Merge remote-tracking branch 'moduleh/module.h-split'
[linux-2.6/next.git] / arch / arm / mach-s3c2443 / clock.c
bloba1a7176675b9904210545133303542e25d4636b6
1 /* linux/arch/arm/mach-s3c2443/clock.c
3 * Copyright (c) 2007, 2010 Simtec Electronics
4 * Ben Dooks <ben@simtec.co.uk>
6 * S3C2443 Clock control support
8 * This program is free software; you can redistribute it and/or modify
9 * it under the terms of the GNU General Public License as published by
10 * the Free Software Foundation; either version 2 of the License, or
11 * (at your option) any later version.
13 * This program is distributed in the hope that it will be useful,
14 * but WITHOUT ANY WARRANTY; without even the implied warranty of
15 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 * GNU General Public License for more details.
18 * You should have received a copy of the GNU General Public License
19 * along with this program; if not, write to the Free Software
20 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
23 #include <linux/init.h>
25 #include <linux/module.h>
26 #include <linux/kernel.h>
27 #include <linux/list.h>
28 #include <linux/errno.h>
29 #include <linux/err.h>
30 #include <linux/sysdev.h>
31 #include <linux/clk.h>
32 #include <linux/mutex.h>
33 #include <linux/serial_core.h>
34 #include <linux/io.h>
36 #include <asm/mach/map.h>
38 #include <mach/hardware.h>
40 #include <mach/regs-s3c2443-clock.h>
42 #include <plat/cpu-freq.h>
44 #include <plat/s3c2443.h>
45 #include <plat/clock.h>
46 #include <plat/clock-clksrc.h>
47 #include <plat/cpu.h>
49 /* We currently have to assume that the system is running
50 * from the XTPll input, and that all ***REFCLKs are being
51 * fed from it, as we cannot read the state of OM[4] from
52 * software.
54 * It would be possible for each board initialisation to
55 * set the correct muxing at initialisation
58 /* clock selections */
60 static struct clk clk_i2s_ext = {
61 .name = "i2s-ext",
64 /* armdiv
66 * this clock is sourced from msysclk and can have a number of
67 * divider values applied to it to then be fed into armclk.
70 /* armdiv divisor table */
72 static unsigned int armdiv[16] = {
73 [S3C2443_CLKDIV0_ARMDIV_1 >> S3C2443_CLKDIV0_ARMDIV_SHIFT] = 1,
74 [S3C2443_CLKDIV0_ARMDIV_2 >> S3C2443_CLKDIV0_ARMDIV_SHIFT] = 2,
75 [S3C2443_CLKDIV0_ARMDIV_3 >> S3C2443_CLKDIV0_ARMDIV_SHIFT] = 3,
76 [S3C2443_CLKDIV0_ARMDIV_4 >> S3C2443_CLKDIV0_ARMDIV_SHIFT] = 4,
77 [S3C2443_CLKDIV0_ARMDIV_6 >> S3C2443_CLKDIV0_ARMDIV_SHIFT] = 6,
78 [S3C2443_CLKDIV0_ARMDIV_8 >> S3C2443_CLKDIV0_ARMDIV_SHIFT] = 8,
79 [S3C2443_CLKDIV0_ARMDIV_12 >> S3C2443_CLKDIV0_ARMDIV_SHIFT] = 12,
80 [S3C2443_CLKDIV0_ARMDIV_16 >> S3C2443_CLKDIV0_ARMDIV_SHIFT] = 16,
83 static inline unsigned int s3c2443_fclk_div(unsigned long clkcon0)
85 clkcon0 &= S3C2443_CLKDIV0_ARMDIV_MASK;
87 return armdiv[clkcon0 >> S3C2443_CLKDIV0_ARMDIV_SHIFT];
90 static unsigned long s3c2443_armclk_roundrate(struct clk *clk,
91 unsigned long rate)
93 unsigned long parent = clk_get_rate(clk->parent);
94 unsigned long calc;
95 unsigned best = 256; /* bigger than any value */
96 unsigned div;
97 int ptr;
99 for (ptr = 0; ptr < ARRAY_SIZE(armdiv); ptr++) {
100 div = armdiv[ptr];
101 calc = parent / div;
102 if (calc <= rate && div < best)
103 best = div;
106 return parent / best;
109 static int s3c2443_armclk_setrate(struct clk *clk, unsigned long rate)
111 unsigned long parent = clk_get_rate(clk->parent);
112 unsigned long calc;
113 unsigned div;
114 unsigned best = 256; /* bigger than any value */
115 int ptr;
116 int val = -1;
118 for (ptr = 0; ptr < ARRAY_SIZE(armdiv); ptr++) {
119 div = armdiv[ptr];
120 calc = parent / div;
121 if (calc <= rate && div < best) {
122 best = div;
123 val = ptr;
127 if (val >= 0) {
128 unsigned long clkcon0;
130 clkcon0 = __raw_readl(S3C2443_CLKDIV0);
131 clkcon0 &= S3C2443_CLKDIV0_ARMDIV_MASK;
132 clkcon0 |= val << S3C2443_CLKDIV0_ARMDIV_SHIFT;
133 __raw_writel(clkcon0, S3C2443_CLKDIV0);
136 return (val == -1) ? -EINVAL : 0;
139 static struct clk clk_armdiv = {
140 .name = "armdiv",
141 .parent = &clk_msysclk.clk,
142 .ops = &(struct clk_ops) {
143 .round_rate = s3c2443_armclk_roundrate,
144 .set_rate = s3c2443_armclk_setrate,
148 /* armclk
150 * this is the clock fed into the ARM core itself, from armdiv or from hclk.
153 static struct clk *clk_arm_sources[] = {
154 [0] = &clk_armdiv,
155 [1] = &clk_h,
158 static struct clksrc_clk clk_arm = {
159 .clk = {
160 .name = "armclk",
162 .sources = &(struct clksrc_sources) {
163 .sources = clk_arm_sources,
164 .nr_sources = ARRAY_SIZE(clk_arm_sources),
166 .reg_src = { .reg = S3C2443_CLKDIV0, .size = 1, .shift = 13 },
169 /* hsspi
171 * high-speed spi clock, sourced from esysclk
174 static struct clksrc_clk clk_hsspi = {
175 .clk = {
176 .name = "hsspi",
177 .parent = &clk_esysclk.clk,
178 .ctrlbit = S3C2443_SCLKCON_HSSPICLK,
179 .enable = s3c2443_clkcon_enable_s,
181 .reg_div = { .reg = S3C2443_CLKDIV1, .size = 2, .shift = 4 },
185 /* clk_hsmcc_div
187 * this clock is sourced from epll, and is fed through a divider,
188 * to a mux controlled by sclkcon where either it or a extclk can
189 * be fed to the hsmmc block
192 static struct clksrc_clk clk_hsmmc_div = {
193 .clk = {
194 .name = "hsmmc-div",
195 .devname = "s3c-sdhci.1",
196 .parent = &clk_esysclk.clk,
198 .reg_div = { .reg = S3C2443_CLKDIV1, .size = 2, .shift = 6 },
201 static int s3c2443_setparent_hsmmc(struct clk *clk, struct clk *parent)
203 unsigned long clksrc = __raw_readl(S3C2443_SCLKCON);
205 clksrc &= ~(S3C2443_SCLKCON_HSMMCCLK_EXT |
206 S3C2443_SCLKCON_HSMMCCLK_EPLL);
208 if (parent == &clk_epll)
209 clksrc |= S3C2443_SCLKCON_HSMMCCLK_EPLL;
210 else if (parent == &clk_ext)
211 clksrc |= S3C2443_SCLKCON_HSMMCCLK_EXT;
212 else
213 return -EINVAL;
215 if (clk->usage > 0) {
216 __raw_writel(clksrc, S3C2443_SCLKCON);
219 clk->parent = parent;
220 return 0;
223 static int s3c2443_enable_hsmmc(struct clk *clk, int enable)
225 return s3c2443_setparent_hsmmc(clk, clk->parent);
228 static struct clk clk_hsmmc = {
229 .name = "hsmmc-if",
230 .devname = "s3c-sdhci.1",
231 .parent = &clk_hsmmc_div.clk,
232 .enable = s3c2443_enable_hsmmc,
233 .ops = &(struct clk_ops) {
234 .set_parent = s3c2443_setparent_hsmmc,
238 /* i2s_eplldiv
240 * This clock is the output from the I2S divisor of ESYSCLK, and is separate
241 * from the mux that comes after it (cannot merge into one single clock)
244 static struct clksrc_clk clk_i2s_eplldiv = {
245 .clk = {
246 .name = "i2s-eplldiv",
247 .parent = &clk_esysclk.clk,
249 .reg_div = { .reg = S3C2443_CLKDIV1, .size = 4, .shift = 12, },
252 /* i2s-ref
254 * i2s bus reference clock, selectable from external, esysclk or epllref
256 * Note, this used to be two clocks, but was compressed into one.
259 struct clk *clk_i2s_srclist[] = {
260 [0] = &clk_i2s_eplldiv.clk,
261 [1] = &clk_i2s_ext,
262 [2] = &clk_epllref.clk,
263 [3] = &clk_epllref.clk,
266 static struct clksrc_clk clk_i2s = {
267 .clk = {
268 .name = "i2s-if",
269 .ctrlbit = S3C2443_SCLKCON_I2SCLK,
270 .enable = s3c2443_clkcon_enable_s,
273 .sources = &(struct clksrc_sources) {
274 .sources = clk_i2s_srclist,
275 .nr_sources = ARRAY_SIZE(clk_i2s_srclist),
277 .reg_src = { .reg = S3C2443_CLKSRC, .size = 2, .shift = 14 },
280 /* standard clock definitions */
282 static struct clk init_clocks_off[] = {
284 .name = "sdi",
285 .parent = &clk_p,
286 .enable = s3c2443_clkcon_enable_p,
287 .ctrlbit = S3C2443_PCLKCON_SDI,
288 }, {
289 .name = "iis",
290 .parent = &clk_p,
291 .enable = s3c2443_clkcon_enable_p,
292 .ctrlbit = S3C2443_PCLKCON_IIS,
293 }, {
294 .name = "spi",
295 .devname = "s3c2410-spi.0",
296 .parent = &clk_p,
297 .enable = s3c2443_clkcon_enable_p,
298 .ctrlbit = S3C2443_PCLKCON_SPI0,
299 }, {
300 .name = "spi",
301 .devname = "s3c2410-spi.1",
302 .parent = &clk_p,
303 .enable = s3c2443_clkcon_enable_p,
304 .ctrlbit = S3C2443_PCLKCON_SPI1,
308 static struct clk init_clocks[] = {
311 /* clocks to add straight away */
313 static struct clksrc_clk *clksrcs[] __initdata = {
314 &clk_arm,
315 &clk_i2s_eplldiv,
316 &clk_i2s,
317 &clk_hsspi,
318 &clk_hsmmc_div,
321 static struct clk *clks[] __initdata = {
322 &clk_hsmmc,
323 &clk_armdiv,
326 void __init_or_cpufreq s3c2443_setup_clocks(void)
328 s3c2443_common_setup_clocks(s3c2443_get_mpll, s3c2443_fclk_div);
331 void __init s3c2443_init_clocks(int xtal)
333 unsigned long epllcon = __raw_readl(S3C2443_EPLLCON);
334 int ptr;
336 clk_epll.rate = s3c2443_get_epll(epllcon, xtal);
337 clk_epll.parent = &clk_epllref.clk;
339 s3c2443_common_init_clocks(xtal, s3c2443_get_mpll, s3c2443_fclk_div);
341 s3c2443_setup_clocks();
343 s3c24xx_register_clocks(clks, ARRAY_SIZE(clks));
345 for (ptr = 0; ptr < ARRAY_SIZE(clksrcs); ptr++)
346 s3c_register_clksrc(clksrcs[ptr], 1);
348 /* register clocks from clock array */
350 s3c_register_clocks(init_clocks, ARRAY_SIZE(init_clocks));
352 /* We must be careful disabling the clocks we are not intending to
353 * be using at boot time, as subsystems such as the LCD which do
354 * their own DMA requests to the bus can cause the system to lockup
355 * if they where in the middle of requesting bus access.
357 * Disabling the LCD clock if the LCD is active is very dangerous,
358 * and therefore the bootloader should be careful to not enable
359 * the LCD clock if it is not needed.
362 /* install (and disable) the clocks we do not need immediately */
364 s3c_register_clocks(init_clocks_off, ARRAY_SIZE(init_clocks_off));
365 s3c_disable_clocks(init_clocks_off, ARRAY_SIZE(init_clocks_off));
367 s3c_pwmclk_init();