drivers/spi/spi_butterfly.c

   1 /*
   2  * spi_butterfly.c - parport-to-butterfly adapter
   3  *
   4  * Copyright (C) 2005 David Brownell
   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 as published by
   8  * the Free Software Foundation; either version 2 of the License, or
   9  * (at your option) any later version.
  10  *
  11  * This program is distributed in the hope that it will be useful,
  12  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  13  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  14  * GNU General Public License for more details.
  15  *
  16  * You should have received a copy of the GNU General Public License
  17  * along with this program; if not, write to the Free Software
  18  * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
  19  */
  20 #include <linux/kernel.h>
  21 #include <linux/init.h>
  22 #include <linux/delay.h>
  23 #include <linux/device.h>
  24 #include <linux/parport.h>
  25
  26 #include <linux/sched.h>
  27 #include <linux/spi/spi.h>
  28 #include <linux/spi/spi_bitbang.h>
  29 #include <linux/spi/flash.h>
  30
  31 #include <linux/mtd/partitions.h>
  32
  33
  34 /*
  35  * This uses SPI to talk with an "AVR Butterfly", which is a $US20 card
  36  * with a battery powered AVR microcontroller and lots of goodies.  You
  37  * can use GCC to develop firmware for this.
  38  *
  39  * See Documentation/spi/butterfly for information about how to build
  40  * and use this custom parallel port cable.
  41  */
  42
  43
  44 /* DATA output bits (pins 2..9 == D0..D7) */
  45 #define butterfly_nreset (1 << 1)               /* pin 3 */
  46
  47 #define spi_sck_bit     (1 << 0)                /* pin 2 */
  48 #define spi_mosi_bit    (1 << 7)                /* pin 9 */
  49
  50 #define vcc_bits        ((1 << 6) | (1 << 5))   /* pins 7, 8 */
  51
  52 /* STATUS input bits */
  53 #define spi_miso_bit    PARPORT_STATUS_BUSY     /* pin 11 */
  54
  55 /* CONTROL output bits */
  56 #define spi_cs_bit      PARPORT_CONTROL_SELECT  /* pin 17 */
  57
  58
  59
  60 static inline struct butterfly *spidev_to_pp(struct spi_device *spi)
  61 {
  62         return spi->controller_data;
  63 }
  64
  65
  66 struct butterfly {
  67         /* REVISIT ... for now, this must be first */
  68         struct spi_bitbang      bitbang;
  69
  70         struct parport          *port;
  71         struct pardevice        *pd;
  72
  73         u8                      lastbyte;
  74
  75         struct spi_device       *dataflash;
  76         struct spi_device       *butterfly;
  77         struct spi_board_info   info[2];
  78
  79 };
  80
  81 /*----------------------------------------------------------------------*/
  82
  83 static inline void
  84 setsck(struct spi_device *spi, int is_on)
  85 {
  86         struct butterfly        *pp = spidev_to_pp(spi);
  87         u8                      bit, byte = pp->lastbyte;
  88
  89         bit = spi_sck_bit;
  90
  91         if (is_on)
  92                 byte |= bit;
  93         else
  94                 byte &= ~bit;
  95         parport_write_data(pp->port, byte);
  96         pp->lastbyte = byte;
  97 }
  98
  99 static inline void
 100 setmosi(struct spi_device *spi, int is_on)
 101 {
 102         struct butterfly        *pp = spidev_to_pp(spi);
 103         u8                      bit, byte = pp->lastbyte;
 104
 105         bit = spi_mosi_bit;
 106
 107         if (is_on)
 108                 byte |= bit;
 109         else
 110                 byte &= ~bit;
 111         parport_write_data(pp->port, byte);
 112         pp->lastbyte = byte;
 113 }
 114
 115 static inline int getmiso(struct spi_device *spi)
 116 {
 117         struct butterfly        *pp = spidev_to_pp(spi);
 118         int                     value;
 119         u8                      bit;
 120
 121         bit = spi_miso_bit;
 122
 123         /* only STATUS_BUSY is NOT negated */
 124         value = !(parport_read_status(pp->port) & bit);
 125         return (bit == PARPORT_STATUS_BUSY) ? value : !value;
 126 }
 127
 128 static void butterfly_chipselect(struct spi_device *spi, int value)
 129 {
 130         struct butterfly        *pp = spidev_to_pp(spi);
 131
 132         /* set default clock polarity */
 133         if (value != BITBANG_CS_INACTIVE)
 134                 setsck(spi, spi->mode & SPI_CPOL);
 135
 136         /* here, value == "activate or not";
 137          * most PARPORT_CONTROL_* bits are negated, so we must
 138          * morph it to value == "bit value to write in control register"
 139          */
 140         if (spi_cs_bit == PARPORT_CONTROL_INIT)
 141                 value = !value;
 142
 143         parport_frob_control(pp->port, spi_cs_bit, value ? spi_cs_bit : 0);
 144 }
 145
 146
 147 /* we only needed to implement one mode here, and choose SPI_MODE_0 */
 148
 149 #define spidelay(X)     do{}while(0)
 150 //#define       spidelay        ndelay
 151
 152 #include "spi_bitbang_txrx.h"
 153
 154 static u32
 155 butterfly_txrx_word_mode0(struct spi_device *spi,
 156                 unsigned nsecs,
 157                 u32 word, u8 bits)
 158 {
 159         return bitbang_txrx_be_cpha0(spi, nsecs, 0, 0, word, bits);
 160 }
 161
 162 /*----------------------------------------------------------------------*/
 163
 164 /* override default partitioning with cmdlinepart */
 165 static struct mtd_partition partitions[] = { {
 166         /* JFFS2 wants partitions of 4*N blocks for this device,
 167          * so sectors 0 and 1 can't be partitions by themselves.
 168          */
 169
 170         /* sector 0 = 8 pages * 264 bytes/page (1 block)
 171          * sector 1 = 248 pages * 264 bytes/page
 172          */
 173         .name           = "bookkeeping",        // 66 KB
 174         .offset         = 0,
 175         .size           = (8 + 248) * 264,
 176 //      .mask_flags     = MTD_WRITEABLE,
 177 }, {
 178         /* sector 2 = 256 pages * 264 bytes/page
 179          * sectors 3-5 = 512 pages * 264 bytes/page
 180          */
 181         .name           = "filesystem",         // 462 KB
 182         .offset         = MTDPART_OFS_APPEND,
 183         .size           = MTDPART_SIZ_FULL,
 184 } };
 185
 186 static struct flash_platform_data flash = {
 187         .name           = "butterflash",
 188         .parts          = partitions,
 189         .nr_parts       = ARRAY_SIZE(partitions),
 190 };
 191
 192
 193 /* REVISIT remove this ugly global and its "only one" limitation */
 194 static struct butterfly *butterfly;
 195
 196 static void butterfly_attach(struct parport *p)
 197 {
 198         struct pardevice        *pd;
 199         int                     status;
 200         struct butterfly        *pp;
 201         struct spi_master       *master;
 202         struct device           *dev = p->physport->dev;
 203
 204         if (butterfly || !dev)
 205                 return;
 206
 207         /* REVISIT:  this just _assumes_ a butterfly is there ... no probe,
 208          * and no way to be selective about what it binds to.
 209          */
 210
 211         master = spi_alloc_master(dev, sizeof *pp);
 212         if (!master) {
 213                 status = -ENOMEM;
 214                 goto done;
 215         }
 216         pp = spi_master_get_devdata(master);
 217
 218         /*
 219          * SPI and bitbang hookup
 220          *
 221          * use default setup(), cleanup(), and transfer() methods; and
 222          * only bother implementing mode 0.  Start it later.
 223          */
 224         master->bus_num = 42;
 225         master->num_chipselect = 2;
 226
 227         pp->bitbang.master = spi_master_get(master);
 228         pp->bitbang.chipselect = butterfly_chipselect;
 229         pp->bitbang.txrx_word[SPI_MODE_0] = butterfly_txrx_word_mode0;
 230
 231         /*
 232          * parport hookup
 233          */
 234         pp->port = p;
 235         pd = parport_register_device(p, "spi_butterfly",
 236                         NULL, NULL, NULL,
 237                         0 /* FLAGS */, pp);
 238         if (!pd) {
 239                 status = -ENOMEM;
 240                 goto clean0;
 241         }
 242         pp->pd = pd;
 243
 244         status = parport_claim(pd);
 245         if (status < 0)
 246                 goto clean1;
 247
 248         /*
 249          * Butterfly reset, powerup, run firmware
 250          */
 251         pr_debug("%s: powerup/reset Butterfly\n", p->name);
 252
 253         /* nCS for dataflash (this bit is inverted on output) */
 254         parport_frob_control(pp->port, spi_cs_bit, 0);
 255
 256         /* stabilize power with chip in reset (nRESET), and
 257          * spi_sck_bit clear (CPOL=0)
 258          */
 259         pp->lastbyte |= vcc_bits;
 260         parport_write_data(pp->port, pp->lastbyte);
 261         msleep(5);
 262
 263         /* take it out of reset; assume long reset delay */
 264         pp->lastbyte |= butterfly_nreset;
 265         parport_write_data(pp->port, pp->lastbyte);
 266         msleep(100);
 267
 268
 269         /*
 270          * Start SPI ... for now, hide that we're two physical busses.
 271          */
 272         status = spi_bitbang_start(&pp->bitbang);
 273         if (status < 0)
 274                 goto clean2;
 275
 276         /* Bus 1 lets us talk to at45db041b (firmware disables AVR SPI), AVR
 277          * (firmware resets at45, acts as spi slave) or neither (we ignore
 278          * both, AVR uses AT45).  Here we expect firmware for the first option.
 279          */
 280
 281         pp->info[0].max_speed_hz = 15 * 1000 * 1000;
 282         strcpy(pp->info[0].modalias, "mtd_dataflash");
 283         pp->info[0].platform_data = &flash;
 284         pp->info[0].chip_select = 1;
 285         pp->info[0].controller_data = pp;
 286         pp->dataflash = spi_new_device(pp->bitbang.master, &pp->info[0]);
 287         if (pp->dataflash)
 288                 pr_debug("%s: dataflash at %s\n", p->name,
 289                                 dev_name(&pp->dataflash->dev));
 290
 291         // dev_info(_what?_, ...)
 292         pr_info("%s: AVR Butterfly\n", p->name);
 293         butterfly = pp;
 294         return;
 295
 296 clean2:
 297         /* turn off VCC */
 298         parport_write_data(pp->port, 0);
 299
 300         parport_release(pp->pd);
 301 clean1:
 302         parport_unregister_device(pd);
 303 clean0:
 304         (void) spi_master_put(pp->bitbang.master);
 305 done:
 306         pr_debug("%s: butterfly probe, fail %d\n", p->name, status);
 307 }
 308
 309 static void butterfly_detach(struct parport *p)
 310 {
 311         struct butterfly        *pp;
 312         int                     status;
 313
 314         /* FIXME this global is ugly ... but, how to quickly get from
 315          * the parport to the "struct butterfly" associated with it?
 316          * "old school" driver-internal device lists?
 317          */
 318         if (!butterfly || butterfly->port != p)
 319                 return;
 320         pp = butterfly;
 321         butterfly = NULL;
 322
 323         /* stop() unregisters child devices too */
 324         status = spi_bitbang_stop(&pp->bitbang);
 325
 326         /* turn off VCC */
 327         parport_write_data(pp->port, 0);
 328         msleep(10);
 329
 330         parport_release(pp->pd);
 331         parport_unregister_device(pp->pd);
 332
 333         (void) spi_master_put(pp->bitbang.master);
 334 }
 335
 336 static struct parport_driver butterfly_driver = {
 337         .name =         "spi_butterfly",
 338         .attach =       butterfly_attach,
 339         .detach =       butterfly_detach,
 340 };
 341
 342
 343 static int __init butterfly_init(void)
 344 {
 345         return parport_register_driver(&butterfly_driver);
 346 }
 347 device_initcall(butterfly_init);
 348
 349 static void __exit butterfly_exit(void)
 350 {
 351         parport_unregister_driver(&butterfly_driver);
 352 }
 353 module_exit(butterfly_exit);
 354
 355 MODULE_DESCRIPTION("Parport Adapter driver for AVR Butterfly");
 356 MODULE_LICENSE("GPL");