Merge remote-tracking branch 's5p/for-next'

[linux-2.6/next.git] / arch / mips / lantiq / xway / clk-xway.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);