 4);
DEV_CLK(pclk, pdc, pba, 16);
static struct clk pico_clk = {
.name = "pico",
.parent = &cpu_clk,
.mode = cpu_clk_mode,
.get_rate = cpu_clk_get_rate,
.users = 1,
};
/* --------------------------------------------------------------------
* HMATRIX
* -------------------------------------------------------------------- */
static struct clk hmatrix_clk = {
.name = "hmatrix_clk",
.parent = &pbb_clk,
.mode = pbb_clk_mode,
.get_rate = pbb_clk_get_rate,
.index = 2,
.users = 1,
};
#define HMATRIX_BASE ((void __iomem *)0xfff00800)
#define hmatrix_readl(reg) \
__raw_readl((HMATRIX_BASE) + HMATRIX_##reg)
#define hmatrix_writel(reg,value) \
__raw_writel((value), (HMATRIX_BASE) + HMATRIX_##reg)
/*
* Set bits in the HMATRIX Special Function Register (SFR) used by the
* External Bus Interface (EBI). This can be used to enable special
* features like CompactFlash support, NAND Flash support, etc. on
* certain chipselects.
*/
static inline void set_ebi_sfr_bits(u32 mask)
{
u32 sfr;
clk_enable(&hmatrix_clk);
sfr = hmatrix_readl(SFR4);
sfr |= mask;
hmatrix_writel(SFR4, sfr);
clk_disable(&hmatrix_clk);
}
/* --------------------------------------------------------------------
* System Timer/Counter (TC)
* -------------------------------------------------------------------- */
static struct resource at32_systc0_resource[] = {
PBMEM(0xfff00c00),
IRQ(22),
};
struct platform_device at32_systc0_device = {
.name = "systc",
.id = 0,
.resource = at32_systc0_resource,
.num_resources = ARRAY_SIZE(at32_systc0_resource),
};
DEV_CLK(pclk, at32_systc0, pbb, 3);
/* --------------------------------------------------------------------
* PIO
* -------------------------------------------------------------------- */
static struct resource pio0_resource[] = {
PBMEM(0xffe02800),
IRQ(13),
};
DEFINE_DEV(pio, 0);
DEV_CLK(mck, pio0, pba, 10);
static struct resource pio1_resource[] = {
PBMEM(0xffe02c00),
IRQ(14),
};
DEFINE_DEV(pio, 1);
DEV_CLK(mck, pio1, pba, 11);
static struct resource pio2_resource[] = {
PBMEM(0xffe03000),
IRQ(15),
};
DEFINE_DEV(pio, 2);
DEV_CLK(mck, pio2, pba, 12);
static struct resource pio3_resource[] = {
PBMEM(0xffe03400),
IRQ(16),
};
DEFINE_DEV(pio, 3);
DEV_CLK(mck, pio3, pba, 13);
static struct resource pio4_resource[] = {
PBMEM(0xffe03800),
IRQ(17),
};
DEFINE_DEV(pio, 4);
DEV_CLK(mck, pio4, pba, 14);
void __init at32_add_system_devices(void)
{
system_manager.eim_first_irq = EIM_IRQ_BASE;
platform_device_register(&at32_sm_device);
platform_device_register(&at32_intc0_device);
platform_device_register(&smc0_device);
platform_device_register(&pdc_device);
platform_device_register(&at32_systc0_device);
platform_device_register(&pio0_device);
platform_device_register(&pio1_device);
platform_device_register(&pio2_device);
platform_device_register(&pio3_device);
platform_device_register(&pio4_device);
}
/* --------------------------------------------------------------------
* USART
* -------------------------------------------------------------------- */
static struct atmel_uart_data atmel_usart0_data = {
.use_dma_tx = 1,
.use_dma_rx = 1,
};
static struct resource atmel_usart0_resource[] = {
PBMEM(0xffe00c00),
IRQ(6),
};
DEFINE_DEV_DATA(atmel_usart, 0);
DEV_CLK(usart, atmel_usart0, pba, 4);
static struct atmel_uart_data atmel_usart1_data = {
.use_dma_tx = 1,
.use_dma_rx = 1,
};
static struct resource atmel_usart1_resource[] = {
PBMEM(0xffe01000),
IRQ(7),
};
DEFINE_DEV_DATA(atmel_usart, 1);
DEV_CLK(usart, atmel_usart1, pba, 4);
static struct atmel_uart_data atmel_usart2_data = {
.use_dma_tx = 1,
.use_dma_rx = 1,
};
static struct resource atmel_usart2_resource[] = {
PBMEM(0xffe01400),
IRQ(8),
};
DEFINE_DEV_DATA(atmel_usart, 2);
DEV_CLK(usart, atmel_usart2, pba, 5);
static struct atmel_uart_data atmel_usart3_data = {
.use_dma_tx = 1,
.use_dma_rx = 1,
};
static struct resource atmel_usart3_resource[] = {
PBMEM(0xffe01800),
IRQ(9),
};
DEFINE_DEV_DATA(atmel_usart, 3);
DEV_CLK(usart, atmel_usart3, pba, 6);
static inline void configure_usart0_pins(void)
{
select_peripheral(PA(8), PERIPH_B, 0); /* RXD */
select_peripheral(PA(9), PERIPH_B, 0); /* TXD */
}
static inline void configure_usart1_pins(void)
{
select_peripheral(PA(17), PERIPH_A, 0); /* RXD */
select_peripheral(PA(18), PERIPH_A, 0); /* TXD */
}
static inline void configure_usart2_pins(void)
{
select_peripheral(PB(26), PERIPH_B, 0); /* RXD */
select_peripheral(PB(27), PERIPH_B, 0); /* TXD */
}
static inline void configure_usart3_pins(void)
{
select_peripheral(PB(18), PERIPH_B, 0); /* RXD */
select_peripheral(PB(17), PERIPH_B, 0); /* TXD */
}
static struct platform_device *__initdata at32_usarts[4];
void __init at32_map_usart(unsigned int hw_id, unsigned int line)
{
struct platform_device *pdev;
switch (hw_id) {
case 0:
pdev = &atmel_usart0_device;
configure_usart0_pins();
break;
case 1:
pdev = &atmel_usart1_device;
configure_usart1_pins();
break;
case 2:
pdev = &atmel_usart2_device;
configure_usart2_pins();
break;
case 3:
pdev = &atmel_usart3_device;
configure_usart3_pins();
break;
default:
return;
}
if (PXSEG(pdev->resource[0].start) == P4SEG) {
/* Addresses in the P4 segment are permanently mapped 1:1 */
struct atmel_uart_data *data = pdev->dev.platform_data;
data->regs = (void __iomem *)pdev->resource[0].start;
}
pdev->id = line;
at32_usarts[line] = pdev;
}
struct platform_device *__init at32_add_device_usart(unsigned int id)
{
platform_device_register(at32_usarts[id]);
return at32_usarts[id];
}
struct platform_device *atmel_default_console_device;
void __init at32_setup_serial_console(unsigned int usart_id)
{
atmel_default_console_device = at32_usarts[usart_id];
}
/* --------------------------------------------------------------------
* Ethernet
* -------------------------------------------------------------------- */
static struct eth_platform_data macb0_data;
static struct resource macb0_resource[] = {
PBMEM(0xfff01800),
IRQ(25),
};
DEFINE_DEV_DATA(macb, 0);
DEV_CLK(hclk, macb0, hsb, 8);
DEV_CLK(pclk, macb0, pbb, 6);
static struct eth_platform_data macb1_data;
static struct resource macb1_resource[] = {
PBMEM(0xfff01c00),
IRQ(26),
};
DEFINE_DEV_DATA(macb, 1);
DEV_CLK(hclk, macb1, hsb, 9);
DEV_CLK(pclk, macb1, pbb, 7);
struct platform_device *__init
at32_add_device_eth(unsigned int id, struct eth_platform_data *data)
{
struct platform_device *pdev;
switch (id) {
case 0:
pdev = &macb0_device;
select_peripheral(PC(3), PERIPH_A, 0); /* TXD0 */
select_peripheral(PC(4), PERIPH_A, 0); /* TXD1 */
select_peripheral(PC(7), PERIPH_A, 0); /* TXEN */
select_peripheral(PC(8), PERIPH_A, 0); /* TXCK */
select_peripheral(PC(9), PERIPH_A, 0); /* RXD0 */
select_peripheral(PC(10), PERIPH_A, 0); /* RXD1 */
select_peripheral(PC(13), PERIPH_A, 0); /* RXER */
select_peripheral(PC(15), PERIPH_A, 0); /* RXDV */
select_peripheral(PC(16), PERIPH_A, 0); /* MDC */
select_peripheral(PC(17), PERIPH_A, 0); /* MDIO */
if (!data->is_rmii) {
select_peripheral(PC(0), PERIPH_A, 0); /* COL */
select_peripheral(PC(1), PERIPH_A, 0); /* CRS */
select_peripheral(PC(2), PERIPH_A, 0); /* TXER */
select_peripheral(PC(5), PERIPH_A, 0); /* TXD2 */
select_peripheral(PC(6), PERIPH_A, 0); /* TXD3 */
select_peripheral(PC(11), PERIPH_A, 0); /* RXD2 */
select_peripheral(PC(12), PERIPH_A, 0); /* RXD3 */
select_peripheral(PC(14), PERIPH_A, 0); /* RXCK */
select_peripheral(PC(18), PERIPH_A, 0); /* SPD */
}
break;
case 1:
pdev = &macb1_device;
select_peripheral(PD(13), PERIPH_B, 0); /* TXD0 */
select_peripheral(PD(14), PERIPH_B, 0); /* TXD1 */
select_peripheral(PD(11), PERIPH_B, 0); /* TXEN */
select_peripheral(PD(12), PERIPH_B, 0); /* TXCK */
select_peripheral(PD(10), PERIPH_B, 0); /* RXD0 */
select_peripheral(PD(6), PERIPH_B, 0); /* RXD1 */
select_peripheral(PD(5), PERIPH_B, 0); /* RXER */
select_peripheral(PD(4), PERIPH_B, 0); /* RXDV */
select_peripheral(PD(3), PERIPH_B, 0); /* MDC */
select_peripheral(PD(2), PERIPH_B, 0); /* MDIO */
if (!data->is_rmii) {
select_peripheral(PC(19), PERIPH_B, 0); /* COL */
select_peripheral(PC(23), PERIPH_B, 0); /* CRS */
select_peripheral(PC(26), PERIPH_B, 0); /* TXER */
select_peripheral(PC(27), PERIPH_B, 0); /* TXD2 */
select_peripheral(PC(28), PERIPH_B, 0); /* TXD3 */
select_peripheral(PC(29), PERIPH_B, 0); /* RXD2 */
select_peripheral(PC(30), PERIPH_B, 0); /* RXD3 */
select_peripheral(PC(24), PERIPH_B, 0); /* RXCK */
select_peripheral(PD(15), PERIPH_B, 0); /* SPD */
}
break;
default:
return NULL;
}
memcpy(pdev->dev.platform_data, data, sizeof(struct eth_platform_data));
platform_device_register(pdev);
return pdev;
}
/* --------------------------------------------------------------------
* SPI
* -------------------------------------------------------------------- */
static struct resource atmel_spi0_resource[] = {
PBMEM(0xffe00000),
IRQ(3),
};
DEFINE_DEV(atmel_spi, 0);
DEV_CLK(spi_clk, atmel_spi0, pba, 0);
static struct resource atmel_spi1_resource[] = {
PBMEM(0xffe00400),
IRQ(4),
};
DEFINE_DEV(atmel_spi, 1);
DEV_CLK(spi_clk, atmel_spi1, pba, 1);
static void __init
at32_spi_setup_slaves(unsigned int bus_num, struct spi_board_info *b,
unsigned int n, const u8 *pins)
{
unsigned int pin, mode;
for (; n; n--, b++) {
b->bus_num = bus_num;
if (b->chip_select >= 4)
continue;
pin = (unsigned)b->controller_data;
if (!pin) {
pin = pins[b->chip_select];
b->controller_data = (void *)pin;
}
mode = AT32_GPIOF_OUTPUT;
if (!(b->mode & SPI_CS_HIGH))
mode |= AT32_GPIOF_HIGH;
at32_select_gpio(pin, mode);
}
}
struct platform_device *__init
at32_add_device_spi(unsigned int id, struct spi_board_info *b, unsigned int n)
{
/*
* Manage the chipselects as GPIOs, normally using the same pins
* the SPI controller expects; but boards can use other pins.
*/
static u8 __initdata spi0_pins[] =
{ GPIO_PIN_PA(3), GPIO_PIN_PA(4),
GPIO_PIN_PA(5), GPIO_PIN_PA(20), };
static u8 __initdata spi1_pins[] =
{ GPIO_PIN_PB(2), GPIO_PIN_PB(3),
GPIO_PIN_PB(4), GPIO_PIN_PA(27), };
struct platform_device *pdev;
switch (id) {
case 0:
pdev = &atmel_spi0_device;
select_peripheral(PA(0), PERIPH_A, 0); /* MISO */
select_peripheral(PA(1), PERIPH_A, 0); /* MOSI */
select_peripheral(PA(2), PERIPH_A, 0); /* SCK */
at32_spi_setup_slaves(0, b, n, spi0_pins);
break;
case 1:
pdev = &atmel_spi1_device;
select_peripheral(PB(0), PERIPH_B, 0); /* MISO */
select_peripheral(PB(1), PERIPH_B, 0); /* MOSI */
select_peripheral(PB(5), PERIPH_B, 0); /* SCK */
at32_spi_setup_slaves(1, b, n, spi1_pins);
break;
default:
return NULL;
}
spi_register_board_info(b, n);
platform_device_register(pdev);
return pdev;
}
/* --------------------------------------------------------------------
* LCDC
* -------------------------------------------------------------------- */
static struct atmel_lcdfb_info atmel_lcdfb0_data;
static struct resource atmel_lcdfb0_resource[] = {
{
.start = 0xff000000,
.end = 0xff000fff,
.flags = IORESOURCE_MEM,
},
IRQ(1),
{
/* Placeholder for pre-allocated fb memory */
.start = 0x00000000,
.end = 0x00000000,
.flags = 0,
},
};
DEFINE_DEV_DATA(atmel_lcdfb, 0);
DEV_CLK(hck1, atmel_lcdfb0, hsb, 7);
static struct clk atmel_lcdfb0_pixclk = {
.name = "lcdc_clk",
.dev = &atmel_lcdfb0_device.dev,
.mode = genclk_mode,
.get_rate = genclk_get_rate,
.set_rate = genclk_set_rate,
.set_parent = genclk_set_parent,
.index = 7,
};
struct platform_device *__init
at32_add_device_lcdc(unsigned int id, struct atmel_lcdfb_info *data,
unsigned long fbmem_start, unsigned long fbmem_len)
{
struct platform_device *pdev;
struct atmel_lcdfb_info *info;
struct fb_monspecs *monspecs;
struct fb_videomode *modedb;
unsigned int modedb_size;
/*
* Do a deep copy of the fb data, monspecs and modedb. Make
* sure all allocations are done before setting up the
* portmux.
*/
monspecs = kmemdup(data->default_monspecs,
sizeof(struct fb_monspecs), GFP_KERNEL);
if (!monspecs)
return NULL;
modedb_size = sizeof(struct fb_videomode) * monspecs->modedb_len;
modedb = kmemdup(monspecs->modedb, modedb_size, GFP_KERNEL);
if (!modedb)
goto err_dup_modedb;
monspecs->modedb = modedb;
switch (id) {
case 0:
pdev = &atmel_lcdfb0_device;
select_peripheral(PC(19), PERIPH_A, 0); /* CC */
select_peripheral(PC(20), PERIPH_A, 0); /* HSYNC */
select_peripheral(PC(21), PERIPH_A, 0); /* PCLK */
select_peripheral(PC(22), PERIPH_A, 0); /* VSYNC */
select_peripheral(PC(23), PERIPH_A, 0); /* DVAL */
select_peripheral(PC(24), PERIPH_A, 0); /* MODE */
select_peripheral(PC(25), PERIPH_A, 0); /* PWR */
select_peripheral(PC(26), PERIPH_A, 0); /* DATA0 */
select_peripheral(PC(27), PERIPH_A, 0); /* DATA1 */
select_peripheral(PC(28), PERIPH_A, 0); /* DATA2 */
select_peripheral(PC(29), PERIPH_A, 0); /* DATA3 */
select_peripheral(PC(30), PERIPH_A, 0); /* DATA4 */
select_peripheral(PC(31), PERIPH_A, 0); /* DATA5 */
select_peripheral(PD(0), PERIPH_A, 0); /* DATA6 */
select_peripheral(PD(1), PERIPH_A, 0); /* DATA7 */
select_peripheral(PD(2), PERIPH_A, 0); /* DATA8 */
select_peripheral(PD(3), PERIPH_A, 0); /* DATA9 */
select_peripheral(PD(4), PERIPH_A, 0); /* DATA10 */
select_peripheral(PD(5), PERIPH_A, 0); /* DATA11 */
select_peripheral(PD(6), PERIPH_A, 0); /* DATA12 */
select_peripheral(PD(7), PERIPH_A, 0); /* DATA13 */
select_peripheral(PD(8), PERIPH_A, 0); /* DATA14 */
select_peripheral(PD(9), PERIPH_A, 0); /* DATA15 */
select_peripheral(PD(10), PERIPH_A, 0); /* DATA16 */
select_peripheral(PD(11), PERIPH_A, 0); /* DATA17 */
select_peripheral(PD(12), PERIPH_A, 0); /* DATA18 */
select_peripheral(PD(13), PERIPH_A, 0); /* DATA19 */
select_peripheral(PD(14), PERIPH_A, 0); /* DATA20 */
select_peripheral(PD(15), PERIPH_A, 0); /* DATA21 */
select_peripheral(PD(16), PERIPH_A, 0); /* DATA22 */
select_peripheral(PD(17), PERIPH_A, 0); /* DATA23 */
clk_set_parent(&atmel_lcdfb0_pixclk, &pll0);
clk_set_rate(&atmel_lcdfb0_pixclk, clk_get_rate(&pll0));
break;
default:
goto err_invalid_id;
}
if (fbmem_len) {
pdev->resource[2].start = fbmem_start;
pdev->resource[2].end = fbmem_start + fbmem_len - 1;
pdev->resource[2].flags = IORESOURCE_MEM;
}
info = pdev->dev.platform_data;
memcpy(info, data, sizeof(struct atmel_lcdfb_info));
info->default_monspecs = monspecs;
platform_device_register(pdev);
return pdev;
err_invalid_id:
kfree(modedb);
err_dup_modedb:
kfree(monspecs);
return NULL;
}
/* --------------------------------------------------------------------
* GCLK
* -------------------------------------------------------------------- */
static struct clk gclk0 = {
.name = "gclk0",
.mode = genclk_mode,
.get_rate = genclk_get_rate,
.set_rate = genclk_set_rate,
.set_parent = genclk_set_parent,
.index = 0,
};
static struct clk gclk1 = {
.name = "gclk1",
.mode = genclk_mode,
.get_rate = genclk_get_rate,
.set_rate = genclk_set_rate,
.set_parent = genclk_set_parent,
.index = 1,
};
static struct clk gclk2 = {
.name = "gclk2",
.mode = genclk_mode,
.get_rate = genclk_get_rate,
.set_rate = genclk_set_rate,
.set_parent = genclk_set_parent,
.index = 2,
};
static struct clk gclk3 = {
.name = "gclk3",
.mode = genclk_mode,
.get_rate = genclk_get_rate,
.set_rate = genclk_set_rate,
.set_parent = genclk_set_parent,
.index = 3,
};
static struct clk gclk4 = {
.name = "gclk4",
.mode = genclk_mode,
.get_rate = genclk_get_rate,
.set_rate = genclk_set_rate,
.set_parent = genclk_set_parent,
.index = 4,
};
struct clk *at32_clock_list[] = {
&osc32k,
&osc0,
&osc1,
&pll0,
&pll1,
&cpu_clk,
&hsb_clk,
&pba_clk,
&pbb_clk,
&at32_sm_pclk,
&at32_intc0_pclk,
&hmatrix_clk,
&ebi_clk,
&hramc_clk,
&smc0_pclk,
&smc0_mck,
&pdc_hclk,
&pdc_pclk,
&pico_clk,
&pio0_mck,
&pio1_mck,
&pio2_mck,
&pio3_mck,
&pio4_mck,
&at32_systc0_pclk,
&atmel_usart0_usart,
&atmel_usart1_usart,
&atmel_usart2_usart,
&atmel_usart3_usart,
&macb0_hclk,
&macb0_pclk,
&macb1_hclk,
&macb1_pclk,
&atmel_spi0_spi_clk,
&atmel_spi1_spi_clk,
&atmel_lcdfb0_hck1,
&atmel_lcdfb0_pixclk,
&gclk0,
&gclk1,
&gclk2,
&gclk3,
&gclk4,
};
unsigned int at32_nr_clocks = ARRAY_SIZE(at32_clock_list);
void __init at32_portmux_init(void)
{
at32_init_pio(&pio0_device);
at32_init_pio(&pio1_device);
at32_init_pio(&pio2_device);
at32_init_pio(&pio3_device);
at32_init_pio(&pio4_device);
}
void __init at32_clock_init(void)
{
struct at32_sm *sm = &system_manager;
u32 cpu_mask = 0, hsb_mask = 0, pba_mask = 0, pbb_mask = 0;
int i;
if (sm_readl(sm, PM_MCCTRL) & SM_BIT(PLLSEL))
main_clock = &pll0;
else
main_clock = &osc0;
if (sm_readl(sm, PM_PLL0) & SM_BIT(PLLOSC))
pll0.parent = &osc1;
if (sm_readl(sm, PM_PLL1) & SM_BIT(PLLOSC))
pll1.parent = &osc1;
genclk_init_parent(&gclk0);
genclk_init_parent(&gclk1);
genclk_init_parent(&gclk2);
genclk_init_parent(&gclk3);
genclk_init_parent(&gclk4);
genclk_init_parent(&atmel_lcdfb0_pixclk);
/*
* Turn on all clocks that have at least one user already, and
* turn off everything else. We only do this for module
* clocks, and even though it isn't particularly pretty to
* check the address of the mode function, it should do the
* trick...
*/
for (i = 0; i < ARRAY_SIZE(at32_clock_list); i++) {
struct clk *clk = at32_clock_list[i];
if (clk->users == 0)
continue;
if (clk->mode == &cpu_clk_mode)
cpu_mask |= 1 << clk->index;
else if (clk->mode == &hsb_clk_mode)
hsb_mask |= 1 << clk->index;
else if (clk->mode == &pba_clk_mode)
pba_mask |= 1 << clk->index;
else if (clk->mode == &pbb_clk_mode)
pbb_mask |= 1 << clk->index;
}
sm_writel(sm, PM_CPU_MASK, cpu_mask);
sm_writel(sm, PM_HSB_MASK, hsb_mask);
sm_writel(sm, PM_PBA_MASK, pba_mask);
sm_writel(sm, PM_PBB_MASK, pbb_mask);
}