regs.h source code [linux/drivers/crypto/caam/regs.h]

1	/ SPDX-License-Identifier: GPL-2.0 /
2	/*
3	* CAAM hardware register-level view
4	*
5	* Copyright 2008-2011 Freescale Semiconductor, Inc.
6	* Copyright 2018, 2023 NXP
7	*/
8
9	#ifndef REGS_H
10	#define REGS_H
11
12	#include <linux/types.h>
13	#include <linux/bitops.h>
14	#include <linux/io.h>
15	#include <linux/io-64-nonatomic-hi-lo.h>
16
17	/*
18	* Architecture-specific register access methods
19	*
20	* CAAM's bus-addressable registers are 64 bits internally.
21	* They have been wired to be safely accessible on 32-bit
22	* architectures, however. Registers were organized such
23	* that (a) they can be contained in 32 bits, (b) if not, then they
24	* can be treated as two 32-bit entities, or finally (c) if they
25	* must be treated as a single 64-bit value, then this can safely
26	* be done with two 32-bit cycles.
27	*
28	* For 32-bit operations on 64-bit values, CAAM follows the same
29	* 64-bit register access conventions as it's predecessors, in that
30	* writes are "triggered" by a write to the register at the numerically
31	* higher address, thus, a full 64-bit write cycle requires a write
32	* to the lower address, followed by a write to the higher address,
33	* which will latch/execute the write cycle.
34	*
35	* For example, let's assume a SW reset of CAAM through the master
36	* configuration register.
37	* - SWRST is in bit 31 of MCFG.
38	* - MCFG begins at base+0x0000.
39	* - Bits 63-32 are a 32-bit word at base+0x0000 (numerically-lower)
40	* - Bits 31-0 are a 32-bit word at base+0x0004 (numerically-higher)
41	*
42	* (and on Power, the convention is 0-31, 32-63, I know...)
43	*
44	* Assuming a 64-bit write to this MCFG to perform a software reset
45	* would then require a write of 0 to base+0x0000, followed by a
46	* write of 0x80000000 to base+0x0004, which would "execute" the
47	* reset.
48	*
49	* Of course, since MCFG 63-32 is all zero, we could cheat and simply
50	* write 0x8000000 to base+0x0004, and the reset would work fine.
51	* However, since CAAM does contain some write-and-read-intended
52	* 64-bit registers, this code defines 64-bit access methods for
53	* the sake of internal consistency and simplicity, and so that a
54	* clean transition to 64-bit is possible when it becomes necessary.
55	*
56	* There are limitations to this that the developer must recognize.
57	* 32-bit architectures cannot enforce an atomic-64 operation,
58	* Therefore:
59	*
60	* - On writes, since the HW is assumed to latch the cycle on the
61	* write of the higher-numeric-address word, then ordered
62	* writes work OK.
63	*
64	* - For reads, where a register contains a relevant value of more
65	* that 32 bits, the hardware employs logic to latch the other
66	* "half" of the data until read, ensuring an accurate value.
67	* This is of particular relevance when dealing with CAAM's
68	* performance counters.
69	*
70	*/
71
72	extern bool caam_little_end;
73	extern bool caam_imx;
74	extern size_t caam_ptr_sz;
75
76	#define caam_to_cpu(len) \
77	static inline u##len caam##len ## _to_cpu(u##len val) \
78	{ \
79	if (caam_little_end) \
80	return le##len ## _to_cpu((__force __le##len)val); \
81	else \
82	return be##len ## _to_cpu((__force __be##len)val); \
83	}
84
85	#define cpu_to_caam(len) \
86	static inline u##len cpu_to_caam##len(u##len val) \
87	{ \
88	if (caam_little_end) \
89	return (__force u##len)cpu_to_le##len(val); \
90	else \
91	return (__force u##len)cpu_to_be##len(val); \
92	}
93
94	caam_to_cpu(`16`)
95	caam_to_cpu(`32`)
96	caam_to_cpu(`64`)
97	cpu_to_caam(`16`)
98	cpu_to_caam(`32`)
99	cpu_to_caam(`64`)
100
101	static inline void wr_reg32(void __iomem *reg, u32 data)
102	{
103	if (caam_little_end)
104	iowrite32(data, reg);
105	else
106	iowrite32be(data, reg);
107	}
108
109	static inline u32 rd_reg32(void __iomem *reg)
110	{
111	if (caam_little_end)
112	return ioread32(reg);
113
114	return ioread32be(reg);
115	}
116
117	static inline void clrsetbits_32(void __iomem *reg, u32 clear, u32 set)
118	{
119	if (caam_little_end)
120	iowrite32((ioread32(reg) & ~clear) \| set, reg);
121	else
122	iowrite32be((ioread32be(reg) & ~clear) \| set, reg);
123	}
124
125	/*
126	* The only users of these wr/rd_reg64 functions is the Job Ring (JR).
127	* The DMA address registers in the JR are handled differently depending on
128	* platform:
129	*
130	* 1. All BE CAAM platforms and i.MX platforms (LE CAAM):
131	*
132	* base + 0x0000 : most-significant 32 bits
133	* base + 0x0004 : least-significant 32 bits
134	*
135	* The 32-bit version of this core therefore has to write to base + 0x0004
136	* to set the 32-bit wide DMA address.
137	*
138	* 2. All other LE CAAM platforms (LS1021A etc.)
139	* base + 0x0000 : least-significant 32 bits
140	* base + 0x0004 : most-significant 32 bits
141	*/
142	static inline void wr_reg64(void __iomem *reg, u64 data)
143	{
144	if (caam_little_end) {
145	if (caam_imx) {
146	iowrite32(data >> `32`, (u32 __iomem *)(reg));
147	iowrite32(data, (u32 __iomem *)(reg) + `1`);
148	} else {
149	iowrite64(val: data, addr: reg);
150	}
151	} else {
152	iowrite64be(val: data, addr: reg);
153	}
154	}
155
156	static inline u64 rd_reg64(void __iomem *reg)
157	{
158	if (caam_little_end) {
159	if (caam_imx) {
160	u32 low, high;
161
162	high = ioread32(reg);
163	low = ioread32(reg + sizeof(u32));
164
165	return low + ((u64)high << `32`);
166	} else {
167	return ioread64(addr: reg);
168	}
169	} else {
170	return ioread64be(addr: reg);
171	}
172	}
173
174	static inline u64 cpu_to_caam_dma64(dma_addr_t value)
175	{
176	if (caam_imx) {
177	u64 ret_val = (u64)cpu_to_caam32(lower_32_bits(value)) << `32`;
178
179	if (IS_ENABLED(CONFIG_ARCH_DMA_ADDR_T_64BIT))
180	ret_val \|= (u64)cpu_to_caam32(upper_32_bits(value));
181
182	return ret_val;
183	}
184
185	return cpu_to_caam64(val: value);
186	}
187
188	static inline u64 caam_dma64_to_cpu(u64 value)
189	{
190	if (caam_imx)
191	return (((u64)caam32_to_cpu(lower_32_bits(value)) << `32`) \|
192	(u64)caam32_to_cpu(upper_32_bits(value)));
193
194	return caam64_to_cpu(val: value);
195	}
196
197	static inline u64 cpu_to_caam_dma(u64 value)
198	{
199	if (IS_ENABLED(CONFIG_ARCH_DMA_ADDR_T_64BIT) &&
200	caam_ptr_sz == sizeof(u64))
201	return cpu_to_caam_dma64(value);
202	else
203	return cpu_to_caam32(val: value);
204	}
205
206	static inline u64 caam_dma_to_cpu(u64 value)
207	{
208	if (IS_ENABLED(CONFIG_ARCH_DMA_ADDR_T_64BIT) &&
209	caam_ptr_sz == sizeof(u64))
210	return caam_dma64_to_cpu(value);
211	else
212	return caam32_to_cpu(val: value);
213	}
214
215	/*
216	* jr_outentry
217	* Represents each entry in a JobR output ring
218	*/
219
220	static inline void jr_outentry_get(void outring, int* hw_idx, dma_addr_t *desc,
221	u32 *jrstatus)
222	{
223
224	if (caam_ptr_sz == sizeof(u32)) {
225	struct {
226	u32 desc;
227	u32 jrstatus;
228	} __packed *outentry = outring;
229
230	*desc = outentry[hw_idx].desc;
231	*jrstatus = outentry[hw_idx].jrstatus;
232	} else {
233	struct {
234	dma_addr_t desc;/ Pointer to completed descriptor /
235	u32 jrstatus; / Status for completed descriptor /
236	} __packed *outentry = outring;
237
238	*desc = outentry[hw_idx].desc;
239	*jrstatus = outentry[hw_idx].jrstatus;
240	}
241	}
242
243	#define SIZEOF_JR_OUTENTRY (caam_ptr_sz + sizeof(u32))
244
245	static inline dma_addr_t jr_outentry_desc(void outring, int* hw_idx)
246	{
247	dma_addr_t desc;
248	u32 unused;
249
250	jr_outentry_get(outring, hw_idx, desc: &desc, jrstatus: &unused);
251
252	return desc;
253	}
254
255	static inline u32 jr_outentry_jrstatus(void outring, int* hw_idx)
256	{
257	dma_addr_t unused;
258	u32 jrstatus;
259
260	jr_outentry_get(outring, hw_idx, desc: &unused, jrstatus: &jrstatus);
261
262	return jrstatus;
263	}
264
265	static inline void jr_inpentry_set(void inpring, int* hw_idx, dma_addr_t val)
266	{
267	if (caam_ptr_sz == sizeof(u32)) {
268	u32 *inpentry = inpring;
269
270	inpentry[hw_idx] = val;
271	} else {
272	dma_addr_t *inpentry = inpring;
273
274	inpentry[hw_idx] = val;
275	}
276	}
277
278	#define SIZEOF_JR_INPENTRY caam_ptr_sz
279
280
281	/ Version registers (Era 10+) e80-eff /
282	struct version_regs {
283	u32 crca; / CRCA_VERSION /
284	u32 afha; / AFHA_VERSION /
285	u32 kfha; / KFHA_VERSION /
286	u32 pkha; / PKHA_VERSION /
287	u32 aesa; / AESA_VERSION /
288	u32 mdha; / MDHA_VERSION /
289	u32 desa; / DESA_VERSION /
290	u32 snw8a; / SNW8A_VERSION /
291	u32 snw9a; / SNW9A_VERSION /
292	u32 zuce; / ZUCE_VERSION /
293	u32 zuca; / ZUCA_VERSION /
294	u32 ccha; / CCHA_VERSION /
295	u32 ptha; / PTHA_VERSION /
296	u32 rng; / RNG_VERSION /
297	u32 trng; / TRNG_VERSION /
298	u32 aaha; / AAHA_VERSION /
299	u32 rsvd[`10`];
300	u32 sr; / SR_VERSION /
301	u32 dma; / DMA_VERSION /
302	u32 ai; / AI_VERSION /
303	u32 qi; / QI_VERSION /
304	u32 jr; / JR_VERSION /
305	u32 deco; / DECO_VERSION /
306	};
307
308	/ Version registers bitfields /
309
310	/ Number of CHAs instantiated /
311	#define CHA_VER_NUM_MASK 0xffull
312	/ CHA Miscellaneous Information /
313	#define CHA_VER_MISC_SHIFT 8
314	#define CHA_VER_MISC_MASK (0xffull << CHA_VER_MISC_SHIFT)
315	/ CHA Revision Number /
316	#define CHA_VER_REV_SHIFT 16
317	#define CHA_VER_REV_MASK (0xffull << CHA_VER_REV_SHIFT)
318	/ CHA Version ID /
319	#define CHA_VER_VID_SHIFT 24
320	#define CHA_VER_VID_MASK (0xffull << CHA_VER_VID_SHIFT)
321
322	/ CHA Miscellaneous Information - AESA_MISC specific /
323	#define CHA_VER_MISC_AES_NUM_MASK GENMASK(7, 0)
324	#define CHA_VER_MISC_AES_GCM BIT(1 + CHA_VER_MISC_SHIFT)
325
326	/ CHA Miscellaneous Information - PKHA_MISC specific /
327	#define CHA_VER_MISC_PKHA_NO_CRYPT BIT(7 + CHA_VER_MISC_SHIFT)
328
329	/*
330	* caam_perfmon - Performance Monitor/Secure Memory Status/
331	* CAAM Global Status/Component Version IDs
332	*
333	* Spans f00-fff wherever instantiated
334	*/
335
336	/ Number of DECOs /
337	#define CHA_NUM_MS_DECONUM_SHIFT 24
338	#define CHA_NUM_MS_DECONUM_MASK (0xfull << CHA_NUM_MS_DECONUM_SHIFT)
339
340	/*
341	* CHA version IDs / instantiation bitfields (< Era 10)
342	* Defined for use with the cha_id fields in perfmon, but the same shift/mask
343	* selectors can be used to pull out the number of instantiated blocks within
344	* cha_num fields in perfmon because the locations are the same.
345	*/
346	#define CHA_ID_LS_AES_SHIFT 0
347	#define CHA_ID_LS_AES_MASK (0xfull << CHA_ID_LS_AES_SHIFT)
348
349	#define CHA_ID_LS_DES_SHIFT 4
350	#define CHA_ID_LS_DES_MASK (0xfull << CHA_ID_LS_DES_SHIFT)
351
352	#define CHA_ID_LS_ARC4_SHIFT 8
353	#define CHA_ID_LS_ARC4_MASK (0xfull << CHA_ID_LS_ARC4_SHIFT)
354
355	#define CHA_ID_LS_MD_SHIFT 12
356	#define CHA_ID_LS_MD_MASK (0xfull << CHA_ID_LS_MD_SHIFT)
357
358	#define CHA_ID_LS_RNG_SHIFT 16
359	#define CHA_ID_LS_RNG_MASK (0xfull << CHA_ID_LS_RNG_SHIFT)
360
361	#define CHA_ID_LS_SNW8_SHIFT 20
362	#define CHA_ID_LS_SNW8_MASK (0xfull << CHA_ID_LS_SNW8_SHIFT)
363
364	#define CHA_ID_LS_KAS_SHIFT 24
365	#define CHA_ID_LS_KAS_MASK (0xfull << CHA_ID_LS_KAS_SHIFT)
366
367	#define CHA_ID_LS_PK_SHIFT 28
368	#define CHA_ID_LS_PK_MASK (0xfull << CHA_ID_LS_PK_SHIFT)
369
370	#define CHA_ID_MS_CRC_SHIFT 0
371	#define CHA_ID_MS_CRC_MASK (0xfull << CHA_ID_MS_CRC_SHIFT)
372
373	#define CHA_ID_MS_SNW9_SHIFT 4
374	#define CHA_ID_MS_SNW9_MASK (0xfull << CHA_ID_MS_SNW9_SHIFT)
375
376	#define CHA_ID_MS_DECO_SHIFT 24
377	#define CHA_ID_MS_DECO_MASK (0xfull << CHA_ID_MS_DECO_SHIFT)
378
379	#define CHA_ID_MS_JR_SHIFT 28
380	#define CHA_ID_MS_JR_MASK (0xfull << CHA_ID_MS_JR_SHIFT)
381
382	/ Specific CHA version IDs /
383	#define CHA_VER_VID_AES_LP 0x3ull
384	#define CHA_VER_VID_AES_HP 0x4ull
385	#define CHA_VER_VID_MD_LP256 0x0ull
386	#define CHA_VER_VID_MD_LP512 0x1ull
387	#define CHA_VER_VID_MD_HP 0x2ull
388
389	struct sec_vid {
390	u16 ip_id;
391	u8 maj_rev;
392	u8 min_rev;
393	};
394
395	struct caam_perfmon {
396	/ Performance Monitor Registers f00-f9f /
397	u64 req_dequeued; / PC_REQ_DEQ - Dequeued Requests /
398	u64 ob_enc_req; / PC_OB_ENC_REQ - Outbound Encrypt Requests /
399	u64 ib_dec_req; / PC_IB_DEC_REQ - Inbound Decrypt Requests /
400	u64 ob_enc_bytes; / PC_OB_ENCRYPT - Outbound Bytes Encrypted /
401	u64 ob_prot_bytes; / PC_OB_PROTECT - Outbound Bytes Protected /
402	u64 ib_dec_bytes; / PC_IB_DECRYPT - Inbound Bytes Decrypted /
403	u64 ib_valid_bytes; / PC_IB_VALIDATED Inbound Bytes Validated /
404	u64 rsvd[`13`];
405
406	/ CAAM Hardware Instantiation Parameters fa0-fbf /
407	u32 cha_rev_ms; / CRNR - CHA Rev No. Most significant half/
408	u32 cha_rev_ls; / CRNR - CHA Rev No. Least significant half/
409	#define CTPR_MS_QI_SHIFT 25
410	#define CTPR_MS_QI_MASK (0x1ull << CTPR_MS_QI_SHIFT)
411	#define CTPR_MS_PS BIT(17)
412	#define CTPR_MS_DPAA2 BIT(13)
413	#define CTPR_MS_VIRT_EN_INCL 0x00000001
414	#define CTPR_MS_VIRT_EN_POR 0x00000002
415	#define CTPR_MS_PG_SZ_MASK 0x10
416	#define CTPR_MS_PG_SZ_SHIFT 4
417	u32 comp_parms_ms; / CTPR - Compile Parameters Register /
418	#define CTPR_LS_BLOB BIT(1)
419	u32 comp_parms_ls; / CTPR - Compile Parameters Register /
420	u64 rsvd1[`2`];
421
422	/ CAAM Global Status fc0-fdf /
423	u64 faultaddr; / FAR - Fault Address /
424	u32 faultliodn; / FALR - Fault Address LIODN /
425	u32 faultdetail; / FADR - Fault Addr Detail /
426	u32 rsvd2;
427	#define CSTA_PLEND BIT(10)
428	#define CSTA_ALT_PLEND BIT(18)
429	#define CSTA_MOO GENMASK(9, 8)
430	#define CSTA_MOO_SECURE 1
431	#define CSTA_MOO_TRUSTED 2
432	u32 status; / CSTA - CAAM Status /
433	u64 rsvd3;
434
435	/ Component Instantiation Parameters fe0-fff /
436	u32 rtic_id; / RVID - RTIC Version ID /
437	#define CCBVID_ERA_MASK 0xff000000
438	#define CCBVID_ERA_SHIFT 24
439	u32 ccb_id; / CCBVID - CCB Version ID /
440	u32 cha_id_ms; / CHAVID - CHA Version ID Most Significant/
441	u32 cha_id_ls; / CHAVID - CHA Version ID Least Significant/
442	u32 cha_num_ms; / CHANUM - CHA Number Most Significant /
443	u32 cha_num_ls; / CHANUM - CHA Number Least Significant/
444	#define SECVID_MS_IPID_MASK 0xffff0000
445	#define SECVID_MS_IPID_SHIFT 16
446	#define SECVID_MS_MAJ_REV_MASK 0x0000ff00
447	#define SECVID_MS_MAJ_REV_SHIFT 8
448	u32 caam_id_ms; / CAAMVID - CAAM Version ID MS /
449	u32 caam_id_ls; / CAAMVID - CAAM Version ID LS /
450	};
451
452	/ LIODN programming for DMA configuration /
453	#define MSTRID_LOCK_LIODN 0x80000000
454	#define MSTRID_LOCK_MAKETRUSTED 0x00010000 /* only for JR masterid */
455
456	#define MSTRID_LIODN_MASK 0x0fff
457	struct masterid {
458	u32 liodn_ms; / lock and make-trusted control bits /
459	u32 liodn_ls; / LIODN for non-sequence and seq access /
460	};
461
462	/ RNGB test mode (replicated twice in some configurations) /
463	/ Padded out to 0x100 /
464	struct rngtst {
465	u32 mode; / RTSTMODEx - Test mode /
466	u32 rsvd1[`3`];
467	u32 reset; / RTSTRESETx - Test reset control /
468	u32 rsvd2[`3`];
469	u32 status; / RTSTSSTATUSx - Test status /
470	u32 rsvd3;
471	u32 errstat; / RTSTERRSTATx - Test error status /
472	u32 rsvd4;
473	u32 errctl; / RTSTERRCTLx - Test error control /
474	u32 rsvd5;
475	u32 entropy; / RTSTENTROPYx - Test entropy /
476	u32 rsvd6[`15`];
477	u32 verifctl; / RTSTVERIFCTLx - Test verification control /
478	u32 rsvd7;
479	u32 verifstat; / RTSTVERIFSTATx - Test verification status /
480	u32 rsvd8;
481	u32 verifdata; / RTSTVERIFDx - Test verification data /
482	u32 rsvd9;
483	u32 xkey; / RTSTXKEYx - Test XKEY /
484	u32 rsvd10;
485	u32 oscctctl; / RTSTOSCCTCTLx - Test osc. counter control /
486	u32 rsvd11;
487	u32 oscct; / RTSTOSCCTx - Test oscillator counter /
488	u32 rsvd12;
489	u32 oscctstat; / RTSTODCCTSTATx - Test osc counter status /
490	u32 rsvd13[`2`];
491	u32 ofifo[`4`]; / RTSTOFIFOx - Test output FIFO /
492	u32 rsvd14[`15`];
493	};
494
495	/ RNG4 TRNG test registers /
496	struct rng4tst {
497	#define RTMCTL_ACC BIT(5) /* TRNG access mode */
498	#define RTMCTL_PRGM BIT(16) /* 1 -> program mode, 0 -> run mode */
499	#define RTMCTL_SAMP_MODE_VON_NEUMANN_ES_SC 0 /* use von Neumann data in
500	both entropy shifter and
501	statistical checker */
502	#define RTMCTL_SAMP_MODE_RAW_ES_SC 1 /* use raw data in both
503	entropy shifter and
504	statistical checker */
505	#define RTMCTL_SAMP_MODE_VON_NEUMANN_ES_RAW_SC 2 /* use von Neumann data in
506	entropy shifter, raw data
507	in statistical checker */
508	#define RTMCTL_SAMP_MODE_INVALID 3 /* invalid combination */
509	u32 rtmctl; / misc. control register /
510	u32 rtscmisc; / statistical check misc. register /
511	u32 rtpkrrng; / poker range register /
512	union {
513	u32 rtpkrmax; / PRGM=1: poker max. limit register /
514	u32 rtpkrsq; / PRGM=0: poker square calc. result register /
515	};
516	#define RTSDCTL_ENT_DLY_SHIFT 16
517	#define RTSDCTL_ENT_DLY_MASK (0xffff << RTSDCTL_ENT_DLY_SHIFT)
518	#define RTSDCTL_ENT_DLY_MIN 3200
519	#define RTSDCTL_ENT_DLY_MAX 12800
520	#define RTSDCTL_SAMP_SIZE_MASK 0xffff
521	#define RTSDCTL_SAMP_SIZE_VAL 512
522	u32 rtsdctl; / seed control register /
523	union {
524	u32 rtsblim; / PRGM=1: sparse bit limit register /
525	u32 rttotsam; / PRGM=0: total samples register /
526	};
527	u32 rtfrqmin; / frequency count min. limit register /
528	#define RTFRQMAX_DISABLE (1 << 20)
529	union {
530	u32 rtfrqmax; / PRGM=1: freq. count max. limit register /
531	u32 rtfrqcnt; / PRGM=0: freq. count register /
532	};
533	union {
534	u32 rtscmc; / statistical check run monobit count /
535	u32 rtscml; / statistical check run monobit limit /
536	};
537	union {
538	u32 rtscrc[`6`]; / statistical check run length count /
539	u32 rtscrl[`6`]; / statistical check run length limit /
540	};
541	u32 rsvd1[`33`];
542	#define RDSTA_SKVT 0x80000000
543	#define RDSTA_SKVN 0x40000000
544	#define RDSTA_PR0 BIT(4)
545	#define RDSTA_PR1 BIT(5)
546	#define RDSTA_IF0 0x00000001
547	#define RDSTA_IF1 0x00000002
548	#define RDSTA_MASK (RDSTA_PR1 \| RDSTA_PR0 \| RDSTA_IF1 \| RDSTA_IF0)
549	u32 rdsta;
550	u32 rsvd2[`15`];
551	};
552
553	/*
554	* caam_ctrl - basic core configuration
555	* starts base + 0x0000 padded out to 0x1000
556	*/
557
558	#define KEK_KEY_SIZE 8
559	#define TKEK_KEY_SIZE 8
560	#define TDSK_KEY_SIZE 8
561
562	#define DECO_RESET 1 /* Use with DECO reset/availability regs */
563	#define DECO_RESET_0 (DECO_RESET << 0)
564	#define DECO_RESET_1 (DECO_RESET << 1)
565	#define DECO_RESET_2 (DECO_RESET << 2)
566	#define DECO_RESET_3 (DECO_RESET << 3)
567	#define DECO_RESET_4 (DECO_RESET << 4)
568
569	struct caam_ctrl {
570	/ Basic Configuration Section 000-01f /
571	/ Read/Writable /
572	u32 rsvd1;
573	u32 mcr; / MCFG Master Config Register /
574	u32 rsvd2;
575	u32 scfgr; / SCFGR, Security Config Register /
576
577	/ Bus Access Configuration Section 010-11f /
578	/ Read/Writable /
579	struct masterid jr_mid[`4`]; / JRxLIODNR - JobR LIODN setup /
580	u32 rsvd3[`11`];
581	u32 jrstart; / JRSTART - Job Ring Start Register /
582	struct masterid rtic_mid[`4`]; / RTICxLIODNR - RTIC LIODN setup /
583	u32 rsvd4[`5`];
584	u32 deco_rsr; / DECORSR - Deco Request Source /
585	u32 rsvd11;
586	u32 deco_rq; / DECORR - DECO Request /
587	struct masterid deco_mid[`16`]; / DECOxLIODNR - 1 per DECO /
588
589	/ DECO Availability/Reset Section 120-3ff /
590	u32 deco_avail; / DAR - DECO availability /
591	u32 deco_reset; / DRR - DECO reset /
592	u32 rsvd6[`182`];
593
594	/ Key Encryption/Decryption Configuration 400-5ff /
595	/ Read/Writable only while in Non-secure mode /
596	u32 kek[KEK_KEY_SIZE]; / JDKEKR - Key Encryption Key /
597	u32 tkek[TKEK_KEY_SIZE]; / TDKEKR - Trusted Desc KEK /
598	u32 tdsk[TDSK_KEY_SIZE]; / TDSKR - Trusted Desc Signing Key /
599	u32 rsvd7[`32`];
600	u64 sknonce; / SKNR - Secure Key Nonce /
601	u32 rsvd8[`70`];
602
603	/ RNG Test/Verification/Debug Access 600-7ff /
604	/ (Useful in Test/Debug modes only...) /
605	union {
606	struct rngtst rtst[`2`];
607	struct rng4tst r4tst[`2`];
608	};
609
610	u32 rsvd9[`416`];
611
612	/ Version registers - introduced with era 10 e80-eff /
613	struct version_regs vreg;
614	/ Performance Monitor f00-fff /
615	struct caam_perfmon perfmon;
616	};
617
618	/*
619	* Controller master config register defs
620	*/
621	#define MCFGR_SWRESET 0x80000000 /* software reset */
622	#define MCFGR_WDENABLE 0x40000000 /* DECO watchdog enable */
623	#define MCFGR_WDFAIL 0x20000000 /* DECO watchdog force-fail */
624	#define MCFGR_DMA_RESET 0x10000000
625	#define MCFGR_LONG_PTR 0x00010000 /* Use >32-bit desc addressing */
626	#define SCFGR_RDBENABLE 0x00000400
627	#define SCFGR_VIRT_EN 0x00008000
628	#define DECORR_RQD0ENABLE 0x00000001 /* Enable DECO0 for direct access */
629	#define DECORSR_JR0 0x00000001 /* JR to supply TZ, SDID, ICID */
630	#define DECORSR_VALID 0x80000000
631	#define DECORR_DEN0 0x00010000 /* DECO0 available for access*/
632
633	/ AXI read cache control /
634	#define MCFGR_ARCACHE_SHIFT 12
635	#define MCFGR_ARCACHE_MASK (0xf << MCFGR_ARCACHE_SHIFT)
636	#define MCFGR_ARCACHE_BUFF (0x1 << MCFGR_ARCACHE_SHIFT)
637	#define MCFGR_ARCACHE_CACH (0x2 << MCFGR_ARCACHE_SHIFT)
638	#define MCFGR_ARCACHE_RALL (0x4 << MCFGR_ARCACHE_SHIFT)
639
640	/ AXI write cache control /
641	#define MCFGR_AWCACHE_SHIFT 8
642	#define MCFGR_AWCACHE_MASK (0xf << MCFGR_AWCACHE_SHIFT)
643	#define MCFGR_AWCACHE_BUFF (0x1 << MCFGR_AWCACHE_SHIFT)
644	#define MCFGR_AWCACHE_CACH (0x2 << MCFGR_AWCACHE_SHIFT)
645	#define MCFGR_AWCACHE_WALL (0x8 << MCFGR_AWCACHE_SHIFT)
646
647	/ AXI pipeline depth /
648	#define MCFGR_AXIPIPE_SHIFT 4
649	#define MCFGR_AXIPIPE_MASK (0xf << MCFGR_AXIPIPE_SHIFT)
650
651	#define MCFGR_AXIPRI 0x00000008 /* Assert AXI priority sideband */
652	#define MCFGR_LARGE_BURST 0x00000004 /* 128/256-byte burst size */
653	#define MCFGR_BURST_64 0x00000001 /* 64-byte burst size */
654
655	/ JRSTART register offsets /
656	#define JRSTART_JR0_START 0x00000001 /* Start Job ring 0 */
657	#define JRSTART_JR1_START 0x00000002 /* Start Job ring 1 */
658	#define JRSTART_JR2_START 0x00000004 /* Start Job ring 2 */
659	#define JRSTART_JR3_START 0x00000008 /* Start Job ring 3 */
660
661	/*
662	* caam_job_ring - direct job ring setup
663	* 1-4 possible per instantiation, base + 1000/2000/3000/4000
664	* Padded out to 0x1000
665	*/
666	struct caam_job_ring {
667	/ Input ring /
668	u64 inpring_base; / IRBAx - Input desc ring baseaddr /
669	u32 rsvd1;
670	u32 inpring_size; / IRSx - Input ring size /
671	u32 rsvd2;
672	u32 inpring_avail; / IRSAx - Input ring room remaining /
673	u32 rsvd3;
674	u32 inpring_jobadd; / IRJAx - Input ring jobs added /
675
676	/ Output Ring /
677	u64 outring_base; / ORBAx - Output status ring base addr /
678	u32 rsvd4;
679	u32 outring_size; / ORSx - Output ring size /
680	u32 rsvd5;
681	u32 outring_rmvd; / ORJRx - Output ring jobs removed /
682	u32 rsvd6;
683	u32 outring_used; / ORSFx - Output ring slots full /
684
685	/ Status/Configuration /
686	u32 rsvd7;
687	u32 jroutstatus; / JRSTAx - JobR output status /
688	u32 rsvd8;
689	u32 jrintstatus; / JRINTx - JobR interrupt status /
690	u32 rconfig_hi; / JRxCFG - Ring configuration /
691	u32 rconfig_lo;
692
693	/ Indices. CAAM maintains as "heads" of each queue /
694	u32 rsvd9;
695	u32 inp_rdidx; / IRRIx - Input ring read index /
696	u32 rsvd10;
697	u32 out_wtidx; / ORWIx - Output ring write index /
698
699	/ Command/control /
700	u32 rsvd11;
701	u32 jrcommand; / JRCRx - JobR command /
702
703	u32 rsvd12[`900`];
704
705	/ Version registers - introduced with era 10 e80-eff /
706	struct version_regs vreg;
707	/ Performance Monitor f00-fff /
708	struct caam_perfmon perfmon;
709	};
710
711	#define JR_RINGSIZE_MASK 0x03ff
712	/*
713	* jrstatus - Job Ring Output Status
714	* All values in lo word
715	* Also note, same values written out as status through QI
716	* in the command/status field of a frame descriptor
717	*/
718	#define JRSTA_SSRC_SHIFT 28
719	#define JRSTA_SSRC_MASK 0xf0000000
720
721	#define JRSTA_SSRC_NONE 0x00000000
722	#define JRSTA_SSRC_CCB_ERROR 0x20000000
723	#define JRSTA_SSRC_JUMP_HALT_USER 0x30000000
724	#define JRSTA_SSRC_DECO 0x40000000
725	#define JRSTA_SSRC_QI 0x50000000
726	#define JRSTA_SSRC_JRERROR 0x60000000
727	#define JRSTA_SSRC_JUMP_HALT_CC 0x70000000
728
729	#define JRSTA_DECOERR_JUMP 0x08000000
730	#define JRSTA_DECOERR_INDEX_SHIFT 8
731	#define JRSTA_DECOERR_INDEX_MASK 0xff00
732	#define JRSTA_DECOERR_ERROR_MASK 0x00ff
733
734	#define JRSTA_DECOERR_NONE 0x00
735	#define JRSTA_DECOERR_LINKLEN 0x01
736	#define JRSTA_DECOERR_LINKPTR 0x02
737	#define JRSTA_DECOERR_JRCTRL 0x03
738	#define JRSTA_DECOERR_DESCCMD 0x04
739	#define JRSTA_DECOERR_ORDER 0x05
740	#define JRSTA_DECOERR_KEYCMD 0x06
741	#define JRSTA_DECOERR_LOADCMD 0x07
742	#define JRSTA_DECOERR_STORECMD 0x08
743	#define JRSTA_DECOERR_OPCMD 0x09
744	#define JRSTA_DECOERR_FIFOLDCMD 0x0a
745	#define JRSTA_DECOERR_FIFOSTCMD 0x0b
746	#define JRSTA_DECOERR_MOVECMD 0x0c
747	#define JRSTA_DECOERR_JUMPCMD 0x0d
748	#define JRSTA_DECOERR_MATHCMD 0x0e
749	#define JRSTA_DECOERR_SHASHCMD 0x0f
750	#define JRSTA_DECOERR_SEQCMD 0x10
751	#define JRSTA_DECOERR_DECOINTERNAL 0x11
752	#define JRSTA_DECOERR_SHDESCHDR 0x12
753	#define JRSTA_DECOERR_HDRLEN 0x13
754	#define JRSTA_DECOERR_BURSTER 0x14
755	#define JRSTA_DECOERR_DESCSIGNATURE 0x15
756	#define JRSTA_DECOERR_DMA 0x16
757	#define JRSTA_DECOERR_BURSTFIFO 0x17
758	#define JRSTA_DECOERR_JRRESET 0x1a
759	#define JRSTA_DECOERR_JOBFAIL 0x1b
760	#define JRSTA_DECOERR_DNRERR 0x80
761	#define JRSTA_DECOERR_UNDEFPCL 0x81
762	#define JRSTA_DECOERR_PDBERR 0x82
763	#define JRSTA_DECOERR_ANRPLY_LATE 0x83
764	#define JRSTA_DECOERR_ANRPLY_REPLAY 0x84
765	#define JRSTA_DECOERR_SEQOVF 0x85
766	#define JRSTA_DECOERR_INVSIGN 0x86
767	#define JRSTA_DECOERR_DSASIGN 0x87
768
769	#define JRSTA_QIERR_ERROR_MASK 0x00ff
770
771	#define JRSTA_CCBERR_JUMP 0x08000000
772	#define JRSTA_CCBERR_INDEX_MASK 0xff00
773	#define JRSTA_CCBERR_INDEX_SHIFT 8
774	#define JRSTA_CCBERR_CHAID_MASK 0x00f0
775	#define JRSTA_CCBERR_CHAID_SHIFT 4
776	#define JRSTA_CCBERR_ERRID_MASK 0x000f
777
778	#define JRSTA_CCBERR_CHAID_AES (0x01 << JRSTA_CCBERR_CHAID_SHIFT)
779	#define JRSTA_CCBERR_CHAID_DES (0x02 << JRSTA_CCBERR_CHAID_SHIFT)
780	#define JRSTA_CCBERR_CHAID_ARC4 (0x03 << JRSTA_CCBERR_CHAID_SHIFT)
781	#define JRSTA_CCBERR_CHAID_MD (0x04 << JRSTA_CCBERR_CHAID_SHIFT)
782	#define JRSTA_CCBERR_CHAID_RNG (0x05 << JRSTA_CCBERR_CHAID_SHIFT)
783	#define JRSTA_CCBERR_CHAID_SNOW (0x06 << JRSTA_CCBERR_CHAID_SHIFT)
784	#define JRSTA_CCBERR_CHAID_KASUMI (0x07 << JRSTA_CCBERR_CHAID_SHIFT)
785	#define JRSTA_CCBERR_CHAID_PK (0x08 << JRSTA_CCBERR_CHAID_SHIFT)
786	#define JRSTA_CCBERR_CHAID_CRC (0x09 << JRSTA_CCBERR_CHAID_SHIFT)
787
788	#define JRSTA_CCBERR_ERRID_NONE 0x00
789	#define JRSTA_CCBERR_ERRID_MODE 0x01
790	#define JRSTA_CCBERR_ERRID_DATASIZ 0x02
791	#define JRSTA_CCBERR_ERRID_KEYSIZ 0x03
792	#define JRSTA_CCBERR_ERRID_PKAMEMSZ 0x04
793	#define JRSTA_CCBERR_ERRID_PKBMEMSZ 0x05
794	#define JRSTA_CCBERR_ERRID_SEQUENCE 0x06
795	#define JRSTA_CCBERR_ERRID_PKDIVZRO 0x07
796	#define JRSTA_CCBERR_ERRID_PKMODEVN 0x08
797	#define JRSTA_CCBERR_ERRID_KEYPARIT 0x09
798	#define JRSTA_CCBERR_ERRID_ICVCHK 0x0a
799	#define JRSTA_CCBERR_ERRID_HARDWARE 0x0b
800	#define JRSTA_CCBERR_ERRID_CCMAAD 0x0c
801	#define JRSTA_CCBERR_ERRID_INVCHA 0x0f
802
803	#define JRINT_ERR_INDEX_MASK 0x3fff0000
804	#define JRINT_ERR_INDEX_SHIFT 16
805	#define JRINT_ERR_TYPE_MASK 0xf00
806	#define JRINT_ERR_TYPE_SHIFT 8
807	#define JRINT_ERR_HALT_MASK 0xc
808	#define JRINT_ERR_HALT_SHIFT 2
809	#define JRINT_ERR_HALT_INPROGRESS 0x4
810	#define JRINT_ERR_HALT_COMPLETE 0x8
811	#define JRINT_JR_ERROR 0x02
812	#define JRINT_JR_INT 0x01
813
814	#define JRINT_ERR_TYPE_WRITE 1
815	#define JRINT_ERR_TYPE_BAD_INPADDR 3
816	#define JRINT_ERR_TYPE_BAD_OUTADDR 4
817	#define JRINT_ERR_TYPE_INV_INPWRT 5
818	#define JRINT_ERR_TYPE_INV_OUTWRT 6
819	#define JRINT_ERR_TYPE_RESET 7
820	#define JRINT_ERR_TYPE_REMOVE_OFL 8
821	#define JRINT_ERR_TYPE_ADD_OFL 9
822
823	#define JRCFG_SOE 0x04
824	#define JRCFG_ICEN 0x02
825	#define JRCFG_IMSK 0x01
826	#define JRCFG_ICDCT_SHIFT 8
827	#define JRCFG_ICTT_SHIFT 16
828
829	#define JRCR_RESET 0x01
830
831	/*
832	* caam_assurance - Assurance Controller View
833	* base + 0x6000 padded out to 0x1000
834	*/
835
836	struct rtic_element {
837	u64 address;
838	u32 rsvd;
839	u32 length;
840	};
841
842	struct rtic_block {
843	struct rtic_element element[`2`];
844	};
845
846	struct rtic_memhash {
847	u32 memhash_be[`32`];
848	u32 memhash_le[`32`];
849	};
850
851	struct caam_assurance {
852	/ Status/Command/Watchdog /
853	u32 rsvd1;
854	u32 status; / RSTA - Status /
855	u32 rsvd2;
856	u32 cmd; / RCMD - Command /
857	u32 rsvd3;
858	u32 ctrl; / RCTL - Control /
859	u32 rsvd4;
860	u32 throttle; / RTHR - Throttle /
861	u32 rsvd5[`2`];
862	u64 watchdog; / RWDOG - Watchdog Timer /
863	u32 rsvd6;
864	u32 rend; / REND - Endian corrections /
865	u32 rsvd7[`50`];
866
867	/ Block access/configuration @ 100/110/120/130 /
868	struct rtic_block memblk[`4`]; / Memory Blocks A-D /
869	u32 rsvd8[`32`];
870
871	/ Block hashes @ 200/300/400/500 /
872	struct rtic_memhash hash[`4`]; / Block hash values A-D /
873	u32 rsvd_3[`640`];
874	};
875
876	/*
877	* caam_queue_if - QI configuration and control
878	* starts base + 0x7000, padded out to 0x1000 long
879	*/
880
881	struct caam_queue_if {
882	u32 qi_control_hi; / QICTL - QI Control /
883	u32 qi_control_lo;
884	u32 rsvd1;
885	u32 qi_status; / QISTA - QI Status /
886	u32 qi_deq_cfg_hi; / QIDQC - QI Dequeue Configuration /
887	u32 qi_deq_cfg_lo;
888	u32 qi_enq_cfg_hi; / QISEQC - QI Enqueue Command /
889	u32 qi_enq_cfg_lo;
890	u32 rsvd2[`1016`];
891	};
892
893	/ QI control bits - low word /
894	#define QICTL_DQEN 0x01 /* Enable frame pop */
895	#define QICTL_STOP 0x02 /* Stop dequeue/enqueue */
896	#define QICTL_SOE 0x04 /* Stop on error */
897
898	/ QI control bits - high word /
899	#define QICTL_MBSI 0x01
900	#define QICTL_MHWSI 0x02
901	#define QICTL_MWSI 0x04
902	#define QICTL_MDWSI 0x08
903	#define QICTL_CBSI 0x10 /* CtrlDataByteSwapInput */
904	#define QICTL_CHWSI 0x20 /* CtrlDataHalfSwapInput */
905	#define QICTL_CWSI 0x40 /* CtrlDataWordSwapInput */
906	#define QICTL_CDWSI 0x80 /* CtrlDataDWordSwapInput */
907	#define QICTL_MBSO 0x0100
908	#define QICTL_MHWSO 0x0200
909	#define QICTL_MWSO 0x0400
910	#define QICTL_MDWSO 0x0800
911	#define QICTL_CBSO 0x1000 /* CtrlDataByteSwapOutput */
912	#define QICTL_CHWSO 0x2000 /* CtrlDataHalfSwapOutput */
913	#define QICTL_CWSO 0x4000 /* CtrlDataWordSwapOutput */
914	#define QICTL_CDWSO 0x8000 /* CtrlDataDWordSwapOutput */
915	#define QICTL_DMBS 0x010000
916	#define QICTL_EPO 0x020000
917
918	/ QI status bits /
919	#define QISTA_PHRDERR 0x01 /* PreHeader Read Error */
920	#define QISTA_CFRDERR 0x02 /* Compound Frame Read Error */
921	#define QISTA_OFWRERR 0x04 /* Output Frame Read Error */
922	#define QISTA_BPDERR 0x08 /* Buffer Pool Depleted */
923	#define QISTA_BTSERR 0x10 /* Buffer Undersize */
924	#define QISTA_CFWRERR 0x20 /* Compound Frame Write Err */
925	#define QISTA_STOPD 0x80000000 /* QI Stopped (see QICTL) */
926
927	/ deco_sg_table - DECO view of scatter/gather table /
928	struct deco_sg_table {
929	u64 addr; / Segment Address /
930	u32 elen; / E, F bits + 30-bit length /
931	u32 bpid_offset; / Buffer Pool ID + 16-bit length /
932	};
933
934	/*
935	* caam_deco - descriptor controller - CHA cluster block
936	*
937	* Only accessible when direct DECO access is turned on
938	* (done in DECORR, via MID programmed in DECOxMID
939	*
940	* 5 typical, base + 0x8000/9000/a000/b000
941	* Padded out to 0x1000 long
942	*/
943	struct caam_deco {
944	u32 rsvd1;
945	u32 cls1_mode; / CxC1MR - Class 1 Mode /
946	u32 rsvd2;
947	u32 cls1_keysize; / CxC1KSR - Class 1 Key Size /
948	u32 cls1_datasize_hi; / CxC1DSR - Class 1 Data Size /
949	u32 cls1_datasize_lo;
950	u32 rsvd3;
951	u32 cls1_icvsize; / CxC1ICVSR - Class 1 ICV size /
952	u32 rsvd4[`5`];
953	u32 cha_ctrl; / CCTLR - CHA control /
954	u32 rsvd5;
955	u32 irq_crtl; / CxCIRQ - CCB interrupt done/error/clear /
956	u32 rsvd6;
957	u32 clr_written; / CxCWR - Clear-Written /
958	u32 ccb_status_hi; / CxCSTA - CCB Status/Error /
959	u32 ccb_status_lo;
960	u32 rsvd7[`3`];
961	u32 aad_size; / CxAADSZR - Current AAD Size /
962	u32 rsvd8;
963	u32 cls1_iv_size; / CxC1IVSZR - Current Class 1 IV Size /
964	u32 rsvd9[`7`];
965	u32 pkha_a_size; / PKASZRx - Size of PKHA A /
966	u32 rsvd10;
967	u32 pkha_b_size; / PKBSZRx - Size of PKHA B /
968	u32 rsvd11;
969	u32 pkha_n_size; / PKNSZRx - Size of PKHA N /
970	u32 rsvd12;
971	u32 pkha_e_size; / PKESZRx - Size of PKHA E /
972	u32 rsvd13[`24`];
973	u32 cls1_ctx[`16`]; / CxC1CTXR - Class 1 Context @100 /
974	u32 rsvd14[`48`];
975	u32 cls1_key[`8`]; / CxC1KEYR - Class 1 Key @200 /
976	u32 rsvd15[`121`];
977	u32 cls2_mode; / CxC2MR - Class 2 Mode /
978	u32 rsvd16;
979	u32 cls2_keysize; / CxX2KSR - Class 2 Key Size /
980	u32 cls2_datasize_hi; / CxC2DSR - Class 2 Data Size /
981	u32 cls2_datasize_lo;
982	u32 rsvd17;
983	u32 cls2_icvsize; / CxC2ICVSZR - Class 2 ICV Size /
984	u32 rsvd18[`56`];
985	u32 cls2_ctx[`18`]; / CxC2CTXR - Class 2 Context @500 /
986	u32 rsvd19[`46`];
987	u32 cls2_key[`32`]; / CxC2KEYR - Class2 Key @600 /
988	u32 rsvd20[`84`];
989	u32 inp_infofifo_hi; / CxIFIFO - Input Info FIFO @7d0 /
990	u32 inp_infofifo_lo;
991	u32 rsvd21[`2`];
992	u64 inp_datafifo; / CxDFIFO - Input Data FIFO /
993	u32 rsvd22[`2`];
994	u64 out_datafifo; / CxOFIFO - Output Data FIFO /
995	u32 rsvd23[`2`];
996	u32 jr_ctl_hi; / CxJRR - JobR Control Register @800 /
997	u32 jr_ctl_lo;
998	u64 jr_descaddr; / CxDADR - JobR Descriptor Address /
999	#define DECO_OP_STATUS_HI_ERR_MASK 0xF00000FF
1000	u32 op_status_hi; / DxOPSTA - DECO Operation Status /
1001	u32 op_status_lo;
1002	u32 rsvd24[`2`];
1003	u32 liodn; / DxLSR - DECO LIODN Status - non-seq /
1004	u32 td_liodn; / DxLSR - DECO LIODN Status - trustdesc /
1005	u32 rsvd26[`6`];
1006	u64 math[`4`]; / DxMTH - Math register /
1007	u32 rsvd27[`8`];
1008	struct deco_sg_table gthr_tbl[`4`]; / DxGTR - Gather Tables /
1009	u32 rsvd28[`16`];
1010	struct deco_sg_table sctr_tbl[`4`]; / DxSTR - Scatter Tables /
1011	u32 rsvd29[`48`];
1012	u32 descbuf[`64`]; / DxDESB - Descriptor buffer /
1013	u32 rscvd30[`193`];
1014	#define DESC_DBG_DECO_STAT_VALID 0x80000000
1015	#define DESC_DBG_DECO_STAT_MASK 0x00F00000
1016	#define DESC_DBG_DECO_STAT_SHIFT 20
1017	u32 desc_dbg; / DxDDR - DECO Debug Register /
1018	u32 rsvd31[`13`];
1019	#define DESC_DER_DECO_STAT_MASK 0x000F0000
1020	#define DESC_DER_DECO_STAT_SHIFT 16
1021	u32 dbg_exec; / DxDER - DECO Debug Exec Register /
1022	u32 rsvd32[`112`];
1023	};
1024
1025	#define DECO_STAT_HOST_ERR 0xD
1026
1027	#define DECO_JQCR_WHL 0x20000000
1028	#define DECO_JQCR_FOUR 0x10000000
1029
1030	#define JR_BLOCK_NUMBER 1
1031	#define ASSURE_BLOCK_NUMBER 6
1032	#define QI_BLOCK_NUMBER 7
1033	#define DECO_BLOCK_NUMBER 8
1034	#define PG_SIZE_4K 0x1000
1035	#define PG_SIZE_64K 0x10000
1036	#endif /* REGS_H */
1037

source code of linux/drivers/crypto/caam/regs.h