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[/] [neorv32/] [trunk/] [sw/] [bootloader/] [bootloader.c] - Blame information for rev 2

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// #################################################################################################
2
// # << NEORV32 - Bootloader >>                                                                    #
3
// # ********************************************************************************************* #
4
// # THE BOOTLOADER SHOULD BE COMPILED USING THE BASE ISA ONLY (rv32i or rv32e)!                   #
5
// # ********************************************************************************************* #
6
// # Boot from (internal) instruction memory, UART or SPI Flash.                                   #
7
// #                                                                                               #
8
// # UART configuration: 8N1 at 19200 baud                                                         #
9
// # Boot Flash: 8-bit SPI, 24-bit addresses (like Micron N25Q032A) @ neorv32.spi_csn_o(0)         #
10
// # neorv32.gpio_o(0) is used as high-active status LED.                                          #
11
// #                                                                                               #
12
// # Auto boot sequence after timeout:                                                             #
13
// #  -> Try booting from SPI flash at spi_csn_o(0).                                               #
14
// #  -> Permanently light up status led and freeze if SPI flash booting attempt fails.            #
15
// # ********************************************************************************************* #
16
// # BSD 3-Clause License                                                                          #
17
// #                                                                                               #
18
// # Copyright (c) 2020, Stephan Nolting. All rights reserved.                                     #
19
// #                                                                                               #
20
// # Redistribution and use in source and binary forms, with or without modification, are          #
21
// # permitted provided that the following conditions are met:                                     #
22
// #                                                                                               #
23
// # 1. Redistributions of source code must retain the above copyright notice, this list of        #
24
// #    conditions and the following disclaimer.                                                   #
25
// #                                                                                               #
26
// # 2. Redistributions in binary form must reproduce the above copyright notice, this list of     #
27
// #    conditions and the following disclaimer in the documentation and/or other materials        #
28
// #    provided with the distribution.                                                            #
29
// #                                                                                               #
30
// # 3. Neither the name of the copyright holder nor the names of its contributors may be used to  #
31
// #    endorse or promote products derived from this software without specific prior written      #
32
// #    permission.                                                                                #
33
// #                                                                                               #
34
// # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS   #
35
// # OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF               #
36
// # MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE    #
37
// # COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,     #
38
// # EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE #
39
// # GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED    #
40
// # AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING     #
41
// # NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED  #
42
// # OF THE POSSIBILITY OF SUCH DAMAGE.                                                            #
43
// # ********************************************************************************************* #
44
// # The NEORV32 Processor - https://github.com/stnolting/neorv32              (c) Stephan Nolting #
45
// #################################################################################################
46
 
47
 
48
/**********************************************************************//**
49
 * @file bootloader.c
50
 * @author Stephan Nolting
51
 * @brief Default NEORV32 bootloader. Compile only for rv32i or rv32e (better).
52
 **************************************************************************/
53
 
54
// Libraries
55
#include <stdint.h>
56
#include <neorv32.h>
57
 
58
 
59
/**********************************************************************//**
60
 * @name User configuration
61
 **************************************************************************/
62
/**@{*/
63
/** UART BAUD rate */
64
#define BAUD_RATE              (19200)
65
/** Time until the auto-boot sequence starts (in seconds) */
66
#define AUTOBOOT_TIMEOUT       (8)
67
/** Bootloader status LED at GPIO output port (0..15) */
68
#define STATUS_LED             (0)
69
/** SPI flash boot image base address */
70
#define SPI_FLASH_BOOT_ADR     (0x00040000)
71
/** SPI flash chip select at spi_csn_o */
72
#define SPI_FLASH_CS           (0)
73
/** Default SPI flash clock prescaler for serial peripheral interface */
74
#define SPI_FLASH_CLK_PRSC     (CLK_PRSC_8)
75
/** SPI flash sector size in bytes */
76
#define SPI_FLASH_SECTOR_SIZE  (64*1024)
77
/**@}*/
78
 
79
 
80
/**********************************************************************//**
81
  Executable stream source select
82
 **************************************************************************/
83
enum EXE_STREAM_SOURCE {
84
  EXE_STREAM_UART  = 0, /**< Get executable via UART */
85
  EXE_STREAM_FLASH = 1  /**< Get executable via SPI flash */
86
};
87
 
88
 
89
/**********************************************************************//**
90
 * Error codes
91
 **************************************************************************/
92
enum ERROR_CODES {
93
  ERROR_SIGNATURE = 0, /**< 0: Wrong signature in executable */
94
  ERROR_SIZE      = 1, /**< 1: Insufficient instruction memory capacity */
95
  ERROR_CHECKSUM  = 2, /**< 2: Checksum error in executable */
96
  ERROR_FLASH     = 3, /**< 3: SPI flash access error */
97
  ERROR_ROM       = 4, /**< 4: Instruction memory is marked as read-only */
98
  ERROR_SYSTEM    = 5  /**< 5: System exception */
99
};
100
 
101
 
102
/**********************************************************************//**
103
 * SPI flash commands
104
 **************************************************************************/
105
enum SPI_FLASH_CMD {
106
  SPI_FLASH_CMD_PAGE_PROGRAM = 0x02, /**< Program page */
107
  SPI_FLASH_CMD_READ         = 0x03, /**< Read data */
108
  SPI_FLASH_CMD_READ_STATUS  = 0x05, /**< Get status register */
109
  SPI_FLASH_CMD_WRITE_ENABLE = 0x06, /**< Allow write access */
110
  SPI_FLASH_CMD_READ_ID      = 0x9E, /**< Read manufacturer ID */
111
  SPI_FLASH_CMD_SECTOR_ERASE = 0xD8  /**< Erase complete sector */
112
};
113
 
114
 
115
/**********************************************************************//**
116
 * NEORV32 executable
117
 **************************************************************************/
118
enum NEORV32_EXECUTABLE {
119
  EXE_OFFSET_SIGNATURE =  0, /**< Offset in bytes from start to signature (32-bit) */
120
  EXE_OFFSET_SIZE      =  4, /**< Offset in bytes from start to size (32-bit) */
121
  EXE_OFFSET_CHECKSUM  =  8, /**< Offset in bytes from start to checksum (32-bit) */
122
  EXE_OFFSET_DATA      = 12, /**< Offset in bytes from start to data (32-bit) */
123
};
124
 
125
 
126
/**********************************************************************//**
127
 * Valid executable identification signature.
128
 **************************************************************************/
129
#define EXE_SIGNATURE 0x4788CAFE
130
 
131
 
132
/**********************************************************************//**
133
 * String output helper macros.
134
 **************************************************************************/
135
/**@{*/
136
/* Actual define-to-string helper */
137
#define xstr(a) str(a)
138
/* Internal helper macro */
139
#define str(a) #a
140
/**@}*/
141
 
142
 
143
// Function prototypes
144
void __attribute__((__interrupt__)) mtime_irq_handler(void);
145
void print_help(void);
146
void start_app(void);
147
void get_exe(int src);
148
void save_exe(void);
149
uint32_t get_exe_word(int src, uint32_t addr);
150
void system_error(uint8_t err_code);
151
void print_hex_word(uint32_t num);
152
void print_proc_version(void);
153
 
154
// SPI flash access
155
uint8_t spi_flash_read_byte(uint32_t addr);
156
void spi_flash_write_byte(uint32_t addr, uint8_t wdata);
157
void spi_flash_write_word(uint32_t addr, uint32_t wdata);
158
void spi_flash_erase_sector(uint32_t addr);
159
uint8_t spi_flash_read_status(void);
160
uint8_t spi_flash_read_1st_id(void);
161
void spi_flash_write_cmd(uint8_t cmd);
162
 
163
 
164
/**********************************************************************//**
165
 * Bootloader main.
166
 **************************************************************************/
167
int main(void) {
168
 
169
  // ------------------------------------------------
170
  // Processor hardware initialization
171
  // ------------------------------------------------
172
 
173
  // deactivate unused IO devices
174
  neorv32_clic_disable();
175
  neorv32_pwm_disable();
176
  neorv32_spi_disable();
177
  neorv32_trng_disable();
178
  neorv32_twi_disable();
179
  neorv32_wdt_disable();
180
 
181
  // get clock speed (in Hz)
182
  uint32_t clock_speed = neorv32_cpu_csr_read(CSR_MCLOCK);
183
 
184
  // init SPI for 8-bit, clock-mode 0, MSB-first, no interrupt
185
  if (clock_speed < 40000000) {
186
    neorv32_spi_setup(SPI_FLASH_CLK_PRSC, 0, 0, 0, 0);
187
  }
188
  else {
189
    neorv32_spi_setup(CLK_PRSC_128, 0, 0, 0, 0);
190
  }
191
 
192
  // init UART (no interrupts)
193
  neorv32_uart_setup(BAUD_RATE, 0, 0);
194
 
195
  // reset system time
196
  neorv32_mtime_set_time(0);
197
 
198
  // Configure machine system timer interrupt for ~2Hz
199
  neorv32_mtime_set_timecmp(neorv32_mtime_get_time() + (clock_speed/4));
200
 
201
  // confiure interrupt vector (bare-metal, no neorv32 rte)
202
  neorv32_cpu_csr_write(CSR_MTVEC, (uint32_t)(&mtime_irq_handler));
203
  neorv32_cpu_csr_write(CSR_MIE, 1 << CPU_MIE_MTIE); // activate MTIME IRQ source
204
 
205
  neorv32_cpu_eint(); // enable global interrupts
206
 
207
  // init GPIO
208
  neorv32_gpio_port_set(1 << STATUS_LED); // activate status LED, clear all others
209
 
210
  // abuse mscratch CSR as global variable to store the size of the last uploaded executable
211
  // this CSR must not be used by the bootloader's crt0.S!
212
  neorv32_cpu_csr_write(CSR_MSCRATCH, 0);
213
 
214
 
215
  // ------------------------------------------------
216
  // Show bootloader intro and system info
217
  // ------------------------------------------------
218
  neorv32_uart_print("\n\n\n\n<< NEORV32 Bootloader >>\n\n"
219
                     "BLDV: "__DATE__"\nHWV:  ");
220
  print_proc_version();
221
  neorv32_uart_print("\nCLK:  ");
222
  print_hex_word(neorv32_cpu_csr_read(CSR_MCLOCK));
223
  neorv32_uart_print(" Hz\nMISA: ");
224
  print_hex_word(neorv32_cpu_csr_read(CSR_MISA));
225
  neorv32_uart_print("\nCONF: ");
226
  print_hex_word(neorv32_cpu_csr_read(CSR_MFEATURES));
227
  neorv32_uart_print("\nIMEM: ");
228
  print_hex_word(neorv32_cpu_csr_read(CSR_MISPACESIZE));
229
  neorv32_uart_print(" bytes @ ");
230
  print_hex_word(neorv32_cpu_csr_read(CSR_MISPACEBASE));
231
  neorv32_uart_print("\nDMEM: ");
232
  print_hex_word(neorv32_cpu_csr_read(CSR_MDSPACESIZE));
233
  neorv32_uart_print(" bytes @ ");
234
  print_hex_word(neorv32_cpu_csr_read(CSR_MDSPACEBASE));
235
 
236
 
237
  // ------------------------------------------------
238
  // Auto boot sequence
239
  // ------------------------------------------------
240
  neorv32_uart_print("\n\nAutoboot in "xstr(AUTOBOOT_TIMEOUT)"s. Press key to abort.\n");
241
 
242
  uint64_t timeout_time = (uint64_t)(AUTOBOOT_TIMEOUT * clock_speed);
243
  while ((UART_DATA & (1 << UART_DATA_AVAIL)) == 0) { // wait for any key to be pressed or timeout
244
 
245
    if (neorv32_mtime_get_time() >= timeout_time) { // timeout? start auto boot sequence
246
      get_exe(EXE_STREAM_FLASH); // try loading from spi flash
247
      neorv32_uart_print("\n");
248
      start_app();
249
    }
250
  }
251
  neorv32_uart_print("Aborted.\n\n");
252
  print_help();
253
 
254
 
255
  // ------------------------------------------------
256
  // Bootloader console
257
  // ------------------------------------------------
258
  while (1) {
259
 
260
    neorv32_uart_print("\nCMD:> ");
261
    char c = neorv32_uart_getc();
262
    neorv32_uart_putc(c); // echo
263
    neorv32_uart_print("\n");
264
 
265
    if (c == 'r') { // restart bootloader
266
      break;
267
    }
268
    else if (c == 'h') { // help menu
269
      print_help();
270
    }
271
    else if (c == 'u') { // get executable via UART
272
      get_exe(EXE_STREAM_UART);
273
    }
274
    else if (c == 's') { // program EEPROM from RAM
275
      save_exe();
276
    }
277
    else if (c == 'l') { // get executable from flash
278
      get_exe(EXE_STREAM_FLASH);
279
    }
280
    else if (c == 'e') { // start application program
281
      start_app();
282
    }
283
    else if (c == '?') { // credits
284
      neorv32_uart_print("by Stephan Nolting");
285
    }
286
    else { // unknown command
287
      neorv32_uart_print("Invalid CMD");
288
    }
289
  }
290
 
291
  return 0; // bootloader will restart when returning
292
}
293
 
294
 
295
/**********************************************************************//**
296
 * Print help menu.
297
 **************************************************************************/
298
void print_help(void) {
299
 
300
  neorv32_uart_print("Available CMDs:\n"
301
                     " h: Help\n"
302
                     " r: Restart\n"
303
                     " u: Upload\n"
304
                     " s: Store to flash\n"
305
                     " l: Load from flash\n"
306
                     " e: Execute");
307
}
308
 
309
 
310
/**********************************************************************//**
311
 * Start application program at the beginning of instruction space.
312
 **************************************************************************/
313
void start_app(void) {
314
 
315
  // no need to shutdown or reset the used peripherals
316
  // -> this will be done by application's crt0
317
 
318
  // deactivate IRQs and IRQ sources
319
  neorv32_cpu_dint();
320
  neorv32_cpu_csr_write(CSR_MIE, 0);
321
 
322
  neorv32_uart_print("Booting...\n\n");
323
 
324
  // wait for UART to finish transmitting
325
  while ((UART_CT & (1<<UART_CT_TX_BUSY)) != 0);
326
 
327
  // start app at instruction space base address
328
  while (1) {
329
    register uint32_t app_base = neorv32_cpu_csr_read(CSR_MISPACEBASE);
330
    asm volatile ("jalr zero, %0" : : "r" (app_base));
331
  }
332
}
333
 
334
 
335
/**********************************************************************//**
336
 * Machine system timer (MTIME) interrupt handler.
337
 * @warning Since we have no runtime environment, we have to use the interrupt attribute here. Here, and only here!
338
 **************************************************************************/
339
void __attribute__((__interrupt__)) mtime_irq_handler(void) {
340
 
341
  // make sure this was caused by MTIME IRQ
342
  uint32_t cause = neorv32_cpu_csr_read(CSR_MCAUSE);
343
  if (cause != 0x80000007) { // raw exception code for MTI
344
    neorv32_uart_print("\n\nEXCEPTION: ");
345
    print_hex_word(cause);
346
    neorv32_uart_print(" @ 0x");
347
    print_hex_word(neorv32_cpu_csr_read(CSR_MEPC));
348
    system_error(ERROR_SYSTEM);
349
    while(1); // freeze
350
  }
351
  else {
352
    // toggle status LED
353
    neorv32_gpio_pin_toggle(STATUS_LED);
354
    // set time for next IRQ
355
    neorv32_mtime_set_timecmp(neorv32_mtime_get_time() + (neorv32_cpu_csr_read(CSR_MCLOCK)/4));
356
  }
357
}
358
 
359
 
360
/**********************************************************************//**
361
 * Get executable stream.
362
 *
363
 * @param src Source of executable stream data. See #EXE_STREAM_SOURCE.
364
 **************************************************************************/
365
void get_exe(int src) {
366
 
367
  // is instruction memory (actually, the IMEM) read-only?
368
  if (neorv32_cpu_csr_read(CSR_MFEATURES) & (1 << CPU_MFEATURES_MEM_INT_IMEM_ROM)) {
369
    system_error(ERROR_ROM);
370
  }
371
 
372
  // flash image base address
373
  uint32_t addr = SPI_FLASH_BOOT_ADR;
374
 
375
  // get image from flash?
376
  if (src == EXE_STREAM_UART) {
377
    neorv32_uart_print("Awaiting neorv32_exe.bin... ");
378
  }
379
  else {
380
    neorv32_uart_print("Loading... ");
381
 
382
    // check if flash ready (or available at all)
383
    if (spi_flash_read_1st_id() == 0x00) { // manufacturer ID
384
      system_error(ERROR_FLASH);
385
    }
386
  }
387
 
388
  // check if valid image
389
  uint32_t signature = get_exe_word(src, addr + EXE_OFFSET_SIGNATURE);
390
  if (signature != EXE_SIGNATURE) { // signature
391
    system_error(ERROR_SIGNATURE);
392
  }
393
 
394
  // image size and checksum
395
  uint32_t size  = get_exe_word(src, addr + EXE_OFFSET_SIZE); // size in bytes
396
  uint32_t check = get_exe_word(src, addr + EXE_OFFSET_CHECKSUM); // complement sum checksum
397
 
398
  // executable too large?
399
  uint32_t imem_size = neorv32_cpu_csr_read(CSR_MISPACESIZE);
400
  if (size > imem_size) {
401
    system_error(ERROR_SIZE);
402
  }
403
 
404
  // transfer program data
405
  uint32_t *pnt = (uint32_t*)neorv32_cpu_csr_read(CSR_MISPACEBASE);
406
  uint32_t checksum = 0;
407
  uint32_t d = 0, i = 0;
408
  addr = addr + EXE_OFFSET_DATA;
409
  while (i < (size/4)) { // in words
410
    d = get_exe_word(src, addr);
411
    checksum += d;
412
    pnt[i++] = d;
413
    addr += 4;
414
  }
415
 
416
/*
417
  // Debugging stuff
418
  neorv32_uart_putc('.');
419
  print_hex_word(signature);
420
  neorv32_uart_putc('.');
421
  print_hex_word(imem_size);
422
  neorv32_uart_putc('.');
423
  print_hex_word(check);
424
  neorv32_uart_putc('.');
425
  print_hex_word(checksum);
426
  neorv32_uart_putc('.');
427
*/
428
 
429
  // error during transfer?
430
  if ((checksum + check) != 0) {
431
    system_error(ERROR_CHECKSUM);
432
  }
433
  else {
434
    neorv32_uart_print("OK");
435
    neorv32_cpu_csr_write(CSR_MSCRATCH, size); // store exe size in "global variable"
436
  }
437
}
438
 
439
 
440
/**********************************************************************//**
441
 * Store content of instruction memory to SPI flash.
442
 **************************************************************************/
443
void save_exe(void) {
444
 
445
  // size of last uploaded executable
446
  uint32_t size = neorv32_cpu_csr_read(CSR_MSCRATCH);
447
 
448
  if (size == 0) {
449
    neorv32_uart_print("No executable available.");
450
    return;
451
  }
452
 
453
  uint32_t addr = SPI_FLASH_BOOT_ADR;
454
 
455
  // info and prompt
456
  neorv32_uart_print("Write 0x");
457
  print_hex_word(size);
458
  neorv32_uart_print(" bytes to SPI flash @ 0x");
459
  print_hex_word(addr);
460
  neorv32_uart_print("? (y/n) ");
461
 
462
  char c = neorv32_uart_getc();
463
  neorv32_uart_putc(c);
464
  if (c != 'y') {
465
    return;
466
  }
467
 
468
  // check if flash ready (or available at all)
469
  if (spi_flash_read_1st_id() == 0x00) { // manufacturer ID
470
    system_error(ERROR_FLASH);
471
  }
472
 
473
  neorv32_uart_print("\nFlashing... ");
474
 
475
  // clear memory before writing
476
  uint32_t num_sectors = (size / SPI_FLASH_SECTOR_SIZE) + 1; // clear at least 1 sector
477
  uint32_t sector = SPI_FLASH_BOOT_ADR;
478
  while (num_sectors--) {
479
    spi_flash_erase_sector(sector);
480
    sector += SPI_FLASH_SECTOR_SIZE;
481
  }
482
 
483
  // write EXE signature
484
  spi_flash_write_word(addr + EXE_OFFSET_SIGNATURE, EXE_SIGNATURE);
485
 
486
  // write size
487
  spi_flash_write_word(addr + EXE_OFFSET_SIZE, size);
488
 
489
  // store data from instruction memory and update checksum
490
  uint32_t checksum = 0;
491
  uint32_t *pnt = (uint32_t*)neorv32_cpu_csr_read(CSR_MISPACEBASE);
492
  addr = addr + EXE_OFFSET_DATA;
493
  uint32_t i = 0;
494
  while (i < (size/4)) { // in words
495
    uint32_t d = (uint32_t)*pnt++;
496
    checksum += d;
497
    spi_flash_write_word(addr, d);
498
    addr += 4;
499
    i++;
500
//  if ((i & 0x000000FF) == 0) {
501
//    neorv32_uart_putc('.');
502
//  }
503
  }
504
 
505
  // write checksum (sum complement)
506
  checksum = (~checksum) + 1;
507
  spi_flash_write_word(SPI_FLASH_BOOT_ADR + EXE_OFFSET_CHECKSUM, checksum);
508
 
509
  neorv32_uart_print("OK");
510
}
511
 
512
 
513
/**********************************************************************//**
514
 * Get word from executable stream
515
 *
516
 * @param src Source of executable stream data. See #EXE_STREAM_SOURCE.
517
 * @param addr Address when accessing SPI flash.
518
 * @return 32-bit data word from stream.
519
 **************************************************************************/
520
uint32_t get_exe_word(int src, uint32_t addr) {
521
 
522
  union {
523
    uint32_t uint32;
524
    uint8_t  uint8[sizeof(uint32_t)];
525
  } data;
526
 
527
  uint32_t i;
528
  for (i=0; i<4; i++) {
529
    if (src == EXE_STREAM_UART) {
530
      data.uint8[3-i] = (uint8_t)neorv32_uart_getc();
531
    }
532
    else {
533
      data.uint8[3-i] = spi_flash_read_byte(addr + i);
534
    }
535
  }
536
 
537
  return data.uint32;
538
}
539
 
540
 
541
/**********************************************************************//**
542
 * Output system error ID and stall.
543
 *
544
 * @param[in] err_code Error code. See #ERROR_CODES.
545
 **************************************************************************/
546
void system_error(uint8_t err_code) {
547
 
548
  neorv32_uart_print("\a\nERR_"); // output error code with annoying bell sound
549
  if (err_code <= ERROR_SYSTEM) {
550
    neorv32_uart_putc('0' + ((char)err_code));
551
  }
552
  else {
553
    neorv32_uart_print("unknown");
554
  }
555
 
556
  neorv32_cpu_dint(); // deactivate IRQs
557
  neorv32_gpio_port_set(1 << STATUS_LED); // permanently light up status LED
558
 
559
  while(1); // freeze
560
}
561
 
562
 
563
/**********************************************************************//**
564
 * Print 32-bit number as 8-digit hexadecimal value (with "0x" suffix).
565
 *
566
 * @param[in] num Number to print as hexadecimal.
567
 **************************************************************************/
568
void print_hex_word(uint32_t num) {
569
 
570
  static const char hex_symbols[16] = "0123456789ABCDEF";
571
 
572
  neorv32_uart_print("0x");
573
 
574
  int i;
575
  for (i=0; i<8; i++) {
576
    uint32_t index = (num >> (28 - 4*i)) & 0xF;
577
    neorv32_uart_putc(hex_symbols[index]);
578
  }
579
}
580
 
581
 
582
/**********************************************************************//**
583
 * Print processor version. Deciaml format: "Dd.Dd.Dd.Dd".
584
 **************************************************************************/
585
void print_proc_version(void) {
586
 
587
  uint32_t i;
588
  char tmp, cnt;
589
  uint32_t version = neorv32_cpu_csr_read(CSR_MIMPID);
590
 
591
  for (i=0; i<4; i++) {
592
 
593
    tmp = (char)(version >> (24 - 8*i));
594
 
595
    // serial division
596
    cnt = 0;
597
    while (tmp >= 10) {
598
      tmp = tmp - 10;
599
      cnt++;
600
    }
601
 
602
    if (cnt) {
603
      neorv32_uart_putc('0' + cnt);
604
    }
605
    neorv32_uart_putc('0' + tmp);
606
    if (i < 3) {
607
      neorv32_uart_putc('.');
608
    }
609
  }
610
}
611
 
612
 
613
 
614
// -------------------------------------------------------------------------------------
615
// SPI flash functions
616
// -------------------------------------------------------------------------------------
617
 
618
/**********************************************************************//**
619
 * Read byte from SPI flash.
620
 *
621
 * @param[in] addr Flash read address.
622
 * @return Read byte from SPI flash.
623
 **************************************************************************/
624
uint8_t spi_flash_read_byte(uint32_t addr) {
625
 
626
  union {
627
    uint32_t uint32;
628
    uint8_t  uint8[sizeof(uint32_t)];
629
  } address;
630
 
631
  address.uint32 = addr;
632
 
633
  neorv32_spi_cs_en(SPI_FLASH_CS);
634
 
635
  neorv32_spi_trans(SPI_FLASH_CMD_READ);
636
  neorv32_spi_trans(address.uint8[2]);
637
  neorv32_spi_trans(address.uint8[1]);
638
  neorv32_spi_trans(address.uint8[0]);
639
  uint8_t rdata = (uint8_t)neorv32_spi_trans(0);
640
 
641
  neorv32_spi_cs_dis(SPI_FLASH_CS);
642
 
643
  return rdata;
644
}
645
 
646
 
647
/**********************************************************************//**
648
 * Write byte to SPI flash.
649
 *
650
 * @param[in] addr SPI flash read address.
651
 * @param[in] wdata SPI flash read data.
652
 **************************************************************************/
653
void spi_flash_write_byte(uint32_t addr, uint8_t wdata) {
654
 
655
  union {
656
    uint32_t uint32;
657
    uint8_t  uint8[sizeof(uint32_t)];
658
  } address;
659
 
660
  address.uint32 = addr;
661
 
662
  spi_flash_write_cmd(SPI_FLASH_CMD_WRITE_ENABLE); // allow write-access
663
 
664
  neorv32_spi_cs_en(SPI_FLASH_CS);
665
 
666
  neorv32_spi_trans(SPI_FLASH_CMD_PAGE_PROGRAM);
667
  neorv32_spi_trans(address.uint8[2]);
668
  neorv32_spi_trans(address.uint8[1]);
669
  neorv32_spi_trans(address.uint8[0]);
670
  neorv32_spi_trans(wdata);
671
 
672
  neorv32_spi_cs_dis(SPI_FLASH_CS);
673
 
674
  while (1) {
675
    uint8_t tmp = spi_flash_read_status();
676
    if ((tmp & 0x01) == 0) { // write in progress flag cleared?
677
      break;
678
    }
679
  }
680
}
681
 
682
 
683
/**********************************************************************//**
684
 * Write word to SPI flash.
685
 *
686
 * @param addr SPI flash write address.
687
 * @param wdata SPI flash write data.
688
 **************************************************************************/
689
void spi_flash_write_word(uint32_t addr, uint32_t wdata) {
690
 
691
  union {
692
    uint32_t uint32;
693
    uint8_t  uint8[sizeof(uint32_t)];
694
  } data;
695
 
696
  data.uint32 = wdata;
697
 
698
  uint32_t i;
699
  for (i=0; i<4; i++) {
700
    spi_flash_write_byte(addr + i, data.uint8[3-i]);
701
  }
702
}
703
 
704
 
705
/**********************************************************************//**
706
 * Erase sector (64kB) at base adress.
707
 *
708
 * @param[in] addr Base address of sector to erase.
709
 **************************************************************************/
710
void spi_flash_erase_sector(uint32_t addr) {
711
 
712
  union {
713
    uint32_t uint32;
714
    uint8_t  uint8[sizeof(uint32_t)];
715
  } address;
716
 
717
  address.uint32 = addr;
718
 
719
  spi_flash_write_cmd(SPI_FLASH_CMD_WRITE_ENABLE); // allow write-access
720
 
721
  neorv32_spi_cs_en(SPI_FLASH_CS);
722
 
723
  neorv32_spi_trans(SPI_FLASH_CMD_SECTOR_ERASE);
724
  neorv32_spi_trans(address.uint8[2]);
725
  neorv32_spi_trans(address.uint8[1]);
726
  neorv32_spi_trans(address.uint8[0]);
727
 
728
  neorv32_spi_cs_dis(SPI_FLASH_CS);
729
 
730
  while (1) {
731
    uint8_t tmp = spi_flash_read_status();
732
    if ((tmp & 0x01) == 0) { // write in progress flag cleared?
733
      break;
734
    }
735
  }
736
}
737
 
738
 
739
/**********************************************************************//**
740
 * Read status register.
741
 *
742
 * @return Status register.
743
 **************************************************************************/
744
uint8_t spi_flash_read_status(void) {
745
 
746
  neorv32_spi_cs_en(SPI_FLASH_CS);
747
 
748
  neorv32_spi_trans(SPI_FLASH_CMD_READ_STATUS);
749
  uint8_t status = (uint8_t)neorv32_spi_trans(0);
750
 
751
  neorv32_spi_cs_dis(SPI_FLASH_CS);
752
 
753
  return status;
754
}
755
 
756
 
757
/**********************************************************************//**
758
 * Read first byte of ID (manufacturer ID), should be != 0x00.
759
 *
760
 * @note The first bit of the manufacturer ID is used to detect if a Flash is connected at all.
761
 *
762
 * @return First byte of ID.
763
 **************************************************************************/
764
uint8_t spi_flash_read_1st_id(void) {
765
 
766
  neorv32_spi_cs_en(SPI_FLASH_CS);
767
 
768
  neorv32_spi_trans(SPI_FLASH_CMD_READ_ID);
769
  uint8_t id = (uint8_t)neorv32_spi_trans(0);
770
 
771
  neorv32_spi_cs_dis(SPI_FLASH_CS);
772
 
773
  return id;
774
}
775
 
776
 
777
/**********************************************************************//**
778
 * Write command to flash.
779
 *
780
 * @param[in] cmd Command byte.
781
 **************************************************************************/
782
void spi_flash_write_cmd(uint8_t cmd) {
783
 
784
  neorv32_spi_cs_en(SPI_FLASH_CS);
785
 
786
  neorv32_spi_trans(cmd);
787
 
788
  neorv32_spi_cs_dis(SPI_FLASH_CS);
789
}
790
 

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