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https://github.com/AuxXxilium/linux_dsm_epyc7002.git
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fe829ed8ef
The policy->transition_latency field is used for multiple purposes today and its not straight forward at all. This is how it is used: A. Set the correct transition_latency value. B. Set it to CPUFREQ_ETERNAL because: 1. We don't want automatic dynamic switching (with ondemand/conservative) to happen at all. 2. We don't know the transition latency. This patch handles the B.1. case in a more readable way. A new flag for the cpufreq drivers is added to disallow use of cpufreq governors which have dynamic_switching flag set. All the current cpufreq drivers which are setting transition_latency unconditionally to CPUFREQ_ETERNAL are updated to use it. They don't need to set transition_latency anymore. There shouldn't be any functional change after this patch. Signed-off-by: Viresh Kumar <viresh.kumar@linaro.org> Reviewed-by: Dominik Brodowski <linux@dominikbrodowski.net> Signed-off-by: Rafael J. Wysocki <rafael.j.wysocki@intel.com>
376 lines
9.0 KiB
C
376 lines
9.0 KiB
C
/*
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* linux/arch/arm/mach-sa1100/cpu-sa1110.c
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*
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* Copyright (C) 2001 Russell King
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License version 2 as
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* published by the Free Software Foundation.
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*
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* Note: there are two erratas that apply to the SA1110 here:
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* 7 - SDRAM auto-power-up failure (rev A0)
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* 13 - Corruption of internal register reads/writes following
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* SDRAM reads (rev A0, B0, B1)
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*
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* We ignore rev. A0 and B0 devices; I don't think they're worth supporting.
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*
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* The SDRAM type can be passed on the command line as cpu_sa1110.sdram=type
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*/
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#include <linux/cpufreq.h>
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#include <linux/delay.h>
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#include <linux/init.h>
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#include <linux/io.h>
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#include <linux/kernel.h>
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#include <linux/moduleparam.h>
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#include <linux/types.h>
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#include <asm/cputype.h>
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#include <asm/mach-types.h>
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#include <mach/generic.h>
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#include <mach/hardware.h>
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#undef DEBUG
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struct sdram_params {
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const char name[20];
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u_char rows; /* bits */
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u_char cas_latency; /* cycles */
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u_char tck; /* clock cycle time (ns) */
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u_char trcd; /* activate to r/w (ns) */
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u_char trp; /* precharge to activate (ns) */
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u_char twr; /* write recovery time (ns) */
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u_short refresh; /* refresh time for array (us) */
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};
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struct sdram_info {
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u_int mdcnfg;
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u_int mdrefr;
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u_int mdcas[3];
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};
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static struct sdram_params sdram_tbl[] __initdata = {
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{ /* Toshiba TC59SM716 CL2 */
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.name = "TC59SM716-CL2",
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.rows = 12,
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.tck = 10,
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.trcd = 20,
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.trp = 20,
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.twr = 10,
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.refresh = 64000,
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.cas_latency = 2,
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}, { /* Toshiba TC59SM716 CL3 */
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.name = "TC59SM716-CL3",
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.rows = 12,
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.tck = 8,
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.trcd = 20,
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.trp = 20,
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.twr = 8,
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.refresh = 64000,
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.cas_latency = 3,
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}, { /* Samsung K4S641632D TC75 */
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.name = "K4S641632D",
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.rows = 14,
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.tck = 9,
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.trcd = 27,
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.trp = 20,
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.twr = 9,
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.refresh = 64000,
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.cas_latency = 3,
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}, { /* Samsung K4S281632B-1H */
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.name = "K4S281632B-1H",
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.rows = 12,
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.tck = 10,
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.trp = 20,
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.twr = 10,
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.refresh = 64000,
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.cas_latency = 3,
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}, { /* Samsung KM416S4030CT */
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.name = "KM416S4030CT",
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.rows = 13,
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.tck = 8,
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.trcd = 24, /* 3 CLKs */
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.trp = 24, /* 3 CLKs */
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.twr = 16, /* Trdl: 2 CLKs */
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.refresh = 64000,
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.cas_latency = 3,
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}, { /* Winbond W982516AH75L CL3 */
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.name = "W982516AH75L",
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.rows = 16,
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.tck = 8,
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.trcd = 20,
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.trp = 20,
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.twr = 8,
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.refresh = 64000,
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.cas_latency = 3,
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}, { /* Micron MT48LC8M16A2TG-75 */
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.name = "MT48LC8M16A2TG-75",
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.rows = 12,
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.tck = 8,
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.trcd = 20,
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.trp = 20,
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.twr = 8,
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.refresh = 64000,
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.cas_latency = 3,
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},
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};
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static struct sdram_params sdram_params;
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/*
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* Given a period in ns and frequency in khz, calculate the number of
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* cycles of frequency in period. Note that we round up to the next
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* cycle, even if we are only slightly over.
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*/
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static inline u_int ns_to_cycles(u_int ns, u_int khz)
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{
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return (ns * khz + 999999) / 1000000;
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}
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/*
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* Create the MDCAS register bit pattern.
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*/
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static inline void set_mdcas(u_int *mdcas, int delayed, u_int rcd)
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{
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u_int shift;
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rcd = 2 * rcd - 1;
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shift = delayed + 1 + rcd;
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mdcas[0] = (1 << rcd) - 1;
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mdcas[0] |= 0x55555555 << shift;
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mdcas[1] = mdcas[2] = 0x55555555 << (shift & 1);
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}
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static void
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sdram_calculate_timing(struct sdram_info *sd, u_int cpu_khz,
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struct sdram_params *sdram)
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{
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u_int mem_khz, sd_khz, trp, twr;
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mem_khz = cpu_khz / 2;
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sd_khz = mem_khz;
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/*
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* If SDCLK would invalidate the SDRAM timings,
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* run SDCLK at half speed.
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*
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* CPU steppings prior to B2 must either run the memory at
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* half speed or use delayed read latching (errata 13).
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*/
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if ((ns_to_cycles(sdram->tck, sd_khz) > 1) ||
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(read_cpuid_revision() < ARM_CPU_REV_SA1110_B2 && sd_khz < 62000))
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sd_khz /= 2;
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sd->mdcnfg = MDCNFG & 0x007f007f;
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twr = ns_to_cycles(sdram->twr, mem_khz);
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/* trp should always be >1 */
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trp = ns_to_cycles(sdram->trp, mem_khz) - 1;
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if (trp < 1)
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trp = 1;
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sd->mdcnfg |= trp << 8;
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sd->mdcnfg |= trp << 24;
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sd->mdcnfg |= sdram->cas_latency << 12;
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sd->mdcnfg |= sdram->cas_latency << 28;
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sd->mdcnfg |= twr << 14;
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sd->mdcnfg |= twr << 30;
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sd->mdrefr = MDREFR & 0xffbffff0;
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sd->mdrefr |= 7;
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if (sd_khz != mem_khz)
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sd->mdrefr |= MDREFR_K1DB2;
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/* initial number of '1's in MDCAS + 1 */
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set_mdcas(sd->mdcas, sd_khz >= 62000,
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ns_to_cycles(sdram->trcd, mem_khz));
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#ifdef DEBUG
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printk(KERN_DEBUG "MDCNFG: %08x MDREFR: %08x MDCAS0: %08x MDCAS1: %08x MDCAS2: %08x\n",
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sd->mdcnfg, sd->mdrefr, sd->mdcas[0], sd->mdcas[1],
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sd->mdcas[2]);
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#endif
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}
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/*
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* Set the SDRAM refresh rate.
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*/
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static inline void sdram_set_refresh(u_int dri)
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{
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MDREFR = (MDREFR & 0xffff000f) | (dri << 4);
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(void) MDREFR;
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}
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/*
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* Update the refresh period. We do this such that we always refresh
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* the SDRAMs within their permissible period. The refresh period is
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* always a multiple of the memory clock (fixed at cpu_clock / 2).
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*
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* FIXME: we don't currently take account of burst accesses here,
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* but neither do Intels DM nor Angel.
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*/
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static void
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sdram_update_refresh(u_int cpu_khz, struct sdram_params *sdram)
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{
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u_int ns_row = (sdram->refresh * 1000) >> sdram->rows;
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u_int dri = ns_to_cycles(ns_row, cpu_khz / 2) / 32;
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#ifdef DEBUG
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mdelay(250);
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printk(KERN_DEBUG "new dri value = %d\n", dri);
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#endif
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sdram_set_refresh(dri);
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}
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/*
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* Ok, set the CPU frequency.
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*/
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static int sa1110_target(struct cpufreq_policy *policy, unsigned int ppcr)
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{
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struct sdram_params *sdram = &sdram_params;
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struct sdram_info sd;
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unsigned long flags;
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unsigned int unused;
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sdram_calculate_timing(&sd, sa11x0_freq_table[ppcr].frequency, sdram);
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#if 0
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/*
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* These values are wrong according to the SA1110 documentation
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* and errata, but they seem to work. Need to get a storage
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* scope on to the SDRAM signals to work out why.
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*/
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if (policy->max < 147500) {
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sd.mdrefr |= MDREFR_K1DB2;
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sd.mdcas[0] = 0xaaaaaa7f;
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} else {
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sd.mdrefr &= ~MDREFR_K1DB2;
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sd.mdcas[0] = 0xaaaaaa9f;
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}
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sd.mdcas[1] = 0xaaaaaaaa;
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sd.mdcas[2] = 0xaaaaaaaa;
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#endif
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/*
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* The clock could be going away for some time. Set the SDRAMs
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* to refresh rapidly (every 64 memory clock cycles). To get
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* through the whole array, we need to wait 262144 mclk cycles.
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* We wait 20ms to be safe.
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*/
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sdram_set_refresh(2);
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if (!irqs_disabled())
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msleep(20);
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else
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mdelay(20);
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/*
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* Reprogram the DRAM timings with interrupts disabled, and
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* ensure that we are doing this within a complete cache line.
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* This means that we won't access SDRAM for the duration of
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* the programming.
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*/
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local_irq_save(flags);
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asm("mcr p15, 0, %0, c7, c10, 4" : : "r" (0));
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udelay(10);
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__asm__ __volatile__("\n\
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b 2f \n\
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.align 5 \n\
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1: str %3, [%1, #0] @ MDCNFG \n\
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str %4, [%1, #28] @ MDREFR \n\
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str %5, [%1, #4] @ MDCAS0 \n\
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str %6, [%1, #8] @ MDCAS1 \n\
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str %7, [%1, #12] @ MDCAS2 \n\
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str %8, [%2, #0] @ PPCR \n\
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ldr %0, [%1, #0] \n\
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b 3f \n\
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2: b 1b \n\
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3: nop \n\
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nop"
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: "=&r" (unused)
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: "r" (&MDCNFG), "r" (&PPCR), "0" (sd.mdcnfg),
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"r" (sd.mdrefr), "r" (sd.mdcas[0]),
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"r" (sd.mdcas[1]), "r" (sd.mdcas[2]), "r" (ppcr));
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local_irq_restore(flags);
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/*
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* Now, return the SDRAM refresh back to normal.
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*/
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sdram_update_refresh(sa11x0_freq_table[ppcr].frequency, sdram);
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return 0;
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}
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static int __init sa1110_cpu_init(struct cpufreq_policy *policy)
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{
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return cpufreq_generic_init(policy, sa11x0_freq_table, 0);
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}
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/* sa1110_driver needs __refdata because it must remain after init registers
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* it with cpufreq_register_driver() */
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static struct cpufreq_driver sa1110_driver __refdata = {
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.flags = CPUFREQ_STICKY | CPUFREQ_NEED_INITIAL_FREQ_CHECK |
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CPUFREQ_NO_AUTO_DYNAMIC_SWITCHING,
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.verify = cpufreq_generic_frequency_table_verify,
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.target_index = sa1110_target,
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.get = sa11x0_getspeed,
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.init = sa1110_cpu_init,
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.name = "sa1110",
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};
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static struct sdram_params *sa1110_find_sdram(const char *name)
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{
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struct sdram_params *sdram;
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for (sdram = sdram_tbl; sdram < sdram_tbl + ARRAY_SIZE(sdram_tbl);
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sdram++)
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if (strcmp(name, sdram->name) == 0)
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return sdram;
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return NULL;
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}
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static char sdram_name[16];
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static int __init sa1110_clk_init(void)
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{
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struct sdram_params *sdram;
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const char *name = sdram_name;
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if (!cpu_is_sa1110())
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return -ENODEV;
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if (!name[0]) {
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if (machine_is_assabet())
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name = "TC59SM716-CL3";
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if (machine_is_pt_system3())
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name = "K4S641632D";
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if (machine_is_h3100())
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name = "KM416S4030CT";
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if (machine_is_jornada720() || machine_is_h3600())
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name = "K4S281632B-1H";
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if (machine_is_nanoengine())
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name = "MT48LC8M16A2TG-75";
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}
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sdram = sa1110_find_sdram(name);
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if (sdram) {
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printk(KERN_DEBUG "SDRAM: tck: %d trcd: %d trp: %d"
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" twr: %d refresh: %d cas_latency: %d\n",
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sdram->tck, sdram->trcd, sdram->trp,
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sdram->twr, sdram->refresh, sdram->cas_latency);
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memcpy(&sdram_params, sdram, sizeof(sdram_params));
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return cpufreq_register_driver(&sa1110_driver);
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}
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return 0;
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}
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module_param_string(sdram, sdram_name, sizeof(sdram_name), 0);
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arch_initcall(sa1110_clk_init);
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