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1
/*
2
AMiRo-LLD is a compilation of low-level hardware drivers for the Autonomous Mini Robot (AMiRo) platform.
3
Copyright (C) 2016..2019  Thomas Schöpping et al.
4

5
This program is free software: you can redistribute it and/or modify
6
it under the terms of the GNU Lesser General Public License as published by
7
the Free Software Foundation, either version 3 of the License, or
8
(at your option) any later version.
9

10
This program is distributed in the hope that it will be useful,
11
but WITHOUT ANY WARRANTY; without even the implied warranty of
12
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
13
GNU Lesser General Public License for more details.
14

15
You should have received a copy of the GNU Lesser General Public License
16
along with this program.  If not, see <http://www.gnu.org/licenses/>.
17
*/
18

    
19
/*! ------------------------------------------------------------------------------------------------------------------
20
 * @file    deca_device.c
21
 * @brief   Decawave device configuration and control functions
22
 *
23
 * @attention
24
 *
25
 * Copyright 2013 (c) Decawave Ltd, Dublin, Ireland.
26
 *
27
 * All rights reserved.
28
 *
29
 */
30

    
31
#include <alld_DW1000.h>
32
#include <alld_DW1000_regs.h>
33
#include <assert.h>
34
#include <string.h>
35
#include <stdlib.h>
36
#include <math.h>
37

    
38

    
39
// HW dependent implementation (see bottom of file)
40
static int writetospi(uint16_t headerLength,
41
               const        uint8_t *headerBuffer,
42
               uint32_t bodyLength,
43
               const        uint8_t *bodyBuffer);
44

    
45
static int readfromspi(uint16_t headerLength,
46
                const uint8_t *headerBuffer,
47
                uint32_t readlength,
48
                uint8_t *readBuffer);
49

    
50

    
51
// Defines for enable_clocks function
52
#define FORCE_SYS_XTI  0
53
#define ENABLE_ALL_SEQ 1
54
#define FORCE_SYS_PLL  2
55
#define READ_ACC_ON    7
56
#define READ_ACC_OFF   8
57
#define FORCE_OTP_ON   11
58
#define FORCE_OTP_OFF  12
59
#define FORCE_TX_PLL   13
60
#define FORCE_LDE      14
61

    
62
// Defines for ACK request bitmask in DATA and MAC COMMAND frame control (first byte) - Used to detect AAT bit wrongly set.
63
#define FCTRL_ACK_REQ_MASK 0x20
64
// Frame control maximum length in bytes.
65
#define FCTRL_LEN_MAX 2
66

    
67

    
68
typedef struct {
69
    uint32_t lo32;
70
    uint16_t target[NUM_PRF];
71
} agc_cfg_struct ;
72

    
73
extern const agc_cfg_struct agc_config ;
74

    
75
//SFD threshold settings for 110k, 850k, 6.8Mb standard and non-standard
76
extern const uint16_t sftsh[NUM_BR][NUM_SFD];
77

    
78
extern const uint16_t dtune1[NUM_PRF];
79

    
80
#define XMLPARAMS_VERSION   (1.17f)
81

    
82
extern const uint32_t fs_pll_cfg[NUM_CH];
83
extern const uint8_t fs_pll_tune[NUM_CH];
84
extern const uint8_t rx_config[NUM_BW];
85
extern const uint32_t tx_config[NUM_CH];
86
extern const uint8_t dwnsSFDlen[NUM_BR]; //length of SFD for each of the bitrates
87
extern const uint32_t digital_bb_config[NUM_PRF][NUM_PACS];
88
//extern const uint8_t chan_idx[NUM_CH_SUPPORTED]; // move to header file
89
extern const double txpwr_compensation[NUM_CH];
90

    
91
#define PEAK_MULTPLIER  (0x60) //3 -> (0x3 * 32) & 0x00E0
92
#define N_STD_FACTOR    (13)
93
#define LDE_PARAM1      (PEAK_MULTPLIER | N_STD_FACTOR)
94

    
95
#define LDE_PARAM3_16 (0x1607)
96
#define LDE_PARAM3_64 (0x0607)
97

    
98
#define MIXER_GAIN_STEP (0.5)
99
#define DA_ATTN_STEP    (2.5)
100

    
101
// #define DWT_API_ERROR_CHECK     // define so API checks config input parameters
102

    
103
//-----------------------------------------
104
// map the channel number to the index in the configuration arrays below
105
// 0th element is chan 1, 1st is chan 2, 2nd is chan 3, 3rd is chan 4, 4th is chan 5, 5th is chan 7
106
const uint8_t chan_idx[NUM_CH_SUPPORTED] = {0, 0, 1, 2, 3, 4, 0, 5};
107

    
108
//-----------------------------------------
109
const uint32_t tx_config[NUM_CH] =
110
{
111
    RF_TXCTRL_CH1,
112
    RF_TXCTRL_CH2,
113
    RF_TXCTRL_CH3,
114
    RF_TXCTRL_CH4,
115
    RF_TXCTRL_CH5,
116
    RF_TXCTRL_CH7,
117
};
118

    
119
//Frequency Synthesiser - PLL configuration
120
const uint32_t fs_pll_cfg[NUM_CH] =
121
{
122
    FS_PLLCFG_CH1,
123
    FS_PLLCFG_CH2,
124
    FS_PLLCFG_CH3,
125
    FS_PLLCFG_CH4,
126
    FS_PLLCFG_CH5,
127
    FS_PLLCFG_CH7
128
};
129

    
130
//Frequency Synthesiser - PLL tuning
131
const uint8_t fs_pll_tune[NUM_CH] =
132
{
133
    FS_PLLTUNE_CH1,
134
    FS_PLLTUNE_CH2,
135
    FS_PLLTUNE_CH3,
136
    FS_PLLTUNE_CH4,
137
    FS_PLLTUNE_CH5,
138
    FS_PLLTUNE_CH7
139
};
140

    
141
//bandwidth configuration
142
const uint8_t rx_config[NUM_BW] =
143
{
144
    RF_RXCTRLH_NBW,
145
    RF_RXCTRLH_WBW
146
};
147

    
148

    
149
const agc_cfg_struct agc_config =
150
{
151
    AGC_TUNE2_VAL,
152
    { AGC_TUNE1_16M , AGC_TUNE1_64M }  //adc target
153
};
154

    
155
//DW non-standard SFD length for 110k, 850k and 6.81M
156
const uint8_t dwnsSFDlen[NUM_BR] =
157
{
158
    DW_NS_SFD_LEN_110K,
159
    DW_NS_SFD_LEN_850K,
160
    DW_NS_SFD_LEN_6M8
161
};
162

    
163
// SFD Threshold
164
const uint16_t sftsh[NUM_BR][NUM_SFD] =
165
{
166
    {
167
        DRX_TUNE0b_110K_STD,
168
        DRX_TUNE0b_110K_NSTD
169
    },
170
    {
171
        DRX_TUNE0b_850K_STD,
172
        DRX_TUNE0b_850K_NSTD
173
    },
174
    {
175
        DRX_TUNE0b_6M8_STD,
176
        DRX_TUNE0b_6M8_NSTD
177
    }
178
};
179

    
180
const uint16_t dtune1[NUM_PRF] =
181
{
182
    DRX_TUNE1a_PRF16,
183
    DRX_TUNE1a_PRF64
184
};
185

    
186
const uint32_t digital_bb_config[NUM_PRF][NUM_PACS] =
187
{
188
    {
189
        DRX_TUNE2_PRF16_PAC8,
190
        DRX_TUNE2_PRF16_PAC16,
191
        DRX_TUNE2_PRF16_PAC32,
192
        DRX_TUNE2_PRF16_PAC64
193
    },
194
    {
195
        DRX_TUNE2_PRF64_PAC8,
196
        DRX_TUNE2_PRF64_PAC16,
197
        DRX_TUNE2_PRF64_PAC32,
198
        DRX_TUNE2_PRF64_PAC64
199
    }
200
};
201

    
202
const uint16_t lde_replicaCoeff[PCODES] =
203
{
204
    0, // No preamble code 0
205
    LDE_REPC_PCODE_1,
206
    LDE_REPC_PCODE_2,
207
    LDE_REPC_PCODE_3,
208
    LDE_REPC_PCODE_4,
209
    LDE_REPC_PCODE_5,
210
    LDE_REPC_PCODE_6,
211
    LDE_REPC_PCODE_7,
212
    LDE_REPC_PCODE_8,
213
    LDE_REPC_PCODE_9,
214
    LDE_REPC_PCODE_10,
215
    LDE_REPC_PCODE_11,
216
    LDE_REPC_PCODE_12,
217
    LDE_REPC_PCODE_13,
218
    LDE_REPC_PCODE_14,
219
    LDE_REPC_PCODE_15,
220
    LDE_REPC_PCODE_16,
221
    LDE_REPC_PCODE_17,
222
    LDE_REPC_PCODE_18,
223
    LDE_REPC_PCODE_19,
224
    LDE_REPC_PCODE_20,
225
    LDE_REPC_PCODE_21,
226
    LDE_REPC_PCODE_22,
227
    LDE_REPC_PCODE_23,
228
    LDE_REPC_PCODE_24
229
};
230

    
231
const double txpwr_compensation[NUM_CH] = {
232
    0.0,
233
    0.035,
234
    0.0,
235
    0.0,
236
    0.065,
237
    0.0
238
};
239

    
240

    
241
const uint8_t chan_idxnb[NUM_CH_SUPPORTED] = {0, 0, 1, 2, 0, 3, 0, 0}; //only channels 1,2,3 and 5 are in the narrow band tables
242
const uint8_t chan_idxwb[NUM_CH_SUPPORTED] = {0, 0, 0, 0, 0, 0, 0, 1}; //only channels 4 and 7 are in in the wide band tables
243

    
244
//---------------------------------------------------------------------------------------------------------------------------
245
// Range Bias Correction TABLES of range values in integer units of 25 CM, for 8-bit unsigned storage, MUST END IN 255 !!!!!!
246
//---------------------------------------------------------------------------------------------------------------------------
247

    
248
// offsets to nearest centimeter for index 0, all rest are +1 cm per value
249

    
250
#define CM_OFFSET_16M_NB    (-23)   // for normal band channels at 16 MHz PRF
251
#define CM_OFFSET_16M_WB    (-28)   // for wider  band channels at 16 MHz PRF
252
#define CM_OFFSET_64M_NB    (-17)   // for normal band channels at 64 MHz PRF
253
#define CM_OFFSET_64M_WB    (-30)   // for wider  band channels at 64 MHz PRF
254

    
255

    
256
//---------------------------------------------------------------------------------------------------------------------------
257
// range25cm16PRFnb: Range Bias Correction table for narrow band channels at 16 MHz PRF, NB: !!!! each MUST END IN 255 !!!!
258
//---------------------------------------------------------------------------------------------------------------------------
259

    
260
const uint8_t range25cm16PRFnb[4][NUM_16M_OFFSET] =
261
{
262
    // ch 1 - range25cm16PRFnb
263
    {
264
           1,
265
           3,
266
           4,
267
           5,
268
           7,
269
           9,
270
          11,
271
          12,
272
          13,
273
          15,
274
          18,
275
          20,
276
          23,
277
          25,
278
          28,
279
          30,
280
          33,
281
          36,
282
          40,
283
          43,
284
          47,
285
          50,
286
          54,
287
          58,
288
          63,
289
          66,
290
          71,
291
          76,
292
          82,
293
          89,
294
          98,
295
         109,
296
         127,
297
         155,
298
         222,
299
         255,
300
         255
301
    },
302

    
303
    // ch 2 - range25cm16PRFnb
304
    {
305
           1,
306
           2,
307
           4,
308
           5,
309
           6,
310
           8,
311
           9,
312
          10,
313
          12,
314
          13,
315
          15,
316
          18,
317
          20,
318
          22,
319
          24,
320
          27,
321
          29,
322
          32,
323
          35,
324
          38,
325
          41,
326
          44,
327
          47,
328
          51,
329
          55,
330
          58,
331
          62,
332
          66,
333
          71,
334
          78,
335
          85,
336
          96,
337
         111,
338
         135,
339
         194,
340
         240,
341
         255
342
    },
343

    
344
    // ch 3 - range25cm16PRFnb
345
    {
346
           1,
347
           2,
348
           3,
349
           4,
350
           5,
351
           7,
352
           8,
353
           9,
354
          10,
355
          12,
356
          14,
357
          16,
358
          18,
359
          20,
360
          22,
361
          24,
362
          26,
363
          28,
364
          31,
365
          33,
366
          36,
367
          39,
368
          42,
369
          45,
370
          49,
371
          52,
372
          55,
373
          59,
374
          63,
375
          69,
376
          76,
377
          85,
378
          98,
379
         120,
380
         173,
381
         213,
382
         255
383
    },
384

    
385
    // ch 5 - range25cm16PRFnb
386
    {
387
           1,
388
           1,
389
           2,
390
           3,
391
           4,
392
           5,
393
           6,
394
           6,
395
           7,
396
           8,
397
           9,
398
          11,
399
          12,
400
          14,
401
          15,
402
          16,
403
          18,
404
          20,
405
          21,
406
          23,
407
          25,
408
          27,
409
          29,
410
          31,
411
          34,
412
          36,
413
          38,
414
          41,
415
          44,
416
          48,
417
          53,
418
          59,
419
          68,
420
          83,
421
         120,
422
         148,
423
         255
424
    }
425
}; // end range25cm16PRFnb
426

    
427

    
428
//---------------------------------------------------------------------------------------------------------------------------
429
// range25cm16PRFwb: Range Bias Correction table for wide band channels at 16 MHz PRF, NB: !!!! each MUST END IN 255 !!!!
430
//---------------------------------------------------------------------------------------------------------------------------
431

    
432
const uint8_t range25cm16PRFwb[2][NUM_16M_OFFSETWB] =
433
{
434
    // ch 4 - range25cm16PRFwb
435
    {
436
           7,
437
           7,
438
           8,
439
           9,
440
           9,
441
          10,
442
          11,
443
          11,
444
          12,
445
          13,
446
          14,
447
          15,
448
          16,
449
          17,
450
          18,
451
          19,
452
          20,
453
          21,
454
          22,
455
          23,
456
          24,
457
          26,
458
          27,
459
          28,
460
          30,
461
          31,
462
          32,
463
          34,
464
          36,
465
          38,
466
          40,
467
          42,
468
          44,
469
          46,
470
          48,
471
          50,
472
          52,
473
          55,
474
          57,
475
          59,
476
          61,
477
          63,
478
          66,
479
          68,
480
          71,
481
          74,
482
          78,
483
          81,
484
          85,
485
          89,
486
          94,
487
          99,
488
         104,
489
         110,
490
         116,
491
         123,
492
         130,
493
         139,
494
         150,
495
         164,
496
         182,
497
         207,
498
         238,
499
         255,
500
         255,
501
         255,
502
         255,
503
         255
504
    },
505

    
506
    // ch 7 - range25cm16PRFwb
507
    {
508
           4,
509
           5,
510
           5,
511
           5,
512
           6,
513
           6,
514
           7,
515
           7,
516
           7,
517
           8,
518
           9,
519
           9,
520
          10,
521
          10,
522
          11,
523
          11,
524
          12,
525
          13,
526
          13,
527
          14,
528
          15,
529
          16,
530
          17,
531
          17,
532
          18,
533
          19,
534
          20,
535
          21,
536
          22,
537
          23,
538
          25,
539
          26,
540
          27,
541
          29,
542
          30,
543
          31,
544
          32,
545
          34,
546
          35,
547
          36,
548
          38,
549
          39,
550
          40,
551
          42,
552
          44,
553
          46,
554
          48,
555
          50,
556
          52,
557
          55,
558
          58,
559
          61,
560
          64,
561
          68,
562
          72,
563
          75,
564
          80,
565
          85,
566
          92,
567
         101,
568
         112,
569
         127,
570
         147,
571
         168,
572
         182,
573
         194,
574
         205,
575
         255
576
    }
577
}; // end range25cm16PRFwb
578

    
579
//---------------------------------------------------------------------------------------------------------------------------
580
// range25cm64PRFnb: Range Bias Correction table for narrow band channels at 64 MHz PRF, NB: !!!! each MUST END IN 255 !!!!
581
//---------------------------------------------------------------------------------------------------------------------------
582

    
583
const uint8_t range25cm64PRFnb[4][NUM_64M_OFFSET] =
584
{
585
    // ch 1 - range25cm64PRFnb
586
    {
587
           1,
588
           2,
589
           2,
590
           3,
591
           4,
592
           5,
593
           7,
594
          10,
595
          13,
596
          16,
597
          19,
598
          22,
599
          24,
600
          27,
601
          30,
602
          32,
603
          35,
604
          38,
605
          43,
606
          48,
607
          56,
608
          78,
609
         101,
610
         120,
611
         157,
612
         255
613
    },
614

    
615
    // ch 2 - range25cm64PRFnb
616
    {
617
           1,
618
           2,
619
           2,
620
           3,
621
           4,
622
           4,
623
           6,
624
           9,
625
          12,
626
          14,
627
          17,
628
          19,
629
          21,
630
          24,
631
          26,
632
          28,
633
          31,
634
          33,
635
          37,
636
          42,
637
          49,
638
          68,
639
          89,
640
         105,
641
         138,
642
         255
643
    },
644

    
645
    // ch 3 - range25cm64PRFnb
646
    {
647
           1,
648
           1,
649
           2,
650
           3,
651
           3,
652
           4,
653
           5,
654
           8,
655
          10,
656
          13,
657
          15,
658
          17,
659
          19,
660
          21,
661
          23,
662
          25,
663
          27,
664
          30,
665
          33,
666
          37,
667
          44,
668
          60,
669
          79,
670
          93,
671
         122,
672
         255
673
    },
674

    
675
    // ch 5 - range25cm64PRFnb
676
    {
677
           1,
678
           1,
679
           1,
680
           2,
681
           2,
682
           3,
683
           4,
684
           6,
685
           7,
686
           9,
687
          10,
688
          12,
689
          13,
690
          15,
691
          16,
692
          17,
693
          19,
694
          21,
695
          23,
696
          26,
697
          30,
698
          42,
699
          55,
700
          65,
701
          85,
702
         255
703
    }
704
}; // end range25cm64PRFnb
705

    
706
//---------------------------------------------------------------------------------------------------------------------------
707
// range25cm64PRFwb: Range Bias Correction table for wide band channels at 64 MHz PRF, NB: !!!! each MUST END IN 255 !!!!
708
//---------------------------------------------------------------------------------------------------------------------------
709

    
710
const uint8_t range25cm64PRFwb[2][NUM_64M_OFFSETWB] =
711
{
712
    // ch 4 - range25cm64PRFwb
713
    {
714
           7,
715
           8,
716
           8,
717
           9,
718
           9,
719
          10,
720
          11,
721
          12,
722
          13,
723
          13,
724
          14,
725
          15,
726
          16,
727
          16,
728
          17,
729
          18,
730
          19,
731
          19,
732
          20,
733
          21,
734
          22,
735
          24,
736
          25,
737
          27,
738
          28,
739
          29,
740
          30,
741
          32,
742
          33,
743
          34,
744
          35,
745
          37,
746
          39,
747
          41,
748
          43,
749
          45,
750
          48,
751
          50,
752
          53,
753
          56,
754
          60,
755
          64,
756
          68,
757
          74,
758
          81,
759
          89,
760
          98,
761
         109,
762
         122,
763
         136,
764
         146,
765
         154,
766
         162,
767
         178,
768
         220,
769
         249,
770
         255,
771
         255,
772
         255
773
    },
774

    
775
    // ch 7 - range25cm64PRFwb
776
    {
777
           4,
778
           5,
779
           5,
780
           5,
781
           6,
782
           6,
783
           7,
784
           7,
785
           8,
786
           8,
787
           9,
788
           9,
789
          10,
790
          10,
791
          10,
792
          11,
793
          11,
794
          12,
795
          13,
796
          13,
797
          14,
798
          15,
799
          16,
800
          16,
801
          17,
802
          18,
803
          19,
804
          19,
805
          20,
806
          21,
807
          22,
808
          23,
809
          24,
810
          25,
811
          26,
812
          28,
813
          29,
814
          31,
815
          33,
816
          35,
817
          37,
818
          39,
819
          42,
820
          46,
821
          50,
822
          54,
823
          60,
824
          67,
825
          75,
826
          83,
827
          90,
828
          95,
829
         100,
830
         110,
831
         135,
832
         153,
833
         172,
834
         192,
835
         255
836
    }
837
}; // end range25cm64PRFwb
838

    
839

    
840
/*! ------------------------------------------------------------------------------------------------------------------
841
 * Function: dwt_getrangebias()
842
 *
843
 * Description: This function is used to return the range bias correction need for TWR with DW1000 units.
844
 *
845
 * input parameters:        
846
 * @param chan  - specifies the operating channel (e.g. 1, 2, 3, 4, 5, 6 or 7) 
847
 * @param range - the calculated distance before correction
848
 * @param prf        - this is the PRF e.g. DWT_PRF_16M or DWT_PRF_64M
849
 *
850
 * output parameters
851
 *
852
 * returns correction needed in meters
853
 */
854
double dwt_getrangebias(uint8_t chan, float range, uint8_t prf)
855
{
856
    //first get the lookup index that corresponds to given range for a particular channel at 16M PRF
857
    int i = 0 ;
858
    int chanIdx ;
859
    int cmoffseti ;                                 // integer number of CM offset
860

    
861
    double mOffset ;                                // final offset result in metres
862

    
863
    // NB: note we may get some small negitive values e.g. up to -50 cm.
864

    
865
    int rangeint25cm = (int) ((double)range * 4.00) ;       // convert range to integer number of 25cm values.
866

    
867
    if (rangeint25cm > 255) rangeint25cm = 255 ;    // make sure it matches largest value in table (all tables end in 255 !!!!)
868

    
869
    if (prf == DWT_PRF_16M)
870
    {
871
        switch(chan)
872
        {
873
            case 4:
874
            case 7:
875
            {
876
                chanIdx = chan_idxwb[chan];
877
                while (rangeint25cm > range25cm16PRFwb[chanIdx][i]) i++ ;       // find index in table corresponding to range
878
                cmoffseti = i + CM_OFFSET_16M_WB ;                              // nearest centimeter correction
879
            }
880
            break;
881
            default:
882
            {
883
                chanIdx = chan_idxnb[chan];
884
                while (rangeint25cm > range25cm16PRFnb[chanIdx][i]) i++ ;       // find index in table corresponding to range
885
                cmoffseti = i + CM_OFFSET_16M_NB ;                              // nearest centimeter correction
886
            }
887
        }//end of switch
888
    }
889
    else // 64M PRF
890
    {
891
        switch(chan)
892
        {
893
            case 4:
894
            case 7:
895
            {
896
                chanIdx = chan_idxwb[chan];
897
                while (rangeint25cm > range25cm64PRFwb[chanIdx][i]) i++ ;       // find index in table corresponding to range
898
                cmoffseti = i + CM_OFFSET_64M_WB ;                              // nearest centimeter correction
899
            }
900
            break;
901
            default:
902
            {
903
                chanIdx = chan_idxnb[chan];
904
                while (rangeint25cm > range25cm64PRFnb[chanIdx][i]) i++ ;       // find index in table corresponding to range
905
                cmoffseti = i + CM_OFFSET_64M_NB ;                              // nearest centimeter correction
906
            }
907
        }//end of switch
908
    } // end else
909

    
910

    
911
    mOffset = (double) cmoffseti ;                                       // offset result in centimmetres
912

    
913
    mOffset *= 0.01 ;                                                   // convert to metres
914

    
915
    return (mOffset) ;
916
}
917

    
918
// -------------------------------------------------------------------------------------------------------------------
919
//
920
// Internal functions for controlling and configuring the device
921
//
922
// -------------------------------------------------------------------------------------------------------------------
923

    
924
// Enable and Configure specified clocks
925
void _dwt_enableclocks(int clocks) ;
926
// Configure the ucode (FP algorithm) parameters
927
void _dwt_configlde(int prf);
928
// Load ucode from OTP/ROM
929
void _dwt_loaducodefromrom(void);
930
// Read non-volatile memory
931
uint32_t _dwt_otpread(uint32_t address);
932
// Program the non-volatile memory
933
int32_t _dwt_otpprogword32(uint32_t data, uint16_t address);
934
// Upload the device configuration into always on memory
935
void _dwt_aonarrayupload(void);
936
// -------------------------------------------------------------------------------------------------------------------
937

    
938
/*!
939
 * Static data for DW1000 DecaWave Transceiver control
940
 */
941

    
942
static dwt_local_data_t dw1000local[DWT_NUM_DW_DEV] ; // Static local device data, can be an array to support multiple DW1000 testing applications/platforms
943
static dwt_local_data_t *pdw1000local = dw1000local ; // Static local data structure pointer
944

    
945

    
946
/*! ------------------------------------------------------------------------------------------------------------------
947
 * @fn dwt_setdevicedataptr()
948
 *
949
 * @brief This function sets the local data structure pointer to point to the structure in the local array as given by the index.
950
 *
951
 * input parameters
952
 * @param index    - selects the array object to point to. Must be within the array bounds, i.e. < DWT_NUM_DW_DEV
953
 *
954
 * output parameters
955
 *
956
 * returns DWT_SUCCESS for success, or DWT_ERROR for error
957
 */
958
int dwt_setdevicedataptr(unsigned int index)
959
{
960
    // Check the index is within the array bounds
961
    if (DWT_NUM_DW_DEV > index) // return error if index outside the array bounds
962
    {
963
        return DWT_ERROR ;
964
    }
965

    
966
    pdw1000local = &dw1000local[index];
967

    
968
    return DWT_SUCCESS ;
969
}
970

    
971
/*! ------------------------------------------------------------------------------------------------------------------
972
 * @fn dwt_initialise()
973
 *
974
 * @brief This function initiates communications with the DW1000 transceiver
975
 * and reads its DEV_ID register (address 0x00) to verify the IC is one supported
976
 * by this software (e.g. DW1000 32-bit device ID value is 0xDECA0130).  Then it
977
 * does any initial once only device configurations needed for use and initialises
978
 * as necessary any static data items belonging to this low-level driver.
979
 *
980
 * NOTES:
981
 * 1.this function needs to be run before dwt_configuresleep, also the SPI frequency has to be < 3MHz
982
 * 2.it also reads and applies LDO tune and crystal trim values from OTP memory
983
 *
984
 * input parameters
985
 * @param config    -   specifies what configuration to load
986
 *                  DWT_LOADUCODE     0x1 - load the LDE microcode from ROM - enabled accurate RX timestamp
987
 *                  DWT_LOADNONE      0x0 - do not load any values from OTP memory
988
 *
989
 * output parameters
990
 *
991
 * returns DWT_SUCCESS for success, or DWT_ERROR for error
992
 */
993
// OTP addresses definitions
994
#define LDOTUNE_ADDRESS (0x04)
995
#define PARTID_ADDRESS (0x06)
996
#define LOTID_ADDRESS  (0x07)
997
#define VBAT_ADDRESS   (0x08)
998
#define VTEMP_ADDRESS  (0x09)
999
#define XTRIM_ADDRESS  (0x1E)
1000

    
1001
int dwt_initialise(const uint16_t config, DW1000Driver* drv)
1002
{
1003
    uint16_t otp_addr = 0;
1004
    uint32_t ldo_tune = 0;
1005

    
1006
    pdw1000local->dblbuffon = 0; // Double buffer mode off by default
1007
    pdw1000local->wait4resp = 0;
1008
    pdw1000local->sleep_mode = 0;
1009

    
1010
    pdw1000local->cbTxDone = NULL;
1011
    pdw1000local->cbRxOk = NULL;
1012
    pdw1000local->cbRxTo = NULL;
1013
    pdw1000local->cbRxErr = NULL;
1014

    
1015
    pdw1000local->driver = drv;
1016

    
1017
    // Read and validate device ID return -1 if not recognised
1018
    if (DWT_DEVICE_ID != dwt_readdevid()) // MP IC ONLY (i.e. DW1000) FOR THIS CODE
1019
    {
1020
        return DWT_ERROR ;
1021
    }
1022

    
1023
    // Make sure the device is completely reset before starting initialisation
1024
    dwt_softreset();
1025

    
1026
    _dwt_enableclocks(FORCE_SYS_XTI); // NOTE: set system clock to XTI - this is necessary to make sure the values read by _dwt_otpread are reliable
1027

    
1028
    // Configure the CPLL lock detect
1029
    dwt_write8bitoffsetreg(EXT_SYNC_ID, EC_CTRL_OFFSET, EC_CTRL_PLLLCK);
1030

    
1031
    // Read OTP revision number
1032
    otp_addr = _dwt_otpread(XTRIM_ADDRESS) & 0xffff;        // Read 32 bit value, XTAL trim val is in low octet-0 (5 bits)
1033
    pdw1000local->otprev = (otp_addr >> 8) & 0xff;            // OTP revision is next byte
1034

    
1035
    // Load LDO tune from OTP and kick it if there is a value actually programmed.
1036
    ldo_tune = _dwt_otpread(LDOTUNE_ADDRESS);
1037
    if((ldo_tune & 0xFF) != 0)
1038
    {
1039
        // Kick LDO tune
1040
        dwt_write8bitoffsetreg(OTP_IF_ID, OTP_SF, OTP_SF_LDO_KICK); // Set load LDE kick bit
1041
        pdw1000local->sleep_mode |= AON_WCFG_ONW_LLDO; // LDO tune must be kicked at wake-up
1042
    }
1043

    
1044
    // Load Part and Lot ID from OTP
1045
    pdw1000local->partID = _dwt_otpread(PARTID_ADDRESS);
1046
    pdw1000local->lotID = _dwt_otpread(LOTID_ADDRESS);
1047

    
1048
    // XTAL trim value is set in OTP for DW1000 module and EVK/TREK boards but that might not be the case in a custom design
1049
    pdw1000local->init_xtrim = otp_addr & 0x1F;
1050
    if (!pdw1000local->init_xtrim) // A value of 0 means that the crystal has not been trimmed
1051
    {
1052
        pdw1000local->init_xtrim = FS_XTALT_MIDRANGE ; // Set to mid-range if no calibration value inside
1053
    }
1054
    // Configure XTAL trim
1055
    dwt_setxtaltrim(pdw1000local->init_xtrim);
1056

    
1057
    // Load leading edge detect code
1058
    if(config & DWT_LOADUCODE)
1059
    {
1060
        _dwt_loaducodefromrom();
1061
        pdw1000local->sleep_mode |= AON_WCFG_ONW_LLDE; // microcode must be loaded at wake-up
1062
    }
1063
    else // Should disable the LDERUN enable bit in 0x36, 0x4
1064
    {
1065
        uint16_t rega = dwt_read16bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET+1) ;
1066
        rega &= 0xFDFF ; // Clear LDERUN bit
1067
        dwt_write16bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET+1, rega) ;
1068
    }
1069

    
1070
    _dwt_enableclocks(ENABLE_ALL_SEQ); // Enable clocks for sequencing
1071

    
1072
    // The 3 bits in AON CFG1 register must be cleared to ensure proper operation of the DW1000 in DEEPSLEEP mode.
1073
    dwt_write8bitoffsetreg(AON_ID, AON_CFG1_OFFSET, 0x00);
1074

    
1075
    // Read system register / store local copy
1076
    pdw1000local->sysCFGreg = dwt_read32bitreg(SYS_CFG_ID) ; // Read sysconfig register
1077

    
1078
    return DWT_SUCCESS ;
1079

    
1080
} // end dwt_initialise()
1081

    
1082
/*! ------------------------------------------------------------------------------------------------------------------
1083
 * @fn dwt_otprevision()
1084
 *
1085
 * @brief This is used to return the read OTP revision
1086
 *
1087
 * NOTE: dwt_initialise() must be called prior to this function so that it can return a relevant value.
1088
 *
1089
 * input parameters
1090
 *
1091
 * output parameters
1092
 *
1093
 * returns the read OTP revision value
1094
 */
1095
uint8_t dwt_otprevision(void)
1096
{
1097
    return pdw1000local->otprev ;
1098
}
1099

    
1100
/*! ------------------------------------------------------------------------------------------------------------------
1101
 * @fn dwt_setfinegraintxseq()
1102
 *
1103
 * @brief This function enables/disables the fine grain TX sequencing (enabled by default).
1104
 *
1105
 * input parameters
1106
 * @param enable - 1 to enable fine grain TX sequencing, 0 to disable it.
1107
 *
1108
 * output parameters none
1109
 *
1110
 * no return value
1111
 */
1112
void dwt_setfinegraintxseq(int enable)
1113
{
1114
    if (enable)
1115
    {
1116
        dwt_write16bitoffsetreg(PMSC_ID, PMSC_TXFINESEQ_OFFSET, PMSC_TXFINESEQ_ENABLE);
1117
    }
1118
    else
1119
    {
1120
        dwt_write16bitoffsetreg(PMSC_ID, PMSC_TXFINESEQ_OFFSET, PMSC_TXFINESEQ_DISABLE);
1121
    }
1122
}
1123

    
1124
/*! ------------------------------------------------------------------------------------------------------------------
1125
 * @fn dwt_setlnapamode()
1126
 *
1127
 * @brief This is used to enable GPIO for external LNA or PA functionality - HW dependent, consult the DW1000 User Manual.
1128
 *        This can also be used for debug as enabling TX and RX GPIOs is quite handy to monitor DW1000's activity.
1129
 *
1130
 * NOTE: Enabling PA functionality requires that fine grain TX sequencing is deactivated. This can be done using
1131
 *       dwt_setfinegraintxseq().
1132
 *
1133
 * input parameters
1134
 * @param lna - 1 to enable LNA functionality, 0 to disable it
1135
 * @param pa - 1 to enable PA functionality, 0 to disable it
1136
 *
1137
 * output parameters
1138
 *
1139
 * no return value
1140
 */
1141
void dwt_setlnapamode(int lna, int pa)
1142
{
1143
    uint32_t gpio_mode = dwt_read32bitoffsetreg(GPIO_CTRL_ID, GPIO_MODE_OFFSET);
1144
    gpio_mode &= ~(GPIO_MSGP4_MASK | GPIO_MSGP5_MASK | GPIO_MSGP6_MASK);
1145
    if (lna)
1146
    {
1147
        gpio_mode |= GPIO_PIN6_EXTRXE;
1148
    }
1149
    if (pa)
1150
    {
1151
        gpio_mode |= (GPIO_PIN5_EXTTXE | GPIO_PIN4_EXTPA);
1152
    }
1153
    dwt_write32bitoffsetreg(GPIO_CTRL_ID, GPIO_MODE_OFFSET, gpio_mode);
1154
}
1155

    
1156
/*! ------------------------------------------------------------------------------------------------------------------
1157
 * @fn dwt_setgpiodirection()
1158
 *
1159
 * @brief This is used to set GPIO direction as an input (1) or output (0)
1160
 *
1161
 * input parameters
1162
 * @param gpioNum    -   this is the GPIO to configure - see GxM0... GxM8 in the deca_regs.h file
1163
 * @param direction  -   this sets the GPIO direction - see GxP0... GxP8 in the deca_regs.h file
1164
 *
1165
 * output parameters
1166
 *
1167
 * no return value
1168
 */
1169
void dwt_setgpiodirection(uint32_t gpioNum, uint32_t direction)
1170
{
1171
    uint8_t buf[GPIO_DIR_LEN];
1172
    uint32_t command = direction | gpioNum;
1173

    
1174
    buf[0] = command & 0xff;
1175
    buf[1] = (command >> 8) & 0xff;
1176
    buf[2] = (command >> 16) & 0xff;
1177

    
1178
    dwt_writetodevice(GPIO_CTRL_ID, GPIO_DIR_OFFSET, GPIO_DIR_LEN, buf);
1179
}
1180

    
1181
/*! ------------------------------------------------------------------------------------------------------------------
1182
 * @fn dwt_setgpiovalue()
1183
 *
1184
 * @brief This is used to set GPIO value as (1) or (0) only applies if the GPIO is configured as output
1185
 *
1186
 * input parameters
1187
 * @param gpioNum    -   this is the GPIO to configure - see GxM0... GxM8 in the deca_regs.h file
1188
 * @param value  -   this sets the GPIO value - see GDP0... GDP8 in the deca_regs.h file
1189
 *
1190
 * output parameters
1191
 *
1192
 * no return value
1193
 */
1194
void dwt_setgpiovalue(uint32_t gpioNum, uint32_t value)
1195
{
1196
    uint8_t buf[GPIO_DOUT_LEN];
1197
    uint32_t command = value | gpioNum;
1198

    
1199
    buf[0] = command & 0xff;
1200
    buf[1] = (command >> 8) & 0xff;
1201
    buf[2] = (command >> 16) & 0xff;
1202

    
1203
    dwt_writetodevice(GPIO_CTRL_ID, GPIO_DOUT_OFFSET, GPIO_DOUT_LEN, buf);
1204
}
1205

    
1206
/*! ------------------------------------------------------------------------------------------------------------------
1207
 * @fn dwt_getpartid()
1208
 *
1209
 * @brief This is used to return the read part ID of the device
1210
 *
1211
 * NOTE: dwt_initialise() must be called prior to this function so that it can return a relevant value.
1212
 *
1213
 * input parameters
1214
 *
1215
 * output parameters
1216
 *
1217
 * returns the 32 bit part ID value as programmed in the factory
1218
 */
1219
uint32_t dwt_getpartid(void)
1220
{
1221
    return pdw1000local->partID;
1222
}
1223

    
1224
/*! ------------------------------------------------------------------------------------------------------------------
1225
 * @fn dwt_getlotid()
1226
 *
1227
 * @brief This is used to return the read lot ID of the device
1228
 *
1229
 * NOTE: dwt_initialise() must be called prior to this function so that it can return a relevant value.
1230
 *
1231
 * input parameters
1232
 *
1233
 * output parameters
1234
 *
1235
 * returns the 32 bit lot ID value as programmed in the factory
1236
 */
1237
uint32_t dwt_getlotid(void)
1238
{
1239
    return pdw1000local->lotID;
1240
}
1241

    
1242
/*! ------------------------------------------------------------------------------------------------------------------
1243
 * @fn dwt_readdevid()
1244
 *
1245
 * @brief This is used to return the read device type and revision information of the DW1000 device (MP part is 0xDECA0130)
1246
 *
1247
 * input parameters
1248
 *
1249
 * output parameters
1250
 *
1251
 * returns the read value which for DW1000 is 0xDECA0130
1252
 */
1253
uint32_t dwt_readdevid(void)
1254
{
1255
    return dwt_read32bitoffsetreg(DEV_ID_ID,0);
1256
}
1257

    
1258
/*! ------------------------------------------------------------------------------------------------------------------
1259
 * @fn dwt_configuretxrf()
1260
 *
1261
 * @brief This function provides the API for the configuration of the TX spectrum
1262
 * including the power and pulse generator delay. The input is a pointer to the data structure
1263
 * of type dwt_txconfig_t that holds all the configurable items.
1264
 *
1265
 * input parameters
1266
 * @param config    -   pointer to the txrf configuration structure, which contains the tx rf config data
1267
 *
1268
 * output parameters
1269
 *
1270
 * no return value
1271
 */
1272
void dwt_configuretxrf(dwt_txconfig_t* config)
1273
{
1274

    
1275
    // Configure RF TX PG_DELAY
1276
    dwt_write8bitoffsetreg(TX_CAL_ID, TC_PGDELAY_OFFSET, config->PGdly);
1277

    
1278
    // Configure TX power
1279
    dwt_write32bitreg(TX_POWER_ID, config->power);
1280

    
1281
}
1282

    
1283
/*! ------------------------------------------------------------------------------------------------------------------
1284
 * @fn dwt_configure()
1285
 *
1286
 * @brief This function provides the main API for the configuration of the
1287
 * DW1000 and this low-level driver.  The input is a pointer to the data structure
1288
 * of type dwt_config_t that holds all the configurable items.
1289
 * The dwt_config_t structure shows which ones are supported
1290
 *
1291
 * input parameters
1292
 * @param config    -   pointer to the configuration structure, which contains the device configuration data.
1293
 *
1294
 * output parameters
1295
 *
1296
 * no return value
1297
 */
1298
void dwt_configure(dwt_config_t *config)
1299
{
1300
    uint8_t nsSfd_result  = 0;
1301
    uint8_t useDWnsSFD = 0;
1302
    uint8_t chan = config->chan ;
1303
    uint32_t regval ;
1304
    uint16_t reg16 = lde_replicaCoeff[config->rxCode];
1305
    uint8_t prfIndex = config->prf - DWT_PRF_16M;
1306
    uint8_t bw = ((chan == 4) || (chan == 7)) ? 1 : 0 ; // Select wide or narrow band
1307

    
1308
#ifdef DWT_API_ERROR_CHECK
1309
    assert(config->dataRate <= DWT_BR_6M8);
1310
    assert(config->rxPAC <= DWT_PAC64);
1311
    assert((chan >= 1) && (chan <= 7) && (chan != 6));
1312
    assert(((config->prf == DWT_PRF_64M) && (config->txCode >= 9) && (config->txCode <= 24))
1313
           || ((config->prf == DWT_PRF_16M) && (config->txCode >= 1) && (config->txCode <= 8)));
1314
    assert(((config->prf == DWT_PRF_64M) && (config->rxCode >= 9) && (config->rxCode <= 24))
1315
           || ((config->prf == DWT_PRF_16M) && (config->rxCode >= 1) && (config->rxCode <= 8)));
1316
    assert((config->txPreambLength == DWT_PLEN_64) || (config->txPreambLength == DWT_PLEN_128) || (config->txPreambLength == DWT_PLEN_256)
1317
           || (config->txPreambLength == DWT_PLEN_512) || (config->txPreambLength == DWT_PLEN_1024) || (config->txPreambLength == DWT_PLEN_1536)
1318
           || (config->txPreambLength == DWT_PLEN_2048) || (config->txPreambLength == DWT_PLEN_4096));
1319
    assert((config->phrMode == DWT_PHRMODE_STD) || (config->phrMode == DWT_PHRMODE_EXT));
1320
#endif
1321

    
1322
    // For 110 kbps we need a special setup
1323
    if(DWT_BR_110K == config->dataRate)
1324
    {
1325
        pdw1000local->sysCFGreg |= SYS_CFG_RXM110K ;
1326
        reg16 >>= 3; // lde_replicaCoeff must be divided by 8
1327
    }
1328
    else
1329
    {
1330
        pdw1000local->sysCFGreg &= (~SYS_CFG_RXM110K) ;
1331
    }
1332

    
1333
    pdw1000local->longFrames = config->phrMode ;
1334

    
1335
    pdw1000local->sysCFGreg &= ~SYS_CFG_PHR_MODE_11;
1336
    pdw1000local->sysCFGreg |= (SYS_CFG_PHR_MODE_11 & (uint32_t)(config->phrMode << SYS_CFG_PHR_MODE_SHFT));
1337

    
1338
    dwt_write32bitreg(SYS_CFG_ID,pdw1000local->sysCFGreg) ;
1339
    // Set the lde_replicaCoeff
1340
    dwt_write16bitoffsetreg(LDE_IF_ID, LDE_REPC_OFFSET, reg16) ;
1341

    
1342
    _dwt_configlde(prfIndex);
1343

    
1344
    // Configure PLL2/RF PLL block CFG/TUNE (for a given channel)
1345
    dwt_write32bitoffsetreg(FS_CTRL_ID, FS_PLLCFG_OFFSET, fs_pll_cfg[chan_idx[chan]]);
1346
    dwt_write8bitoffsetreg(FS_CTRL_ID, FS_PLLTUNE_OFFSET, fs_pll_tune[chan_idx[chan]]);
1347

    
1348
    // Configure RF RX blocks (for specified channel/bandwidth)
1349
    dwt_write8bitoffsetreg(RF_CONF_ID, RF_RXCTRLH_OFFSET, rx_config[bw]);
1350

    
1351
    // Configure RF TX blocks (for specified channel and PRF)
1352
    // Configure RF TX control
1353
    dwt_write32bitoffsetreg(RF_CONF_ID, RF_TXCTRL_OFFSET, tx_config[chan_idx[chan]]);
1354

    
1355
    // Configure the baseband parameters (for specified PRF, bit rate, PAC, and SFD settings)
1356
    // DTUNE0
1357
    dwt_write16bitoffsetreg(DRX_CONF_ID, DRX_TUNE0b_OFFSET, sftsh[config->dataRate][config->nsSFD]);
1358

    
1359
    // DTUNE1
1360
    dwt_write16bitoffsetreg(DRX_CONF_ID, DRX_TUNE1a_OFFSET, dtune1[prfIndex]);
1361

    
1362
    if(config->dataRate == DWT_BR_110K)
1363
    {
1364
        dwt_write16bitoffsetreg(DRX_CONF_ID, DRX_TUNE1b_OFFSET, DRX_TUNE1b_110K);
1365
    }
1366
    else
1367
    {
1368
        if(config->txPreambLength == DWT_PLEN_64)
1369
        {
1370
            dwt_write16bitoffsetreg(DRX_CONF_ID, DRX_TUNE1b_OFFSET, DRX_TUNE1b_6M8_PRE64);
1371
            dwt_write8bitoffsetreg(DRX_CONF_ID, DRX_TUNE4H_OFFSET, DRX_TUNE4H_PRE64);
1372
        }
1373
        else
1374
        {
1375
            dwt_write16bitoffsetreg(DRX_CONF_ID, DRX_TUNE1b_OFFSET, DRX_TUNE1b_850K_6M8);
1376
            dwt_write8bitoffsetreg(DRX_CONF_ID, DRX_TUNE4H_OFFSET, DRX_TUNE4H_PRE128PLUS);
1377
        }
1378
    }
1379

    
1380
    // DTUNE2
1381
    dwt_write32bitoffsetreg(DRX_CONF_ID, DRX_TUNE2_OFFSET, digital_bb_config[prfIndex][config->rxPAC]);
1382

    
1383
    // DTUNE3 (SFD timeout)
1384
    // Don't allow 0 - SFD timeout will always be enabled
1385
    if(config->sfdTO == 0)
1386
    {
1387
        config->sfdTO = DWT_SFDTOC_DEF;
1388
    }
1389
    dwt_write16bitoffsetreg(DRX_CONF_ID, DRX_SFDTOC_OFFSET, config->sfdTO);
1390

    
1391
    // Configure AGC parameters
1392
    dwt_write32bitoffsetreg( AGC_CFG_STS_ID, 0xC, agc_config.lo32);
1393
    dwt_write16bitoffsetreg( AGC_CFG_STS_ID, 0x4, agc_config.target[prfIndex]);
1394

    
1395
    // Set (non-standard) user SFD for improved performance,
1396
    if(config->nsSFD)
1397
    {
1398
        // Write non standard (DW) SFD length
1399
        dwt_write8bitoffsetreg(USR_SFD_ID, 0x00, dwnsSFDlen[config->dataRate]);
1400
        nsSfd_result = 3 ;
1401
        useDWnsSFD = 1 ;
1402
    }
1403
    regval =  (CHAN_CTRL_TX_CHAN_MASK & (uint32_t)(chan << CHAN_CTRL_TX_CHAN_SHIFT)) | // Transmit Channel
1404
              (CHAN_CTRL_RX_CHAN_MASK & (uint32_t)(chan << CHAN_CTRL_RX_CHAN_SHIFT)) | // Receive Channel
1405
              (CHAN_CTRL_RXFPRF_MASK & (uint32_t)(config->prf << CHAN_CTRL_RXFPRF_SHIFT)) | // RX PRF
1406
              ((CHAN_CTRL_TNSSFD|CHAN_CTRL_RNSSFD) & (uint32_t)(nsSfd_result << CHAN_CTRL_TNSSFD_SHIFT)) | // nsSFD enable RX&TX
1407
              (CHAN_CTRL_DWSFD & (uint32_t)(useDWnsSFD << CHAN_CTRL_DWSFD_SHIFT)) | // Use DW nsSFD
1408
              (CHAN_CTRL_TX_PCOD_MASK & (uint32_t)(config->txCode << CHAN_CTRL_TX_PCOD_SHIFT)) | // TX Preamble Code
1409
              (CHAN_CTRL_RX_PCOD_MASK & (uint32_t)(config->rxCode << CHAN_CTRL_RX_PCOD_SHIFT)) ; // RX Preamble Code
1410

    
1411
    dwt_write32bitreg(CHAN_CTRL_ID,regval) ;
1412

    
1413
    // Set up TX Preamble Size, PRF and Data Rate
1414
    pdw1000local->txFCTRL = (uint32_t)(((config->txPreambLength | config->prf) << TX_FCTRL_TXPRF_SHFT) | (config->dataRate << TX_FCTRL_TXBR_SHFT));
1415
    dwt_write32bitreg(TX_FCTRL_ID, pdw1000local->txFCTRL);
1416

    
1417
    // The SFD transmit pattern is initialised by the DW1000 upon a user TX request, but (due to an IC issue) it is not done for an auto-ACK TX. The
1418
    // SYS_CTRL write below works around this issue, by simultaneously initiating and aborting a transmission, which correctly initialises the SFD
1419
    // after its configuration or reconfiguration.
1420
    // This issue is not documented at the time of writing this code. It should be in next release of DW1000 User Manual (v2.09, from July 2016).
1421
    dwt_write8bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_OFFSET, SYS_CTRL_TXSTRT | SYS_CTRL_TRXOFF); // Request TX start and TRX off at the same time
1422
} // end dwt_configure()
1423

    
1424
/*! ------------------------------------------------------------------------------------------------------------------
1425
 * @fn dwt_setrxantennadelay()
1426
 *
1427
 * @brief This API function writes the antenna delay (in time units) to RX registers
1428
 *
1429
 * input parameters:
1430
 * @param rxDelay - this is the total (RX) antenna delay value, which
1431
 *                          will be programmed into the RX register
1432
 *
1433
 * output parameters
1434
 *
1435
 * no return value
1436
 */
1437
void dwt_setrxantennadelay(uint16_t rxDelay)
1438
{
1439
    // Set the RX antenna delay for auto TX timestamp adjustment
1440
    dwt_write16bitoffsetreg(LDE_IF_ID, LDE_RXANTD_OFFSET, rxDelay);
1441
}
1442

    
1443
/*! ------------------------------------------------------------------------------------------------------------------
1444
 * @fn dwt_settxantennadelay()
1445
 *
1446
 * @brief This API function writes the antenna delay (in time units) to TX registers
1447
 *
1448
 * input parameters:
1449
 * @param txDelay - this is the total (TX) antenna delay value, which
1450
 *                          will be programmed into the TX delay register
1451
 *
1452
 * output parameters
1453
 *
1454
 * no return value
1455
 */
1456
void dwt_settxantennadelay(uint16_t txDelay)
1457
{
1458
    // Set the TX antenna delay for auto TX timestamp adjustment
1459
    dwt_write16bitoffsetreg(TX_ANTD_ID, TX_ANTD_OFFSET, txDelay);
1460
}
1461

    
1462
/*! ------------------------------------------------------------------------------------------------------------------
1463
 * @fn dwt_writetxdata()
1464
 *
1465
 * @brief This API function writes the supplied TX data into the DW1000's
1466
 * TX buffer.  The input parameters are the data length in bytes and a pointer
1467
 * to those data bytes.
1468
 *
1469
 * input parameters
1470
 * @param txFrameLength  - This is the total frame length, including the two byte CRC.
1471
 *                         Note: this is the length of TX message (including the 2 byte CRC) - max is 1023
1472
 *                         standard PHR mode allows up to 127 bytes
1473
 *                         if > 127 is programmed, DWT_PHRMODE_EXT needs to be set in the phrMode configuration
1474
 *                         see dwt_configure function
1475
 * @param txFrameBytes   - Pointer to the user’s buffer containing the data to send.
1476
 * @param txBufferOffset - This specifies an offset in the DW1000’s TX Buffer at which to start writing data.
1477
 *
1478
 * output parameters
1479
 *
1480
 * returns DWT_SUCCESS for success, or DWT_ERROR for error
1481
 */
1482
int dwt_writetxdata(uint16_t txFrameLength, uint8_t *txFrameBytes, uint16_t txBufferOffset)
1483
{
1484
#ifdef DWT_API_ERROR_CHECK
1485
    assert(txFrameLength >= 2);
1486
    assert((pdw1000local->longFrames && (txFrameLength <= 1023)) || (txFrameLength <= 127));
1487
    assert((txBufferOffset + txFrameLength) <= 1024);
1488
#endif
1489

    
1490
    if ((txBufferOffset + txFrameLength) <= 1024)
1491
    {
1492
        // Write the data to the IC TX buffer, (-2 bytes for auto generated CRC)
1493
        dwt_writetodevice( TX_BUFFER_ID, txBufferOffset, txFrameLength-2, txFrameBytes);
1494
        return DWT_SUCCESS;
1495
    }
1496
    else
1497
    {
1498
        return DWT_ERROR;
1499
    }
1500
} // end dwt_writetxdata()
1501

    
1502
/*! ------------------------------------------------------------------------------------------------------------------
1503
 * @fn dwt_writetxfctrl()
1504
 *
1505
 * @brief This API function configures the TX frame control register before the transmission of a frame
1506
 *
1507
 * input parameters:
1508
 * @param txFrameLength - this is the length of TX message (including the 2 byte CRC) - max is 1023
1509
 *                              NOTE: standard PHR mode allows up to 127 bytes
1510
 *                              if > 127 is programmed, DWT_PHRMODE_EXT needs to be set in the phrMode configuration
1511
 *                              see dwt_configure function
1512
 * @param txBufferOffset - the offset in the tx buffer to start writing the data
1513
 * @param ranging - 1 if this is a ranging frame, else 0
1514
 *
1515
 * output parameters
1516
 *
1517
 * no return value
1518
 */
1519
void dwt_writetxfctrl(uint16_t txFrameLength, uint16_t txBufferOffset, int ranging)
1520
{
1521

    
1522
#ifdef DWT_API_ERROR_CHECK
1523
    assert((pdw1000local->longFrames && (txFrameLength <= 1023)) || (txFrameLength <= 127));
1524
#endif
1525

    
1526
    // Write the frame length to the TX frame control register
1527
    // pdw1000local->txFCTRL has kept configured bit rate information
1528
    uint32_t reg32 = pdw1000local->txFCTRL | txFrameLength | (uint16_t)(txBufferOffset << TX_FCTRL_TXBOFFS_SHFT) | (uint16_t)(ranging << TX_FCTRL_TR_SHFT);
1529
    dwt_write32bitreg(TX_FCTRL_ID, reg32);
1530
} // end dwt_writetxfctrl()
1531

    
1532

    
1533
/*! ------------------------------------------------------------------------------------------------------------------
1534
 * @fn dwt_readrxdata()
1535
 *
1536
 * @brief This is used to read the data from the RX buffer, from an offset location give by offset parameter
1537
 *
1538
 * input parameters
1539
 * @param buffer - the buffer into which the data will be read
1540
 * @param length - the length of data to read (in bytes)
1541
 * @param rxBufferOffset - the offset in the rx buffer from which to read the data
1542
 *
1543
 * output parameters
1544
 *
1545
 * no return value
1546
 */
1547
void dwt_readrxdata(uint8_t *buffer, uint16_t length, uint16_t rxBufferOffset)
1548
{
1549
    dwt_readfromdevice(RX_BUFFER_ID,rxBufferOffset,length,buffer) ;
1550
}
1551

    
1552
/*! ------------------------------------------------------------------------------------------------------------------
1553
 * @fn dwt_readaccdata()
1554
 *
1555
 * @brief This is used to read the data from the Accumulator buffer, from an offset location give by offset parameter
1556
 *
1557
 * NOTE: Because of an internal memory access delay when reading the accumulator the first octet output is a dummy octet
1558
 *       that should be discarded. This is true no matter what sub-index the read begins at.
1559
 *
1560
 * input parameters
1561
 * @param buffer - the buffer into which the data will be read
1562
 * @param length - the length of data to read (in bytes)
1563
 * @param accOffset - the offset in the acc buffer from which to read the data
1564
 *
1565
 * output parameters
1566
 *
1567
 * no return value
1568
 */
1569
void dwt_readaccdata(uint8_t *buffer, uint16_t len, uint16_t accOffset)
1570
{
1571
    // Force on the ACC clocks if we are sequenced
1572
    _dwt_enableclocks(READ_ACC_ON);
1573

    
1574
    dwt_readfromdevice(ACC_MEM_ID,accOffset,len,buffer) ;
1575

    
1576
    _dwt_enableclocks(READ_ACC_OFF); // Revert clocks back
1577
}
1578

    
1579
/*! ------------------------------------------------------------------------------------------------------------------
1580
 * @fn dwt_readdiagnostics()
1581
 *
1582
 * @brief this function reads the RX signal quality diagnostic data
1583
 *
1584
 * input parameters
1585
 * @param diagnostics - diagnostic structure pointer, this will contain the diagnostic data read from the DW1000
1586
 *
1587
 * output parameters
1588
 *
1589
 * no return value
1590
 */
1591
void dwt_readdiagnostics(dwt_rxdiag_t *diagnostics)
1592
{
1593
    // Read the HW FP index
1594
    diagnostics->firstPath = dwt_read16bitoffsetreg(RX_TIME_ID, RX_TIME_FP_INDEX_OFFSET);
1595

    
1596
    // LDE diagnostic data
1597
    diagnostics->maxNoise = dwt_read16bitoffsetreg(LDE_IF_ID, LDE_THRESH_OFFSET);
1598

    
1599
    // Read all 8 bytes in one SPI transaction
1600
    dwt_readfromdevice(RX_FQUAL_ID, 0x0, 8, (uint8_t*)&diagnostics->stdNoise);
1601

    
1602
    diagnostics->firstPathAmp1 = dwt_read16bitoffsetreg(RX_TIME_ID, RX_TIME_FP_AMPL1_OFFSET);
1603

    
1604
    diagnostics->rxPreamCount = (dwt_read32bitreg(RX_FINFO_ID) & RX_FINFO_RXPACC_MASK) >> RX_FINFO_RXPACC_SHIFT  ;
1605
}
1606

    
1607
/*! ------------------------------------------------------------------------------------------------------------------
1608
 * @fn dwt_readtxtimestamp()
1609
 *
1610
 * @brief This is used to read the TX timestamp (adjusted with the programmed antenna delay)
1611
 *
1612
 * input parameters
1613
 * @param timestamp - a pointer to a 5-byte buffer which will store the read TX timestamp time
1614
 *
1615
 * output parameters - the timestamp buffer will contain the value after the function call
1616
 *
1617
 * no return value
1618
 */
1619
void dwt_readtxtimestamp(uint8_t * timestamp)
1620
{
1621
    dwt_readfromdevice(TX_TIME_ID, TX_TIME_TX_STAMP_OFFSET, TX_TIME_TX_STAMP_LEN, timestamp) ; // Read bytes directly into buffer
1622
}
1623

    
1624
/*! ------------------------------------------------------------------------------------------------------------------
1625
 * @fn dwt_readtxtimestamphi32()
1626
 *
1627
 * @brief This is used to read the high 32-bits of the TX timestamp (adjusted with the programmed antenna delay)
1628
 *
1629
 * input parameters
1630
 *
1631
 * output parameters
1632
 *
1633
 * returns high 32-bits of TX timestamp
1634
 */
1635
uint32_t dwt_readtxtimestamphi32(void)
1636
{
1637
    return dwt_read32bitoffsetreg(TX_TIME_ID, 1); // Offset is 1 to get the 4 upper bytes out of 5
1638
}
1639

    
1640
/*! ------------------------------------------------------------------------------------------------------------------
1641
 * @fn dwt_readtxtimestamplo32()
1642
 *
1643
 * @brief This is used to read the low 32-bits of the TX timestamp (adjusted with the programmed antenna delay)
1644
 *
1645
 * input parameters
1646
 *
1647
 * output parameters
1648
 *
1649
 * returns low 32-bits of TX timestamp
1650
 */
1651
uint32_t dwt_readtxtimestamplo32(void)
1652
{
1653
    return dwt_read32bitreg(TX_TIME_ID); // Read TX TIME as a 32-bit register to get the 4 lower bytes out of 5
1654
}
1655

    
1656
/*! ------------------------------------------------------------------------------------------------------------------
1657
 * @fn dwt_readrxtimestamp()
1658
 *
1659
 * @brief This is used to read the RX timestamp (adjusted time of arrival)
1660
 *
1661
 * input parameters
1662
 * @param timestamp - a pointer to a 5-byte buffer which will store the read RX timestamp time
1663
 *
1664
 * output parameters - the timestamp buffer will contain the value after the function call
1665
 *
1666
 * no return value
1667
 */
1668
void dwt_readrxtimestamp(uint8_t * timestamp)
1669
{
1670
    dwt_readfromdevice(RX_TIME_ID, RX_TIME_RX_STAMP_OFFSET, RX_TIME_RX_STAMP_LEN, timestamp) ; // Get the adjusted time of arrival
1671
}
1672

    
1673
/*! ------------------------------------------------------------------------------------------------------------------
1674
 * @fn dwt_readrxtimestamphi32()
1675
 *
1676
 * @brief This is used to read the high 32-bits of the RX timestamp (adjusted with the programmed antenna delay)
1677
 *
1678
 * input parameters
1679
 *
1680
 * output parameters
1681
 *
1682
 * returns high 32-bits of RX timestamp
1683
 */
1684
uint32_t dwt_readrxtimestamphi32(void)
1685
{
1686
    return dwt_read32bitoffsetreg(RX_TIME_ID, 1); // Offset is 1 to get the 4 upper bytes out of 5
1687
}
1688

    
1689
/*! ------------------------------------------------------------------------------------------------------------------
1690
 * @fn dwt_readrxtimestamplo32()
1691
 *
1692
 * @brief This is used to read the low 32-bits of the RX timestamp (adjusted with the programmed antenna delay)
1693
 *
1694
 * input parameters
1695
 *
1696
 * output parameters
1697
 *
1698
 * returns low 32-bits of RX timestamp
1699
 */
1700
uint32_t dwt_readrxtimestamplo32(void)
1701
{
1702
    return dwt_read32bitreg(RX_TIME_ID); // Read RX TIME as a 32-bit register to get the 4 lower bytes out of 5
1703
}
1704

    
1705
/*! ------------------------------------------------------------------------------------------------------------------
1706
 * @fn dwt_readsystimestamphi32()
1707
 *
1708
 * @brief This is used to read the high 32-bits of the system time
1709
 *
1710
 * input parameters
1711
 *
1712
 * output parameters
1713
 *
1714
 * returns high 32-bits of system time timestamp
1715
 */
1716
uint32_t dwt_readsystimestamphi32(void)
1717
{
1718
    return dwt_read32bitoffsetreg(SYS_TIME_ID, 1); // Offset is 1 to get the 4 upper bytes out of 5
1719
}
1720

    
1721
/*! ------------------------------------------------------------------------------------------------------------------
1722
 * @fn dwt_readsystime()
1723
 *
1724
 * @brief This is used to read the system time
1725
 *
1726
 * input parameters
1727
 * @param timestamp - a pointer to a 5-byte buffer which will store the read system time
1728
 *
1729
 * output parameters
1730
 * @param timestamp - the timestamp buffer will contain the value after the function call
1731
 *
1732
 * no return value
1733
 */
1734
void dwt_readsystime(uint8_t * timestamp)
1735
{
1736
    dwt_readfromdevice(SYS_TIME_ID, SYS_TIME_OFFSET, SYS_TIME_LEN, timestamp) ;
1737
}
1738

    
1739
/*! ------------------------------------------------------------------------------------------------------------------
1740
 * @fn dwt_writetodevice()
1741
 *
1742
 * @brief  this function is used to write to the DW1000 device registers
1743
 * Notes:
1744
 *        1. Firstly we create a header (the first byte is a header byte)
1745
 *        a. check if sub index is used, if subindexing is used - set bit-6 to 1 to signify that the sub-index address follows the register index byte
1746
 *        b. set bit-7 (or with 0x80) for write operation
1747
 *        c. if extended sub address index is used (i.e. if index > 127) set bit-7 of the first sub-index byte following the first header byte
1748
 *
1749
 *        2. Write the header followed by the data bytes to the DW1000 device
1750
 *
1751
 *
1752
 * input parameters:
1753
 * @param recordNumber  - ID of register file or buffer being accessed
1754
 * @param index         - byte index into register file or buffer being accessed
1755
 * @param length        - number of bytes being written
1756
 * @param buffer        - pointer to buffer containing the 'length' bytes to be written
1757
 *
1758
 * output parameters
1759
 *
1760
 * no return value
1761
 */
1762
void dwt_writetodevice
1763
(
1764
    uint16_t      recordNumber,
1765
    uint16_t      index,
1766
    uint32_t      length,
1767
    const uint8_t *buffer
1768
)
1769
{
1770
    uint8_t header[3] ; // Buffer to compose header in
1771
    int   cnt = 0; // Counter for length of header
1772
#ifdef DWT_API_ERROR_CHECK
1773
    assert(recordNumber <= 0x3F); // Record number is limited to 6-bits.
1774
#endif
1775

    
1776
    // Write message header selecting WRITE operation and addresses as appropriate (this is one to three bytes long)
1777
    if (index == 0) // For index of 0, no sub-index is required
1778
    {
1779
        header[cnt++] = 0x80 | (uint8_t)recordNumber ; // Bit-7 is WRITE operation, bit-6 zero=NO sub-addressing, bits 5-0 is reg file id
1780
    }
1781
    else
1782
    {
1783
#ifdef DWT_API_ERROR_CHECK
1784
        assert((index <= 0x7FFF) && ((index + length) <= 0x7FFF)); // Index and sub-addressable area are limited to 15-bits.
1785
#endif
1786
        header[cnt++] = 0xC0 | (uint8_t)recordNumber ; // Bit-7 is WRITE operation, bit-6 one=sub-address follows, bits 5-0 is reg file id
1787

    
1788
        if (index <= 127) // For non-zero index < 127, just a single sub-index byte is required
1789
        {
1790
            header[cnt++] = (uint8_t)index ; // Bit-7 zero means no extension, bits 6-0 is index.
1791
        }
1792
        else
1793
        {
1794
            header[cnt++] = 0x80 | (uint8_t)(index) ; // Bit-7 one means extended index, bits 6-0 is low seven bits of index.
1795
            header[cnt++] =  (uint8_t) (index >> 7) ; // 8-bit value = high eight bits of index.
1796
        }
1797
    }
1798

    
1799
    // Write it to the SPI
1800
    writetospi((uint16_t)cnt,header,length,buffer);
1801
} // end dwt_writetodevice()
1802

    
1803
/*! ------------------------------------------------------------------------------------------------------------------
1804
 * @fn dwt_readfromdevice()
1805
 *
1806
 * @brief  this function is used to read from the DW1000 device registers
1807
 * Notes:
1808
 *        1. Firstly we create a header (the first byte is a header byte)
1809
 *        a. check if sub index is used, if subindexing is used - set bit-6 to 1 to signify that the sub-index address follows the register index byte
1810
 *        b. set bit-7 (or with 0x80) for write operation
1811
 *        c. if extended sub address index is used (i.e. if index > 127) set bit-7 of the first sub-index byte following the first header byte
1812
 *
1813
 *        2. Write the header followed by the data bytes to the DW1000 device
1814
 *        3. Store the read data in the input buffer
1815
 *
1816
 * input parameters:
1817
 * @param recordNumber  - ID of register file or buffer being accessed
1818
 * @param index         - byte index into register file or buffer being accessed
1819
 * @param length        - number of bytes being read
1820
 * @param buffer        - pointer to buffer in which to return the read data.
1821
 *
1822
 * output parameters
1823
 *
1824
 * no return value
1825
 */
1826
void dwt_readfromdevice
1827
(
1828
    uint16_t  recordNumber,
1829
    uint16_t  index,
1830
    uint32_t  length,
1831
    uint8_t   *buffer
1832
)
1833
{
1834
    uint8_t header[3] ; // Buffer to compose header in
1835
    int   cnt = 0; // Counter for length of header
1836
#ifdef DWT_API_ERROR_CHECK
1837
    assert(recordNumber <= 0x3F); // Record number is limited to 6-bits.
1838
#endif
1839

    
1840
    // Write message header selecting READ operation and addresses as appropriate (this is one to three bytes long)
1841
    if (index == 0) // For index of 0, no sub-index is required
1842
    {
1843
        header[cnt++] = (uint8_t) recordNumber ; // Bit-7 zero is READ operation, bit-6 zero=NO sub-addressing, bits 5-0 is reg file id
1844
    }
1845
    else
1846
    {
1847
#ifdef DWT_API_ERROR_CHECK
1848
        assert((index <= 0x7FFF) && ((index + length) <= 0x7FFF)); // Index and sub-addressable area are limited to 15-bits.
1849
#endif
1850
        header[cnt++] = (uint8_t)(0x40 | recordNumber) ; // Bit-7 zero is READ operation, bit-6 one=sub-address follows, bits 5-0 is reg file id
1851

    
1852
        if (index <= 127) // For non-zero index < 127, just a single sub-index byte is required
1853
        {
1854
            header[cnt++] = (uint8_t) index ; // Bit-7 zero means no extension, bits 6-0 is index.
1855
        }
1856
        else
1857
        {
1858
            header[cnt++] = 0x80 | (uint8_t)(index) ; // Bit-7 one means extended index, bits 6-0 is low seven bits of index.
1859
            header[cnt++] =  (uint8_t) (index >> 7) ; // 8-bit value = high eight bits of index.
1860
        }
1861
    }
1862

    
1863
    // Do the read from the SPI
1864
    readfromspi((uint16_t)cnt, header, length, buffer);
1865
} // end dwt_readfromdevice()
1866

    
1867

    
1868

    
1869
/*! ------------------------------------------------------------------------------------------------------------------
1870
 * @fn dwt_read32bitoffsetreg()
1871
 *
1872
 * @brief  this function is used to read 32-bit value from the DW1000 device registers
1873
 *
1874
 * input parameters:
1875
 * @param regFileID - ID of register file or buffer being accessed
1876
 * @param regOffset - the index into register file or buffer being accessed
1877
 *
1878
 * output parameters
1879
 *
1880
 * returns 32 bit register value
1881
 */
1882
uint32_t dwt_read32bitoffsetreg(int regFileID,int regOffset)
1883
{
1884
    uint32_t  regval = 0 ;
1885
    int     j ;
1886
    uint8_t   buffer[4] ;
1887

    
1888
    dwt_readfromdevice((uint16_t)regFileID, (uint16_t)regOffset,4,buffer); // Read 4 bytes (32-bits) register into buffer
1889

    
1890
    for (j = 3 ; j >= 0 ; j --)
1891
    {
1892
        regval = (regval << 8) + buffer[j] ;
1893
    }
1894
    return regval ;
1895

    
1896
} // end dwt_read32bitoffsetreg()
1897

    
1898
/*! ------------------------------------------------------------------------------------------------------------------
1899
 * @fn dwt_read16bitoffsetreg()
1900
 *
1901
 * @brief  this function is used to read 16-bit value from the DW1000 device registers
1902
 *
1903
 * input parameters:
1904
 * @param regFileID - ID of register file or buffer being accessed
1905
 * @param regOffset - the index into register file or buffer being accessed
1906
 *
1907
 * output parameters
1908
 *
1909
 * returns 16 bit register value
1910
 */
1911
uint16_t dwt_read16bitoffsetreg(int regFileID,int regOffset)
1912
{
1913
    uint16_t  regval = 0 ;
1914
    uint8_t   buffer[2] ;
1915

    
1916
    dwt_readfromdevice((uint16_t)regFileID, (uint16_t)regOffset,2,buffer); // Read 2 bytes (16-bits) register into buffer
1917

    
1918
    regval = (uint16_t)((buffer[1] << 8) + buffer[0] );
1919
    return regval ;
1920

    
1921
} // end dwt_read16bitoffsetreg()
1922

    
1923
/*! ------------------------------------------------------------------------------------------------------------------
1924
 * @fn dwt_read8bitoffsetreg()
1925
 *
1926
 * @brief  this function is used to read an 8-bit value from the DW1000 device registers
1927
 *
1928
 * input parameters:
1929
 * @param regFileID - ID of register file or buffer being accessed
1930
 * @param regOffset - the index into register file or buffer being accessed
1931
 *
1932
 * output parameters
1933
 *
1934
 * returns 8-bit register value
1935
 */
1936
uint8_t dwt_read8bitoffsetreg(int regFileID, int regOffset)
1937
{
1938
    uint8_t regval;
1939

    
1940
    dwt_readfromdevice((uint16_t)regFileID, (uint16_t)regOffset, 1, &regval);
1941

    
1942
    return regval ;
1943
}
1944

    
1945
/*! ------------------------------------------------------------------------------------------------------------------
1946
 * @fn dwt_write8bitoffsetreg()
1947
 *
1948
 * @brief  this function is used to write an 8-bit value to the DW1000 device registers
1949
 *
1950
 * input parameters:
1951
 * @param regFileID - ID of register file or buffer being accessed
1952
 * @param regOffset - the index into register file or buffer being accessed
1953
 * @param regval    - the value to write
1954
 *
1955
 * output parameters
1956
 *
1957
 * no return value
1958
 */
1959
void dwt_write8bitoffsetreg(int regFileID, int regOffset, uint8_t regval)
1960
{
1961
    dwt_writetodevice((uint16_t)regFileID, (uint16_t)regOffset, 1, &regval);
1962
}
1963

    
1964
/*! ------------------------------------------------------------------------------------------------------------------
1965
 * @fn dwt_write16bitoffsetreg()
1966
 *
1967
 * @brief  this function is used to write 16-bit value to the DW1000 device registers
1968
 *
1969
 * input parameters:
1970
 * @param regFileID - ID of register file or buffer being accessed
1971
 * @param regOffset - the index into register file or buffer being accessed
1972
 * @param regval    - the value to write
1973
 *
1974
 * output parameters
1975
 *
1976
 * no return value
1977
 */
1978
void dwt_write16bitoffsetreg(int regFileID,int regOffset,uint16_t regval)
1979
{
1980
    uint8_t   buffer[2] ;
1981

    
1982
    buffer[0] = regval & 0xFF;
1983
    buffer[1] = regval >> 8 ;
1984

    
1985
    dwt_writetodevice((uint16_t)regFileID, (uint16_t)regOffset,2,buffer);
1986
} // end dwt_write16bitoffsetreg()
1987

    
1988
/*! ------------------------------------------------------------------------------------------------------------------
1989
 * @fn dwt_write32bitoffsetreg()
1990
 *
1991
 * @brief  this function is used to write 32-bit value to the DW1000 device registers
1992
 *
1993
 * input parameters:
1994
 * @param regFileID - ID of register file or buffer being accessed
1995
 * @param regOffset - the index into register file or buffer being accessed
1996
 * @param regval    - the value to write
1997
 *
1998
 * output parameters
1999
 *
2000
 * no return value
2001
 */
2002
void dwt_write32bitoffsetreg(int regFileID,int regOffset,uint32_t regval)
2003
{
2004
    int     j ;
2005
    uint8_t   buffer[4] ;
2006

    
2007
    for ( j = 0 ; j < 4 ; j++ )
2008
    {
2009
        buffer[j] = regval & 0xff ;
2010
        regval >>= 8 ;
2011
    }
2012

    
2013
    dwt_writetodevice((uint16_t)regFileID,(uint16_t)regOffset,4,buffer);
2014
} // end dwt_write32bitoffsetreg()
2015

    
2016
/*! ------------------------------------------------------------------------------------------------------------------
2017
 * @fn dwt_enableframefilter()
2018
 *
2019
 * @brief This is used to enable the frame filtering - (the default option is to
2020
 * accept any data and ACK frames with correct destination address
2021
 *
2022
 * input parameters
2023
 * @param - bitmask - enables/disables the frame filtering options according to
2024
 *      DWT_FF_NOTYPE_EN        0x000   no frame types allowed
2025
 *      DWT_FF_COORD_EN         0x002   behave as coordinator (can receive frames with no destination address (PAN ID has to match))
2026
 *      DWT_FF_BEACON_EN        0x004   beacon frames allowed
2027
 *      DWT_FF_DATA_EN          0x008   data frames allowed
2028
 *      DWT_FF_ACK_EN           0x010   ack frames allowed
2029
 *      DWT_FF_MAC_EN           0x020   mac control frames allowed
2030
 *      DWT_FF_RSVD_EN          0x040   reserved frame types allowed
2031
 *
2032
 * output parameters
2033
 *
2034
 * no return value
2035
 */
2036
void dwt_enableframefilter(uint16_t enable)
2037
{
2038
    uint32_t sysconfig = SYS_CFG_MASK & dwt_read32bitreg(SYS_CFG_ID) ; // Read sysconfig register
2039

    
2040
    if(enable)
2041
    {
2042
        // Enable frame filtering and configure frame types
2043
        sysconfig &= ~(SYS_CFG_FF_ALL_EN); // Clear all
2044
        sysconfig |= (enable & SYS_CFG_FF_ALL_EN) | SYS_CFG_FFE;
2045
    }
2046
    else
2047
    {
2048
        sysconfig &= ~(SYS_CFG_FFE);
2049
    }
2050

    
2051
    pdw1000local->sysCFGreg = sysconfig ;
2052
    dwt_write32bitreg(SYS_CFG_ID,sysconfig) ;
2053
}
2054

    
2055
/*! ------------------------------------------------------------------------------------------------------------------
2056
 * @fn dwt_setpanid()
2057
 *
2058
 * @brief This is used to set the PAN ID
2059
 *
2060
 * input parameters
2061
 * @param panID - this is the PAN ID
2062
 *
2063
 * output parameters
2064
 *
2065
 * no return value
2066
 */
2067
void dwt_setpanid(uint16_t panID)
2068
{
2069
    // PAN ID is high 16 bits of register
2070
    dwt_write16bitoffsetreg(PANADR_ID, PANADR_PAN_ID_OFFSET, panID);
2071
}
2072

    
2073
/*! ------------------------------------------------------------------------------------------------------------------
2074
 * @fn dwt_setaddress16()
2075
 *
2076
 * @brief This is used to set 16-bit (short) address
2077
 *
2078
 * input parameters
2079
 * @param shortAddress - this sets the 16 bit short address
2080
 *
2081
 * output parameters
2082
 *
2083
 * no return value
2084
 */
2085
void dwt_setaddress16(uint16_t shortAddress)
2086
{
2087
    // Short address into low 16 bits
2088
    dwt_write16bitoffsetreg(PANADR_ID, PANADR_SHORT_ADDR_OFFSET, shortAddress);
2089
}
2090

    
2091
/*! ------------------------------------------------------------------------------------------------------------------
2092
 * @fn dwt_seteui()
2093
 *
2094
 * @brief This is used to set the EUI 64-bit (long) address
2095
 *
2096
 * input parameters
2097
 * @param eui64 - this is the pointer to a buffer that contains the 64bit address
2098
 *
2099
 * output parameters
2100
 *
2101
 * no return value
2102
 */
2103
void dwt_seteui(uint8_t *eui64)
2104
{
2105
    dwt_writetodevice(EUI_64_ID, EUI_64_OFFSET, EUI_64_LEN, eui64);
2106
}
2107

    
2108
/*! ------------------------------------------------------------------------------------------------------------------
2109
 * @fn dwt_geteui()
2110
 *
2111
 * @brief This is used to get the EUI 64-bit from the DW1000
2112
 *
2113
 * input parameters
2114
 * @param eui64 - this is the pointer to a buffer that will contain the read 64-bit EUI value
2115
 *
2116
 * output parameters
2117
 *
2118
 * no return value
2119
 */
2120
void dwt_geteui(uint8_t *eui64)
2121
{
2122
    dwt_readfromdevice(EUI_64_ID, EUI_64_OFFSET, EUI_64_LEN, eui64);
2123
}
2124

    
2125
/*! ------------------------------------------------------------------------------------------------------------------
2126
 * @fn dwt_otpread()
2127
 *
2128
 * @brief This is used to read the OTP data from given address into provided array
2129
 *
2130
 * input parameters
2131
 * @param address - this is the OTP address to read from
2132
 * @param array - this is the pointer to the array into which to read the data
2133
 * @param length - this is the number of 32 bit words to read (array needs to be at least this length)
2134
 *
2135
 * output parameters
2136
 *
2137
 * no return value
2138
 */
2139
void dwt_otpread(uint32_t address, uint32_t *array, uint8_t length)
2140
{
2141
    int i;
2142

    
2143
    _dwt_enableclocks(FORCE_SYS_XTI); // NOTE: Set system clock to XTAL - this is necessary to make sure the values read by _dwt_otpread are reliable
2144

    
2145
    for(i=0; i<length; i++)
2146
    {
2147
        array[i] = _dwt_otpread(address + (uint32_t)i) ;
2148
    }
2149

    
2150
    _dwt_enableclocks(ENABLE_ALL_SEQ); // Restore system clock to PLL
2151

    
2152
    return ;
2153
}
2154

    
2155
/*! ------------------------------------------------------------------------------------------------------------------
2156
 * @fn _dwt_otpread()
2157
 *
2158
 * @brief function to read the OTP memory. Ensure that MR,MRa,MRb are reset to 0.
2159
 *
2160
 * input parameters
2161
 * @param address - address to read at
2162
 *
2163
 * output parameters
2164
 *
2165
 * returns the 32bit of read data
2166
 */
2167
uint32_t _dwt_otpread(uint32_t address)
2168
{
2169
    uint32_t ret_data;
2170

    
2171
    // Write the address
2172
    dwt_write16bitoffsetreg(OTP_IF_ID, OTP_ADDR, (uint16_t)address);
2173

    
2174
    // Perform OTP Read - Manual read mode has to be set
2175
    dwt_write8bitoffsetreg(OTP_IF_ID, OTP_CTRL, OTP_CTRL_OTPREAD | OTP_CTRL_OTPRDEN);
2176
    dwt_write8bitoffsetreg(OTP_IF_ID, OTP_CTRL, 0x00); // OTPREAD is self clearing but OTPRDEN is not
2177

    
2178
    // Read read data, available 40ns after rising edge of OTP_READ
2179
    ret_data = dwt_read32bitoffsetreg(OTP_IF_ID, OTP_RDAT);
2180

    
2181
    // Return the 32bit of read data
2182
    return ret_data;
2183
}
2184

    
2185
/*! ------------------------------------------------------------------------------------------------------------------
2186
 * @fn _dwt_otpsetmrregs()
2187
 *
2188
 * @brief Configure the MR registers for initial programming (enable charge pump).
2189
 * Read margin is used to stress the read back from the
2190
 * programmed bit. In normal operation this is relaxed.
2191
 *
2192
 * input parameters
2193
 * @param mode - "0" : Reset all to 0x0:           MRA=0x0000, MRB=0x0000, MR=0x0000
2194
 *               "1" : Set for inital programming: MRA=0x9220, MRB=0x000E, MR=0x1024
2195
 *               "2" : Set for soak programming:   MRA=0x9220, MRB=0x0003, MR=0x1824
2196
 *               "3" : High Vpp:                   MRA=0x9220, MRB=0x004E, MR=0x1824
2197
 *               "4" : Low Read Margin:            MRA=0x0000, MRB=0x0003, MR=0x0000
2198
 *               "5" : Array Clean:                MRA=0x0049, MRB=0x0003, MR=0x0024
2199
 *               "4" : Very Low Read Margin:       MRA=0x0000, MRB=0x0003, MR=0x0000
2200
 *
2201
 * output parameters
2202
 *
2203
 * returns DWT_SUCCESS for success, or DWT_ERROR for error
2204
 */
2205
int32_t _dwt_otpsetmrregs(int mode)
2206
{
2207
    uint8_t rd_buf[4];
2208
    uint8_t wr_buf[4];
2209
    uint32_t mra=0,mrb=0,mr=0;
2210

    
2211
    // PROGRAMME MRA
2212
    // Set MRA, MODE_SEL
2213
    wr_buf[0] = 0x03;
2214
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL+1,1,wr_buf);
2215

    
2216
    // Load data
2217
    switch(mode&0x0f) {
2218
    case 0x0 :
2219
        mr =0x0000;
2220
        mra=0x0000;
2221
        mrb=0x0000;
2222
        break;
2223
    case 0x1 :
2224
        mr =0x1024;
2225
        mra=0x9220; // Enable CPP mon
2226
        mrb=0x000e;
2227
        break;
2228
    case 0x2 :
2229
        mr =0x1824;
2230
        mra=0x9220;
2231
        mrb=0x0003;
2232
        break;
2233
    case 0x3 :
2234
        mr =0x1824;
2235
        mra=0x9220;
2236
        mrb=0x004e;
2237
        break;
2238
    case 0x4 :
2239
        mr =0x0000;
2240
        mra=0x0000;
2241
        mrb=0x0003;
2242
        break;
2243
    case 0x5 :
2244
        mr =0x0024;
2245
        mra=0x0000;
2246
        mrb=0x0003;
2247
        break;
2248
    default :
2249
        return DWT_ERROR;
2250
    }
2251

    
2252
    wr_buf[0] = mra & 0x00ff;
2253
    wr_buf[1] = (mra & 0xff00)>>8;
2254
    dwt_writetodevice(OTP_IF_ID, OTP_WDAT,2,wr_buf);
2255

    
2256

    
2257
    // Set WRITE_MR
2258
    wr_buf[0] = 0x08;
2259
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2260

    
2261
    // Wait?
2262

    
2263
    // Set Clear Mode sel
2264
    wr_buf[0] = 0x02;
2265
    dwt_writetodevice(OTP_IF_ID,OTP_CTRL+1,1,wr_buf);
2266

    
2267
    // Set AUX update, write MR
2268
    wr_buf[0] = 0x88;
2269
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2270
    // Clear write MR
2271
    wr_buf[0] = 0x80;
2272
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2273
    // Clear AUX update
2274
    wr_buf[0] = 0x00;
2275
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2276

    
2277
    ///////////////////////////////////////////
2278
    // PROGRAM MRB
2279
    // Set SLOW, MRB, MODE_SEL
2280
    wr_buf[0] = 0x05;
2281
    dwt_writetodevice(OTP_IF_ID,OTP_CTRL+1,1,wr_buf);
2282

    
2283
    wr_buf[0] = mrb & 0x00ff;
2284
    wr_buf[1] = (mrb & 0xff00)>>8;
2285
    dwt_writetodevice(OTP_IF_ID, OTP_WDAT,2,wr_buf);
2286

    
2287
    // Set WRITE_MR
2288
    wr_buf[0] = 0x08;
2289
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2290

    
2291
    // Wait?
2292

    
2293
    // Set Clear Mode sel
2294
    wr_buf[0] = 0x04;
2295
    dwt_writetodevice(OTP_IF_ID,OTP_CTRL+1,1,wr_buf);
2296

    
2297
    // Set AUX update, write MR
2298
    wr_buf[0] = 0x88;
2299
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2300
    // Clear write MR
2301
    wr_buf[0] = 0x80;
2302
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2303
    // Clear AUX update
2304
    wr_buf[0] = 0x00;
2305
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2306

    
2307
    ///////////////////////////////////////////
2308
    // PROGRAM MR
2309
    // Set SLOW, MODE_SEL
2310
    wr_buf[0] = 0x01;
2311
    dwt_writetodevice(OTP_IF_ID,OTP_CTRL+1,1,wr_buf);
2312
    // Load data
2313

    
2314
    wr_buf[0] = mr & 0x00ff;
2315
    wr_buf[1] = (mr & 0xff00)>>8;
2316
    dwt_writetodevice(OTP_IF_ID, OTP_WDAT,2,wr_buf);
2317

    
2318
    // Set WRITE_MR
2319
    wr_buf[0] = 0x08;
2320
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2321

    
2322
    // Wait?
2323
    deca_sleep(10);
2324
    // Set Clear Mode sel
2325
    wr_buf[0] = 0x00;
2326
    dwt_writetodevice(OTP_IF_ID,OTP_CTRL+1,1,wr_buf);
2327

    
2328
    // Read confirm mode writes.
2329
    // Set man override, MRA_SEL
2330
    wr_buf[0] = OTP_CTRL_OTPRDEN;
2331
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2332
    wr_buf[0] = 0x02;
2333
    dwt_writetodevice(OTP_IF_ID,OTP_CTRL+1,1,wr_buf);
2334
    // MRB_SEL
2335
    wr_buf[0] = 0x04;
2336
    dwt_writetodevice(OTP_IF_ID,OTP_CTRL+1,1,wr_buf);
2337
    deca_sleep(100);
2338

    
2339
    // Clear mode sel
2340
    wr_buf[0] = 0x00;
2341
    dwt_writetodevice(OTP_IF_ID,OTP_CTRL+1,1,wr_buf);
2342
    // Clear MAN_OVERRIDE
2343
    wr_buf[0] = 0x00;
2344
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL,1,wr_buf);
2345

    
2346
    deca_sleep(10);
2347

    
2348
    if (((mode&0x0f) == 0x1)||((mode&0x0f) == 0x2))
2349
    {
2350
        // Read status register
2351
        dwt_readfromdevice(OTP_IF_ID, OTP_STAT,1,rd_buf);
2352
    }
2353

    
2354
    return DWT_SUCCESS;
2355
}
2356

    
2357
/*! ------------------------------------------------------------------------------------------------------------------
2358
 * @fn _dwt_otpprogword32()
2359
 *
2360
 * @brief function to program the OTP memory. Ensure that MR,MRa,MRb are reset to 0.
2361
 * VNM Charge pump needs to be enabled (see _dwt_otpsetmrregs)
2362
 * Note the address is only 11 bits long.
2363
 *
2364
 * input parameters
2365
 * @param address - address to read at
2366
 *
2367
 * output parameters
2368
 *
2369
 * returns DWT_SUCCESS for success, or DWT_ERROR for error
2370
 */
2371
int32_t _dwt_otpprogword32(uint32_t data, uint16_t address)
2372
{
2373
    uint8_t rd_buf[1];
2374
    uint8_t wr_buf[4];
2375
    uint8_t otp_done;
2376

    
2377
    // Read status register
2378
    dwt_readfromdevice(OTP_IF_ID, OTP_STAT, 1, rd_buf);
2379

    
2380
    if((rd_buf[0] & 0x02) != 0x02)
2381
    {
2382
        return DWT_ERROR;
2383
    }
2384

    
2385
    // Write the data
2386
    wr_buf[3] = (data>>24) & 0xff;
2387
    wr_buf[2] = (data>>16) & 0xff;
2388
    wr_buf[1] = (data>>8) & 0xff;
2389
    wr_buf[0] = data & 0xff;
2390
    dwt_writetodevice(OTP_IF_ID, OTP_WDAT, 4, wr_buf);
2391

    
2392
    // Write the address [10:0]
2393
    wr_buf[1] = (address>>8) & 0x07;
2394
    wr_buf[0] = address & 0xff;
2395
    dwt_writetodevice(OTP_IF_ID, OTP_ADDR, 2, wr_buf);
2396

    
2397
    // Enable Sequenced programming
2398
    wr_buf[0] = OTP_CTRL_OTPPROG;
2399
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL, 1, wr_buf);
2400
    wr_buf[0] = 0x00; // And clear
2401
    dwt_writetodevice(OTP_IF_ID, OTP_CTRL, 1, wr_buf);
2402

    
2403
    // WAIT for status to flag PRGM OK..
2404
    otp_done = 0;
2405
    while(otp_done == 0)
2406
    {
2407
        deca_sleep(1);
2408
        dwt_readfromdevice(OTP_IF_ID, OTP_STAT, 1, rd_buf);
2409

    
2410
        if((rd_buf[0] & 0x01) == 0x01)
2411
        {
2412
            otp_done = 1;
2413
        }
2414
    }
2415

    
2416
    return DWT_SUCCESS;
2417
}
2418

    
2419
/*! ------------------------------------------------------------------------------------------------------------------
2420
 * @fn dwt_otpwriteandverify()
2421
 *
2422
 * @brief This is used to program 32-bit value into the DW1000 OTP memory.
2423
 *
2424
 * input parameters
2425
 * @param value - this is the 32-bit value to be programmed into OTP
2426
 * @param address - this is the 16-bit OTP address into which the 32-bit value is programmed
2427
 *
2428
 * output parameters
2429
 *
2430
 * returns DWT_SUCCESS for success, or DWT_ERROR for error
2431
 */
2432
int dwt_otpwriteandverify(uint32_t value, uint16_t address)
2433
{
2434
    int prog_ok = DWT_SUCCESS;
2435
    int retry = 0;
2436
    // Firstly set the system clock to crystal
2437
    _dwt_enableclocks(FORCE_SYS_XTI); //set system clock to XTI
2438

    
2439
    //
2440
    //!!!!!!!!!!!!!! NOTE !!!!!!!!!!!!!!!!!!!!!
2441
    //Set the supply to 3.7V
2442
    //
2443

    
2444
    _dwt_otpsetmrregs(1); // Set mode for programming
2445

    
2446
    // For each value to program - the readback/check is done couple of times to verify it has programmed successfully
2447
    while(1)
2448
    {
2449
        _dwt_otpprogword32(value, address);
2450

    
2451
        if(_dwt_otpread(address) == value)
2452
        {
2453
            break;
2454
        }
2455
        retry++;
2456
        if(retry==5)
2457
        {
2458
            break;
2459
        }
2460
    }
2461

    
2462
    // Even if the above does not exit before retry reaches 5, the programming has probably been successful
2463

    
2464
    _dwt_otpsetmrregs(4); // Set mode for reading
2465

    
2466
    if(_dwt_otpread(address) != value) // If this does not pass please check voltage supply on VDDIO
2467
    {
2468
        prog_ok = DWT_ERROR;
2469
    }
2470

    
2471
    _dwt_otpsetmrregs(0); // Setting OTP mode register for low RM read - resetting the device would be alternative
2472

    
2473
    return prog_ok;
2474
}
2475

    
2476
/*! ------------------------------------------------------------------------------------------------------------------
2477
 * @fn _dwt_aonconfigupload()
2478
 *
2479
 * @brief This function uploads always on (AON) configuration, as set in the AON_CFG0_OFFSET register.
2480
 *
2481
 * input parameters
2482
 *
2483
 * output parameters
2484
 *
2485
 * no return value
2486
 */
2487
void _dwt_aonconfigupload(void)
2488
{
2489
    dwt_write8bitoffsetreg(AON_ID, AON_CTRL_OFFSET, AON_CTRL_UPL_CFG);
2490
    dwt_write8bitoffsetreg(AON_ID, AON_CTRL_OFFSET, 0x00); // Clear the register
2491
}
2492

    
2493
/*! ------------------------------------------------------------------------------------------------------------------
2494
 * @fn _dwt_aonarrayupload()
2495
 *
2496
 * @brief This function uploads always on (AON) data array and configuration. Thus if this function is used, then _dwt_aonconfigupload
2497
 * is not necessary. The DW1000 will go so SLEEP straight after this if the DWT_SLP_EN has been set.
2498
 *
2499
 * input parameters
2500
 *
2501
 * output parameters
2502
 *
2503
 * no return value
2504
 */
2505
void _dwt_aonarrayupload(void)
2506
{
2507
    dwt_write8bitoffsetreg(AON_ID, AON_CTRL_OFFSET, 0x00); // Clear the register
2508
    dwt_write8bitoffsetreg(AON_ID, AON_CTRL_OFFSET, AON_CTRL_SAVE);
2509
}
2510

    
2511
/*! ------------------------------------------------------------------------------------------------------------------
2512
 * @fn dwt_entersleep()
2513
 *
2514
 * @brief This function puts the device into deep sleep or sleep. dwt_configuresleep() should be called first
2515
 * to configure the sleep and on-wake/wake-up parameters
2516
 *
2517
 * input parameters
2518
 *
2519
 * output parameters
2520
 *
2521
 * no return value
2522
 */
2523
void dwt_entersleep(void)
2524
{
2525
    // Copy config to AON - upload the new configuration
2526
    _dwt_aonarrayupload();
2527
}
2528

    
2529
/*! ------------------------------------------------------------------------------------------------------------------
2530
 * @fn dwt_configuresleepcnt()
2531
 *
2532
 * @brief sets the sleep counter to new value, this function programs the high 16-bits of the 28-bit counter
2533
 *
2534
 * NOTE: this function needs to be run before dwt_configuresleep, also the SPI frequency has to be < 3MHz
2535
 *
2536
 * input parameters
2537
 * @param sleepcnt - this it value of the sleep counter to program
2538
 *
2539
 * output parameters
2540
 *
2541
 * no return value
2542
 */
2543
void dwt_configuresleepcnt(uint16_t sleepcnt)
2544
{
2545
    // Force system clock to crystal
2546
    _dwt_enableclocks(FORCE_SYS_XTI);
2547

    
2548
    // Reset sleep configuration to make sure we don't accidentally go to sleep
2549
    dwt_write8bitoffsetreg(AON_ID, AON_CFG0_OFFSET, 0x00); // NB: this write change the default LPCLKDIVA value which is not used anyway.
2550
    dwt_write8bitoffsetreg(AON_ID, AON_CFG1_OFFSET, 0x00);
2551

    
2552
    // Disable the sleep counter
2553
    _dwt_aonconfigupload();
2554

    
2555
    // Set new value
2556
    dwt_write16bitoffsetreg(AON_ID, AON_CFG0_OFFSET + AON_CFG0_SLEEP_TIM_OFFSET, sleepcnt);
2557
    _dwt_aonconfigupload();
2558

    
2559
    // Enable the sleep counter
2560
    dwt_write8bitoffsetreg(AON_ID, AON_CFG1_OFFSET, AON_CFG1_SLEEP_CEN);
2561
    _dwt_aonconfigupload();
2562

    
2563
    // Put system PLL back on
2564
    _dwt_enableclocks(ENABLE_ALL_SEQ);
2565
}
2566

    
2567

    
2568
/*! ------------------------------------------------------------------------------------------------------------------
2569
 * @fn dwt_calibratesleepcnt()
2570
 *
2571
 * @brief calibrates the local oscillator as its frequency can vary between 7 and 13kHz depending on temp and voltage
2572
 *
2573
 * NOTE: this function needs to be run before dwt_configuresleepcnt, so that we know what the counter units are
2574
 *
2575
 * input parameters
2576
 *
2577
 * output parameters
2578
 *
2579
 * returns the number of XTAL/2 cycles per low-power oscillator cycle. LP OSC frequency = 19.2 MHz/return value
2580
 */
2581
uint16_t dwt_calibratesleepcnt(void)
2582
{
2583
    uint16_t result;
2584

    
2585
    // Enable calibration of the sleep counter
2586
    dwt_write8bitoffsetreg(AON_ID, AON_CFG1_OFFSET, AON_CFG1_LPOSC_CAL);
2587
    _dwt_aonconfigupload();
2588

    
2589
    // Disable calibration of the sleep counter
2590
    dwt_write8bitoffsetreg(AON_ID, AON_CFG1_OFFSET, 0x00);
2591
    _dwt_aonconfigupload();
2592

    
2593
    // Force system clock to crystal
2594
    _dwt_enableclocks(FORCE_SYS_XTI);
2595

    
2596
    deca_sleep(1);
2597

    
2598
    // Read the number of XTAL/2 cycles one LP oscillator cycle took.
2599
    // Set up address - Read upper byte first
2600
    dwt_write8bitoffsetreg(AON_ID, AON_ADDR_OFFSET, AON_ADDR_LPOSC_CAL_1);
2601

    
2602
    // Enable manual override
2603
    dwt_write8bitoffsetreg(AON_ID, AON_CTRL_OFFSET, AON_CTRL_DCA_ENAB);
2604

    
2605
    // Read confirm data that was written
2606
    dwt_write8bitoffsetreg(AON_ID, AON_CTRL_OFFSET, AON_CTRL_DCA_ENAB | AON_CTRL_DCA_READ);
2607

    
2608
    // Read back byte from AON
2609
    result = dwt_read8bitoffsetreg(AON_ID, AON_RDAT_OFFSET);
2610
    result <<= 8;
2611

    
2612
    // Set up address - Read lower byte
2613
    dwt_write8bitoffsetreg(AON_ID, AON_ADDR_OFFSET, AON_ADDR_LPOSC_CAL_0);
2614

    
2615
    // Enable manual override
2616
    dwt_write8bitoffsetreg(AON_ID, AON_CTRL_OFFSET, AON_CTRL_DCA_ENAB);
2617

    
2618
    // Read confirm data that was written
2619
    dwt_write8bitoffsetreg(AON_ID, AON_CTRL_OFFSET, AON_CTRL_DCA_ENAB | AON_CTRL_DCA_READ);
2620

    
2621
    // Read back byte from AON
2622
    result |= dwt_read8bitoffsetreg(AON_ID, AON_RDAT_OFFSET);
2623

    
2624
    // Disable manual override
2625
    dwt_write8bitoffsetreg(AON_ID, AON_CTRL_OFFSET, 0x00);
2626

    
2627
    // Put system PLL back on
2628
    _dwt_enableclocks(ENABLE_ALL_SEQ);
2629

    
2630
    // Returns the number of XTAL/2 cycles per one LP OSC cycle
2631
    // This can be converted into LP OSC frequency by 19.2 MHz/result
2632
    return result;
2633
}
2634

    
2635
/*! ------------------------------------------------------------------------------------------------------------------
2636
 * @fn dwt_configuresleep()
2637
 *
2638
 * @brief configures the device for both DEEP_SLEEP and SLEEP modes, and on-wake mode
2639
 * i.e. before entering the sleep, the device should be programmed for TX or RX, then upon "waking up" the TX/RX settings
2640
 * will be preserved and the device can immediately perform the desired action TX/RX
2641
 *
2642
 * NOTE: e.g. Tag operation - after deep sleep, the device needs to just load the TX buffer and send the frame
2643
 *
2644
 *
2645
 *      mode: the array and LDE code (OTP/ROM) and LDO tune, and set sleep persist
2646
 *      DWT_PRESRV_SLEEP 0x0100 - preserve sleep
2647
 *      DWT_LOADOPSET    0x0080 - load operating parameter set on wakeup
2648
 *      DWT_CONFIG       0x0040 - download the AON array into the HIF (configuration download)
2649
 *      DWT_LOADEUI      0x0008
2650
 *      DWT_GOTORX       0x0002
2651
 *      DWT_TANDV        0x0001
2652
 *
2653
 *      wake: wake up parameters
2654
 *      DWT_XTAL_EN      0x10 - keep XTAL running during sleep
2655
 *      DWT_WAKE_SLPCNT  0x8 - wake up after sleep count
2656
 *      DWT_WAKE_CS      0x4 - wake up on chip select
2657
 *      DWT_WAKE_WK      0x2 - wake up on WAKEUP PIN
2658
 *      DWT_SLP_EN       0x1 - enable sleep/deep sleep functionality
2659
 *
2660
 * input parameters
2661
 * @param mode - config on-wake parameters
2662
 * @param wake - config wake up parameters
2663
 *
2664
 * output parameters
2665
 *
2666
 * no return value
2667
 */
2668
void dwt_configuresleep(uint16_t mode, uint8_t wake)
2669
{
2670
    // Add predefined sleep settings before writing the mode
2671
    mode |= pdw1000local->sleep_mode;
2672
    dwt_write16bitoffsetreg(AON_ID, AON_WCFG_OFFSET, mode);
2673

    
2674
    dwt_write8bitoffsetreg(AON_ID, AON_CFG0_OFFSET, wake);
2675
}
2676

    
2677
/*! ------------------------------------------------------------------------------------------------------------------
2678
 * @fn dwt_entersleepaftertx(int enable)
2679
 *
2680
 * @brief sets the auto TX to sleep bit. This means that after a frame
2681
 * transmission the device will enter deep sleep mode. The dwt_configuresleep() function
2682
 * needs to be called before this to configure the on-wake settings
2683
 *
2684
 * NOTE: the IRQ line has to be low/inactive (i.e. no pending events)
2685
 *
2686
 * input parameters
2687
 * @param enable - 1 to configure the device to enter deep sleep after TX, 0 - disables the configuration
2688
 *
2689
 * output parameters
2690
 *
2691
 * no return value
2692
 */
2693
void dwt_entersleepaftertx(int enable)
2694
{
2695
    uint32_t reg = dwt_read32bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET);
2696
    // Set the auto TX -> sleep bit
2697
    if(enable)
2698
    {
2699
        reg |= PMSC_CTRL1_ATXSLP;
2700
    }
2701
    else
2702
    {
2703
        reg &= ~(PMSC_CTRL1_ATXSLP);
2704
    }
2705
    dwt_write32bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET, reg);
2706
}
2707

    
2708

    
2709
/*! ------------------------------------------------------------------------------------------------------------------
2710
 * @fn dwt_spicswakeup()
2711
 *
2712
 * @brief wake up the device from sleep mode using the SPI read,
2713
 * the device will wake up on chip select line going low if the line is held low for at least 500us.
2714
 * To define the length depending on the time one wants to hold
2715
 * the chip select line low, use the following formula:
2716
 *
2717
 *      length (bytes) = time (s) * byte_rate (Hz)
2718
 *
2719
 * where fastest byte_rate is spi_rate (Hz) / 8 if the SPI is sending the bytes back-to-back.
2720
 * To save time and power, a system designer could determine byte_rate value more precisely.
2721
 *
2722
 * NOTE: Alternatively the device can be waken up with WAKE_UP pin if configured for that operation
2723
 *
2724
 * input parameters
2725
 * @param buff   - this is a pointer to the dummy buffer which will be used in the SPI read transaction used for the WAKE UP of the device
2726
 * @param length - this is the length of the dummy buffer
2727
 *
2728
 * output parameters
2729
 *
2730
 * returns DWT_SUCCESS for success, or DWT_ERROR for error
2731
 */
2732
int dwt_spicswakeup(uint8_t *buff, uint16_t length)
2733
{
2734
    if(dwt_readdevid() != DWT_DEVICE_ID) // Device was in deep sleep (the first read fails)
2735
    {
2736
        // Need to keep chip select line low for at least 500us
2737
        dwt_readfromdevice(0x0, 0x0, length, buff); // Do a long read to wake up the chip (hold the chip select low)
2738

    
2739
        // Need 5ms for XTAL to start and stabilise (could wait for PLL lock IRQ status bit !!!)
2740
        // NOTE: Polling of the STATUS register is not possible unless frequency is < 3MHz
2741
        deca_sleep(5);
2742
    }
2743
    else
2744
    {
2745
        return DWT_SUCCESS;
2746
    }
2747
    // DEBUG - check if still in sleep mode
2748
    if(dwt_readdevid() != DWT_DEVICE_ID)
2749
    {
2750
        return DWT_ERROR;
2751
    }
2752

    
2753
    return DWT_SUCCESS;
2754
}
2755

    
2756
/*! ------------------------------------------------------------------------------------------------------------------
2757
 * @fn _dwt_configlde()
2758
 *
2759
 * @brief configure LDE algorithm parameters
2760
 *
2761
 * input parameters
2762
 * @param prf   -   this is the PRF index (0 or 1) 0 corresponds to 16 and 1 to 64 PRF
2763
 *
2764
 * output parameters
2765
 *
2766
 * no return value
2767
 */
2768
void _dwt_configlde(int prfIndex)
2769
{
2770
    dwt_write8bitoffsetreg(LDE_IF_ID, LDE_CFG1_OFFSET, LDE_PARAM1); // 8-bit configuration register
2771

    
2772
    if(prfIndex)
2773
    {
2774
        dwt_write16bitoffsetreg( LDE_IF_ID, LDE_CFG2_OFFSET, (uint16_t) LDE_PARAM3_64); // 16-bit LDE configuration tuning register
2775
    }
2776
    else
2777
    {
2778
        dwt_write16bitoffsetreg( LDE_IF_ID, LDE_CFG2_OFFSET, (uint16_t) LDE_PARAM3_16);
2779
    }
2780
}
2781

    
2782

    
2783
/*! ------------------------------------------------------------------------------------------------------------------
2784
 * @fn _dwt_loaducodefromrom()
2785
 *
2786
 * @brief  load ucode from OTP MEMORY or ROM
2787
 *
2788
 * input parameters
2789
 *
2790
 * output parameters
2791
 *
2792
 * no return value
2793
 */
2794
void _dwt_loaducodefromrom(void)
2795
{
2796
    // Set up clocks
2797
    _dwt_enableclocks(FORCE_LDE);
2798

    
2799
    // Kick off the LDE load
2800
    dwt_write16bitoffsetreg(OTP_IF_ID, OTP_CTRL, OTP_CTRL_LDELOAD); // Set load LDE kick bit
2801

    
2802
    deca_sleep(1); // Allow time for code to upload (should take up to 120 us)
2803

    
2804
    // Default clocks (ENABLE_ALL_SEQ)
2805
    _dwt_enableclocks(ENABLE_ALL_SEQ); // Enable clocks for sequencing
2806
}
2807

    
2808
/*! ------------------------------------------------------------------------------------------------------------------
2809
 * @fn dwt_loadopsettabfromotp()
2810
 *
2811
 * @brief This is used to select which Operational Parameter Set table to load from OTP memory
2812
 *
2813
 * input parameters
2814
 * @param ops_sel - Operational Parameter Set table to load:
2815
 *                  DWT_OPSET_64LEN = 0x0 - load the operational parameter set table for 64 length preamble configuration
2816
 *                  DWT_OPSET_TIGHT = 0x1 - load the operational parameter set table for tight xtal offsets (<1ppm)
2817
 *                  DWT_OPSET_DEFLT = 0x2 - load the default operational parameter set table (this is loaded from reset)
2818
 *
2819
 * output parameters
2820
 *
2821
 * no return value
2822
 */
2823
void dwt_loadopsettabfromotp(uint8_t ops_sel)
2824
{
2825
    uint16_t reg = ((ops_sel << OTP_SF_OPS_SEL_SHFT) & OTP_SF_OPS_SEL_MASK) | OTP_SF_OPS_KICK; // Select defined OPS table and trigger its loading
2826

    
2827
    // Set up clocks
2828
    _dwt_enableclocks(FORCE_LDE);
2829

    
2830
    dwt_write16bitoffsetreg(OTP_IF_ID, OTP_SF, reg);
2831

    
2832
    // Default clocks (ENABLE_ALL_SEQ)
2833
    _dwt_enableclocks(ENABLE_ALL_SEQ); // Enable clocks for sequencing
2834

    
2835
}
2836

    
2837
/*! ------------------------------------------------------------------------------------------------------------------
2838
 * @fn dwt_setsmarttxpower()
2839
 *
2840
 * @brief This call enables or disables the smart TX power feature.
2841
 *
2842
 * input parameters
2843
 * @param enable - this enables or disables the TX smart power (1 = enable, 0 = disable)
2844
 *
2845
 * output parameters
2846
 *
2847
 * no return value
2848
 */
2849
void dwt_setsmarttxpower(int enable)
2850
{
2851
    // Config system register
2852
    pdw1000local->sysCFGreg = dwt_read32bitreg(SYS_CFG_ID) ; // Read sysconfig register
2853

    
2854
    // Disable smart power configuration
2855
    if(enable)
2856
    {
2857
        pdw1000local->sysCFGreg &= ~(SYS_CFG_DIS_STXP) ;
2858
    }
2859
    else
2860
    {
2861
        pdw1000local->sysCFGreg |= SYS_CFG_DIS_STXP ;
2862
    }
2863

    
2864
    dwt_write32bitreg(SYS_CFG_ID,pdw1000local->sysCFGreg) ;
2865
}
2866

    
2867

    
2868
/*! ------------------------------------------------------------------------------------------------------------------
2869
 * @fn dwt_enableautoack()
2870
 *
2871
 * @brief This call enables the auto-ACK feature. If the responseDelayTime (parameter) is 0, the ACK will be sent a.s.a.p.
2872
 * otherwise it will be sent with a programmed delay (in symbols), max is 255.
2873
 * NOTE: needs to have frame filtering enabled as well
2874
 *
2875
 * input parameters
2876
 * @param responseDelayTime - if non-zero the ACK is sent after this delay, max is 255.
2877
 *
2878
 * output parameters
2879
 *
2880
 * no return value
2881
 */
2882
void dwt_enableautoack(uint8_t responseDelayTime)
2883
{
2884
    // Set auto ACK reply delay
2885
    dwt_write8bitoffsetreg(ACK_RESP_T_ID, ACK_RESP_T_ACK_TIM_OFFSET, responseDelayTime); // In symbols
2886
    // Enable auto ACK
2887
    pdw1000local->sysCFGreg |= SYS_CFG_AUTOACK;
2888
    dwt_write32bitreg(SYS_CFG_ID,pdw1000local->sysCFGreg) ;
2889
}
2890

    
2891
/*! ------------------------------------------------------------------------------------------------------------------
2892
 * @fn dwt_setdblrxbuffmode()
2893
 *
2894
 * @brief This call enables the double receive buffer mode
2895
 *
2896
 * input parameters
2897
 * @param enable - 1 to enable, 0 to disable the double buffer mode
2898
 *
2899
 * output parameters
2900
 *
2901
 * no return value
2902
 */
2903
void dwt_setdblrxbuffmode(int enable)
2904
{
2905
    if(enable)
2906
    {
2907
        // Enable double RX buffer mode
2908
        pdw1000local->sysCFGreg &= ~SYS_CFG_DIS_DRXB;
2909
        pdw1000local->dblbuffon = 1;
2910
    }
2911
    else
2912
    {
2913
        // Disable double RX buffer mode
2914
        pdw1000local->sysCFGreg |= SYS_CFG_DIS_DRXB;
2915
        pdw1000local->dblbuffon = 0;
2916
    }
2917

    
2918
    dwt_write32bitreg(SYS_CFG_ID,pdw1000local->sysCFGreg) ;
2919
}
2920

    
2921
/*! ------------------------------------------------------------------------------------------------------------------
2922
 * @fn dwt_setrxaftertxdelay()
2923
 *
2924
 * @brief This sets the receiver turn on delay time after a transmission of a frame
2925
 *
2926
 * input parameters
2927
 * @param rxDelayTime - (20 bits) - the delay is in UWB microseconds
2928
 *
2929
 * output parameters
2930
 *
2931
 * no return value
2932
 */
2933
void dwt_setrxaftertxdelay(uint32_t rxDelayTime)
2934
{
2935
    uint32_t val = dwt_read32bitreg(ACK_RESP_T_ID) ; // Read ACK_RESP_T_ID register
2936

    
2937
    val &= ~(ACK_RESP_T_W4R_TIM_MASK) ; // Clear the timer (19:0)
2938

    
2939
    val |= (rxDelayTime & ACK_RESP_T_W4R_TIM_MASK) ; // In UWB microseconds (e.g. turn the receiver on 20uus after TX)
2940

    
2941
    dwt_write32bitreg(ACK_RESP_T_ID, val) ;
2942
}
2943

    
2944
/*! ------------------------------------------------------------------------------------------------------------------
2945
 * @fn dwt_setcallbacks()
2946
 *
2947
 * @brief This function is used to register the different callbacks called when one of the corresponding event occurs.
2948
 *
2949
 * NOTE: Callbacks can be undefined (set to NULL). In this case, dwt_isr() will process the event as usual but the 'null'
2950
 * callback will not be called.
2951
 *
2952
 * input parameters
2953
 * @param cbTxDone - the pointer to the TX confirmation event callback function
2954
 * @param cbRxOk - the pointer to the RX good frame event callback function
2955
 * @param cbRxTo - the pointer to the RX timeout events callback function
2956
 * @param cbRxErr - the pointer to the RX error events callback function
2957
 *
2958
 * output parameters
2959
 *
2960
 * no return value
2961
 */
2962
void dwt_setcallbacks(dwt_cb_t cbTxDone, dwt_cb_t cbRxOk, dwt_cb_t cbRxTo, dwt_cb_t cbRxErr)
2963
{
2964
    pdw1000local->cbTxDone = cbTxDone;
2965
    pdw1000local->cbRxOk = cbRxOk;
2966
    pdw1000local->cbRxTo = cbRxTo;
2967
    pdw1000local->cbRxErr = cbRxErr;
2968
}
2969

    
2970
/*! ------------------------------------------------------------------------------------------------------------------
2971
 * @fn dwt_checkirq()
2972
 *
2973
 * @brief This function checks if the IRQ line is active - this is used instead of interrupt handler
2974
 *
2975
 * input parameters
2976
 *
2977
 * output parameters
2978
 *
2979
 * return value is 1 if the IRQS bit is set and 0 otherwise
2980
 */
2981
uint8_t dwt_checkirq(void)
2982
{
2983
    return (dwt_read8bitoffsetreg(SYS_STATUS_ID, SYS_STATUS_OFFSET) & SYS_STATUS_IRQS); // Reading the lower byte only is enough for this operation
2984
}
2985

    
2986
/*! ------------------------------------------------------------------------------------------------------------------
2987
 * @fn dwt_isr()
2988
 *
2989
 * @brief This is the DW1000's general Interrupt Service Routine. It will process/report the following events:
2990
 *          - RXFCG (through cbRxOk callback)
2991
 *          - TXFRS (through cbTxDone callback)
2992
 *          - RXRFTO/RXPTO (through cbRxTo callback)
2993
 *          - RXPHE/RXFCE/RXRFSL/RXSFDTO/AFFREJ/LDEERR (through cbRxTo cbRxErr)
2994
 *        For all events, corresponding interrupts are cleared and necessary resets are performed. In addition, in the RXFCG case,
2995
 *        received frame information and frame control are read before calling the callback. If double buffering is activated, it
2996
 *        will also toggle between reception buffers once the reception callback processing has ended.
2997
 *
2998
 *        /!\ This version of the ISR supports double buffering but does not support automatic RX re-enabling!
2999
 *
3000
 * NOTE:  In PC based system using (Cheetah or ARM) USB to SPI converter there can be no interrupts, however we still need something
3001
 *        to take the place of it and operate in a polled way. In an embedded system this function should be configured to be triggered
3002
 *        on any of the interrupts described above.
3003

3004
 * input parameters
3005
 *
3006
 * output parameters
3007
 *
3008
 * no return value
3009
 */
3010
void dwt_isr(void)
3011
{
3012
    uint32_t status = pdw1000local->cbData.status = dwt_read32bitreg(SYS_STATUS_ID); // Read status register low 32bits
3013

    
3014
    // Handle RX good frame event
3015
    if(status & SYS_STATUS_RXFCG)
3016
    {
3017
        uint16_t finfo16;
3018
        uint16_t len;
3019

    
3020
        dwt_write32bitreg(SYS_STATUS_ID, SYS_STATUS_ALL_RX_GOOD); // Clear all receive status bits
3021

    
3022
        pdw1000local->cbData.rx_flags = 0;
3023

    
3024
        // Read frame info - Only the first two bytes of the register are used here.
3025
        finfo16 = dwt_read16bitoffsetreg(RX_FINFO_ID, RX_FINFO_OFFSET);
3026

    
3027
        // Report frame length - Standard frame length up to 127, extended frame length up to 1023 bytes
3028
        len = finfo16 & RX_FINFO_RXFL_MASK_1023;
3029
        if(pdw1000local->longFrames == 0)
3030
        {
3031
            len &= RX_FINFO_RXFLEN_MASK;
3032
        }
3033
        pdw1000local->cbData.datalength = len;
3034

    
3035
        // Report ranging bit
3036
        if(finfo16 & RX_FINFO_RNG)
3037
        {
3038
            pdw1000local->cbData.rx_flags |= DWT_CB_DATA_RX_FLAG_RNG;
3039
        }
3040

    
3041
        // Report frame control - First bytes of the received frame.
3042
        dwt_readfromdevice(RX_BUFFER_ID, 0, FCTRL_LEN_MAX, pdw1000local->cbData.fctrl);
3043

    
3044
        // Because of a previous frame not being received properly, AAT bit can be set upon the proper reception of a frame not requesting for
3045
        // acknowledgement (ACK frame is not actually sent though). If the AAT bit is set, check ACK request bit in frame control to confirm (this
3046
        // implementation works only for IEEE802.15.4-2011 compliant frames).
3047
        // This issue is not documented at the time of writing this code. It should be in next release of DW1000 User Manual (v2.09, from July 2016).
3048
        if((status & SYS_STATUS_AAT) && ((pdw1000local->cbData.fctrl[0] & FCTRL_ACK_REQ_MASK) == 0))
3049
        {
3050
            dwt_write32bitreg(SYS_STATUS_ID, SYS_STATUS_AAT); // Clear AAT status bit in register
3051
            pdw1000local->cbData.status &= ~SYS_STATUS_AAT; // Clear AAT status bit in callback data register copy
3052
            pdw1000local->wait4resp = 0;
3053
        }
3054

    
3055
        // Call the corresponding callback if present
3056
        if(pdw1000local->cbRxOk != NULL)
3057
        {
3058
            pdw1000local->cbRxOk(&pdw1000local->cbData);
3059
        }
3060

    
3061
        if (pdw1000local->dblbuffon)
3062
        {
3063
            // Toggle the Host side Receive Buffer Pointer
3064
            dwt_write8bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_HRBT_OFFSET, 1);
3065
        }
3066
    }
3067

    
3068
    // Handle TX confirmation event
3069
    if(status & SYS_STATUS_TXFRS)
3070
    {
3071
        dwt_write32bitreg(SYS_STATUS_ID, SYS_STATUS_ALL_TX); // Clear TX event bits
3072

    
3073
        // In the case where this TXFRS interrupt is due to the automatic transmission of an ACK solicited by a response (with ACK request bit set)
3074
        // that we receive through using wait4resp to a previous TX (and assuming that the IRQ processing of that TX has already been handled), then
3075
        // we need to handle the IC issue which turns on the RX again in this situation (i.e. because it is wrongly applying the wait4resp after the
3076
        // ACK TX).
3077
        // See section "Transmit and automatically wait for response" in DW1000 User Manual
3078
        if((status & SYS_STATUS_AAT) && pdw1000local->wait4resp)
3079
        {
3080
            dwt_forcetrxoff(); // Turn the RX off
3081
            dwt_rxreset(); // Reset in case we were late and a frame was already being received
3082
        }
3083

    
3084
        // Call the corresponding callback if present
3085
        if(pdw1000local->cbTxDone != NULL)
3086
        {
3087
            pdw1000local->cbTxDone(&pdw1000local->cbData);
3088
        }
3089
    }
3090

    
3091
    // Handle frame reception/preamble detect timeout events
3092
    if(status & SYS_STATUS_ALL_RX_TO)
3093
    {
3094
        dwt_write32bitreg(SYS_STATUS_ID, SYS_STATUS_RXRFTO); // Clear RX timeout event bits
3095

    
3096
        pdw1000local->wait4resp = 0;
3097

    
3098
        // Because of an issue with receiver restart after error conditions, an RX reset must be applied after any error or timeout event to ensure
3099
        // the next good frame's timestamp is computed correctly.
3100
        // See section "RX Message timestamp" in DW1000 User Manual.
3101
        dwt_forcetrxoff();
3102
        dwt_rxreset();
3103

    
3104
        // Call the corresponding callback if present
3105
        if(pdw1000local->cbRxTo != NULL)
3106
        {
3107
            pdw1000local->cbRxTo(&pdw1000local->cbData);
3108
        }
3109
    }
3110

    
3111
    // Handle RX errors events
3112
    if(status & SYS_STATUS_ALL_RX_ERR)
3113
    {
3114
        dwt_write32bitreg(SYS_STATUS_ID, SYS_STATUS_ALL_RX_ERR); // Clear RX error event bits
3115

    
3116
        pdw1000local->wait4resp = 0;
3117

    
3118
        // Because of an issue with receiver restart after error conditions, an RX reset must be applied after any error or timeout event to ensure
3119
        // the next good frame's timestamp is computed correctly.
3120
        // See section "RX Message timestamp" in DW1000 User Manual.
3121
        dwt_forcetrxoff();
3122
        dwt_rxreset();
3123

    
3124
        // Call the corresponding callback if present
3125
        if(pdw1000local->cbRxErr != NULL)
3126
        {
3127
            pdw1000local->cbRxErr(&pdw1000local->cbData);
3128
        }
3129
    }
3130
}
3131

    
3132
/*! ------------------------------------------------------------------------------------------------------------------
3133
 * @fn dwt_isr_lplisten()
3134
 *
3135
 * @brief This is the DW1000's Interrupt Service Routine to use when low-power listening scheme is implemented. It will
3136
 *        only process/report the RXFCG event (through cbRxOk callback).
3137
 *        It clears RXFCG interrupt and reads received frame information and frame control before calling the callback.
3138
 *
3139
 *        /!\ This version of the ISR is designed for single buffering case only!
3140
 *
3141
 * input parameters
3142
 *
3143
 * output parameters
3144
 *
3145
 * no return value
3146
 */
3147
void dwt_lowpowerlistenisr(void)
3148
{
3149
    uint32_t status = pdw1000local->cbData.status = dwt_read32bitreg(SYS_STATUS_ID); // Read status register low 32bits
3150
    uint16_t finfo16;
3151
    uint16_t len;
3152

    
3153
    // The only interrupt handled when in low-power listening mode is RX good frame so proceed directly to the handling of the received frame.
3154

    
3155
    // Deactivate low-power listening before clearing the interrupt. If not, the DW1000 will go back to sleep as soon as the interrupt is cleared.
3156
    dwt_setlowpowerlistening(0);
3157

    
3158
    dwt_write32bitreg(SYS_STATUS_ID, SYS_STATUS_ALL_RX_GOOD); // Clear all receive status bits
3159

    
3160
    pdw1000local->cbData.rx_flags = 0;
3161

    
3162
    // Read frame info - Only the first two bytes of the register are used here.
3163
    finfo16 = dwt_read16bitoffsetreg(RX_FINFO_ID, 0);
3164

    
3165
    // Report frame length - Standard frame length up to 127, extended frame length up to 1023 bytes
3166
    len = finfo16 & RX_FINFO_RXFL_MASK_1023;
3167
    if(pdw1000local->longFrames == 0)
3168
    {
3169
        len &= RX_FINFO_RXFLEN_MASK;
3170
    }
3171
    pdw1000local->cbData.datalength = len;
3172

    
3173
    // Report ranging bit
3174
    if(finfo16 & RX_FINFO_RNG)
3175
    {
3176
        pdw1000local->cbData.rx_flags |= DWT_CB_DATA_RX_FLAG_RNG;
3177
    }
3178

    
3179
    // Report frame control - First bytes of the received frame.
3180
    dwt_readfromdevice(RX_BUFFER_ID, 0, FCTRL_LEN_MAX, pdw1000local->cbData.fctrl);
3181

    
3182
    // Because of a previous frame not being received properly, AAT bit can be set upon the proper reception of a frame not requesting for
3183
    // acknowledgement (ACK frame is not actually sent though). If the AAT bit is set, check ACK request bit in frame control to confirm (this
3184
    // implementation works only for IEEE802.15.4-2011 compliant frames).
3185
    // This issue is not documented at the time of writing this code. It should be in next release of DW1000 User Manual (v2.09, from July 2016).
3186
    if((status & SYS_STATUS_AAT) && ((pdw1000local->cbData.fctrl[0] & FCTRL_ACK_REQ_MASK) == 0))
3187
    {
3188
        dwt_write32bitreg(SYS_STATUS_ID, SYS_STATUS_AAT); // Clear AAT status bit in register
3189
        pdw1000local->cbData.status &= ~SYS_STATUS_AAT; // Clear AAT status bit in callback data register copy
3190
        pdw1000local->wait4resp = 0;
3191
    }
3192

    
3193
    // Call the corresponding callback if present
3194
    if(pdw1000local->cbRxOk != NULL)
3195
    {
3196
        pdw1000local->cbRxOk(&pdw1000local->cbData);
3197
    }
3198
}
3199

    
3200
/*! ------------------------------------------------------------------------------------------------------------------
3201
 * @fn dwt_setleds()
3202
 *
3203
 * @brief This is used to set up Tx/Rx GPIOs which could be used to control LEDs
3204
 * Note: not completely IC dependent, also needs board with LEDS fitted on right I/O lines
3205
 *       this function enables GPIOs 2 and 3 which are connected to LED3 and LED4 on EVB1000
3206
 *
3207
 * input parameters
3208
 * @param mode - this is a bit field interpreted as follows:
3209
 *          - bit 0: 1 to enable LEDs, 0 to disable them
3210
 *          - bit 1: 1 to make LEDs blink once on init. Only valid if bit 0 is set (enable LEDs)
3211
 *          - bit 2 to 7: reserved
3212
 *
3213
 * output parameters none
3214
 *
3215
 * no return value
3216
 */
3217
void dwt_setleds(uint8_t mode)
3218
{
3219
    uint32_t reg;
3220

    
3221
    if (mode & DWT_LEDS_ENABLE)
3222
    {
3223
        // Set up MFIO for LED output.
3224
        reg = dwt_read32bitoffsetreg(GPIO_CTRL_ID, GPIO_MODE_OFFSET);
3225
        reg &= ~(GPIO_MSGP2_MASK | GPIO_MSGP3_MASK);
3226
        reg |= (GPIO_PIN2_RXLED | GPIO_PIN3_TXLED);
3227
        dwt_write32bitoffsetreg(GPIO_CTRL_ID, GPIO_MODE_OFFSET, reg);
3228

    
3229
        // Enable LP Oscillator to run from counter and turn on de-bounce clock.
3230
        reg = dwt_read32bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET);
3231
        reg |= (PMSC_CTRL0_GPDCE | PMSC_CTRL0_KHZCLEN);
3232
        dwt_write32bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, reg);
3233

    
3234
        // Enable LEDs to blink and set default blink time.
3235
        reg = PMSC_LEDC_BLNKEN | PMSC_LEDC_BLINK_TIME_DEF;
3236
        // Make LEDs blink once if requested.
3237
        if (mode & DWT_LEDS_INIT_BLINK)
3238
        {
3239
            reg |= PMSC_LEDC_BLINK_NOW_ALL;
3240
        }
3241
        dwt_write32bitoffsetreg(PMSC_ID, PMSC_LEDC_OFFSET, reg);
3242
        // Clear force blink bits if needed.
3243
        if(mode & DWT_LEDS_INIT_BLINK)
3244
        {
3245
            reg &= ~PMSC_LEDC_BLINK_NOW_ALL;
3246
            dwt_write32bitoffsetreg(PMSC_ID, PMSC_LEDC_OFFSET, reg);
3247
        }
3248
    }
3249
    else
3250
    {
3251
        // Clear the GPIO bits that are used for LED control.
3252
        reg = dwt_read32bitoffsetreg(GPIO_CTRL_ID, GPIO_MODE_OFFSET);
3253
        reg &= ~(GPIO_MSGP2_MASK | GPIO_MSGP3_MASK);
3254
        dwt_write32bitoffsetreg(GPIO_CTRL_ID, GPIO_MODE_OFFSET, reg);
3255
    }
3256
}
3257

    
3258
/*! ------------------------------------------------------------------------------------------------------------------
3259
 * @fn _dwt_enableclocks()
3260
 *
3261
 * @brief function to enable/disable clocks to particular digital blocks/system
3262
 *
3263
 * input parameters
3264
 * @param clocks - set of clocks to enable/disable
3265
 *
3266
 * output parameters none
3267
 *
3268
 * no return value
3269
 */
3270
void _dwt_enableclocks(int clocks)
3271
{
3272
    uint8_t reg[2];
3273

    
3274
    dwt_readfromdevice(PMSC_ID, PMSC_CTRL0_OFFSET, 2, reg);
3275
    switch(clocks)
3276
    {
3277
        case ENABLE_ALL_SEQ:
3278
        {
3279
            reg[0] = 0x00 ;
3280
            reg[1] = reg[1] & 0xfe;
3281
        }
3282
        break;
3283
        case FORCE_SYS_XTI:
3284
        {
3285
            // System and RX
3286
            reg[0] = 0x01 | (reg[0] & 0xfc);
3287
        }
3288
        break;
3289
        case FORCE_SYS_PLL:
3290
        {
3291
            // System
3292
            reg[0] = 0x02 | (reg[0] & 0xfc);
3293
        }
3294
        break;
3295
        case READ_ACC_ON:
3296
        {
3297
            reg[0] = 0x48 | (reg[0] & 0xb3);
3298
            reg[1] = 0x80 | reg[1];
3299
        }
3300
        break;
3301
        case READ_ACC_OFF:
3302
        {
3303
            reg[0] = reg[0] & 0xb3;
3304
            reg[1] = 0x7f & reg[1];
3305
        }
3306
        break;
3307
        case FORCE_OTP_ON:
3308
        {
3309
            reg[1] = 0x02 | reg[1];
3310
        }
3311
        break;
3312
        case FORCE_OTP_OFF:
3313
        {
3314
            reg[1] = reg[1] & 0xfd;
3315
        }
3316
        break;
3317
        case FORCE_TX_PLL:
3318
        {
3319
            reg[0] = 0x20 | (reg[0] & 0xcf);
3320
        }
3321
        break;
3322
        case FORCE_LDE:
3323
        {
3324
            reg[0] = 0x01;
3325
            reg[1] = 0x03;
3326
        }
3327
        break;
3328
        default:
3329
        break;
3330
    }
3331

    
3332

    
3333
    // Need to write lower byte separately before setting the higher byte(s)
3334
    dwt_writetodevice(PMSC_ID, PMSC_CTRL0_OFFSET, 1, &reg[0]);
3335
    dwt_writetodevice(PMSC_ID, 0x1, 1, &reg[1]);
3336

    
3337
} // end _dwt_enableclocks()
3338

    
3339
/*! ------------------------------------------------------------------------------------------------------------------
3340
 * @fn _dwt_disablesequencing()
3341
 *
3342
 * @brief This function disables the TX blocks sequencing, it disables PMSC control of RF blocks, system clock is also set to XTAL
3343
 *
3344
 * input parameters none
3345
 *
3346
 * output parameters none
3347
 *
3348
 * no return value
3349
 */
3350
void _dwt_disablesequencing(void) // Disable sequencing and go to state "INIT"
3351
{
3352
    _dwt_enableclocks(FORCE_SYS_XTI); // Set system clock to XTI
3353

    
3354
    dwt_write16bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET, PMSC_CTRL1_PKTSEQ_DISABLE); // Disable PMSC ctrl of RF and RX clk blocks
3355
}
3356

    
3357
/*! ------------------------------------------------------------------------------------------------------------------
3358
 * @fn dwt_setdelayedtrxtime()
3359
 *
3360
 * @brief This API function configures the delayed transmit time or the delayed RX on time
3361
 *
3362
 * input parameters
3363
 * @param starttime - the TX/RX start time (the 32 bits should be the high 32 bits of the system time at which to send the message,
3364
 * or at which to turn on the receiver)
3365
 *
3366
 * output parameters none
3367
 *
3368
 * no return value
3369
 */
3370
void dwt_setdelayedtrxtime(uint32_t starttime)
3371
{
3372
    dwt_write32bitoffsetreg(DX_TIME_ID, 1, starttime); // Write at offset 1 as the lower 9 bits of this register are ignored
3373

    
3374
} // end dwt_setdelayedtrxtime()
3375

    
3376
/*! ------------------------------------------------------------------------------------------------------------------
3377
 * @fn dwt_starttx()
3378
 *
3379
 * @brief This call initiates the transmission, input parameter indicates which TX mode is used see below
3380
 *
3381
 * input parameters:
3382
 * @param mode - if 0 immediate TX (no response expected)
3383
 *               if 1 delayed TX (no response expected)
3384
 *               if 2 immediate TX (response expected - so the receiver will be automatically turned on after TX is done)
3385
 *               if 3 delayed TX (response expected - so the receiver will be automatically turned on after TX is done)
3386
 *
3387
 * output parameters
3388
 *
3389
 * returns DWT_SUCCESS for success, or DWT_ERROR for error (e.g. a delayed transmission will fail if the delayed time has passed)
3390
 */
3391
int dwt_starttx(uint8_t mode)
3392
{
3393
    int retval = DWT_SUCCESS ;
3394
    uint8_t temp  = 0x00;
3395
    uint16_t checkTxOK = 0 ;
3396

    
3397
    if(mode & DWT_RESPONSE_EXPECTED)
3398
    {
3399
        temp = (uint8_t)SYS_CTRL_WAIT4RESP ; // Set wait4response bit
3400
        dwt_write8bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_OFFSET, temp);
3401
        pdw1000local->wait4resp = 1;
3402
    }
3403

    
3404
    if (mode & DWT_START_TX_DELAYED)
3405
    {
3406
        // Both SYS_CTRL_TXSTRT and SYS_CTRL_TXDLYS to correctly enable TX
3407
        temp |= (uint8_t)(SYS_CTRL_TXDLYS | SYS_CTRL_TXSTRT) ;
3408
        dwt_write8bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_OFFSET, temp);
3409
        checkTxOK = dwt_read16bitoffsetreg(SYS_STATUS_ID, 3); // Read at offset 3 to get the upper 2 bytes out of 5
3410
        if ((checkTxOK & SYS_STATUS_TXERR) == 0) // Transmit Delayed Send set over Half a Period away or Power Up error (there is enough time to send but not to power up individual blocks).
3411
        {
3412
            retval = DWT_SUCCESS ; // All okay
3413
        }
3414
        else
3415
        {
3416
            // I am taking DSHP set to Indicate that the TXDLYS was set too late for the specified DX_TIME.
3417
            // Remedial Action - (a) cancel delayed send
3418
            temp = (uint8_t)SYS_CTRL_TRXOFF; // This assumes the bit is in the lowest byte
3419
            dwt_write8bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_OFFSET, temp);
3420
            // Note event Delayed TX Time too Late
3421
            // Could fall through to start a normal send (below) just sending late.....
3422
            // ... instead return and assume return value of 1 will be used to detect and recover from the issue.
3423
            pdw1000local->wait4resp = 0;
3424
            retval = DWT_ERROR ; // Failed !
3425
        }
3426
    }
3427
    else
3428
    {
3429
        temp |= (uint8_t)SYS_CTRL_TXSTRT ;
3430
        dwt_write8bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_OFFSET, temp);
3431
    }
3432

    
3433
    return retval;
3434

    
3435
} // end dwt_starttx()
3436

    
3437
/*! ------------------------------------------------------------------------------------------------------------------
3438
 * @fn dwt_forcetrxoff()
3439
 *
3440
 * @brief This is used to turn off the transceiver
3441
 *
3442
 * input parameters
3443
 *
3444
 * output parameters
3445
 *
3446
 * no return value
3447
 */
3448
void dwt_forcetrxoff(void)
3449
{
3450
    decaIrqStatus_t stat ;
3451
    uint32_t mask;
3452

    
3453
    mask = dwt_read32bitreg(SYS_MASK_ID) ; // Read set interrupt mask
3454

    
3455
    // Need to beware of interrupts occurring in the middle of following read modify write cycle
3456
    // We can disable the radio, but before the status is cleared an interrupt can be set (e.g. the
3457
    // event has just happened before the radio was disabled)
3458
    // thus we need to disable interrupt during this operation
3459
    stat = decamutexon() ;
3460

    
3461
    dwt_write32bitreg(SYS_MASK_ID, 0) ; // Clear interrupt mask - so we don't get any unwanted events
3462

    
3463
    dwt_write8bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_OFFSET, (uint8_t)SYS_CTRL_TRXOFF) ; // Disable the radio
3464

    
3465
    // Forcing Transceiver off - so we do not want to see any new events that may have happened
3466
    dwt_write32bitreg(SYS_STATUS_ID, (SYS_STATUS_ALL_TX | SYS_STATUS_ALL_RX_ERR | SYS_STATUS_ALL_RX_TO | SYS_STATUS_ALL_RX_GOOD));
3467

    
3468
    dwt_syncrxbufptrs();
3469

    
3470
    dwt_write32bitreg(SYS_MASK_ID, mask) ; // Set interrupt mask to what it was
3471

    
3472
    // Enable/restore interrupts again...
3473
    decamutexoff(stat) ;
3474
    pdw1000local->wait4resp = 0;
3475

    
3476
} // end deviceforcetrxoff()
3477

    
3478
/*! ------------------------------------------------------------------------------------------------------------------
3479
 * @fn dwt_syncrxbufptrs()
3480
 *
3481
 * @brief this function synchronizes rx buffer pointers
3482
 * need to make sure that the host/IC buffer pointers are aligned before starting RX
3483
 *
3484
 * input parameters:
3485
 *
3486
 * output parameters
3487
 *
3488
 * no return value
3489
 */
3490
void dwt_syncrxbufptrs(void)
3491
{
3492
    uint8_t  buff ;
3493
    // Need to make sure that the host/IC buffer pointers are aligned before starting RX
3494
    buff = dwt_read8bitoffsetreg(SYS_STATUS_ID, 3); // Read 1 byte at offset 3 to get the 4th byte out of 5
3495

    
3496
    if((buff & (SYS_STATUS_ICRBP >> 24)) !=     // IC side Receive Buffer Pointer
3497
       ((buff & (SYS_STATUS_HSRBP>>24)) << 1) ) // Host Side Receive Buffer Pointer
3498
    {
3499
        dwt_write8bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_HRBT_OFFSET , 0x01) ; // We need to swap RX buffer status reg (write one to toggle internally)
3500
    }
3501
}
3502

    
3503
/*! ------------------------------------------------------------------------------------------------------------------
3504
 * @fn dwt_setsniffmode()
3505
 *
3506
 * @brief enable/disable and configure SNIFF mode.
3507
 *
3508
 * SNIFF mode is a low-power reception mode where the receiver is sequenced on and off instead of being on all the time.
3509
 * The time spent in each state (on/off) is specified through the parameters below.
3510
 * See DW1000 User Manual section 4.5 "Low-Power SNIFF mode" for more details.
3511
 *
3512
 * input parameters:
3513
 * @param enable - 1 to enable SNIFF mode, 0 to disable. When 0, all other parameters are not taken into account.
3514
 * @param timeOn - duration of receiver ON phase, expressed in multiples of PAC size. The counter automatically adds 1 PAC
3515
 *                 size to the value set. Min value that can be set is 1 (i.e. an ON time of 2 PAC size), max value is 15.
3516
 * @param timeOff - duration of receiver OFF phase, expressed in multiples of 128/125 µs (~1 µs). Max value is 255.
3517
 *
3518
 * output parameters
3519
 *
3520
 * no return value
3521
 */
3522
void dwt_setsniffmode(int enable, uint8_t timeOn, uint8_t timeOff)
3523
{
3524
    uint32_t pmsc_reg;
3525
    if (enable)
3526
    {
3527
        /* Configure ON/OFF times and enable PLL2 on/off sequencing by SNIFF mode. */
3528
        uint16_t sniff_reg = (uint16_t)((timeOff << 8) | timeOn) & RX_SNIFF_MASK;
3529
        dwt_write16bitoffsetreg(RX_SNIFF_ID, RX_SNIFF_OFFSET, sniff_reg);
3530
        pmsc_reg = dwt_read32bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET);
3531
        pmsc_reg |= PMSC_CTRL0_PLL2_SEQ_EN;
3532
        dwt_write32bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, pmsc_reg);
3533
    }
3534
    else
3535
    {
3536
        /* Clear ON/OFF times and disable PLL2 on/off sequencing by SNIFF mode. */
3537
        dwt_write16bitoffsetreg(RX_SNIFF_ID, RX_SNIFF_OFFSET, 0x0000);
3538
        pmsc_reg = dwt_read32bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET);
3539
        pmsc_reg &= ~PMSC_CTRL0_PLL2_SEQ_EN;
3540
        dwt_write32bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, pmsc_reg);
3541
    }
3542
}
3543

    
3544
/*! ------------------------------------------------------------------------------------------------------------------
3545
 * @fn dwt_setlowpowerlistening()
3546
 *
3547
 * @brief enable/disable low-power listening mode.
3548
 *
3549
 * Low-power listening is a feature whereby the DW1000 is predominantly in the SLEEP state but wakes periodically, (after
3550
 * this "long sleep"), for a very short time to sample the air for a preamble sequence. This preamble sampling "listening"
3551
 * phase is actually two reception phases separated by a "short sleep" time. See DW1000 User Manual section "Low-Power
3552
 * Listening" for more details.
3553
 *
3554
 * NOTE: Before enabling low-power listening, the following functions have to be called to fully configure it:
3555
 *           - dwt_configuresleep() to configure long sleep phase. "mode" parameter should at least have DWT_PRESRV_SLEEP,
3556
 *             DWT_CONFIG and DWT_RX_EN set and "wake" parameter should at least have both DWT_WAKE_SLPCNT and DWT_SLP_EN set.
3557
 *           - dwt_calibratesleepcnt() and dwt_configuresleepcnt() to define the "long sleep" phase duration.
3558
 *           - dwt_setsnoozetime() to define the "short sleep" phase duration.
3559
 *           - dwt_setpreambledetecttimeout() to define the reception phases duration.
3560
 *           - dwt_setinterrupt() to activate RX good frame interrupt (DWT_INT_RFCG) only.
3561
 *       When configured, low-power listening mode can be triggered either by putting the DW1000 to sleep (using
3562
 *       dwt_entersleep()) or by activating reception (using dwt_rxenable()).
3563
 *
3564
 *       Please refer to the low-power listening examples (examples 8a/8b accompanying the API distribution on Decawave's
3565
 *       website). They form a working example code that shows how to use low-power listening correctly.
3566
 *
3567
 * input parameters:
3568
 * @param enable - 1 to enable low-power listening, 0 to disable.
3569
 *
3570
 * output parameters
3571
 *
3572
 * no return value
3573
 */
3574
void dwt_setlowpowerlistening(int enable)
3575
{
3576
    uint32_t pmsc_reg = dwt_read32bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET);
3577
    if (enable)
3578
    {
3579
        /* Configure RX to sleep and snooze features. */
3580
        pmsc_reg |= (PMSC_CTRL1_ARXSLP | PMSC_CTRL1_SNOZE);
3581
    }
3582
    else
3583
    {
3584
        /* Reset RX to sleep and snooze features. */
3585
        pmsc_reg &= ~(PMSC_CTRL1_ARXSLP | PMSC_CTRL1_SNOZE);
3586
    }
3587
    dwt_write32bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET, pmsc_reg);
3588
}
3589

    
3590
/*! ------------------------------------------------------------------------------------------------------------------
3591
 * @fn dwt_setsnoozetime()
3592
 *
3593
 * @brief Set duration of "short sleep" phase when in low-power listening mode.
3594
 *
3595
 * input parameters:
3596
 * @param snooze_time - "short sleep" phase duration, expressed in multiples of 512/19.2 µs (~26.7 µs). The counter
3597
 *                      automatically adds 1 to the value set. The smallest working value that should be set is 1,
3598
 *                      i.e. giving a snooze time of 2 units (or ~53 µs).
3599
 *
3600
 * output parameters
3601
 *
3602
 * no return value
3603
 */
3604
void dwt_setsnoozetime(uint8_t snooze_time)
3605
{
3606
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_SNOZT_OFFSET, snooze_time);
3607
}
3608

    
3609
/*! ------------------------------------------------------------------------------------------------------------------
3610
 * @fn dwt_rxenable()
3611
 *
3612
 * @brief This call turns on the receiver, can be immediate or delayed (depending on the mode parameter). In the case of a
3613
 * "late" error the receiver will only be turned on if the DWT_IDLE_ON_DLY_ERR is not set.
3614
 * The receiver will stay turned on, listening to any messages until
3615
 * it either receives a good frame, an error (CRC, PHY header, Reed Solomon) or  it times out (SFD, Preamble or Frame).
3616
 *
3617
 * input parameters
3618
 * @param mode - this can be one of the following allowed values:
3619
 *
3620
 * DWT_START_RX_IMMEDIATE      0 used to enbale receiver immediately
3621
 * DWT_START_RX_DELAYED        1 used to set up delayed RX, if "late" error triggers, then the RX will be enabled immediately
3622
 * (DWT_START_RX_DELAYED | DWT_IDLE_ON_DLY_ERR) 3 used to disable re-enabling of receiver if delayed RX failed due to "late" error
3623
 * (DWT_START_RX_IMMEDIATE | DWT_NO_SYNC_PTRS) 4 used to re-enable RX without trying to sync IC and host side buffer pointers, typically when
3624
 *                                               performing manual RX re-enabling in double buffering mode
3625
 *
3626
 * returns DWT_SUCCESS for success, or DWT_ERROR for error (e.g. a delayed receive enable will be too far in the future if delayed time has passed)
3627
 */
3628
int dwt_rxenable(int mode)
3629
{
3630
    uint16_t temp ;
3631
    uint8_t temp1 ;
3632

    
3633
    if ((mode & DWT_NO_SYNC_PTRS) == 0)
3634
    {
3635
        dwt_syncrxbufptrs();
3636
    }
3637

    
3638
    temp = (uint16_t)SYS_CTRL_RXENAB ;
3639

    
3640
    if (mode & DWT_START_RX_DELAYED)
3641
    {
3642
        temp |= (uint16_t)SYS_CTRL_RXDLYE ;
3643
    }
3644

    
3645
    dwt_write16bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_OFFSET, temp);
3646

    
3647
    if (mode & DWT_START_RX_DELAYED) // check for errors
3648
    {
3649
        temp1 = dwt_read8bitoffsetreg(SYS_STATUS_ID, 3); // Read 1 byte at offset 3 to get the 4th byte out of 5
3650
        if ((temp1 & (SYS_STATUS_HPDWARN >> 24)) != 0) // if delay has passed do immediate RX on unless DWT_IDLE_ON_DLY_ERR is true
3651
        {
3652
            dwt_forcetrxoff(); // turn the delayed receive off
3653

    
3654
            if((mode & DWT_IDLE_ON_DLY_ERR) == 0) // if DWT_IDLE_ON_DLY_ERR not set then re-enable receiver
3655
            {
3656
                dwt_write16bitoffsetreg(SYS_CTRL_ID, SYS_CTRL_OFFSET, SYS_CTRL_RXENAB);
3657
            }
3658
            return DWT_ERROR; // return warning indication
3659
        }
3660
    }
3661

    
3662
    return DWT_SUCCESS;
3663
} // end dwt_rxenable()
3664

    
3665
/*! ------------------------------------------------------------------------------------------------------------------
3666
 * @fn dwt_setrxtimeout()
3667
 *
3668
 * @brief This call enables RX timeout (SY_STAT_RFTO event)
3669
 *
3670
 * input parameters
3671
 * @param time - how long the receiver remains on from the RX enable command
3672
 *               The time parameter used here is in 1.0256 us (512/499.2MHz) units
3673
 *               If set to 0 the timeout is disabled.
3674
 *
3675
 * output parameters
3676
 *
3677
 * no return value
3678
 */
3679
void dwt_setrxtimeout(uint16_t time)
3680
{
3681
    uint8_t temp ;
3682

    
3683
    temp = dwt_read8bitoffsetreg(SYS_CFG_ID, 3); // Read at offset 3 to get the upper byte only
3684

    
3685
    if(time > 0)
3686
    {
3687
        dwt_write16bitoffsetreg(RX_FWTO_ID, RX_FWTO_OFFSET, time) ;
3688

    
3689
        temp |= (uint8_t)(SYS_CFG_RXWTOE>>24); // Shift RXWTOE mask as we read the upper byte only
3690
        // OR in 32bit value (1 bit set), I know this is in high byte.
3691
        pdw1000local->sysCFGreg |= SYS_CFG_RXWTOE;
3692

    
3693
        dwt_write8bitoffsetreg(SYS_CFG_ID, 3, temp); // Write at offset 3 to write the upper byte only
3694
    }
3695
    else
3696
    {
3697
        temp &= ~((uint8_t)(SYS_CFG_RXWTOE>>24)); // Shift RXWTOE mask as we read the upper byte only
3698
        // AND in inverted 32bit value (1 bit clear), I know this is in high byte.
3699
        pdw1000local->sysCFGreg &= ~(SYS_CFG_RXWTOE);
3700

    
3701
        dwt_write8bitoffsetreg(SYS_CFG_ID, 3, temp); // Write at offset 3 to write the upper byte only
3702
    }
3703

    
3704
} // end dwt_setrxtimeout()
3705

    
3706

    
3707
/*! ------------------------------------------------------------------------------------------------------------------
3708
 * @fn dwt_setpreambledetecttimeout()
3709
 *
3710
 * @brief This call enables preamble timeout (SY_STAT_RXPTO event)
3711
 *
3712
 * input parameters
3713
 * @param  timeout - Preamble detection timeout, expressed in multiples of PAC size. The counter automatically adds 1 PAC
3714
 *                   size to the value set. Min value that can be set is 1 (i.e. a timeout of 2 PAC size).
3715
 *
3716
 * output parameters
3717
 *
3718
 * no return value
3719
 */
3720
void dwt_setpreambledetecttimeout(uint16_t timeout)
3721
{
3722
    dwt_write16bitoffsetreg(DRX_CONF_ID, DRX_PRETOC_OFFSET, timeout);
3723
}
3724

    
3725
/*! ------------------------------------------------------------------------------------------------------------------
3726
 * @fn void dwt_setinterrupt()
3727
 *
3728
 * @brief This function enables the specified events to trigger an interrupt.
3729
 * The following events can be enabled:
3730
 * DWT_INT_TFRS         0x00000080          // frame sent
3731
 * DWT_INT_RFCG         0x00004000          // frame received with good CRC
3732
 * DWT_INT_RPHE         0x00001000          // receiver PHY header error
3733
 * DWT_INT_RFCE         0x00008000          // receiver CRC error
3734
 * DWT_INT_RFSL         0x00010000          // receiver sync loss error
3735
 * DWT_INT_RFTO         0x00020000          // frame wait timeout
3736
 * DWT_INT_RXPTO        0x00200000          // preamble detect timeout
3737
 * DWT_INT_SFDT         0x04000000          // SFD timeout
3738
 * DWT_INT_ARFE         0x20000000          // frame rejected (due to frame filtering configuration)
3739
 *
3740
 *
3741
 * input parameters:
3742
 * @param bitmask - sets the events which will generate interrupt
3743
 * @param enable - if set the interrupts are enabled else they are cleared
3744
 *
3745
 * output parameters
3746
 *
3747
 * no return value
3748
 */
3749
void dwt_setinterrupt(uint32_t bitmask, uint8_t enable)
3750
{
3751
    decaIrqStatus_t stat ;
3752
    uint32_t mask ;
3753

    
3754
    // Need to beware of interrupts occurring in the middle of following read modify write cycle
3755
    stat = decamutexon() ;
3756

    
3757
    mask = dwt_read32bitreg(SYS_MASK_ID) ; // Read register
3758

    
3759
    if(enable)
3760
    {
3761
        mask |= bitmask ;
3762
    }
3763
    else
3764
    {
3765
        mask &= ~bitmask ; // Clear the bit
3766
    }
3767
    dwt_write32bitreg(SYS_MASK_ID,mask) ; // New value
3768

    
3769
    decamutexoff(stat) ;
3770
}
3771

    
3772
/*! ------------------------------------------------------------------------------------------------------------------
3773
 * @fn dwt_configeventcounters()
3774
 *
3775
 * @brief This is used to enable/disable the event counter in the IC
3776
 *
3777
 * input parameters
3778
 * @param - enable - 1 enables (and reset), 0 disables the event counters
3779
 * output parameters
3780
 *
3781
 * no return value
3782
 */
3783
void dwt_configeventcounters(int enable)
3784
{
3785
    // Need to clear and disable, can't just clear
3786
    dwt_write8bitoffsetreg(DIG_DIAG_ID, EVC_CTRL_OFFSET, (uint8_t)(EVC_CLR));
3787

    
3788
    if(enable)
3789
    {
3790
        dwt_write8bitoffsetreg(DIG_DIAG_ID, EVC_CTRL_OFFSET, (uint8_t)(EVC_EN)); // Enable
3791
    }
3792
}
3793

    
3794
/*! ------------------------------------------------------------------------------------------------------------------
3795
 * @fn dwt_readeventcounters()
3796
 *
3797
 * @brief This is used to read the event counters in the IC
3798
 *
3799
 * input parameters
3800
 * @param counters - pointer to the dwt_deviceentcnts_t structure which will hold the read data
3801
 *
3802
 * output parameters
3803
 *
3804
 * no return value
3805
 */
3806
void dwt_readeventcounters(dwt_deviceentcnts_t *counters)
3807
{
3808
    uint32_t temp;
3809

    
3810
    temp= dwt_read32bitoffsetreg(DIG_DIAG_ID, EVC_PHE_OFFSET); // Read sync loss (31-16), PHE (15-0)
3811
    counters->PHE = temp & 0xFFF;
3812
    counters->RSL = (temp >> 16) & 0xFFF;
3813

    
3814
    temp = dwt_read32bitoffsetreg(DIG_DIAG_ID, EVC_FCG_OFFSET); // Read CRC bad (31-16), CRC good (15-0)
3815
    counters->CRCG = temp & 0xFFF;
3816
    counters->CRCB = (temp >> 16) & 0xFFF;
3817

    
3818
    temp = dwt_read32bitoffsetreg(DIG_DIAG_ID, EVC_FFR_OFFSET); // Overruns (31-16), address errors (15-0)
3819
    counters->ARFE = temp & 0xFFF;
3820
    counters->OVER = (temp >> 16) & 0xFFF;
3821

    
3822
    temp = dwt_read32bitoffsetreg(DIG_DIAG_ID, EVC_STO_OFFSET); // Read PTO (31-16), SFDTO (15-0)
3823
    counters->PTO = (temp >> 16) & 0xFFF;
3824
    counters->SFDTO = temp & 0xFFF;
3825

    
3826
    temp = dwt_read32bitoffsetreg(DIG_DIAG_ID, EVC_FWTO_OFFSET); // Read RX TO (31-16), TXFRAME (15-0)
3827
    counters->TXF = (temp >> 16) & 0xFFF;
3828
    counters->RTO = temp & 0xFFF;
3829

    
3830
    temp = dwt_read32bitoffsetreg(DIG_DIAG_ID, EVC_HPW_OFFSET); // Read half period warning events
3831
    counters->HPW = temp & 0xFFF;
3832
    counters->TXW = (temp >> 16) & 0xFFF;                       // Power-up warning events
3833

    
3834
}
3835

    
3836
/*! ------------------------------------------------------------------------------------------------------------------
3837
 * @fn dwt_rxreset()
3838
 *
3839
 * @brief this function resets the receiver of the DW1000
3840
 *
3841
 * input parameters:
3842
 *
3843
 * output parameters
3844
 *
3845
 * no return value
3846
 */
3847
void dwt_rxreset(void)
3848
{
3849
    // Set RX reset
3850
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_SOFTRESET_OFFSET, PMSC_CTRL0_RESET_RX);
3851

    
3852
    // Clear RX reset
3853
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_SOFTRESET_OFFSET, PMSC_CTRL0_RESET_CLEAR);
3854
}
3855

    
3856
/*! ------------------------------------------------------------------------------------------------------------------
3857
 * @fn dwt_softreset()
3858
 *
3859
 * @brief this function resets the DW1000
3860
 *
3861
 * input parameters:
3862
 *
3863
 * output parameters
3864
 *
3865
 * no return value
3866
 */
3867
void dwt_softreset(void)
3868
{
3869
    _dwt_disablesequencing();
3870

    
3871
    // Clear any AON auto download bits (as reset will trigger AON download)
3872
    dwt_write16bitoffsetreg(AON_ID, AON_WCFG_OFFSET, 0x00);
3873
    // Clear the wake-up configuration
3874
    dwt_write8bitoffsetreg(AON_ID, AON_CFG0_OFFSET, 0x00);
3875
    // Upload the new configuration
3876
    _dwt_aonarrayupload();
3877

    
3878
    // Reset HIF, TX, RX and PMSC
3879
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_SOFTRESET_OFFSET, PMSC_CTRL0_RESET_ALL);
3880

    
3881
    // DW1000 needs a 10us sleep to let clk PLL lock after reset - the PLL will automatically lock after the reset
3882
    // Could also have polled the PLL lock flag, but then the SPI needs to be < 3MHz !! So a simple delay is easier
3883
    deca_sleep(1);
3884

    
3885
    // Clear reset
3886
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_SOFTRESET_OFFSET, PMSC_CTRL0_RESET_CLEAR);
3887

    
3888
    pdw1000local->wait4resp = 0;
3889
}
3890

    
3891
/*! ------------------------------------------------------------------------------------------------------------------
3892
 * @fn dwt_setxtaltrim()
3893
 *
3894
 * @brief This is used to adjust the crystal frequency
3895
 *
3896
 * input parameters:
3897
 * @param   value - crystal trim value (in range 0x0 to 0x1F) 31 steps (~1.5ppm per step)
3898
 *
3899
 * output parameters
3900
 *
3901
 * no return value
3902
 */
3903
void dwt_setxtaltrim(uint8_t value)
3904
{
3905
    // The 3 MSb in this 8-bit register must be kept to 0b011 to avoid any malfunction.
3906
    uint8_t reg_val = (3 << 5) | (value & FS_XTALT_MASK);
3907
    dwt_write8bitoffsetreg(FS_CTRL_ID, FS_XTALT_OFFSET, reg_val);
3908
}
3909

    
3910
/*! ------------------------------------------------------------------------------------------------------------------
3911
 * @fn dwt_getinitxtaltrim()
3912
 *
3913
 * @brief This function returns the value of XTAL trim that has been applied during initialisation (dwt_init). This can
3914
 *        be either the value read in OTP memory or a default value.
3915
 *
3916
 * NOTE: The value returned by this function is the initial value only! It is not updated on dwt_setxtaltrim calls.
3917
 *
3918
 * input parameters
3919
 *
3920
 * output parameters
3921
 *
3922
 * returns the XTAL trim value set upon initialisation
3923
 */
3924
uint8_t dwt_getinitxtaltrim(void)
3925
{
3926
    return pdw1000local->init_xtrim;
3927
}
3928

    
3929
/*! ------------------------------------------------------------------------------------------------------------------
3930
 * @fn dwt_configcwmode()
3931
 *
3932
 * @brief this function sets the DW1000 to transmit cw signal at specific channel frequency
3933
 *
3934
 * input parameters:
3935
 * @param chan - specifies the operating channel (e.g. 1, 2, 3, 4, 5, 6 or 7)
3936
 *
3937
 * output parameters
3938
 *
3939
 * no return value
3940
 */
3941
void dwt_configcwmode(uint8_t chan)
3942
{
3943
#ifdef DWT_API_ERROR_CHECK
3944
    assert((chan >= 1) && (chan <= 7) && (chan != 6));
3945
#endif
3946

    
3947
    //
3948
    // Disable TX/RX RF block sequencing (needed for cw frame mode)
3949
    //
3950
    _dwt_disablesequencing();
3951

    
3952
    // Config RF pll (for a given channel)
3953
    // Configure PLL2/RF PLL block CFG/TUNE
3954
    dwt_write32bitoffsetreg(FS_CTRL_ID, FS_PLLCFG_OFFSET, fs_pll_cfg[chan_idx[chan]]);
3955
    dwt_write8bitoffsetreg(FS_CTRL_ID, FS_PLLTUNE_OFFSET, fs_pll_tune[chan_idx[chan]]);
3956
    // PLL wont be enabled until a TX/RX enable is issued later on
3957
    // Configure RF TX blocks (for specified channel and prf)
3958
    // Config RF TX control
3959
    dwt_write32bitoffsetreg(RF_CONF_ID, RF_TXCTRL_OFFSET, tx_config[chan_idx[chan]]);
3960

    
3961
    //
3962
    // Enable RF PLL
3963
    //
3964
    dwt_write32bitreg(RF_CONF_ID, RF_CONF_TXPLLPOWEN_MASK); // Enable LDO and RF PLL blocks
3965
    dwt_write32bitreg(RF_CONF_ID, RF_CONF_TXALLEN_MASK); // Enable the rest of TX blocks
3966

    
3967
    //
3968
    // Configure TX clocks
3969
    //
3970
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, 0x22);
3971
    dwt_write8bitoffsetreg(PMSC_ID, 0x1, 0x07);
3972

    
3973
    // Disable fine grain TX sequencing
3974
    dwt_setfinegraintxseq(0);
3975

    
3976
    // Configure CW mode
3977
    dwt_write8bitoffsetreg(TX_CAL_ID, TC_PGTEST_OFFSET, TC_PGTEST_CW);
3978
}
3979

    
3980
/*! ------------------------------------------------------------------------------------------------------------------
3981
 * @fn dwt_configcontinuousframemode()
3982
 *
3983
 * @brief this function sets the DW1000 to continuous tx frame mode for regulatory approvals testing.
3984
 *
3985
 * input parameters:
3986
 * @param framerepetitionrate - This is a 32-bit value that is used to set the interval between transmissions.
3987
*  The minimum value is 4. The units are approximately 8 ns. (or more precisely 512/(499.2e6*128) seconds)).
3988
 *
3989
 * output parameters
3990
 *
3991
 * no return value
3992
 */
3993
void dwt_configcontinuousframemode(uint32_t framerepetitionrate)
3994
{
3995
    //
3996
    // Disable TX/RX RF block sequencing (needed for continuous frame mode)
3997
    //
3998
    _dwt_disablesequencing();
3999

    
4000
    //
4001
    // Enable RF PLL and TX blocks
4002
    //
4003
    dwt_write32bitreg(RF_CONF_ID, RF_CONF_TXPLLPOWEN_MASK); // Enable LDO and RF PLL blocks
4004
    dwt_write32bitreg(RF_CONF_ID, RF_CONF_TXALLEN_MASK); // Enable the rest of TX blocks
4005

    
4006
    //
4007
    // Configure TX clocks
4008
    //
4009
    _dwt_enableclocks(FORCE_SYS_PLL);
4010
    _dwt_enableclocks(FORCE_TX_PLL);
4011

    
4012
    // Set the frame repetition rate
4013
    if(framerepetitionrate < 4)
4014
    {
4015
        framerepetitionrate = 4;
4016
    }
4017
    dwt_write32bitreg(DX_TIME_ID, framerepetitionrate);
4018

    
4019
    //
4020
    // Configure continuous frame TX
4021
    //
4022
    dwt_write8bitoffsetreg(DIG_DIAG_ID, DIAG_TMC_OFFSET, (uint8_t)(DIAG_TMC_TX_PSTM)); // Turn the tx power spectrum test mode - continuous sending of frames
4023
}
4024

    
4025
/*! ------------------------------------------------------------------------------------------------------------------
4026
 * @fn dwt_readtempvbat()
4027
 *
4028
 * @brief this function reads the battery voltage and temperature of the MP
4029
 * The values read here will be the current values sampled by DW1000 AtoD converters.
4030
 * Note on Temperature: the temperature value needs to be converted to give the real temperature
4031
 * the formula is: 1.13 * reading - 113.0
4032
 * Note on Voltage: the voltage value needs to be converted to give the real voltage
4033
 * the formula is: 0.0057 * reading + 2.3
4034
 *
4035
 * NB: To correctly read the temperature this read should be done with xtal clock
4036
 * however that means that the receiver will be switched off, if receiver needs to be on then
4037
 * the timer is used to make sure the value is stable before reading
4038
 *
4039
 * input parameters:
4040
 * @param fastSPI - set to 1 if SPI rate > than 3MHz is used
4041
 *
4042
 * output parameters
4043
 *
4044
 * returns  (temp_raw<<8)|(vbat_raw)
4045
 */
4046
uint16_t dwt_readtempvbat(uint8_t fastSPI)
4047
{
4048
    uint8_t wr_buf[2];
4049
    uint8_t vbat_raw;
4050
    uint8_t temp_raw;
4051

    
4052
    // These writes should be single writes and in sequence
4053
    wr_buf[0] = 0x80; // Enable TLD Bias
4054
    dwt_writetodevice(RF_CONF_ID,0x11,1,wr_buf);
4055

    
4056
    wr_buf[0] = 0x0A; // Enable TLD Bias and ADC Bias
4057
    dwt_writetodevice(RF_CONF_ID,0x12,1,wr_buf);
4058

    
4059
    wr_buf[0] = 0x0f; // Enable Outputs (only after Biases are up and running)
4060
    dwt_writetodevice(RF_CONF_ID,0x12,1,wr_buf);    //
4061

    
4062
    // Reading All SAR inputs
4063
    wr_buf[0] = 0x00;
4064
    dwt_writetodevice(TX_CAL_ID, TC_SARL_SAR_C,1,wr_buf);
4065
    wr_buf[0] = 0x01; // Set SAR enable
4066
    dwt_writetodevice(TX_CAL_ID, TC_SARL_SAR_C,1,wr_buf);
4067

    
4068
    if(fastSPI == 1)
4069
    {
4070
        deca_sleep(1); // If using PLL clocks(and fast SPI rate) then this sleep is needed
4071
        // Read voltage and temperature.
4072
        dwt_readfromdevice(TX_CAL_ID, TC_SARL_SAR_LVBAT_OFFSET,2,wr_buf);
4073
    }
4074
    else //change to a slow clock
4075
    {
4076
        _dwt_enableclocks(FORCE_SYS_XTI); // NOTE: set system clock to XTI - this is necessary to make sure the values read are reliable
4077
        // Read voltage and temperature.
4078
        dwt_readfromdevice(TX_CAL_ID, TC_SARL_SAR_LVBAT_OFFSET,2,wr_buf);
4079
        // Default clocks (ENABLE_ALL_SEQ)
4080
        _dwt_enableclocks(ENABLE_ALL_SEQ); // Enable clocks for sequencing
4081
    }
4082

    
4083
    vbat_raw = wr_buf[0];
4084
    temp_raw = wr_buf[1];
4085

    
4086
    wr_buf[0] = 0x00; // Clear SAR enable
4087
    dwt_writetodevice(TX_CAL_ID, TC_SARL_SAR_C,1,wr_buf);
4088

    
4089
    return (uint16_t)((temp_raw<<8)|(vbat_raw));
4090
}
4091

    
4092
/*! ------------------------------------------------------------------------------------------------------------------
4093
 * @fn dwt_readwakeuptemp()
4094
 *
4095
 * @brief this function reads the temperature of the DW1000 that was sampled
4096
 * on waking from Sleep/Deepsleep. They are not current values, but read on last
4097
 * wakeup if DWT_TANDV bit is set in mode parameter of dwt_configuresleep
4098
 *
4099
 * input parameters:
4100
 *
4101
 * output parameters:
4102
 *
4103
 * returns: 8-bit raw temperature sensor value
4104
 */
4105
uint8_t dwt_readwakeuptemp(void)
4106
{
4107
    return dwt_read8bitoffsetreg(TX_CAL_ID, TC_SARL_SAR_LTEMP_OFFSET);
4108
}
4109

    
4110
/*! ------------------------------------------------------------------------------------------------------------------
4111
 * @fn dwt_readwakeupvbat()
4112
 *
4113
 * @brief this function reads the battery voltage of the DW1000 that was sampled
4114
 * on waking from Sleep/Deepsleep. They are not current values, but read on last
4115
 * wakeup if DWT_TANDV bit is set in mode parameter of dwt_configuresleep
4116
 *
4117
 * input parameters:
4118
 *
4119
 * output parameters:
4120
 *
4121
 * returns: 8-bit raw battery voltage sensor value
4122
 */
4123
uint8_t dwt_readwakeupvbat(void)
4124
{
4125
    return dwt_read8bitoffsetreg(TX_CAL_ID, TC_SARL_SAR_LVBAT_OFFSET);
4126
}
4127

    
4128
/*! ------------------------------------------------------------------------------------------------------------------
4129
 * @fn dwt_calcbandwidthtempadj()
4130
 *
4131
 * @brief this function determines the corrected bandwidth setting (PG_DELAY register setting)
4132
 * of the DW1000 which changes over temperature.
4133
 *
4134
 * input parameters:
4135
 * @param target_count - uint16_t - the PG count target to reach in order to correct the bandwidth
4136
 *
4137
 * output parameters:
4138
 *
4139
 * returns: (uint32) The setting to be programmed into the PG_DELAY value
4140
 */
4141
uint32_t dwt_calcbandwidthtempadj(uint16_t target_count)
4142
{
4143
    int i;
4144
    uint32_t bit_field, curr_bw;
4145
    int32_t delta_count = 0;
4146
    uint32_t best_bw = 0;
4147
    uint16_t raw_count = 0;
4148
    int32_t delta_lowest;
4149

    
4150
    // Used to store the current values of the registers so that they can be restored after
4151
    uint8_t old_pmsc_ctrl0;
4152
    uint16_t old_pmsc_ctrl1;
4153
    uint32_t old_rf_conf_txpow_mask;
4154

    
4155
    // Record the current values of these registers, to restore later
4156
    old_pmsc_ctrl0 = dwt_read8bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET);
4157
    old_pmsc_ctrl1 = dwt_read16bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET);
4158
    old_rf_conf_txpow_mask = dwt_read32bitreg(RF_CONF_ID);
4159

    
4160
    //  Set clock to XTAL
4161
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, PMSC_CTRL0_SYSCLKS_19M);
4162

    
4163
    //  Disable sequencing
4164
    dwt_write16bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET, PMSC_CTRL1_PKTSEQ_DISABLE);
4165

    
4166
    //  Turn on CLK PLL, Mix Bias and PG
4167
    dwt_write32bitreg(RF_CONF_ID, RF_CONF_TXPOW_MASK | RF_CONF_PGMIXBIASEN_MASK);
4168

    
4169
    //  Set sys and TX clock to PLL
4170
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, PMSC_CTRL0_SYSCLKS_125M | PMSC_CTRL0_TXCLKS_125M);
4171

    
4172
    // Set the MSB high for first guess
4173
    curr_bw = 0x80;
4174
    // Set starting bit
4175
    bit_field = 0x80;
4176
    // Initial lowest delta is the maximum difference that we should allow the count value to be from the target.
4177
    // If the algorithm is successful, it will be overwritten by a smaller value where the count value is closer
4178
    // to the target
4179
    delta_lowest = 300;
4180

    
4181
    for (i = 0; i < 7; i++)
4182
    {
4183
        // start with 0xc0 and test.
4184
        bit_field = bit_field >> 1;
4185
        curr_bw = curr_bw | bit_field;
4186

    
4187
        // Write bw setting to PG_DELAY register
4188
        dwt_write8bitoffsetreg(TX_CAL_ID, TC_PGDELAY_OFFSET,(uint8_t)curr_bw);
4189

    
4190
        // Set cal direction and time
4191
        dwt_write8bitoffsetreg(TX_CAL_ID, TC_PGCCTRL_OFFSET, TC_PGCCTRL_DIR_CONV | TC_PGCCTRL_TMEAS_MASK);
4192

    
4193
        // Start cal
4194
        dwt_write8bitoffsetreg(TX_CAL_ID, TC_PGCCTRL_OFFSET, TC_PGCCTRL_DIR_CONV | TC_PGCCTRL_TMEAS_MASK | TC_PGCCTRL_CALSTART);
4195
        // Allow cal to complete
4196
        deca_sleep(100);
4197

    
4198
        // Read count value from the PG cal block
4199
        raw_count = dwt_read16bitoffsetreg(TX_CAL_ID, TC_PGCAL_STATUS_OFFSET) & TC_PGCAL_STATUS_DELAY_MASK;
4200

    
4201
        // lets keep track of the closest value to the target in case we overshoot
4202
        delta_count = abs((int)raw_count - (int)target_count);
4203
        if (delta_count < delta_lowest)
4204
        {
4205
            delta_lowest = delta_count;
4206
            best_bw = curr_bw;
4207
        }
4208

    
4209
        // Test the count results
4210
        if (raw_count > target_count)
4211
            // Count was lower, BW was lower so increase PG DELAY
4212
            curr_bw = curr_bw | bit_field;
4213
        else
4214
            // Count was higher
4215
            curr_bw = curr_bw & (~(bit_field));
4216
    }
4217

    
4218
    // Restore old register values
4219
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, old_pmsc_ctrl0);
4220
    dwt_write16bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET, old_pmsc_ctrl1);
4221
    dwt_write32bitreg(RF_CONF_ID, old_rf_conf_txpow_mask);
4222

    
4223
    // Returns the best PG_DELAY setting
4224
    return best_bw;
4225
}
4226

    
4227

    
4228
/*! ------------------------------------------------------------------------------------------------------------------
4229
 * @fn _dwt_computetxpowersetting()
4230
 *
4231
 * @brief this function calculates the appropriate change to the TX_POWER register to compensate
4232
 * the TX power output at different temperatures.
4233
 *
4234
 * input parameters:
4235
 * @param ref_powerreg - uint32_t - the TX_POWER register value recorded when reference measurements were made
4236
 * @param power_adj - uint32_t - the adjustment in power level to be made, in 0.5dB steps
4237
 *
4238
 * output parameters:
4239
 *
4240
 * returns: (uint32) The setting to be programmed into the TX_POWER register
4241
 */
4242
uint32_t _dwt_computetxpowersetting(uint32_t ref_powerreg, int32_t power_adj)
4243
{
4244
    int32_t da_attn_change, mixer_gain_change;
4245
    uint8_t current_da_attn, current_mixer_gain;
4246
    uint8_t new_da_attn, new_mixer_gain;
4247
    uint32_t new_regval = 0;
4248
    int i;
4249

    
4250
    for(i = 0; i < 4; i++)
4251
    {
4252
        da_attn_change = 0;
4253
        mixer_gain_change = power_adj;
4254
        current_da_attn = ((ref_powerreg >> (i*8)) & 0xE0) >> 5;
4255
        current_mixer_gain = (ref_powerreg >> (i*8)) & 0x1F;
4256

    
4257
        // Mixer gain gives best performance between 4 and 20
4258
        while((current_mixer_gain + mixer_gain_change < 4) ||
4259
              (current_mixer_gain + mixer_gain_change > 20))
4260
        {
4261
            // If mixer gain goes outside bounds, adjust the DA attenuation to compensate
4262
            if(current_mixer_gain + mixer_gain_change > 20)
4263
            {
4264
                da_attn_change += 1;
4265
                mixer_gain_change -= (int) (DA_ATTN_STEP / MIXER_GAIN_STEP);
4266
            }
4267
            else if(current_mixer_gain + mixer_gain_change < 4)
4268
            {
4269
                da_attn_change += 1;
4270
                mixer_gain_change += (int) (DA_ATTN_STEP / MIXER_GAIN_STEP);
4271
            }
4272
        }
4273

    
4274
        new_da_attn = current_da_attn + (uint8_t)da_attn_change;
4275
        new_mixer_gain = current_mixer_gain + (uint8_t)mixer_gain_change;
4276

    
4277
        new_regval |= ((uint32_t) ((new_da_attn << 5) | new_mixer_gain)) << (i * 8);
4278
    }
4279

    
4280
    return (uint32_t)new_regval;
4281
}
4282

    
4283
/*! ------------------------------------------------------------------------------------------------------------------
4284
 * @fn dwt_calcpowertempadj()
4285
 *
4286
 * @brief this function determines the corrected power setting (TX_POWER setting) for the
4287
 * DW1000 which changes over temperature.
4288
 *
4289
 * input parameters:
4290
 * @param channel - uint8_t - the channel at which compensation of power level will be applied
4291
 * @param ref_powerreg - uint32_t - the TX_POWER register value recorded when reference measurements were made
4292
 * @param current_temperature - double - the current ambient temperature in degrees Celcius
4293
 * @param reference_temperature - double - the temperature at which reference measurements were made
4294
 * output parameters: None
4295
 *
4296
 * returns: (uint32) The corrected TX_POWER register value
4297
 */
4298
 uint32_t dwt_calcpowertempadj
4299
(
4300
       uint8_t channel,
4301
       uint32_t ref_powerreg,
4302
       double curr_temp,
4303
       double ref_temp
4304
)
4305
{
4306
    double delta_temp;
4307
    double delta_power;
4308

    
4309
    // Find the temperature differential
4310
    delta_temp = curr_temp - ref_temp;
4311

    
4312
    // Calculate the expected power differential at the current temperature
4313
    delta_power = delta_temp * txpwr_compensation[chan_idx[channel]];
4314

    
4315
    // Adjust the TX_POWER register value
4316
    return _dwt_computetxpowersetting(ref_powerreg, (int32_t)(delta_power / MIXER_GAIN_STEP));
4317
}
4318

    
4319
/*! ------------------------------------------------------------------------------------------------------------------
4320
 * @fn dwt_calcpgcount()
4321
 *
4322
 * @brief this function calculates the value in the pulse generator counter register (PGC_STATUS) for a given PG_DELAY
4323
 * This is used to take a reference measurement, and the value recorded as the reference is used to adjust the
4324
 * bandwidth of the device when the temperature changes.
4325
 *
4326
 * input parameters:
4327
 * @param pgdly - uint8_t - the PG_DELAY to set (to control bandwidth), and to find the corresponding count value for
4328
 * output parameters: None
4329
 *
4330
 * returns: (uint16) PGC_STATUS count value calculated from the provided PG_DELAY value - used as reference for later
4331
 * bandwidth adjustments
4332
 */
4333
uint16_t dwt_calcpgcount(uint8_t pgdly)
4334
{
4335
    // Perform PG count read ten times and take an average to smooth out any noise
4336
    const int NUM_SAMPLES = 10;
4337
    uint32_t sum_count = 0;
4338
    uint16_t average_count = 0, count = 0;
4339
    int i = 0;
4340

    
4341
    // Used to store the current values of the registers so that they can be restored after
4342
    uint8_t old_pmsc_ctrl0;
4343
    uint16_t old_pmsc_ctrl1;
4344
    uint32_t old_rf_conf_txpow_mask;
4345

    
4346
    // Record the current values of these registers, to restore later
4347
    old_pmsc_ctrl0 = dwt_read8bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET);
4348
    old_pmsc_ctrl1 = dwt_read16bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET);
4349
    old_rf_conf_txpow_mask = dwt_read32bitreg(RF_CONF_ID);
4350

    
4351
    //  Set clock to XTAL
4352
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, PMSC_CTRL0_SYSCLKS_19M);
4353
    //  Disable sequencing
4354
    dwt_write16bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET, PMSC_CTRL1_PKTSEQ_DISABLE);
4355
    //  Turn on CLK PLL, Mix Bias and PG
4356
    dwt_write32bitreg(RF_CONF_ID, RF_CONF_TXPOW_MASK | RF_CONF_PGMIXBIASEN_MASK);
4357
    //  Set sys and TX clock to PLL
4358
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, PMSC_CTRL0_SYSCLKS_125M | PMSC_CTRL0_TXCLKS_125M);
4359

    
4360
    for(i = 0; i < NUM_SAMPLES; i++) {
4361
        // Write bw setting to PG_DELAY register
4362
        dwt_write8bitoffsetreg(TX_CAL_ID, TC_PGDELAY_OFFSET, pgdly);
4363

    
4364
        // Set cal direction and time
4365
        dwt_write8bitoffsetreg(TX_CAL_ID, TC_PGCCTRL_OFFSET, TC_PGCCTRL_DIR_CONV | TC_PGCCTRL_TMEAS_MASK);
4366

    
4367
        // Start cal
4368
        dwt_write8bitoffsetreg(TX_CAL_ID, TC_PGCCTRL_OFFSET, TC_PGCCTRL_DIR_CONV | TC_PGCCTRL_TMEAS_MASK | TC_PGCCTRL_CALSTART);
4369

    
4370
        // Allow cal to complete - the TC_PGCCTRL_CALSTART bit will clear automatically
4371
        deca_sleep(100);
4372

    
4373
        // Read count value from the PG cal block
4374
        count = dwt_read16bitoffsetreg(TX_CAL_ID, TC_PGCAL_STATUS_OFFSET) & TC_PGCAL_STATUS_DELAY_MASK;
4375

    
4376
        sum_count += count;
4377
    }
4378

    
4379
     // Restore old register values
4380
    dwt_write8bitoffsetreg(PMSC_ID, PMSC_CTRL0_OFFSET, old_pmsc_ctrl0);
4381
    dwt_write16bitoffsetreg(PMSC_ID, PMSC_CTRL1_OFFSET, old_pmsc_ctrl1);
4382
    dwt_write32bitreg(RF_CONF_ID, old_rf_conf_txpow_mask);
4383

    
4384
    average_count = (uint16_t)(sum_count / NUM_SAMPLES);
4385
    return average_count;
4386
}
4387

    
4388

    
4389
/* ===============================================================================================
4390
   List of expected (known) device ID handled by this software
4391
   ===============================================================================================
4392

4393
    0xDECA0130                               // DW1000 - MP
4394

4395
   =============================================================================================== */
4396

    
4397
/****************************************************************************************************************************************************
4398
 *
4399
 * Declaration of platform-dependent lower level functions.
4400
 *
4401
 ****************************************************************************************************************************************************/
4402

    
4403
/****************************************************************************//**
4404
 *
4405
 *         alld_dw1000.c                                        SPI Section
4406
 *
4407
 *******************************************************************************/
4408

    
4409
/*! ------------------------------------------------------------------------------------------------------------------
4410
 * Function: writetospi()
4411
 *
4412
 * Low level abstract function for DW1000 to write to the SPI
4413
 * Takes two separate byte buffers for write header and write data
4414
 * returns 0 for success, or -1 for error
4415
 */
4416
#pragma GCC optimize ("O3")
4417
static int writetospi(uint16_t headerLength,
4418
                      const        uint8_t *headerBuffer,
4419
                      uint32_t bodyLength,
4420
                      const        uint8_t *bodyBuffer)
4421
{   
4422
  uint8_t buffer[SPIBUFFLEN];
4423
  memcpy(buffer, headerBuffer, headerLength); //copy header (register id no.) to the buffer
4424
  memcpy(&buffer[headerLength], bodyBuffer, bodyLength); //copy data to the buffer
4425

    
4426
  apalSPITransmit(pdw1000local->driver->spid,
4427
                  buffer,
4428
                  bodyLength + headerLength); // send header (register id) and data
4429

    
4430
  return 0;
4431
} // end writetospi()
4432

    
4433

    
4434
/*! ------------------------------------------------------------------------------------------------------------------
4435
 * Function: readfromspi()
4436
 *
4437
 * Low level abstract function for DW1000 to read from the SPI
4438
 * Takes two separate byte buffers for write header and read data
4439
 * returns the offset into read buffer where first byte of read data may be found,
4440
 * or returns -1 if there was an error
4441
 */
4442
#pragma GCC optimize ("O3")
4443
static int readfromspi(uint16_t headerLength,
4444
                const uint8_t *headerBuffer,
4445
                uint32_t readlength,
4446
                uint8_t *readBuffer)
4447
{
4448

    
4449
    apalSPITransmitAndReceive(pdw1000local->driver->spid,
4450
                              headerBuffer,
4451
                              readBuffer,
4452
                              headerLength,
4453
                              readlength);
4454

    
4455
    return 0;
4456
} // end readfromspi()
4457

    
4458
/****************************************************************************//**
4459
 *
4460
 *         alld_dw1000.c                                        IRQ section
4461
 *
4462
 *******************************************************************************/
4463

    
4464

    
4465
/*! ------------------------------------------------------------------------------------------------------------------
4466
 * Function: decamutexon()
4467
 *
4468
 * Description: This function should disable interrupts. This is called at the start of a critical section
4469
 * It returns the irq state before disable, this value is used to re-enable in decamutexoff call
4470
 *
4471
 * Note: The body of this function is platform specific
4472
 *
4473
 * input parameters:        
4474
 *
4475
 * output parameters
4476
 *
4477
 * returns the state of the DW1000 interrupt
4478
 */
4479
decaIrqStatus_t decamutexon(void)
4480
{
4481

    
4482
  decaIrqStatus_t s = port_GetEXT_IRQStatus();
4483
  if(s) {
4484
    port_DisableEXT_IRQ(); //disable the external interrupt line
4485
  }
4486
  return s ;   // return state before disable, value is used to re-enable in decamutexoff call
4487
}
4488

    
4489
/*! ------------------------------------------------------------------------------------------------------------------
4490
 * Function: decamutexoff()
4491
 *
4492
 * Description: This function should re-enable interrupts, or at least restore their state as returned(&saved) by decamutexon 
4493
 * This is called at the end of a critical section
4494
 *
4495
 * Note: The body of this function is platform specific
4496
 *
4497
 * input parameters:        
4498
 * @param s - the state of the DW1000 interrupt as returned by decamutexon
4499
 *
4500
 * output parameters
4501
 *
4502
 * returns the state of the DW1000 interrupt
4503
 */
4504
void decamutexoff(decaIrqStatus_t s)
4505
{
4506
//  (void) s;
4507
  if(s) { //need to check the port state as we can't use level sensitive interrupt on the STM ARM
4508
    port_EnableEXT_IRQ();
4509
  }
4510
  return;
4511
}
4512

    
4513

    
4514
/*! Wrapper function to be used by decadriver. Declared in deca_device_api.h 
4515
 *
4516
 */
4517

    
4518
/*! @brief sleep or idle the thread in millisecond */
4519
void deca_sleep(unsigned int time_ms)
4520
{
4521
  apalSleep(time_ms * 1000);
4522
}
4523

    
4524
/*! @brief sleep or idle the thread in millisecond */
4525
void Sleep(unsigned int time_ms)
4526
{
4527
  apalSleep(time_ms * 1000);
4528
}
4529

    
4530

    
4531
void port_wakeup_dw1000_fast(){ // NOT SUPPORTED
4532
  return;
4533
}
4534

    
4535
/*! @brief Get the current system tick time */
4536
uint32_t portGetTickCnt(){
4537
  return chVTGetSystemTimeX();
4538
}
4539

    
4540
/*! @brief Disable the interrupt handler */
4541
void port_DisableEXT_IRQ(void){   
4542
  nvicDisableVector(DW1000_EXTI_IRQn);
4543
}
4544

    
4545
/*! @brief Enable the interrupt handler */
4546
void port_EnableEXT_IRQ(void){    
4547
  nvicEnableVector(DW1000_EXTI_IRQn, STM32_IRQ_EXTI10_15_PRIORITY);
4548
}
4549

    
4550
/*! @brief Get the current status of the interrupt handler */
4551
decaIrqStatus_t port_GetEXT_IRQStatus(void){
4552
  decaIrqStatus_t bitstatus = RESET;
4553

    
4554
  if(NVIC_GetActive(DW1000_EXTI_IRQn)|| NVIC_GetPendingIRQ(DW1000_EXTI_IRQn)){
4555
    bitstatus = SET; //Interrupt is active or panding
4556
  }
4557
  else {
4558
    bitstatus = RESET; //No interrupt IRQ at the moment
4559
  }
4560

    
4561
  return bitstatus;
4562
}
4563