kernel-fxtec-pro1x/arch/mips/lantiq/xway/clk-xway.c
John Crispin 8ec6d93508 MIPS: Lantiq: add SoC specific code for XWAY family
Add support for the Lantiq XWAY family of Mips24KEc SoCs.

* Danube (PSB50702)
* Twinpass (PSB4000)
* AR9 (PSB50802)
* Amazon SE (PSB5061)

The Amazon SE is a lightweight SoC and has no PCI as well as a different
clock. We split the code out into seperate files to handle this.

The GPIO pins on the SoCs are multi function and there are several bits
we can use to configure the pins. To be as compatible as possible to
GPIOLIB we add a function

int lq_gpio_request(unsigned int pin, unsigned int alt0,
        unsigned int alt1, unsigned int dir, const char *name);

which lets you configure the 2 "alternate function" bits. This way drivers like
PCI can make use of GPIOLIB without a cubersome wrapper.

The PLL code inside arch/mips/lantiq/xway/clk-xway.c is voodoo to me. It was
taken from a 2.4.20 source tree and was never really changed by me since then.

Signed-off-by: John Crispin <blogic@openwrt.org>
Signed-off-by: Ralph Hempel <ralph.hempel@lantiq.com>
Cc: linux-mips@linux-mips.org
Patchwork: https://patchwork.linux-mips.org/patch/2249/
Signed-off-by: Ralf Baechle <ralf@linux-mips.org>
2011-05-19 09:55:41 +01:00

223 lines
5.4 KiB
C

/*
* 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.
*
* Copyright (C) 2010 John Crispin <blogic@openwrt.org>
*/
#include <linux/io.h>
#include <linux/module.h>
#include <linux/init.h>
#include <linux/clk.h>
#include <asm/time.h>
#include <asm/irq.h>
#include <asm/div64.h>
#include <lantiq_soc.h>
static unsigned int ltq_ram_clocks[] = {
CLOCK_167M, CLOCK_133M, CLOCK_111M, CLOCK_83M };
#define DDR_HZ ltq_ram_clocks[ltq_cgu_r32(LTQ_CGU_SYS) & 0x3]
#define BASIC_FREQUENCY_1 35328000
#define BASIC_FREQUENCY_2 36000000
#define BASIS_REQUENCY_USB 12000000
#define GET_BITS(x, msb, lsb) \
(((x) & ((1 << ((msb) + 1)) - 1)) >> (lsb))
#define LTQ_CGU_PLL0_CFG 0x0004
#define LTQ_CGU_PLL1_CFG 0x0008
#define LTQ_CGU_PLL2_CFG 0x000C
#define LTQ_CGU_SYS 0x0010
#define LTQ_CGU_UPDATE 0x0014
#define LTQ_CGU_IF_CLK 0x0018
#define LTQ_CGU_OSC_CON 0x001C
#define LTQ_CGU_SMD 0x0020
#define LTQ_CGU_CT1SR 0x0028
#define LTQ_CGU_CT2SR 0x002C
#define LTQ_CGU_PCMCR 0x0030
#define LTQ_CGU_PCI_CR 0x0034
#define LTQ_CGU_PD_PC 0x0038
#define LTQ_CGU_FMR 0x003C
#define CGU_PLL0_PHASE_DIVIDER_ENABLE \
(ltq_cgu_r32(LTQ_CGU_PLL0_CFG) & (1 << 31))
#define CGU_PLL0_BYPASS \
(ltq_cgu_r32(LTQ_CGU_PLL0_CFG) & (1 << 30))
#define CGU_PLL0_CFG_DSMSEL \
(ltq_cgu_r32(LTQ_CGU_PLL0_CFG) & (1 << 28))
#define CGU_PLL0_CFG_FRAC_EN \
(ltq_cgu_r32(LTQ_CGU_PLL0_CFG) & (1 << 27))
#define CGU_PLL1_SRC \
(ltq_cgu_r32(LTQ_CGU_PLL1_CFG) & (1 << 31))
#define CGU_PLL2_PHASE_DIVIDER_ENABLE \
(ltq_cgu_r32(LTQ_CGU_PLL2_CFG) & (1 << 20))
#define CGU_SYS_FPI_SEL (1 << 6)
#define CGU_SYS_DDR_SEL 0x3
#define CGU_PLL0_SRC (1 << 29)
#define CGU_PLL0_CFG_PLLK GET_BITS(ltq_cgu_r32(LTQ_CGU_PLL0_CFG), 26, 17)
#define CGU_PLL0_CFG_PLLN GET_BITS(ltq_cgu_r32(LTQ_CGU_PLL0_CFG), 12, 6)
#define CGU_PLL0_CFG_PLLM GET_BITS(ltq_cgu_r32(LTQ_CGU_PLL0_CFG), 5, 2)
#define CGU_PLL2_SRC GET_BITS(ltq_cgu_r32(LTQ_CGU_PLL2_CFG), 18, 17)
#define CGU_PLL2_CFG_INPUT_DIV GET_BITS(ltq_cgu_r32(LTQ_CGU_PLL2_CFG), 16, 13)
static unsigned int ltq_get_pll0_fdiv(void);
static inline unsigned int get_input_clock(int pll)
{
switch (pll) {
case 0:
if (ltq_cgu_r32(LTQ_CGU_PLL0_CFG) & CGU_PLL0_SRC)
return BASIS_REQUENCY_USB;
else if (CGU_PLL0_PHASE_DIVIDER_ENABLE)
return BASIC_FREQUENCY_1;
else
return BASIC_FREQUENCY_2;
case 1:
if (CGU_PLL1_SRC)
return BASIS_REQUENCY_USB;
else if (CGU_PLL0_PHASE_DIVIDER_ENABLE)
return BASIC_FREQUENCY_1;
else
return BASIC_FREQUENCY_2;
case 2:
switch (CGU_PLL2_SRC) {
case 0:
return ltq_get_pll0_fdiv();
case 1:
return CGU_PLL2_PHASE_DIVIDER_ENABLE ?
BASIC_FREQUENCY_1 :
BASIC_FREQUENCY_2;
case 2:
return BASIS_REQUENCY_USB;
}
default:
return 0;
}
}
static inline unsigned int cal_dsm(int pll, unsigned int num, unsigned int den)
{
u64 res, clock = get_input_clock(pll);
res = num * clock;
do_div(res, den);
return res;
}
static inline unsigned int mash_dsm(int pll, unsigned int M, unsigned int N,
unsigned int K)
{
unsigned int num = ((N + 1) << 10) + K;
unsigned int den = (M + 1) << 10;
return cal_dsm(pll, num, den);
}
static inline unsigned int ssff_dsm_1(int pll, unsigned int M, unsigned int N,
unsigned int K)
{
unsigned int num = ((N + 1) << 11) + K + 512;
unsigned int den = (M + 1) << 11;
return cal_dsm(pll, num, den);
}
static inline unsigned int ssff_dsm_2(int pll, unsigned int M, unsigned int N,
unsigned int K)
{
unsigned int num = K >= 512 ?
((N + 1) << 12) + K - 512 : ((N + 1) << 12) + K + 3584;
unsigned int den = (M + 1) << 12;
return cal_dsm(pll, num, den);
}
static inline unsigned int dsm(int pll, unsigned int M, unsigned int N,
unsigned int K, unsigned int dsmsel, unsigned int phase_div_en)
{
if (!dsmsel)
return mash_dsm(pll, M, N, K);
else if (!phase_div_en)
return mash_dsm(pll, M, N, K);
else
return ssff_dsm_2(pll, M, N, K);
}
static inline unsigned int ltq_get_pll0_fosc(void)
{
if (CGU_PLL0_BYPASS)
return get_input_clock(0);
else
return !CGU_PLL0_CFG_FRAC_EN
? dsm(0, CGU_PLL0_CFG_PLLM, CGU_PLL0_CFG_PLLN, 0,
CGU_PLL0_CFG_DSMSEL,
CGU_PLL0_PHASE_DIVIDER_ENABLE)
: dsm(0, CGU_PLL0_CFG_PLLM, CGU_PLL0_CFG_PLLN,
CGU_PLL0_CFG_PLLK, CGU_PLL0_CFG_DSMSEL,
CGU_PLL0_PHASE_DIVIDER_ENABLE);
}
static unsigned int ltq_get_pll0_fdiv(void)
{
unsigned int div = CGU_PLL2_CFG_INPUT_DIV + 1;
return (ltq_get_pll0_fosc() + (div >> 1)) / div;
}
unsigned int ltq_get_io_region_clock(void)
{
unsigned int ret = ltq_get_pll0_fosc();
switch (ltq_cgu_r32(LTQ_CGU_PLL2_CFG) & CGU_SYS_DDR_SEL) {
default:
case 0:
return (ret + 1) / 2;
case 1:
return (ret * 2 + 2) / 5;
case 2:
return (ret + 1) / 3;
case 3:
return (ret + 2) / 4;
}
}
EXPORT_SYMBOL(ltq_get_io_region_clock);
unsigned int ltq_get_fpi_bus_clock(int fpi)
{
unsigned int ret = ltq_get_io_region_clock();
if ((fpi == 2) && (ltq_cgu_r32(LTQ_CGU_SYS) & CGU_SYS_FPI_SEL))
ret >>= 1;
return ret;
}
EXPORT_SYMBOL(ltq_get_fpi_bus_clock);
unsigned int ltq_get_cpu_hz(void)
{
switch (ltq_cgu_r32(LTQ_CGU_SYS) & 0xc) {
case 0:
return CLOCK_333M;
case 4:
return DDR_HZ;
case 8:
return DDR_HZ << 1;
default:
return DDR_HZ >> 1;
}
}
EXPORT_SYMBOL(ltq_get_cpu_hz);
unsigned int ltq_get_fpi_hz(void)
{
unsigned int ddr_clock = DDR_HZ;
if (ltq_cgu_r32(LTQ_CGU_SYS) & 0x40)
return ddr_clock >> 1;
return ddr_clock;
}
EXPORT_SYMBOL(ltq_get_fpi_hz);