arch/avr32/mach-at32ap/hsmc.c

   1 /*
   2  * Static Memory Controller for AT32 chips
   3  *
   4  * Copyright (C) 2006 Atmel Corporation
   5  *
   6  * This program is free software; you can redistribute it and/or modify
   7  * it under the terms of the GNU General Public License version 2 as
   8  * published by the Free Software Foundation.
   9  */
  10 #include <linux/clk.h>
  11 #include <linux/err.h>
  12 #include <linux/init.h>
  13 #include <linux/module.h>
  14 #include <linux/platform_device.h>
  15
  16 #include <asm/io.h>
  17 #include <asm/arch/smc.h>
  18
  19 #include "hsmc.h"
  20
  21 #define NR_CHIP_SELECTS 6
  22
  23 struct hsmc {
  24         void __iomem *regs;
  25         struct clk *pclk;
  26         struct clk *mck;
  27 };
  28
  29 static struct hsmc *hsmc;
  30
  31 void smc_set_timing(struct smc_config *config,
  32                     const struct smc_timing *timing)
  33 {
  34         int recover;
  35         int cycle;
  36
  37         unsigned long mul;
  38
  39         /* Reset all SMC timings */
  40         config->ncs_read_setup  = 0;
  41         config->nrd_setup       = 0;
  42         config->ncs_write_setup = 0;
  43         config->nwe_setup       = 0;
  44         config->ncs_read_pulse  = 0;
  45         config->nrd_pulse       = 0;
  46         config->ncs_write_pulse = 0;
  47         config->nwe_pulse       = 0;
  48         config->read_cycle      = 0;
  49         config->write_cycle     = 0;
  50
  51         /*
  52          * cycles = x / T = x * f
  53          *   = ((x * 1000000000) * ((f * 65536) / 1000000000)) / 65536
  54          *   = ((x * 1000000000) * (((f / 10000) * 65536) / 100000)) / 65536
  55          */
  56         mul = (clk_get_rate(hsmc->mck) / 10000) << 16;
  57         mul /= 100000;
  58
  59 #define ns2cyc(x) ((((x) * mul) + 65535) >> 16)
  60
  61         if (timing->ncs_read_setup > 0)
  62                 config->ncs_read_setup = ns2cyc(timing->ncs_read_setup);
  63
  64         if (timing->nrd_setup > 0)
  65                 config->nrd_setup = ns2cyc(timing->nrd_setup);
  66
  67         if (timing->ncs_write_setup > 0)
  68                 config->ncs_write_setup = ns2cyc(timing->ncs_write_setup);
  69
  70         if (timing->nwe_setup > 0)
  71                 config->nwe_setup = ns2cyc(timing->nwe_setup);
  72
  73         if (timing->ncs_read_pulse > 0)
  74                 config->ncs_read_pulse = ns2cyc(timing->ncs_read_pulse);
  75
  76         if (timing->nrd_pulse > 0)
  77                 config->nrd_pulse = ns2cyc(timing->nrd_pulse);
  78
  79         if (timing->ncs_write_pulse > 0)
  80                 config->ncs_write_pulse = ns2cyc(timing->ncs_write_pulse);
  81
  82         if (timing->nwe_pulse > 0)
  83                 config->nwe_pulse = ns2cyc(timing->nwe_pulse);
  84
  85         if (timing->read_cycle > 0)
  86                 config->read_cycle = ns2cyc(timing->read_cycle);
  87
  88         if (timing->write_cycle > 0)
  89                 config->write_cycle = ns2cyc(timing->write_cycle);
  90
  91         /* Extend read cycle in needed */
  92         if (timing->ncs_read_recover > 0)
  93                 recover = ns2cyc(timing->ncs_read_recover);
  94         else
  95                 recover = 1;
  96
  97         cycle = config->ncs_read_setup + config->ncs_read_pulse + recover;
  98
  99         if (config->read_cycle < cycle)
 100                 config->read_cycle = cycle;
 101
 102         /* Extend read cycle in needed */
 103         if (timing->nrd_recover > 0)
 104                 recover = ns2cyc(timing->nrd_recover);
 105         else
 106                 recover = 1;
 107
 108         cycle = config->nrd_setup + config->nrd_pulse + recover;
 109
 110         if (config->read_cycle < cycle)
 111                 config->read_cycle = cycle;
 112
 113         /* Extend write cycle in needed */
 114         if (timing->ncs_write_recover > 0)
 115                 recover = ns2cyc(timing->ncs_write_recover);
 116         else
 117                 recover = 1;
 118
 119         cycle = config->ncs_write_setup + config->ncs_write_pulse + recover;
 120
 121         if (config->write_cycle < cycle)
 122                 config->write_cycle = cycle;
 123
 124         /* Extend write cycle in needed */
 125         if (timing->nwe_recover > 0)
 126                 recover = ns2cyc(timing->nwe_recover);
 127         else
 128                 recover = 1;
 129
 130         cycle = config->nwe_setup + config->nwe_pulse + recover;
 131
 132         if (config->write_cycle < cycle)
 133                 config->write_cycle = cycle;
 134 }
 135 EXPORT_SYMBOL(smc_set_timing);
 136
 137 int smc_set_configuration(int cs, const struct smc_config *config)
 138 {
 139         unsigned long offset;
 140         u32 setup, pulse, cycle, mode;
 141
 142         if (!hsmc)
 143                 return -ENODEV;
 144         if (cs >= NR_CHIP_SELECTS)
 145                 return -EINVAL;
 146
 147         setup = (HSMC_BF(NWE_SETUP, config->nwe_setup)
 148                  | HSMC_BF(NCS_WR_SETUP, config->ncs_write_setup)
 149                  | HSMC_BF(NRD_SETUP, config->nrd_setup)
 150                  | HSMC_BF(NCS_RD_SETUP, config->ncs_read_setup));
 151         pulse = (HSMC_BF(NWE_PULSE, config->nwe_pulse)
 152                  | HSMC_BF(NCS_WR_PULSE, config->ncs_write_pulse)
 153                  | HSMC_BF(NRD_PULSE, config->nrd_pulse)
 154                  | HSMC_BF(NCS_RD_PULSE, config->ncs_read_pulse));
 155         cycle = (HSMC_BF(NWE_CYCLE, config->write_cycle)
 156                  | HSMC_BF(NRD_CYCLE, config->read_cycle));
 157
 158         switch (config->bus_width) {
 159         case 1:
 160                 mode = HSMC_BF(DBW, HSMC_DBW_8_BITS);
 161                 break;
 162         case 2:
 163                 mode = HSMC_BF(DBW, HSMC_DBW_16_BITS);
 164                 break;
 165         case 4:
 166                 mode = HSMC_BF(DBW, HSMC_DBW_32_BITS);
 167                 break;
 168         default:
 169                 return -EINVAL;
 170         }
 171
 172         switch (config->nwait_mode) {
 173         case 0:
 174                 mode |= HSMC_BF(EXNW_MODE, HSMC_EXNW_MODE_DISABLED);
 175                 break;
 176         case 1:
 177                 mode |= HSMC_BF(EXNW_MODE, HSMC_EXNW_MODE_RESERVED);
 178                 break;
 179         case 2:
 180                 mode |= HSMC_BF(EXNW_MODE, HSMC_EXNW_MODE_FROZEN);
 181                 break;
 182         case 3:
 183                 mode |= HSMC_BF(EXNW_MODE, HSMC_EXNW_MODE_READY);
 184                 break;
 185         default:
 186                 return -EINVAL;
 187         }
 188
 189         if (config->tdf_cycles) {
 190                 mode |= HSMC_BF(TDF_CYCLES, config->tdf_cycles);
 191         }
 192
 193         if (config->nrd_controlled)
 194                 mode |= HSMC_BIT(READ_MODE);
 195         if (config->nwe_controlled)
 196                 mode |= HSMC_BIT(WRITE_MODE);
 197         if (config->byte_write)
 198                 mode |= HSMC_BIT(BAT);
 199         if (config->tdf_mode)
 200                 mode |= HSMC_BIT(TDF_MODE);
 201
 202         pr_debug("smc cs%d: setup/%08x pulse/%08x cycle/%08x mode/%08x\n",
 203                  cs, setup, pulse, cycle, mode);
 204
 205         offset = cs * 0x10;
 206         hsmc_writel(hsmc, SETUP0 + offset, setup);
 207         hsmc_writel(hsmc, PULSE0 + offset, pulse);
 208         hsmc_writel(hsmc, CYCLE0 + offset, cycle);
 209         hsmc_writel(hsmc, MODE0 + offset, mode);
 210         hsmc_readl(hsmc, MODE0); /* I/O barrier */
 211
 212         return 0;
 213 }
 214 EXPORT_SYMBOL(smc_set_configuration);
 215
 216 static int hsmc_probe(struct platform_device *pdev)
 217 {
 218         struct resource *regs;
 219         struct clk *pclk, *mck;
 220         int ret;
 221
 222         if (hsmc)
 223                 return -EBUSY;
 224
 225         regs = platform_get_resource(pdev, IORESOURCE_MEM, 0);
 226         if (!regs)
 227                 return -ENXIO;
 228         pclk = clk_get(&pdev->dev, "pclk");
 229         if (IS_ERR(pclk))
 230                 return PTR_ERR(pclk);
 231         mck = clk_get(&pdev->dev, "mck");
 232         if (IS_ERR(mck)) {
 233                 ret = PTR_ERR(mck);
 234                 goto out_put_pclk;
 235         }
 236
 237         ret = -ENOMEM;
 238         hsmc = kzalloc(sizeof(struct hsmc), GFP_KERNEL);
 239         if (!hsmc)
 240                 goto out_put_clocks;
 241
 242         clk_enable(pclk);
 243         clk_enable(mck);
 244
 245         hsmc->pclk = pclk;
 246         hsmc->mck = mck;
 247         hsmc->regs = ioremap(regs->start, regs->end - regs->start + 1);
 248         if (!hsmc->regs)
 249                 goto out_disable_clocks;
 250
 251         dev_info(&pdev->dev, "Atmel Static Memory Controller at 0x%08lx\n",
 252                  (unsigned long)regs->start);
 253
 254         platform_set_drvdata(pdev, hsmc);
 255
 256         return 0;
 257
 258 out_disable_clocks:
 259         clk_disable(mck);
 260         clk_disable(pclk);
 261         kfree(hsmc);
 262 out_put_clocks:
 263         clk_put(mck);
 264 out_put_pclk:
 265         clk_put(pclk);
 266         hsmc = NULL;
 267         return ret;
 268 }
 269
 270 static struct platform_driver hsmc_driver = {
 271         .probe          = hsmc_probe,
 272         .driver         = {
 273                 .name   = "smc",
 274         },
 275 };
 276
 277 static int __init hsmc_init(void)
 278 {
 279         return platform_driver_register(&hsmc_driver);
 280 }
 281 arch_initcall(hsmc_init);