acpiphp: Execute ACPI _REG method for hotadded devices
[linux/fpc-iii.git] / arch / arm / mach-sa1100 / cpu-sa1100.c
blobef817876a5d68d6597d42cefd2135c0e8769bbe2
1 /*
2 * cpu-sa1100.c: clock scaling for the SA1100
4 * Copyright (C) 2000 2001, The Delft University of Technology
6 * Authors:
7 * - Johan Pouwelse (J.A.Pouwelse@its.tudelft.nl): initial version
8 * - Erik Mouw (J.A.K.Mouw@its.tudelft.nl):
9 * - major rewrite for linux-2.3.99
10 * - rewritten for the more generic power management scheme in
11 * linux-2.4.5-rmk1
13 * This software has been developed while working on the LART
14 * computing board (http://www.lartmaker.nl/), which is
15 * sponsored by the Mobile Multi-media Communications
16 * (http://www.mmc.tudelft.nl/) and Ubiquitous Communications
17 * (http://www.ubicom.tudelft.nl/) projects.
19 * The authors can be reached at:
21 * Erik Mouw
22 * Information and Communication Theory Group
23 * Faculty of Information Technology and Systems
24 * Delft University of Technology
25 * P.O. Box 5031
26 * 2600 GA Delft
27 * The Netherlands
30 * This program is free software; you can redistribute it and/or modify
31 * it under the terms of the GNU General Public License as published by
32 * the Free Software Foundation; either version 2 of the License, or
33 * (at your option) any later version.
35 * This program is distributed in the hope that it will be useful,
36 * but WITHOUT ANY WARRANTY; without even the implied warranty of
37 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
38 * GNU General Public License for more details.
40 * You should have received a copy of the GNU General Public License
41 * along with this program; if not, write to the Free Software
42 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
45 * Theory of operations
46 * ====================
48 * Clock scaling can be used to lower the power consumption of the CPU
49 * core. This will give you a somewhat longer running time.
51 * The SA-1100 has a single register to change the core clock speed:
53 * PPCR 0x90020014 PLL config
55 * However, the DRAM timings are closely related to the core clock
56 * speed, so we need to change these, too. The used registers are:
58 * MDCNFG 0xA0000000 DRAM config
59 * MDCAS0 0xA0000004 Access waveform
60 * MDCAS1 0xA0000008 Access waveform
61 * MDCAS2 0xA000000C Access waveform
63 * Care must be taken to change the DRAM parameters the correct way,
64 * because otherwise the DRAM becomes unusable and the kernel will
65 * crash.
67 * The simple solution to avoid a kernel crash is to put the actual
68 * clock change in ROM and jump to that code from the kernel. The main
69 * disadvantage is that the ROM has to be modified, which is not
70 * possible on all SA-1100 platforms. Another disadvantage is that
71 * jumping to ROM makes clock switching unecessary complicated.
73 * The idea behind this driver is that the memory configuration can be
74 * changed while running from DRAM (even with interrupts turned on!)
75 * as long as all re-configuration steps yield a valid DRAM
76 * configuration. The advantages are clear: it will run on all SA-1100
77 * platforms, and the code is very simple.
79 * If you really want to understand what is going on in
80 * sa1100_update_dram_timings(), you'll have to read sections 8.2,
81 * 9.5.7.3, and 10.2 from the "Intel StrongARM SA-1100 Microprocessor
82 * Developers Manual" (available for free from Intel).
86 #include <linux/kernel.h>
87 #include <linux/types.h>
88 #include <linux/init.h>
89 #include <linux/cpufreq.h>
91 #include <asm/cputype.h>
93 #include <mach/hardware.h>
95 #include "generic.h"
97 typedef struct {
98 int speed;
99 u32 mdcnfg;
100 u32 mdcas0;
101 u32 mdcas1;
102 u32 mdcas2;
103 } sa1100_dram_regs_t;
106 static struct cpufreq_driver sa1100_driver;
108 static sa1100_dram_regs_t sa1100_dram_settings[] =
110 /* speed, mdcnfg, mdcas0, mdcas1, mdcas2 clock frequency */
111 { 59000, 0x00dc88a3, 0xcccccccf, 0xfffffffc, 0xffffffff }, /* 59.0 MHz */
112 { 73700, 0x011490a3, 0xcccccccf, 0xfffffffc, 0xffffffff }, /* 73.7 MHz */
113 { 88500, 0x014e90a3, 0xcccccccf, 0xfffffffc, 0xffffffff }, /* 88.5 MHz */
114 { 103200, 0x01889923, 0xcccccccf, 0xfffffffc, 0xffffffff }, /* 103.2 MHz */
115 { 118000, 0x01c29923, 0x9999998f, 0xfffffff9, 0xffffffff }, /* 118.0 MHz */
116 { 132700, 0x01fb2123, 0x9999998f, 0xfffffff9, 0xffffffff }, /* 132.7 MHz */
117 { 147500, 0x02352123, 0x3333330f, 0xfffffff3, 0xffffffff }, /* 147.5 MHz */
118 { 162200, 0x026b29a3, 0x38e38e1f, 0xfff8e38e, 0xffffffff }, /* 162.2 MHz */
119 { 176900, 0x02a329a3, 0x71c71c1f, 0xfff1c71c, 0xffffffff }, /* 176.9 MHz */
120 { 191700, 0x02dd31a3, 0xe38e383f, 0xffe38e38, 0xffffffff }, /* 191.7 MHz */
121 { 206400, 0x03153223, 0xc71c703f, 0xffc71c71, 0xffffffff }, /* 206.4 MHz */
122 { 221200, 0x034fba23, 0xc71c703f, 0xffc71c71, 0xffffffff }, /* 221.2 MHz */
123 { 235900, 0x03853a23, 0xe1e1e07f, 0xe1e1e1e1, 0xffffffe1 }, /* 235.9 MHz */
124 { 250700, 0x03bf3aa3, 0xc3c3c07f, 0xc3c3c3c3, 0xffffffc3 }, /* 250.7 MHz */
125 { 265400, 0x03f7c2a3, 0xc3c3c07f, 0xc3c3c3c3, 0xffffffc3 }, /* 265.4 MHz */
126 { 280200, 0x0431c2a3, 0x878780ff, 0x87878787, 0xffffff87 }, /* 280.2 MHz */
127 { 0, 0, 0, 0, 0 } /* last entry */
130 static void sa1100_update_dram_timings(int current_speed, int new_speed)
132 sa1100_dram_regs_t *settings = sa1100_dram_settings;
134 /* find speed */
135 while (settings->speed != 0) {
136 if(new_speed == settings->speed)
137 break;
139 settings++;
142 if (settings->speed == 0) {
143 panic("%s: couldn't find dram setting for speed %d\n",
144 __func__, new_speed);
147 /* No risk, no fun: run with interrupts on! */
148 if (new_speed > current_speed) {
149 /* We're going FASTER, so first relax the memory
150 * timings before changing the core frequency
153 /* Half the memory access clock */
154 MDCNFG |= MDCNFG_CDB2;
156 /* The order of these statements IS important, keep 8
157 * pulses!!
159 MDCAS2 = settings->mdcas2;
160 MDCAS1 = settings->mdcas1;
161 MDCAS0 = settings->mdcas0;
162 MDCNFG = settings->mdcnfg;
163 } else {
164 /* We're going SLOWER: first decrease the core
165 * frequency and then tighten the memory settings.
168 /* Half the memory access clock */
169 MDCNFG |= MDCNFG_CDB2;
171 /* The order of these statements IS important, keep 8
172 * pulses!!
174 MDCAS0 = settings->mdcas0;
175 MDCAS1 = settings->mdcas1;
176 MDCAS2 = settings->mdcas2;
177 MDCNFG = settings->mdcnfg;
181 static int sa1100_target(struct cpufreq_policy *policy,
182 unsigned int target_freq,
183 unsigned int relation)
185 unsigned int cur = sa11x0_getspeed(0);
186 unsigned int new_ppcr;
188 struct cpufreq_freqs freqs;
189 switch(relation){
190 case CPUFREQ_RELATION_L:
191 new_ppcr = sa11x0_freq_to_ppcr(target_freq);
192 if (sa11x0_ppcr_to_freq(new_ppcr) > policy->max)
193 new_ppcr--;
194 break;
195 case CPUFREQ_RELATION_H:
196 new_ppcr = sa11x0_freq_to_ppcr(target_freq);
197 if ((sa11x0_ppcr_to_freq(new_ppcr) > target_freq) &&
198 (sa11x0_ppcr_to_freq(new_ppcr - 1) >= policy->min))
199 new_ppcr--;
200 break;
203 freqs.old = cur;
204 freqs.new = sa11x0_ppcr_to_freq(new_ppcr);
205 freqs.cpu = 0;
207 cpufreq_notify_transition(&freqs, CPUFREQ_PRECHANGE);
209 if (freqs.new > cur)
210 sa1100_update_dram_timings(cur, freqs.new);
212 PPCR = new_ppcr;
214 if (freqs.new < cur)
215 sa1100_update_dram_timings(cur, freqs.new);
217 cpufreq_notify_transition(&freqs, CPUFREQ_POSTCHANGE);
219 return 0;
222 static int __init sa1100_cpu_init(struct cpufreq_policy *policy)
224 if (policy->cpu != 0)
225 return -EINVAL;
226 policy->cur = policy->min = policy->max = sa11x0_getspeed(0);
227 policy->cpuinfo.min_freq = 59000;
228 policy->cpuinfo.max_freq = 287000;
229 policy->cpuinfo.transition_latency = CPUFREQ_ETERNAL;
230 return 0;
233 static struct cpufreq_driver sa1100_driver = {
234 .flags = CPUFREQ_STICKY,
235 .verify = sa11x0_verify_speed,
236 .target = sa1100_target,
237 .get = sa11x0_getspeed,
238 .init = sa1100_cpu_init,
239 .name = "sa1100",
242 static int __init sa1100_dram_init(void)
244 if (cpu_is_sa1100())
245 return cpufreq_register_driver(&sa1100_driver);
246 else
247 return -ENODEV;
250 arch_initcall(sa1100_dram_init);