linux/arch/arm/mach-shmobile/clock-r8a73a4.c
Olof Johansson 9b03c6041c Second Round of Renesas ARM Based SoC Clock Updates for v3.17
* Add legacy clocks for SCI for SoCs that do not yet have CCF support.
   This is to allow SCI (serial) devices to be enabled using DT and
   will be removed after CCF support is added for each SoC.
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Merge tag 'renesas-clock2-for-v3.17' of git://git.kernel.org/pub/scm/linux/kernel/git/horms/renesas into next/soc

Merge "Second Round of Renesas ARM Based SoC Clock Updates for v3.17" from
Simon Horman:

- Add legacy clocks for SCI for SoCs that do not yet have CCF support.
  This is to allow SCI (serial) devices to be enabled using DT and
  will be removed after CCF support is added for each SoC.

* tag 'renesas-clock2-for-v3.17' of git://git.kernel.org/pub/scm/linux/kernel/git/horms/renesas:
  ARM: shmobile: sh73a0: add SCI clock support for DT
  ARM: shmobile: r8a7740: correct SCI clock support for DT
  ARM: shmobile: r8a73a4: add SCI clock support for DT
  ARM: shmobile: r8a7778: add SCI clock support for DT

Signed-off-by: Olof Johansson <olof@lixom.net>
2014-07-18 21:30:26 -07:00

663 lines
19 KiB
C

/*
* r8a73a4 clock framework support
*
* Copyright (C) 2013 Renesas Solutions Corp.
* Copyright (C) 2013 Magnus Damm
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include <linux/init.h>
#include <linux/io.h>
#include <linux/kernel.h>
#include <linux/sh_clk.h>
#include <linux/clkdev.h>
#include "common.h"
#include "clock.h"
#define CPG_BASE 0xe6150000
#define CPG_LEN 0x270
#define SMSTPCR2 0xe6150138
#define SMSTPCR3 0xe615013c
#define SMSTPCR4 0xe6150140
#define SMSTPCR5 0xe6150144
#define FRQCRA 0xE6150000
#define FRQCRB 0xE6150004
#define FRQCRC 0xE61500E0
#define VCLKCR1 0xE6150008
#define VCLKCR2 0xE615000C
#define VCLKCR3 0xE615001C
#define VCLKCR4 0xE6150014
#define VCLKCR5 0xE6150034
#define ZBCKCR 0xE6150010
#define SD0CKCR 0xE6150074
#define SD1CKCR 0xE6150078
#define SD2CKCR 0xE615007C
#define MMC0CKCR 0xE6150240
#define MMC1CKCR 0xE6150244
#define FSIACKCR 0xE6150018
#define FSIBCKCR 0xE6150090
#define MPCKCR 0xe6150080
#define SPUVCKCR 0xE6150094
#define HSICKCR 0xE615026C
#define M4CKCR 0xE6150098
#define PLLECR 0xE61500D0
#define PLL0CR 0xE61500D8
#define PLL1CR 0xE6150028
#define PLL2CR 0xE615002C
#define PLL2SCR 0xE61501F4
#define PLL2HCR 0xE61501E4
#define CKSCR 0xE61500C0
#define CPG_MAP(o) ((o - CPG_BASE) + cpg_mapping.base)
static struct clk_mapping cpg_mapping = {
.phys = CPG_BASE,
.len = CPG_LEN,
};
static struct clk extalr_clk = {
.rate = 32768,
.mapping = &cpg_mapping,
};
static struct clk extal1_clk = {
.rate = 26000000,
.mapping = &cpg_mapping,
};
static struct clk extal2_clk = {
.rate = 48000000,
.mapping = &cpg_mapping,
};
static struct sh_clk_ops followparent_clk_ops = {
.recalc = followparent_recalc,
};
static struct clk main_clk = {
/* .parent will be set r8a73a4_clock_init */
.ops = &followparent_clk_ops,
};
SH_CLK_RATIO(div2, 1, 2);
SH_CLK_RATIO(div4, 1, 4);
SH_FIXED_RATIO_CLK(main_div2_clk, main_clk, div2);
SH_FIXED_RATIO_CLK(extal1_div2_clk, extal1_clk, div2);
SH_FIXED_RATIO_CLK(extal2_div2_clk, extal2_clk, div2);
SH_FIXED_RATIO_CLK(extal2_div4_clk, extal2_clk, div4);
/* External FSIACK/FSIBCK clock */
static struct clk fsiack_clk = {
};
static struct clk fsibck_clk = {
};
/*
* PLL clocks
*/
static struct clk *pll_parent_main[] = {
[0] = &main_clk,
[1] = &main_div2_clk
};
static struct clk *pll_parent_main_extal[8] = {
[0] = &main_div2_clk,
[1] = &extal2_div2_clk,
[3] = &extal2_div4_clk,
[4] = &main_clk,
[5] = &extal2_clk,
};
static unsigned long pll_recalc(struct clk *clk)
{
unsigned long mult = 1;
if (ioread32(CPG_MAP(PLLECR)) & (1 << clk->enable_bit))
mult = (((ioread32(clk->mapped_reg) >> 24) & 0x7f) + 1);
return clk->parent->rate * mult;
}
static int pll_set_parent(struct clk *clk, struct clk *parent)
{
u32 val;
int i, ret;
if (!clk->parent_table || !clk->parent_num)
return -EINVAL;
/* Search the parent */
for (i = 0; i < clk->parent_num; i++)
if (clk->parent_table[i] == parent)
break;
if (i == clk->parent_num)
return -ENODEV;
ret = clk_reparent(clk, parent);
if (ret < 0)
return ret;
val = ioread32(clk->mapped_reg) &
~(((1 << clk->src_width) - 1) << clk->src_shift);
iowrite32(val | i << clk->src_shift, clk->mapped_reg);
return 0;
}
static struct sh_clk_ops pll_clk_ops = {
.recalc = pll_recalc,
.set_parent = pll_set_parent,
};
#define PLL_CLOCK(name, p, pt, w, s, reg, e) \
static struct clk name = { \
.ops = &pll_clk_ops, \
.flags = CLK_ENABLE_ON_INIT, \
.parent = p, \
.parent_table = pt, \
.parent_num = ARRAY_SIZE(pt), \
.src_width = w, \
.src_shift = s, \
.enable_reg = (void __iomem *)reg, \
.enable_bit = e, \
.mapping = &cpg_mapping, \
}
PLL_CLOCK(pll0_clk, &main_clk, pll_parent_main, 1, 20, PLL0CR, 0);
PLL_CLOCK(pll1_clk, &main_clk, pll_parent_main, 1, 7, PLL1CR, 1);
PLL_CLOCK(pll2_clk, &main_div2_clk, pll_parent_main_extal, 3, 5, PLL2CR, 2);
PLL_CLOCK(pll2s_clk, &main_div2_clk, pll_parent_main_extal, 3, 5, PLL2SCR, 4);
PLL_CLOCK(pll2h_clk, &main_div2_clk, pll_parent_main_extal, 3, 5, PLL2HCR, 5);
SH_FIXED_RATIO_CLK(pll1_div2_clk, pll1_clk, div2);
static atomic_t frqcr_lock;
/* Several clocks need to access FRQCRB, have to lock */
static bool frqcr_kick_check(struct clk *clk)
{
return !(ioread32(CPG_MAP(FRQCRB)) & BIT(31));
}
static int frqcr_kick_do(struct clk *clk)
{
int i;
/* set KICK bit in FRQCRB to update hardware setting, check success */
iowrite32(ioread32(CPG_MAP(FRQCRB)) | BIT(31), CPG_MAP(FRQCRB));
for (i = 1000; i; i--)
if (ioread32(CPG_MAP(FRQCRB)) & BIT(31))
cpu_relax();
else
return 0;
return -ETIMEDOUT;
}
static int zclk_set_rate(struct clk *clk, unsigned long rate)
{
void __iomem *frqcrc;
int ret;
unsigned long step, p_rate;
u32 val;
if (!clk->parent || !__clk_get(clk->parent))
return -ENODEV;
if (!atomic_inc_and_test(&frqcr_lock) || !frqcr_kick_check(clk)) {
ret = -EBUSY;
goto done;
}
/*
* Users are supposed to first call clk_set_rate() only with
* clk_round_rate() results. So, we don't fix wrong rates here, but
* guard against them anyway
*/
p_rate = clk_get_rate(clk->parent);
if (rate == p_rate) {
val = 0;
} else {
step = DIV_ROUND_CLOSEST(p_rate, 32);
if (rate > p_rate || rate < step) {
ret = -EINVAL;
goto done;
}
val = 32 - rate / step;
}
frqcrc = clk->mapped_reg + (FRQCRC - (u32)clk->enable_reg);
iowrite32((ioread32(frqcrc) & ~(clk->div_mask << clk->enable_bit)) |
(val << clk->enable_bit), frqcrc);
ret = frqcr_kick_do(clk);
done:
atomic_dec(&frqcr_lock);
__clk_put(clk->parent);
return ret;
}
static long zclk_round_rate(struct clk *clk, unsigned long rate)
{
/*
* theoretical rate = parent rate * multiplier / 32,
* where 1 <= multiplier <= 32. Therefore we should do
* multiplier = rate * 32 / parent rate
* rounded rate = parent rate * multiplier / 32.
* However, multiplication before division won't fit in 32 bits, so
* we sacrifice some precision by first dividing and then multiplying.
* To find the nearest divisor we calculate both and pick up the best
* one. This avoids 64-bit arithmetics.
*/
unsigned long step, mul_min, mul_max, rate_min, rate_max;
rate_max = clk_get_rate(clk->parent);
/* output freq <= parent */
if (rate >= rate_max)
return rate_max;
step = DIV_ROUND_CLOSEST(rate_max, 32);
/* output freq >= parent / 32 */
if (step >= rate)
return step;
mul_min = rate / step;
mul_max = DIV_ROUND_UP(rate, step);
rate_min = step * mul_min;
if (mul_max == mul_min)
return rate_min;
rate_max = step * mul_max;
if (rate_max - rate < rate - rate_min)
return rate_max;
return rate_min;
}
static unsigned long zclk_recalc(struct clk *clk)
{
void __iomem *frqcrc = FRQCRC - (u32)clk->enable_reg + clk->mapped_reg;
unsigned int max = clk->div_mask + 1;
unsigned long val = ((ioread32(frqcrc) >> clk->enable_bit) &
clk->div_mask);
return DIV_ROUND_CLOSEST(clk_get_rate(clk->parent), max) *
(max - val);
}
static struct sh_clk_ops zclk_ops = {
.recalc = zclk_recalc,
.set_rate = zclk_set_rate,
.round_rate = zclk_round_rate,
};
static struct clk z_clk = {
.parent = &pll0_clk,
.div_mask = 0x1f,
.enable_bit = 8,
/* We'll need to access FRQCRB and FRQCRC */
.enable_reg = (void __iomem *)FRQCRB,
.ops = &zclk_ops,
};
/*
* It seems only 1/2 divider is usable in manual mode. 1/2 / 2/3
* switching is only available in auto-DVFS mode
*/
SH_FIXED_RATIO_CLK(pll0_div2_clk, pll0_clk, div2);
static struct clk z2_clk = {
.parent = &pll0_div2_clk,
.div_mask = 0x1f,
.enable_bit = 0,
/* We'll need to access FRQCRB and FRQCRC */
.enable_reg = (void __iomem *)FRQCRB,
.ops = &zclk_ops,
};
static struct clk *main_clks[] = {
&extalr_clk,
&extal1_clk,
&extal1_div2_clk,
&extal2_clk,
&extal2_div2_clk,
&extal2_div4_clk,
&main_clk,
&main_div2_clk,
&fsiack_clk,
&fsibck_clk,
&pll0_clk,
&pll1_clk,
&pll1_div2_clk,
&pll2_clk,
&pll2s_clk,
&pll2h_clk,
&z_clk,
&pll0_div2_clk,
&z2_clk,
};
/* DIV4 */
static void div4_kick(struct clk *clk)
{
if (!WARN(!atomic_inc_and_test(&frqcr_lock), "FRQCR* lock broken!\n"))
frqcr_kick_do(clk);
atomic_dec(&frqcr_lock);
}
static int divisors[] = { 2, 3, 4, 6, 8, 12, 16, 18, 24, 0, 36, 48, 10};
static struct clk_div_mult_table div4_div_mult_table = {
.divisors = divisors,
.nr_divisors = ARRAY_SIZE(divisors),
};
static struct clk_div4_table div4_table = {
.div_mult_table = &div4_div_mult_table,
.kick = div4_kick,
};
enum {
DIV4_I, DIV4_M3, DIV4_B, DIV4_M1, DIV4_M2,
DIV4_ZX, DIV4_ZS, DIV4_HP,
DIV4_NR };
static struct clk div4_clks[DIV4_NR] = {
[DIV4_I] = SH_CLK_DIV4(&pll1_clk, FRQCRA, 20, 0x0dff, CLK_ENABLE_ON_INIT),
[DIV4_M3] = SH_CLK_DIV4(&pll1_clk, FRQCRA, 12, 0x1dff, CLK_ENABLE_ON_INIT),
[DIV4_B] = SH_CLK_DIV4(&pll1_clk, FRQCRA, 8, 0x0dff, CLK_ENABLE_ON_INIT),
[DIV4_M1] = SH_CLK_DIV4(&pll1_clk, FRQCRA, 4, 0x1dff, 0),
[DIV4_M2] = SH_CLK_DIV4(&pll1_clk, FRQCRA, 0, 0x1dff, 0),
[DIV4_ZX] = SH_CLK_DIV4(&pll1_clk, FRQCRB, 12, 0x0dff, 0),
[DIV4_ZS] = SH_CLK_DIV4(&pll1_clk, FRQCRB, 8, 0x0dff, 0),
[DIV4_HP] = SH_CLK_DIV4(&pll1_clk, FRQCRB, 4, 0x0dff, 0),
};
enum {
DIV6_ZB,
DIV6_SDHI0, DIV6_SDHI1, DIV6_SDHI2,
DIV6_MMC0, DIV6_MMC1,
DIV6_VCK1, DIV6_VCK2, DIV6_VCK3, DIV6_VCK4, DIV6_VCK5,
DIV6_FSIA, DIV6_FSIB,
DIV6_MP, DIV6_M4, DIV6_HSI, DIV6_SPUV,
DIV6_NR };
static struct clk *div6_parents[8] = {
[0] = &pll1_div2_clk,
[1] = &pll2s_clk,
[3] = &extal2_clk,
[4] = &main_div2_clk,
[6] = &extalr_clk,
};
static struct clk *fsia_parents[4] = {
[0] = &pll1_div2_clk,
[1] = &pll2s_clk,
[2] = &fsiack_clk,
};
static struct clk *fsib_parents[4] = {
[0] = &pll1_div2_clk,
[1] = &pll2s_clk,
[2] = &fsibck_clk,
};
static struct clk *mp_parents[4] = {
[0] = &pll1_div2_clk,
[1] = &pll2s_clk,
[2] = &extal2_clk,
[3] = &extal2_clk,
};
static struct clk *m4_parents[2] = {
[0] = &pll2s_clk,
};
static struct clk *hsi_parents[4] = {
[0] = &pll2h_clk,
[1] = &pll1_div2_clk,
[3] = &pll2s_clk,
};
/*** FIXME ***
* SH_CLK_DIV6_EXT() macro doesn't care .mapping
* but, it is necessary on R-Car (= ioremap() base CPG)
* The difference between
* SH_CLK_DIV6_EXT() <--> SH_CLK_MAP_DIV6_EXT()
* is only .mapping
*/
#define SH_CLK_MAP_DIV6_EXT(_reg, _flags, _parents, \
_num_parents, _src_shift, _src_width) \
{ \
.enable_reg = (void __iomem *)_reg, \
.enable_bit = 0, /* unused */ \
.flags = _flags | CLK_MASK_DIV_ON_DISABLE, \
.div_mask = SH_CLK_DIV6_MSK, \
.parent_table = _parents, \
.parent_num = _num_parents, \
.src_shift = _src_shift, \
.src_width = _src_width, \
.mapping = &cpg_mapping, \
}
static struct clk div6_clks[DIV6_NR] = {
[DIV6_ZB] = SH_CLK_MAP_DIV6_EXT(ZBCKCR, CLK_ENABLE_ON_INIT,
div6_parents, 2, 7, 1),
[DIV6_SDHI0] = SH_CLK_MAP_DIV6_EXT(SD0CKCR, 0,
div6_parents, 2, 6, 2),
[DIV6_SDHI1] = SH_CLK_MAP_DIV6_EXT(SD1CKCR, 0,
div6_parents, 2, 6, 2),
[DIV6_SDHI2] = SH_CLK_MAP_DIV6_EXT(SD2CKCR, 0,
div6_parents, 2, 6, 2),
[DIV6_MMC0] = SH_CLK_MAP_DIV6_EXT(MMC0CKCR, 0,
div6_parents, 2, 6, 2),
[DIV6_MMC1] = SH_CLK_MAP_DIV6_EXT(MMC1CKCR, 0,
div6_parents, 2, 6, 2),
[DIV6_VCK1] = SH_CLK_MAP_DIV6_EXT(VCLKCR1, 0, /* didn't care bit[6-7] */
div6_parents, ARRAY_SIZE(div6_parents), 12, 3),
[DIV6_VCK2] = SH_CLK_MAP_DIV6_EXT(VCLKCR2, 0, /* didn't care bit[6-7] */
div6_parents, ARRAY_SIZE(div6_parents), 12, 3),
[DIV6_VCK3] = SH_CLK_MAP_DIV6_EXT(VCLKCR3, 0, /* didn't care bit[6-7] */
div6_parents, ARRAY_SIZE(div6_parents), 12, 3),
[DIV6_VCK4] = SH_CLK_MAP_DIV6_EXT(VCLKCR4, 0, /* didn't care bit[6-7] */
div6_parents, ARRAY_SIZE(div6_parents), 12, 3),
[DIV6_VCK5] = SH_CLK_MAP_DIV6_EXT(VCLKCR5, 0, /* didn't care bit[6-7] */
div6_parents, ARRAY_SIZE(div6_parents), 12, 3),
[DIV6_FSIA] = SH_CLK_MAP_DIV6_EXT(FSIACKCR, 0,
fsia_parents, ARRAY_SIZE(fsia_parents), 6, 2),
[DIV6_FSIB] = SH_CLK_MAP_DIV6_EXT(FSIBCKCR, 0,
fsib_parents, ARRAY_SIZE(fsib_parents), 6, 2),
[DIV6_MP] = SH_CLK_MAP_DIV6_EXT(MPCKCR, 0, /* it needs bit[9-11] control */
mp_parents, ARRAY_SIZE(mp_parents), 6, 2),
/* pll2s will be selected always for M4 */
[DIV6_M4] = SH_CLK_MAP_DIV6_EXT(M4CKCR, 0, /* it needs bit[9] control */
m4_parents, ARRAY_SIZE(m4_parents), 6, 1),
[DIV6_HSI] = SH_CLK_MAP_DIV6_EXT(HSICKCR, 0, /* it needs bit[9] control */
hsi_parents, ARRAY_SIZE(hsi_parents), 6, 2),
[DIV6_SPUV] = SH_CLK_MAP_DIV6_EXT(SPUVCKCR, 0,
mp_parents, ARRAY_SIZE(mp_parents), 6, 2),
};
/* MSTP */
enum {
MSTP218, MSTP217, MSTP216, MSTP207, MSTP206, MSTP204, MSTP203,
MSTP329, MSTP323, MSTP318, MSTP317, MSTP316,
MSTP315, MSTP314, MSTP313, MSTP312, MSTP305, MSTP300,
MSTP411, MSTP410, MSTP409,
MSTP522, MSTP515,
MSTP_NR
};
static struct clk mstp_clks[MSTP_NR] = {
[MSTP204] = SH_CLK_MSTP32(&div6_clks[DIV6_MP], SMSTPCR2, 4, 0), /* SCIFA0 */
[MSTP203] = SH_CLK_MSTP32(&div6_clks[DIV6_MP], SMSTPCR2, 3, 0), /* SCIFA1 */
[MSTP206] = SH_CLK_MSTP32(&div6_clks[DIV6_MP], SMSTPCR2, 6, 0), /* SCIFB0 */
[MSTP207] = SH_CLK_MSTP32(&div6_clks[DIV6_MP], SMSTPCR2, 7, 0), /* SCIFB1 */
[MSTP216] = SH_CLK_MSTP32(&div6_clks[DIV6_MP], SMSTPCR2, 16, 0), /* SCIFB2 */
[MSTP217] = SH_CLK_MSTP32(&div6_clks[DIV6_MP], SMSTPCR2, 17, 0), /* SCIFB3 */
[MSTP218] = SH_CLK_MSTP32(&div4_clks[DIV4_HP], SMSTPCR2, 18, 0), /* DMAC */
[MSTP300] = SH_CLK_MSTP32(&div4_clks[DIV4_HP], SMSTPCR3, 0, 0), /* IIC2 */
[MSTP305] = SH_CLK_MSTP32(&div6_clks[DIV6_MMC1],SMSTPCR3, 5, 0), /* MMCIF1 */
[MSTP312] = SH_CLK_MSTP32(&div6_clks[DIV6_SDHI2],SMSTPCR3, 12, 0), /* SDHI2 */
[MSTP313] = SH_CLK_MSTP32(&div6_clks[DIV6_SDHI1],SMSTPCR3, 13, 0), /* SDHI1 */
[MSTP314] = SH_CLK_MSTP32(&div6_clks[DIV6_SDHI0],SMSTPCR3, 14, 0), /* SDHI0 */
[MSTP315] = SH_CLK_MSTP32(&div6_clks[DIV6_MMC0],SMSTPCR3, 15, 0), /* MMCIF0 */
[MSTP316] = SH_CLK_MSTP32(&div4_clks[DIV4_HP], SMSTPCR3, 16, 0), /* IIC6 */
[MSTP317] = SH_CLK_MSTP32(&div4_clks[DIV4_HP], SMSTPCR3, 17, 0), /* IIC7 */
[MSTP318] = SH_CLK_MSTP32(&div4_clks[DIV4_HP], SMSTPCR3, 18, 0), /* IIC0 */
[MSTP323] = SH_CLK_MSTP32(&div4_clks[DIV4_HP], SMSTPCR3, 23, 0), /* IIC1 */
[MSTP329] = SH_CLK_MSTP32(&extalr_clk, SMSTPCR3, 29, 0), /* CMT10 */
[MSTP409] = SH_CLK_MSTP32(&main_div2_clk, SMSTPCR4, 9, 0), /* IIC5 */
[MSTP410] = SH_CLK_MSTP32(&div4_clks[DIV4_HP], SMSTPCR4, 10, 0), /* IIC4 */
[MSTP411] = SH_CLK_MSTP32(&div4_clks[DIV4_HP], SMSTPCR4, 11, 0), /* IIC3 */
[MSTP522] = SH_CLK_MSTP32(&extal2_clk, SMSTPCR5, 22, 0), /* Thermal */
[MSTP515] = SH_CLK_MSTP32(&div4_clks[DIV4_HP], SMSTPCR5, 15, 0), /* IIC8 */
};
static struct clk_lookup lookups[] = {
/* main clock */
CLKDEV_CON_ID("extal1", &extal1_clk),
CLKDEV_CON_ID("extal1_div2", &extal1_div2_clk),
CLKDEV_CON_ID("extal2", &extal2_clk),
CLKDEV_CON_ID("extal2_div2", &extal2_div2_clk),
CLKDEV_CON_ID("extal2_div4", &extal2_div4_clk),
CLKDEV_CON_ID("fsiack", &fsiack_clk),
CLKDEV_CON_ID("fsibck", &fsibck_clk),
/* pll clock */
CLKDEV_CON_ID("pll1", &pll1_clk),
CLKDEV_CON_ID("pll1_div2", &pll1_div2_clk),
CLKDEV_CON_ID("pll2", &pll2_clk),
CLKDEV_CON_ID("pll2s", &pll2s_clk),
CLKDEV_CON_ID("pll2h", &pll2h_clk),
/* CPU clock */
CLKDEV_DEV_ID("cpu0", &z_clk),
/* DIV6 */
CLKDEV_CON_ID("zb", &div6_clks[DIV6_ZB]),
CLKDEV_CON_ID("vck1", &div6_clks[DIV6_VCK1]),
CLKDEV_CON_ID("vck2", &div6_clks[DIV6_VCK2]),
CLKDEV_CON_ID("vck3", &div6_clks[DIV6_VCK3]),
CLKDEV_CON_ID("vck4", &div6_clks[DIV6_VCK4]),
CLKDEV_CON_ID("vck5", &div6_clks[DIV6_VCK5]),
CLKDEV_CON_ID("fsia", &div6_clks[DIV6_FSIA]),
CLKDEV_CON_ID("fsib", &div6_clks[DIV6_FSIB]),
CLKDEV_CON_ID("mp", &div6_clks[DIV6_MP]),
CLKDEV_CON_ID("m4", &div6_clks[DIV6_M4]),
CLKDEV_CON_ID("hsi", &div6_clks[DIV6_HSI]),
CLKDEV_CON_ID("spuv", &div6_clks[DIV6_SPUV]),
/* MSTP */
CLKDEV_DEV_ID("sh-sci.0", &mstp_clks[MSTP204]),
CLKDEV_DEV_ID("e6c40000.serial", &mstp_clks[MSTP204]),
CLKDEV_DEV_ID("sh-sci.1", &mstp_clks[MSTP203]),
CLKDEV_DEV_ID("e6c50000.serial", &mstp_clks[MSTP203]),
CLKDEV_DEV_ID("sh-sci.2", &mstp_clks[MSTP206]),
CLKDEV_DEV_ID("e6c20000.serial", &mstp_clks[MSTP206]),
CLKDEV_DEV_ID("sh-sci.3", &mstp_clks[MSTP207]),
CLKDEV_DEV_ID("e6c30000.serial", &mstp_clks[MSTP207]),
CLKDEV_DEV_ID("sh-sci.4", &mstp_clks[MSTP216]),
CLKDEV_DEV_ID("e6ce0000.serial", &mstp_clks[MSTP216]),
CLKDEV_DEV_ID("sh-sci.5", &mstp_clks[MSTP217]),
CLKDEV_DEV_ID("e6cf0000.serial", &mstp_clks[MSTP217]),
CLKDEV_DEV_ID("sh-dma-engine.0", &mstp_clks[MSTP218]),
CLKDEV_DEV_ID("e6700020.dma-controller", &mstp_clks[MSTP218]),
CLKDEV_DEV_ID("rcar_thermal", &mstp_clks[MSTP522]),
CLKDEV_DEV_ID("e6520000.i2c", &mstp_clks[MSTP300]),
CLKDEV_DEV_ID("sh_mmcif.1", &mstp_clks[MSTP305]),
CLKDEV_DEV_ID("ee220000.mmc", &mstp_clks[MSTP305]),
CLKDEV_DEV_ID("sh_mobile_sdhi.2", &mstp_clks[MSTP312]),
CLKDEV_DEV_ID("ee140000.sd", &mstp_clks[MSTP312]),
CLKDEV_DEV_ID("sh_mobile_sdhi.1", &mstp_clks[MSTP313]),
CLKDEV_DEV_ID("ee120000.sd", &mstp_clks[MSTP313]),
CLKDEV_DEV_ID("sh_mobile_sdhi.0", &mstp_clks[MSTP314]),
CLKDEV_DEV_ID("ee100000.sd", &mstp_clks[MSTP314]),
CLKDEV_DEV_ID("sh_mmcif.0", &mstp_clks[MSTP315]),
CLKDEV_DEV_ID("ee200000.mmc", &mstp_clks[MSTP315]),
CLKDEV_DEV_ID("e6550000.i2c", &mstp_clks[MSTP316]),
CLKDEV_DEV_ID("e6560000.i2c", &mstp_clks[MSTP317]),
CLKDEV_DEV_ID("e6500000.i2c", &mstp_clks[MSTP318]),
CLKDEV_DEV_ID("e6510000.i2c", &mstp_clks[MSTP323]),
CLKDEV_ICK_ID("fck", "sh-cmt-48-gen2.1", &mstp_clks[MSTP329]),
CLKDEV_DEV_ID("e60b0000.i2c", &mstp_clks[MSTP409]),
CLKDEV_DEV_ID("e6540000.i2c", &mstp_clks[MSTP410]),
CLKDEV_DEV_ID("e6530000.i2c", &mstp_clks[MSTP411]),
CLKDEV_DEV_ID("e6570000.i2c", &mstp_clks[MSTP515]),
/* for DT */
CLKDEV_DEV_ID("e61f0000.thermal", &mstp_clks[MSTP522]),
};
void __init r8a73a4_clock_init(void)
{
void __iomem *reg;
int k, ret = 0;
u32 ckscr;
atomic_set(&frqcr_lock, -1);
reg = ioremap_nocache(CKSCR, PAGE_SIZE);
BUG_ON(!reg);
ckscr = ioread32(reg);
iounmap(reg);
switch ((ckscr >> 28) & 0x3) {
case 0:
main_clk.parent = &extal1_clk;
break;
case 1:
main_clk.parent = &extal1_div2_clk;
break;
case 2:
main_clk.parent = &extal2_clk;
break;
case 3:
main_clk.parent = &extal2_div2_clk;
break;
}
for (k = 0; !ret && (k < ARRAY_SIZE(main_clks)); k++)
ret = clk_register(main_clks[k]);
if (!ret)
ret = sh_clk_div4_register(div4_clks, DIV4_NR, &div4_table);
if (!ret)
ret = sh_clk_div6_reparent_register(div6_clks, DIV6_NR);
if (!ret)
ret = sh_clk_mstp_register(mstp_clks, MSTP_NR);
clkdev_add_table(lookups, ARRAY_SIZE(lookups));
if (!ret)
shmobile_clk_init();
else
panic("failed to setup r8a73a4 clocks\n");
}