tjh.dev
Linux kernel mirror (for testing)
git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
kernel
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linux
1/*
2 * CAAM hardware register-level view
3 *
4 * Copyright 2008-2011 Freescale Semiconductor, Inc.
5 */
6
7#ifndef REGS_H
8#define REGS_H
9
10#include <linux/types.h>
11#include <linux/io.h>
12
13/*
14 * Architecture-specific register access methods
15 *
16 * CAAM's bus-addressable registers are 64 bits internally.
17 * They have been wired to be safely accessible on 32-bit
18 * architectures, however. Registers were organized such
19 * that (a) they can be contained in 32 bits, (b) if not, then they
20 * can be treated as two 32-bit entities, or finally (c) if they
21 * must be treated as a single 64-bit value, then this can safely
22 * be done with two 32-bit cycles.
23 *
24 * For 32-bit operations on 64-bit values, CAAM follows the same
25 * 64-bit register access conventions as it's predecessors, in that
26 * writes are "triggered" by a write to the register at the numerically
27 * higher address, thus, a full 64-bit write cycle requires a write
28 * to the lower address, followed by a write to the higher address,
29 * which will latch/execute the write cycle.
30 *
31 * For example, let's assume a SW reset of CAAM through the master
32 * configuration register.
33 * - SWRST is in bit 31 of MCFG.
34 * - MCFG begins at base+0x0000.
35 * - Bits 63-32 are a 32-bit word at base+0x0000 (numerically-lower)
36 * - Bits 31-0 are a 32-bit word at base+0x0004 (numerically-higher)
37 *
38 * (and on Power, the convention is 0-31, 32-63, I know...)
39 *
40 * Assuming a 64-bit write to this MCFG to perform a software reset
41 * would then require a write of 0 to base+0x0000, followed by a
42 * write of 0x80000000 to base+0x0004, which would "execute" the
43 * reset.
44 *
45 * Of course, since MCFG 63-32 is all zero, we could cheat and simply
46 * write 0x8000000 to base+0x0004, and the reset would work fine.
47 * However, since CAAM does contain some write-and-read-intended
48 * 64-bit registers, this code defines 64-bit access methods for
49 * the sake of internal consistency and simplicity, and so that a
50 * clean transition to 64-bit is possible when it becomes necessary.
51 *
52 * There are limitations to this that the developer must recognize.
53 * 32-bit architectures cannot enforce an atomic-64 operation,
54 * Therefore:
55 *
56 * - On writes, since the HW is assumed to latch the cycle on the
57 * write of the higher-numeric-address word, then ordered
58 * writes work OK.
59 *
60 * - For reads, where a register contains a relevant value of more
61 * that 32 bits, the hardware employs logic to latch the other
62 * "half" of the data until read, ensuring an accurate value.
63 * This is of particular relevance when dealing with CAAM's
64 * performance counters.
65 *
66 */
67
68#ifdef __BIG_ENDIAN
69#define wr_reg32(reg, data) out_be32(reg, data)
70#define rd_reg32(reg) in_be32(reg)
71#ifdef CONFIG_64BIT
72#define wr_reg64(reg, data) out_be64(reg, data)
73#define rd_reg64(reg) in_be64(reg)
74#endif
75#else
76#ifdef __LITTLE_ENDIAN
77#define wr_reg32(reg, data) __raw_writel(reg, data)
78#define rd_reg32(reg) __raw_readl(reg)
79#ifdef CONFIG_64BIT
80#define wr_reg64(reg, data) __raw_writeq(reg, data)
81#define rd_reg64(reg) __raw_readq(reg)
82#endif
83#endif
84#endif
85
86#ifndef CONFIG_64BIT
87static inline void wr_reg64(u64 __iomem *reg, u64 data)
88{
89 wr_reg32((u32 __iomem *)reg, (data & 0xffffffff00000000ull) >> 32);
90 wr_reg32((u32 __iomem *)reg + 1, data & 0x00000000ffffffffull);
91}
92
93static inline u64 rd_reg64(u64 __iomem *reg)
94{
95 return (((u64)rd_reg32((u32 __iomem *)reg)) << 32) |
96 ((u64)rd_reg32((u32 __iomem *)reg + 1));
97}
98#endif
99
100/*
101 * jr_outentry
102 * Represents each entry in a JobR output ring
103 */
104struct jr_outentry {
105 dma_addr_t desc;/* Pointer to completed descriptor */
106 u32 jrstatus; /* Status for completed descriptor */
107} __packed;
108
109/*
110 * caam_perfmon - Performance Monitor/Secure Memory Status/
111 * CAAM Global Status/Component Version IDs
112 *
113 * Spans f00-fff wherever instantiated
114 */
115
116/* Number of DECOs */
117#define CHA_NUM_DECONUM_SHIFT 56
118#define CHA_NUM_DECONUM_MASK (0xfull << CHA_NUM_DECONUM_SHIFT)
119
120struct sec_vid {
121 u16 ip_id;
122 u8 maj_rev;
123 u8 min_rev;
124};
125
126struct caam_perfmon {
127 /* Performance Monitor Registers f00-f9f */
128 u64 req_dequeued; /* PC_REQ_DEQ - Dequeued Requests */
129 u64 ob_enc_req; /* PC_OB_ENC_REQ - Outbound Encrypt Requests */
130 u64 ib_dec_req; /* PC_IB_DEC_REQ - Inbound Decrypt Requests */
131 u64 ob_enc_bytes; /* PC_OB_ENCRYPT - Outbound Bytes Encrypted */
132 u64 ob_prot_bytes; /* PC_OB_PROTECT - Outbound Bytes Protected */
133 u64 ib_dec_bytes; /* PC_IB_DECRYPT - Inbound Bytes Decrypted */
134 u64 ib_valid_bytes; /* PC_IB_VALIDATED Inbound Bytes Validated */
135 u64 rsvd[13];
136
137 /* CAAM Hardware Instantiation Parameters fa0-fbf */
138 u64 cha_rev; /* CRNR - CHA Revision Number */
139#define CTPR_QI_SHIFT 57
140#define CTPR_QI_MASK (0x1ull << CTPR_QI_SHIFT)
141 u64 comp_parms; /* CTPR - Compile Parameters Register */
142 u64 rsvd1[2];
143
144 /* CAAM Global Status fc0-fdf */
145 u64 faultaddr; /* FAR - Fault Address */
146 u32 faultliodn; /* FALR - Fault Address LIODN */
147 u32 faultdetail; /* FADR - Fault Addr Detail */
148 u32 rsvd2;
149 u32 status; /* CSTA - CAAM Status */
150 u64 rsvd3;
151
152 /* Component Instantiation Parameters fe0-fff */
153 u32 rtic_id; /* RVID - RTIC Version ID */
154 u32 ccb_id; /* CCBVID - CCB Version ID */
155 u64 cha_id; /* CHAVID - CHA Version ID */
156 u64 cha_num; /* CHANUM - CHA Number */
157 u64 caam_id; /* CAAMVID - CAAM Version ID */
158};
159
160/* LIODN programming for DMA configuration */
161#define MSTRID_LOCK_LIODN 0x80000000
162#define MSTRID_LOCK_MAKETRUSTED 0x00010000 /* only for JR masterid */
163
164#define MSTRID_LIODN_MASK 0x0fff
165struct masterid {
166 u32 liodn_ms; /* lock and make-trusted control bits */
167 u32 liodn_ls; /* LIODN for non-sequence and seq access */
168};
169
170/* Partition ID for DMA configuration */
171struct partid {
172 u32 rsvd1;
173 u32 pidr; /* partition ID, DECO */
174};
175
176/* RNGB test mode (replicated twice in some configurations) */
177/* Padded out to 0x100 */
178struct rngtst {
179 u32 mode; /* RTSTMODEx - Test mode */
180 u32 rsvd1[3];
181 u32 reset; /* RTSTRESETx - Test reset control */
182 u32 rsvd2[3];
183 u32 status; /* RTSTSSTATUSx - Test status */
184 u32 rsvd3;
185 u32 errstat; /* RTSTERRSTATx - Test error status */
186 u32 rsvd4;
187 u32 errctl; /* RTSTERRCTLx - Test error control */
188 u32 rsvd5;
189 u32 entropy; /* RTSTENTROPYx - Test entropy */
190 u32 rsvd6[15];
191 u32 verifctl; /* RTSTVERIFCTLx - Test verification control */
192 u32 rsvd7;
193 u32 verifstat; /* RTSTVERIFSTATx - Test verification status */
194 u32 rsvd8;
195 u32 verifdata; /* RTSTVERIFDx - Test verification data */
196 u32 rsvd9;
197 u32 xkey; /* RTSTXKEYx - Test XKEY */
198 u32 rsvd10;
199 u32 oscctctl; /* RTSTOSCCTCTLx - Test osc. counter control */
200 u32 rsvd11;
201 u32 oscct; /* RTSTOSCCTx - Test oscillator counter */
202 u32 rsvd12;
203 u32 oscctstat; /* RTSTODCCTSTATx - Test osc counter status */
204 u32 rsvd13[2];
205 u32 ofifo[4]; /* RTSTOFIFOx - Test output FIFO */
206 u32 rsvd14[15];
207};
208
209/* RNG4 TRNG test registers */
210struct rng4tst {
211#define RTMCTL_PRGM 0x00010000 /* 1 -> program mode, 0 -> run mode */
212 u32 rtmctl; /* misc. control register */
213 u32 rtscmisc; /* statistical check misc. register */
214 u32 rtpkrrng; /* poker range register */
215 union {
216 u32 rtpkrmax; /* PRGM=1: poker max. limit register */
217 u32 rtpkrsq; /* PRGM=0: poker square calc. result register */
218 };
219#define RTSDCTL_ENT_DLY_SHIFT 16
220#define RTSDCTL_ENT_DLY_MASK (0xffff << RTSDCTL_ENT_DLY_SHIFT)
221 u32 rtsdctl; /* seed control register */
222 union {
223 u32 rtsblim; /* PRGM=1: sparse bit limit register */
224 u32 rttotsam; /* PRGM=0: total samples register */
225 };
226 u32 rtfrqmin; /* frequency count min. limit register */
227 union {
228 u32 rtfrqmax; /* PRGM=1: freq. count max. limit register */
229 u32 rtfrqcnt; /* PRGM=0: freq. count register */
230 };
231 u32 rsvd1[56];
232};
233
234/*
235 * caam_ctrl - basic core configuration
236 * starts base + 0x0000 padded out to 0x1000
237 */
238
239#define KEK_KEY_SIZE 8
240#define TKEK_KEY_SIZE 8
241#define TDSK_KEY_SIZE 8
242
243#define DECO_RESET 1 /* Use with DECO reset/availability regs */
244#define DECO_RESET_0 (DECO_RESET << 0)
245#define DECO_RESET_1 (DECO_RESET << 1)
246#define DECO_RESET_2 (DECO_RESET << 2)
247#define DECO_RESET_3 (DECO_RESET << 3)
248#define DECO_RESET_4 (DECO_RESET << 4)
249
250struct caam_ctrl {
251 /* Basic Configuration Section 000-01f */
252 /* Read/Writable */
253 u32 rsvd1;
254 u32 mcr; /* MCFG Master Config Register */
255 u32 rsvd2[2];
256
257 /* Bus Access Configuration Section 010-11f */
258 /* Read/Writable */
259 struct masterid jr_mid[4]; /* JRxLIODNR - JobR LIODN setup */
260 u32 rsvd3[12];
261 struct masterid rtic_mid[4]; /* RTICxLIODNR - RTIC LIODN setup */
262 u32 rsvd4[7];
263 u32 deco_rq; /* DECORR - DECO Request */
264 struct partid deco_mid[5]; /* DECOxLIODNR - 1 per DECO */
265 u32 rsvd5[22];
266
267 /* DECO Availability/Reset Section 120-3ff */
268 u32 deco_avail; /* DAR - DECO availability */
269 u32 deco_reset; /* DRR - DECO reset */
270 u32 rsvd6[182];
271
272 /* Key Encryption/Decryption Configuration 400-5ff */
273 /* Read/Writable only while in Non-secure mode */
274 u32 kek[KEK_KEY_SIZE]; /* JDKEKR - Key Encryption Key */
275 u32 tkek[TKEK_KEY_SIZE]; /* TDKEKR - Trusted Desc KEK */
276 u32 tdsk[TDSK_KEY_SIZE]; /* TDSKR - Trusted Desc Signing Key */
277 u32 rsvd7[32];
278 u64 sknonce; /* SKNR - Secure Key Nonce */
279 u32 rsvd8[70];
280
281 /* RNG Test/Verification/Debug Access 600-7ff */
282 /* (Useful in Test/Debug modes only...) */
283 union {
284 struct rngtst rtst[2];
285 struct rng4tst r4tst[2];
286 };
287
288 u32 rsvd9[448];
289
290 /* Performance Monitor f00-fff */
291 struct caam_perfmon perfmon;
292};
293
294/*
295 * Controller master config register defs
296 */
297#define MCFGR_SWRESET 0x80000000 /* software reset */
298#define MCFGR_WDENABLE 0x40000000 /* DECO watchdog enable */
299#define MCFGR_WDFAIL 0x20000000 /* DECO watchdog force-fail */
300#define MCFGR_DMA_RESET 0x10000000
301#define MCFGR_LONG_PTR 0x00010000 /* Use >32-bit desc addressing */
302
303/* AXI read cache control */
304#define MCFGR_ARCACHE_SHIFT 12
305#define MCFGR_ARCACHE_MASK (0xf << MCFGR_ARCACHE_SHIFT)
306
307/* AXI write cache control */
308#define MCFGR_AWCACHE_SHIFT 8
309#define MCFGR_AWCACHE_MASK (0xf << MCFGR_AWCACHE_SHIFT)
310
311/* AXI pipeline depth */
312#define MCFGR_AXIPIPE_SHIFT 4
313#define MCFGR_AXIPIPE_MASK (0xf << MCFGR_AXIPIPE_SHIFT)
314
315#define MCFGR_AXIPRI 0x00000008 /* Assert AXI priority sideband */
316#define MCFGR_BURST_64 0x00000001 /* Max burst size */
317
318/*
319 * caam_job_ring - direct job ring setup
320 * 1-4 possible per instantiation, base + 1000/2000/3000/4000
321 * Padded out to 0x1000
322 */
323struct caam_job_ring {
324 /* Input ring */
325 u64 inpring_base; /* IRBAx - Input desc ring baseaddr */
326 u32 rsvd1;
327 u32 inpring_size; /* IRSx - Input ring size */
328 u32 rsvd2;
329 u32 inpring_avail; /* IRSAx - Input ring room remaining */
330 u32 rsvd3;
331 u32 inpring_jobadd; /* IRJAx - Input ring jobs added */
332
333 /* Output Ring */
334 u64 outring_base; /* ORBAx - Output status ring base addr */
335 u32 rsvd4;
336 u32 outring_size; /* ORSx - Output ring size */
337 u32 rsvd5;
338 u32 outring_rmvd; /* ORJRx - Output ring jobs removed */
339 u32 rsvd6;
340 u32 outring_used; /* ORSFx - Output ring slots full */
341
342 /* Status/Configuration */
343 u32 rsvd7;
344 u32 jroutstatus; /* JRSTAx - JobR output status */
345 u32 rsvd8;
346 u32 jrintstatus; /* JRINTx - JobR interrupt status */
347 u32 rconfig_hi; /* JRxCFG - Ring configuration */
348 u32 rconfig_lo;
349
350 /* Indices. CAAM maintains as "heads" of each queue */
351 u32 rsvd9;
352 u32 inp_rdidx; /* IRRIx - Input ring read index */
353 u32 rsvd10;
354 u32 out_wtidx; /* ORWIx - Output ring write index */
355
356 /* Command/control */
357 u32 rsvd11;
358 u32 jrcommand; /* JRCRx - JobR command */
359
360 u32 rsvd12[932];
361
362 /* Performance Monitor f00-fff */
363 struct caam_perfmon perfmon;
364};
365
366#define JR_RINGSIZE_MASK 0x03ff
367/*
368 * jrstatus - Job Ring Output Status
369 * All values in lo word
370 * Also note, same values written out as status through QI
371 * in the command/status field of a frame descriptor
372 */
373#define JRSTA_SSRC_SHIFT 28
374#define JRSTA_SSRC_MASK 0xf0000000
375
376#define JRSTA_SSRC_NONE 0x00000000
377#define JRSTA_SSRC_CCB_ERROR 0x20000000
378#define JRSTA_SSRC_JUMP_HALT_USER 0x30000000
379#define JRSTA_SSRC_DECO 0x40000000
380#define JRSTA_SSRC_JRERROR 0x60000000
381#define JRSTA_SSRC_JUMP_HALT_CC 0x70000000
382
383#define JRSTA_DECOERR_JUMP 0x08000000
384#define JRSTA_DECOERR_INDEX_SHIFT 8
385#define JRSTA_DECOERR_INDEX_MASK 0xff00
386#define JRSTA_DECOERR_ERROR_MASK 0x00ff
387
388#define JRSTA_DECOERR_NONE 0x00
389#define JRSTA_DECOERR_LINKLEN 0x01
390#define JRSTA_DECOERR_LINKPTR 0x02
391#define JRSTA_DECOERR_JRCTRL 0x03
392#define JRSTA_DECOERR_DESCCMD 0x04
393#define JRSTA_DECOERR_ORDER 0x05
394#define JRSTA_DECOERR_KEYCMD 0x06
395#define JRSTA_DECOERR_LOADCMD 0x07
396#define JRSTA_DECOERR_STORECMD 0x08
397#define JRSTA_DECOERR_OPCMD 0x09
398#define JRSTA_DECOERR_FIFOLDCMD 0x0a
399#define JRSTA_DECOERR_FIFOSTCMD 0x0b
400#define JRSTA_DECOERR_MOVECMD 0x0c
401#define JRSTA_DECOERR_JUMPCMD 0x0d
402#define JRSTA_DECOERR_MATHCMD 0x0e
403#define JRSTA_DECOERR_SHASHCMD 0x0f
404#define JRSTA_DECOERR_SEQCMD 0x10
405#define JRSTA_DECOERR_DECOINTERNAL 0x11
406#define JRSTA_DECOERR_SHDESCHDR 0x12
407#define JRSTA_DECOERR_HDRLEN 0x13
408#define JRSTA_DECOERR_BURSTER 0x14
409#define JRSTA_DECOERR_DESCSIGNATURE 0x15
410#define JRSTA_DECOERR_DMA 0x16
411#define JRSTA_DECOERR_BURSTFIFO 0x17
412#define JRSTA_DECOERR_JRRESET 0x1a
413#define JRSTA_DECOERR_JOBFAIL 0x1b
414#define JRSTA_DECOERR_DNRERR 0x80
415#define JRSTA_DECOERR_UNDEFPCL 0x81
416#define JRSTA_DECOERR_PDBERR 0x82
417#define JRSTA_DECOERR_ANRPLY_LATE 0x83
418#define JRSTA_DECOERR_ANRPLY_REPLAY 0x84
419#define JRSTA_DECOERR_SEQOVF 0x85
420#define JRSTA_DECOERR_INVSIGN 0x86
421#define JRSTA_DECOERR_DSASIGN 0x87
422
423#define JRSTA_CCBERR_JUMP 0x08000000
424#define JRSTA_CCBERR_INDEX_MASK 0xff00
425#define JRSTA_CCBERR_INDEX_SHIFT 8
426#define JRSTA_CCBERR_CHAID_MASK 0x00f0
427#define JRSTA_CCBERR_CHAID_SHIFT 4
428#define JRSTA_CCBERR_ERRID_MASK 0x000f
429
430#define JRSTA_CCBERR_CHAID_AES (0x01 << JRSTA_CCBERR_CHAID_SHIFT)
431#define JRSTA_CCBERR_CHAID_DES (0x02 << JRSTA_CCBERR_CHAID_SHIFT)
432#define JRSTA_CCBERR_CHAID_ARC4 (0x03 << JRSTA_CCBERR_CHAID_SHIFT)
433#define JRSTA_CCBERR_CHAID_MD (0x04 << JRSTA_CCBERR_CHAID_SHIFT)
434#define JRSTA_CCBERR_CHAID_RNG (0x05 << JRSTA_CCBERR_CHAID_SHIFT)
435#define JRSTA_CCBERR_CHAID_SNOW (0x06 << JRSTA_CCBERR_CHAID_SHIFT)
436#define JRSTA_CCBERR_CHAID_KASUMI (0x07 << JRSTA_CCBERR_CHAID_SHIFT)
437#define JRSTA_CCBERR_CHAID_PK (0x08 << JRSTA_CCBERR_CHAID_SHIFT)
438#define JRSTA_CCBERR_CHAID_CRC (0x09 << JRSTA_CCBERR_CHAID_SHIFT)
439
440#define JRSTA_CCBERR_ERRID_NONE 0x00
441#define JRSTA_CCBERR_ERRID_MODE 0x01
442#define JRSTA_CCBERR_ERRID_DATASIZ 0x02
443#define JRSTA_CCBERR_ERRID_KEYSIZ 0x03
444#define JRSTA_CCBERR_ERRID_PKAMEMSZ 0x04
445#define JRSTA_CCBERR_ERRID_PKBMEMSZ 0x05
446#define JRSTA_CCBERR_ERRID_SEQUENCE 0x06
447#define JRSTA_CCBERR_ERRID_PKDIVZRO 0x07
448#define JRSTA_CCBERR_ERRID_PKMODEVN 0x08
449#define JRSTA_CCBERR_ERRID_KEYPARIT 0x09
450#define JRSTA_CCBERR_ERRID_ICVCHK 0x0a
451#define JRSTA_CCBERR_ERRID_HARDWARE 0x0b
452#define JRSTA_CCBERR_ERRID_CCMAAD 0x0c
453#define JRSTA_CCBERR_ERRID_INVCHA 0x0f
454
455#define JRINT_ERR_INDEX_MASK 0x3fff0000
456#define JRINT_ERR_INDEX_SHIFT 16
457#define JRINT_ERR_TYPE_MASK 0xf00
458#define JRINT_ERR_TYPE_SHIFT 8
459#define JRINT_ERR_HALT_MASK 0xc
460#define JRINT_ERR_HALT_SHIFT 2
461#define JRINT_ERR_HALT_INPROGRESS 0x4
462#define JRINT_ERR_HALT_COMPLETE 0x8
463#define JRINT_JR_ERROR 0x02
464#define JRINT_JR_INT 0x01
465
466#define JRINT_ERR_TYPE_WRITE 1
467#define JRINT_ERR_TYPE_BAD_INPADDR 3
468#define JRINT_ERR_TYPE_BAD_OUTADDR 4
469#define JRINT_ERR_TYPE_INV_INPWRT 5
470#define JRINT_ERR_TYPE_INV_OUTWRT 6
471#define JRINT_ERR_TYPE_RESET 7
472#define JRINT_ERR_TYPE_REMOVE_OFL 8
473#define JRINT_ERR_TYPE_ADD_OFL 9
474
475#define JRCFG_SOE 0x04
476#define JRCFG_ICEN 0x02
477#define JRCFG_IMSK 0x01
478#define JRCFG_ICDCT_SHIFT 8
479#define JRCFG_ICTT_SHIFT 16
480
481#define JRCR_RESET 0x01
482
483/*
484 * caam_assurance - Assurance Controller View
485 * base + 0x6000 padded out to 0x1000
486 */
487
488struct rtic_element {
489 u64 address;
490 u32 rsvd;
491 u32 length;
492};
493
494struct rtic_block {
495 struct rtic_element element[2];
496};
497
498struct rtic_memhash {
499 u32 memhash_be[32];
500 u32 memhash_le[32];
501};
502
503struct caam_assurance {
504 /* Status/Command/Watchdog */
505 u32 rsvd1;
506 u32 status; /* RSTA - Status */
507 u32 rsvd2;
508 u32 cmd; /* RCMD - Command */
509 u32 rsvd3;
510 u32 ctrl; /* RCTL - Control */
511 u32 rsvd4;
512 u32 throttle; /* RTHR - Throttle */
513 u32 rsvd5[2];
514 u64 watchdog; /* RWDOG - Watchdog Timer */
515 u32 rsvd6;
516 u32 rend; /* REND - Endian corrections */
517 u32 rsvd7[50];
518
519 /* Block access/configuration @ 100/110/120/130 */
520 struct rtic_block memblk[4]; /* Memory Blocks A-D */
521 u32 rsvd8[32];
522
523 /* Block hashes @ 200/300/400/500 */
524 struct rtic_memhash hash[4]; /* Block hash values A-D */
525 u32 rsvd_3[640];
526};
527
528/*
529 * caam_queue_if - QI configuration and control
530 * starts base + 0x7000, padded out to 0x1000 long
531 */
532
533struct caam_queue_if {
534 u32 qi_control_hi; /* QICTL - QI Control */
535 u32 qi_control_lo;
536 u32 rsvd1;
537 u32 qi_status; /* QISTA - QI Status */
538 u32 qi_deq_cfg_hi; /* QIDQC - QI Dequeue Configuration */
539 u32 qi_deq_cfg_lo;
540 u32 qi_enq_cfg_hi; /* QISEQC - QI Enqueue Command */
541 u32 qi_enq_cfg_lo;
542 u32 rsvd2[1016];
543};
544
545/* QI control bits - low word */
546#define QICTL_DQEN 0x01 /* Enable frame pop */
547#define QICTL_STOP 0x02 /* Stop dequeue/enqueue */
548#define QICTL_SOE 0x04 /* Stop on error */
549
550/* QI control bits - high word */
551#define QICTL_MBSI 0x01
552#define QICTL_MHWSI 0x02
553#define QICTL_MWSI 0x04
554#define QICTL_MDWSI 0x08
555#define QICTL_CBSI 0x10 /* CtrlDataByteSwapInput */
556#define QICTL_CHWSI 0x20 /* CtrlDataHalfSwapInput */
557#define QICTL_CWSI 0x40 /* CtrlDataWordSwapInput */
558#define QICTL_CDWSI 0x80 /* CtrlDataDWordSwapInput */
559#define QICTL_MBSO 0x0100
560#define QICTL_MHWSO 0x0200
561#define QICTL_MWSO 0x0400
562#define QICTL_MDWSO 0x0800
563#define QICTL_CBSO 0x1000 /* CtrlDataByteSwapOutput */
564#define QICTL_CHWSO 0x2000 /* CtrlDataHalfSwapOutput */
565#define QICTL_CWSO 0x4000 /* CtrlDataWordSwapOutput */
566#define QICTL_CDWSO 0x8000 /* CtrlDataDWordSwapOutput */
567#define QICTL_DMBS 0x010000
568#define QICTL_EPO 0x020000
569
570/* QI status bits */
571#define QISTA_PHRDERR 0x01 /* PreHeader Read Error */
572#define QISTA_CFRDERR 0x02 /* Compound Frame Read Error */
573#define QISTA_OFWRERR 0x04 /* Output Frame Read Error */
574#define QISTA_BPDERR 0x08 /* Buffer Pool Depleted */
575#define QISTA_BTSERR 0x10 /* Buffer Undersize */
576#define QISTA_CFWRERR 0x20 /* Compound Frame Write Err */
577#define QISTA_STOPD 0x80000000 /* QI Stopped (see QICTL) */
578
579/* deco_sg_table - DECO view of scatter/gather table */
580struct deco_sg_table {
581 u64 addr; /* Segment Address */
582 u32 elen; /* E, F bits + 30-bit length */
583 u32 bpid_offset; /* Buffer Pool ID + 16-bit length */
584};
585
586/*
587 * caam_deco - descriptor controller - CHA cluster block
588 *
589 * Only accessible when direct DECO access is turned on
590 * (done in DECORR, via MID programmed in DECOxMID
591 *
592 * 5 typical, base + 0x8000/9000/a000/b000
593 * Padded out to 0x1000 long
594 */
595struct caam_deco {
596 u32 rsvd1;
597 u32 cls1_mode; /* CxC1MR - Class 1 Mode */
598 u32 rsvd2;
599 u32 cls1_keysize; /* CxC1KSR - Class 1 Key Size */
600 u32 cls1_datasize_hi; /* CxC1DSR - Class 1 Data Size */
601 u32 cls1_datasize_lo;
602 u32 rsvd3;
603 u32 cls1_icvsize; /* CxC1ICVSR - Class 1 ICV size */
604 u32 rsvd4[5];
605 u32 cha_ctrl; /* CCTLR - CHA control */
606 u32 rsvd5;
607 u32 irq_crtl; /* CxCIRQ - CCB interrupt done/error/clear */
608 u32 rsvd6;
609 u32 clr_written; /* CxCWR - Clear-Written */
610 u32 ccb_status_hi; /* CxCSTA - CCB Status/Error */
611 u32 ccb_status_lo;
612 u32 rsvd7[3];
613 u32 aad_size; /* CxAADSZR - Current AAD Size */
614 u32 rsvd8;
615 u32 cls1_iv_size; /* CxC1IVSZR - Current Class 1 IV Size */
616 u32 rsvd9[7];
617 u32 pkha_a_size; /* PKASZRx - Size of PKHA A */
618 u32 rsvd10;
619 u32 pkha_b_size; /* PKBSZRx - Size of PKHA B */
620 u32 rsvd11;
621 u32 pkha_n_size; /* PKNSZRx - Size of PKHA N */
622 u32 rsvd12;
623 u32 pkha_e_size; /* PKESZRx - Size of PKHA E */
624 u32 rsvd13[24];
625 u32 cls1_ctx[16]; /* CxC1CTXR - Class 1 Context @100 */
626 u32 rsvd14[48];
627 u32 cls1_key[8]; /* CxC1KEYR - Class 1 Key @200 */
628 u32 rsvd15[121];
629 u32 cls2_mode; /* CxC2MR - Class 2 Mode */
630 u32 rsvd16;
631 u32 cls2_keysize; /* CxX2KSR - Class 2 Key Size */
632 u32 cls2_datasize_hi; /* CxC2DSR - Class 2 Data Size */
633 u32 cls2_datasize_lo;
634 u32 rsvd17;
635 u32 cls2_icvsize; /* CxC2ICVSZR - Class 2 ICV Size */
636 u32 rsvd18[56];
637 u32 cls2_ctx[18]; /* CxC2CTXR - Class 2 Context @500 */
638 u32 rsvd19[46];
639 u32 cls2_key[32]; /* CxC2KEYR - Class2 Key @600 */
640 u32 rsvd20[84];
641 u32 inp_infofifo_hi; /* CxIFIFO - Input Info FIFO @7d0 */
642 u32 inp_infofifo_lo;
643 u32 rsvd21[2];
644 u64 inp_datafifo; /* CxDFIFO - Input Data FIFO */
645 u32 rsvd22[2];
646 u64 out_datafifo; /* CxOFIFO - Output Data FIFO */
647 u32 rsvd23[2];
648 u32 jr_ctl_hi; /* CxJRR - JobR Control Register @800 */
649 u32 jr_ctl_lo;
650 u64 jr_descaddr; /* CxDADR - JobR Descriptor Address */
651 u32 op_status_hi; /* DxOPSTA - DECO Operation Status */
652 u32 op_status_lo;
653 u32 rsvd24[2];
654 u32 liodn; /* DxLSR - DECO LIODN Status - non-seq */
655 u32 td_liodn; /* DxLSR - DECO LIODN Status - trustdesc */
656 u32 rsvd26[6];
657 u64 math[4]; /* DxMTH - Math register */
658 u32 rsvd27[8];
659 struct deco_sg_table gthr_tbl[4]; /* DxGTR - Gather Tables */
660 u32 rsvd28[16];
661 struct deco_sg_table sctr_tbl[4]; /* DxSTR - Scatter Tables */
662 u32 rsvd29[48];
663 u32 descbuf[64]; /* DxDESB - Descriptor buffer */
664 u32 rsvd30[320];
665};
666
667/*
668 * Current top-level view of memory map is:
669 *
670 * 0x0000 - 0x0fff - CAAM Top-Level Control
671 * 0x1000 - 0x1fff - Job Ring 0
672 * 0x2000 - 0x2fff - Job Ring 1
673 * 0x3000 - 0x3fff - Job Ring 2
674 * 0x4000 - 0x4fff - Job Ring 3
675 * 0x5000 - 0x5fff - (unused)
676 * 0x6000 - 0x6fff - Assurance Controller
677 * 0x7000 - 0x7fff - Queue Interface
678 * 0x8000 - 0x8fff - DECO-CCB 0
679 * 0x9000 - 0x9fff - DECO-CCB 1
680 * 0xa000 - 0xafff - DECO-CCB 2
681 * 0xb000 - 0xbfff - DECO-CCB 3
682 * 0xc000 - 0xcfff - DECO-CCB 4
683 *
684 * caam_full describes the full register view of CAAM if useful,
685 * although many configurations may choose to implement parts of
686 * the register map separately, in differing privilege regions
687 */
688struct caam_full {
689 struct caam_ctrl __iomem ctrl;
690 struct caam_job_ring jr[4];
691 u64 rsvd[512];
692 struct caam_assurance assure;
693 struct caam_queue_if qi;
694};
695
696#endif /* REGS_H */