• Home
  • Line#
  • Scopes#
  • Navigate#
  • Raw
  • Download
1 /*
2  * Copyright (c) 2015-2021, ARM Limited and Contributors. All rights reserved.
3  *
4  * SPDX-License-Identifier: BSD-3-Clause
5  */
6 #ifndef ARM_DEF_H
7 #define ARM_DEF_H
8 
9 #include <arch.h>
10 #include <common/interrupt_props.h>
11 #include <common/tbbr/tbbr_img_def.h>
12 #include <drivers/arm/gic_common.h>
13 #include <lib/utils_def.h>
14 #include <lib/xlat_tables/xlat_tables_defs.h>
15 #include <plat/arm/common/smccc_def.h>
16 #include <plat/common/common_def.h>
17 
18 /******************************************************************************
19  * Definitions common to all ARM standard platforms
20  *****************************************************************************/
21 
22 /*
23  * Root of trust key hash lengths
24  */
25 #define ARM_ROTPK_HEADER_LEN		19
26 #define ARM_ROTPK_HASH_LEN		32
27 
28 /* Special value used to verify platform parameters from BL2 to BL31 */
29 #define ARM_BL31_PLAT_PARAM_VAL		ULL(0x0f1e2d3c4b5a6978)
30 
31 #define ARM_SYSTEM_COUNT		U(1)
32 
33 #define ARM_CACHE_WRITEBACK_SHIFT	6
34 
35 /*
36  * Macros mapping the MPIDR Affinity levels to ARM Platform Power levels. The
37  * power levels have a 1:1 mapping with the MPIDR affinity levels.
38  */
39 #define ARM_PWR_LVL0		MPIDR_AFFLVL0
40 #define ARM_PWR_LVL1		MPIDR_AFFLVL1
41 #define ARM_PWR_LVL2		MPIDR_AFFLVL2
42 #define ARM_PWR_LVL3		MPIDR_AFFLVL3
43 
44 /*
45  *  Macros for local power states in ARM platforms encoded by State-ID field
46  *  within the power-state parameter.
47  */
48 /* Local power state for power domains in Run state. */
49 #define ARM_LOCAL_STATE_RUN	U(0)
50 /* Local power state for retention. Valid only for CPU power domains */
51 #define ARM_LOCAL_STATE_RET	U(1)
52 /* Local power state for OFF/power-down. Valid for CPU and cluster power
53    domains */
54 #define ARM_LOCAL_STATE_OFF	U(2)
55 
56 /* Memory location options for TSP */
57 #define ARM_TRUSTED_SRAM_ID		0
58 #define ARM_TRUSTED_DRAM_ID		1
59 #define ARM_DRAM_ID			2
60 
61 #ifdef PLAT_ARM_TRUSTED_SRAM_BASE
62 #define ARM_TRUSTED_SRAM_BASE		PLAT_ARM_TRUSTED_SRAM_BASE
63 #else
64 #define ARM_TRUSTED_SRAM_BASE		UL(0x04000000)
65 #endif /* PLAT_ARM_TRUSTED_SRAM_BASE */
66 
67 #define ARM_SHARED_RAM_BASE		ARM_TRUSTED_SRAM_BASE
68 #define ARM_SHARED_RAM_SIZE		UL(0x00001000)	/* 4 KB */
69 
70 /* The remaining Trusted SRAM is used to load the BL images */
71 #define ARM_BL_RAM_BASE			(ARM_SHARED_RAM_BASE +	\
72 					 ARM_SHARED_RAM_SIZE)
73 #define ARM_BL_RAM_SIZE			(PLAT_ARM_TRUSTED_SRAM_SIZE -	\
74 					 ARM_SHARED_RAM_SIZE)
75 
76 /*
77  * The top 16MB (or 64MB if RME is enabled) of DRAM1 is configured as
78  * follows:
79  *   - SCP TZC DRAM: If present, DRAM reserved for SCP use
80  *   - L1 GPT DRAM: Reserved for L1 GPT if RME is enabled
81  *   - REALM DRAM: Reserved for Realm world if RME is enabled
82  *   - AP TZC DRAM: The remaining TZC secured DRAM reserved for AP use
83  *
84  *              RME enabled(64MB)                RME not enabled(16MB)
85  *              --------------------             -------------------
86  *              |                  |             |                 |
87  *              |  AP TZC (~28MB)  |             |  AP TZC (~14MB) |
88  *              --------------------             -------------------
89  *              |                  |             |                 |
90  *              |  REALM (32MB)    |             |  EL3 TZC (2MB)  |
91  *              --------------------             -------------------
92  *              |                  |             |                 |
93  *              |  EL3 TZC (3MB)   |             |    SCP TZC      |
94  *              --------------------  0xFFFF_FFFF-------------------
95  *              | L1 GPT + SCP TZC |
96  *              |       (~1MB)     |
97  *  0xFFFF_FFFF --------------------
98  */
99 #if ENABLE_RME
100 #define ARM_TZC_DRAM1_SIZE              UL(0x04000000) /* 64MB */
101 /*
102  * Define a region within the TZC secured DRAM for use by EL3 runtime
103  * firmware. This region is meant to be NOLOAD and will not be zero
104  * initialized. Data sections with the attribute `arm_el3_tzc_dram` will be
105  * placed here. 3MB region is reserved if RME is enabled, 2MB otherwise.
106  */
107 #define ARM_EL3_TZC_DRAM1_SIZE		UL(0x00300000) /* 3MB */
108 #define ARM_L1_GPT_SIZE			UL(0x00100000) /* 1MB */
109 #define ARM_REALM_SIZE			UL(0x02000000) /* 32MB */
110 #else
111 #define ARM_TZC_DRAM1_SIZE		UL(0x01000000) /* 16MB */
112 #define ARM_EL3_TZC_DRAM1_SIZE		UL(0x00200000) /* 2MB */
113 #define ARM_L1_GPT_SIZE			UL(0)
114 #define ARM_REALM_SIZE			UL(0)
115 #endif /* ENABLE_RME */
116 
117 #define ARM_SCP_TZC_DRAM1_BASE		(ARM_DRAM1_BASE +		\
118 					ARM_DRAM1_SIZE -		\
119 					(ARM_SCP_TZC_DRAM1_SIZE +	\
120 					ARM_L1_GPT_SIZE))
121 #define ARM_SCP_TZC_DRAM1_SIZE		PLAT_ARM_SCP_TZC_DRAM1_SIZE
122 #define ARM_SCP_TZC_DRAM1_END		(ARM_SCP_TZC_DRAM1_BASE +	\
123 					ARM_SCP_TZC_DRAM1_SIZE - 1U)
124 #if ENABLE_RME
125 #define ARM_L1_GPT_ADDR_BASE		(ARM_DRAM1_BASE +		\
126 					ARM_DRAM1_SIZE -		\
127 					ARM_L1_GPT_SIZE)
128 #define ARM_L1_GPT_END			(ARM_L1_GPT_ADDR_BASE +		\
129 					ARM_L1_GPT_SIZE - 1U)
130 
131 #define ARM_REALM_BASE			(ARM_DRAM1_BASE +		\
132 					ARM_DRAM1_SIZE -		\
133 					(ARM_SCP_TZC_DRAM1_SIZE +	\
134 					ARM_EL3_TZC_DRAM1_SIZE +	\
135 					ARM_REALM_SIZE +		\
136 					ARM_L1_GPT_SIZE))
137 #define ARM_REALM_END                   (ARM_REALM_BASE + ARM_REALM_SIZE - 1U)
138 #endif /* ENABLE_RME */
139 
140 #define ARM_EL3_TZC_DRAM1_BASE		(ARM_SCP_TZC_DRAM1_BASE -	\
141 					ARM_EL3_TZC_DRAM1_SIZE)
142 #define ARM_EL3_TZC_DRAM1_END		(ARM_EL3_TZC_DRAM1_BASE +	\
143 					ARM_EL3_TZC_DRAM1_SIZE - 1U)
144 
145 #define ARM_AP_TZC_DRAM1_BASE		(ARM_DRAM1_BASE +		\
146 					ARM_DRAM1_SIZE -		\
147 					ARM_TZC_DRAM1_SIZE)
148 #define ARM_AP_TZC_DRAM1_SIZE		(ARM_TZC_DRAM1_SIZE -		\
149 					(ARM_SCP_TZC_DRAM1_SIZE +	\
150 					ARM_EL3_TZC_DRAM1_SIZE +	\
151 					ARM_REALM_SIZE +		\
152 					ARM_L1_GPT_SIZE))
153 #define ARM_AP_TZC_DRAM1_END		(ARM_AP_TZC_DRAM1_BASE +	\
154 					ARM_AP_TZC_DRAM1_SIZE - 1U)
155 
156 /* Define the Access permissions for Secure peripherals to NS_DRAM */
157 #if ARM_CRYPTOCELL_INTEG
158 /*
159  * Allow Secure peripheral to read NS DRAM when integrated with CryptoCell.
160  * This is required by CryptoCell to authenticate BL33 which is loaded
161  * into the Non Secure DDR.
162  */
163 #define ARM_TZC_NS_DRAM_S_ACCESS	TZC_REGION_S_RD
164 #else
165 #define ARM_TZC_NS_DRAM_S_ACCESS	TZC_REGION_S_NONE
166 #endif
167 
168 #ifdef SPD_opteed
169 /*
170  * BL2 needs to map 4MB at the end of TZC_DRAM1 in order to
171  * load/authenticate the trusted os extra image. The first 512KB of
172  * TZC_DRAM1 are reserved for trusted os (OPTEE). The extra image loading
173  * for OPTEE is paged image which only include the paging part using
174  * virtual memory but without "init" data. OPTEE will copy the "init" data
175  * (from pager image) to the first 512KB of TZC_DRAM, and then copy the
176  * extra image behind the "init" data.
177  */
178 #define ARM_OPTEE_PAGEABLE_LOAD_BASE	(ARM_AP_TZC_DRAM1_BASE + \
179 					 ARM_AP_TZC_DRAM1_SIZE - \
180 					 ARM_OPTEE_PAGEABLE_LOAD_SIZE)
181 #define ARM_OPTEE_PAGEABLE_LOAD_SIZE	UL(0x400000)
182 #define ARM_OPTEE_PAGEABLE_LOAD_MEM	MAP_REGION_FLAT(		\
183 					ARM_OPTEE_PAGEABLE_LOAD_BASE,	\
184 					ARM_OPTEE_PAGEABLE_LOAD_SIZE,	\
185 					MT_MEMORY | MT_RW | MT_SECURE)
186 
187 /*
188  * Map the memory for the OP-TEE core (also known as OP-TEE pager when paging
189  * support is enabled).
190  */
191 #define ARM_MAP_OPTEE_CORE_MEM		MAP_REGION_FLAT(		\
192 						BL32_BASE,		\
193 						BL32_LIMIT - BL32_BASE,	\
194 						MT_MEMORY | MT_RW | MT_SECURE)
195 #endif /* SPD_opteed */
196 
197 #define ARM_NS_DRAM1_BASE		ARM_DRAM1_BASE
198 #define ARM_NS_DRAM1_SIZE		(ARM_DRAM1_SIZE -		\
199 					 ARM_TZC_DRAM1_SIZE)
200 #define ARM_NS_DRAM1_END		(ARM_NS_DRAM1_BASE +		\
201 					 ARM_NS_DRAM1_SIZE - 1U)
202 #ifdef PLAT_ARM_DRAM1_BASE
203 #define ARM_DRAM1_BASE			PLAT_ARM_DRAM1_BASE
204 #else
205 #define ARM_DRAM1_BASE			ULL(0x80000000)
206 #endif /* PLAT_ARM_DRAM1_BASE */
207 
208 #define ARM_DRAM1_SIZE			ULL(0x80000000)
209 #define ARM_DRAM1_END			(ARM_DRAM1_BASE +		\
210 					 ARM_DRAM1_SIZE - 1U)
211 
212 #define ARM_DRAM2_BASE			PLAT_ARM_DRAM2_BASE
213 #define ARM_DRAM2_SIZE			PLAT_ARM_DRAM2_SIZE
214 #define ARM_DRAM2_END			(ARM_DRAM2_BASE +		\
215 					 ARM_DRAM2_SIZE - 1U)
216 
217 #define ARM_IRQ_SEC_PHY_TIMER		29
218 
219 #define ARM_IRQ_SEC_SGI_0		8
220 #define ARM_IRQ_SEC_SGI_1		9
221 #define ARM_IRQ_SEC_SGI_2		10
222 #define ARM_IRQ_SEC_SGI_3		11
223 #define ARM_IRQ_SEC_SGI_4		12
224 #define ARM_IRQ_SEC_SGI_5		13
225 #define ARM_IRQ_SEC_SGI_6		14
226 #define ARM_IRQ_SEC_SGI_7		15
227 
228 /*
229  * Define a list of Group 1 Secure and Group 0 interrupt properties as per GICv3
230  * terminology. On a GICv2 system or mode, the lists will be merged and treated
231  * as Group 0 interrupts.
232  */
233 #define ARM_G1S_IRQ_PROPS(grp) \
234 	INTR_PROP_DESC(ARM_IRQ_SEC_PHY_TIMER, GIC_HIGHEST_SEC_PRIORITY, (grp), \
235 			GIC_INTR_CFG_LEVEL), \
236 	INTR_PROP_DESC(ARM_IRQ_SEC_SGI_1, GIC_HIGHEST_SEC_PRIORITY, (grp), \
237 			GIC_INTR_CFG_EDGE), \
238 	INTR_PROP_DESC(ARM_IRQ_SEC_SGI_2, GIC_HIGHEST_SEC_PRIORITY, (grp), \
239 			GIC_INTR_CFG_EDGE), \
240 	INTR_PROP_DESC(ARM_IRQ_SEC_SGI_3, GIC_HIGHEST_SEC_PRIORITY, (grp), \
241 			GIC_INTR_CFG_EDGE), \
242 	INTR_PROP_DESC(ARM_IRQ_SEC_SGI_4, GIC_HIGHEST_SEC_PRIORITY, (grp), \
243 			GIC_INTR_CFG_EDGE), \
244 	INTR_PROP_DESC(ARM_IRQ_SEC_SGI_5, GIC_HIGHEST_SEC_PRIORITY, (grp), \
245 			GIC_INTR_CFG_EDGE), \
246 	INTR_PROP_DESC(ARM_IRQ_SEC_SGI_7, GIC_HIGHEST_SEC_PRIORITY, (grp), \
247 			GIC_INTR_CFG_EDGE)
248 
249 #define ARM_G0_IRQ_PROPS(grp) \
250 	INTR_PROP_DESC(ARM_IRQ_SEC_SGI_0, PLAT_SDEI_NORMAL_PRI, (grp), \
251 			GIC_INTR_CFG_EDGE), \
252 	INTR_PROP_DESC(ARM_IRQ_SEC_SGI_6, GIC_HIGHEST_SEC_PRIORITY, (grp), \
253 			GIC_INTR_CFG_EDGE)
254 
255 #define ARM_MAP_SHARED_RAM	MAP_REGION_FLAT(			\
256 					ARM_SHARED_RAM_BASE,		\
257 					ARM_SHARED_RAM_SIZE,		\
258 					MT_DEVICE | MT_RW | EL3_PAS)
259 
260 #define ARM_MAP_NS_DRAM1	MAP_REGION_FLAT(			\
261 					ARM_NS_DRAM1_BASE,		\
262 					ARM_NS_DRAM1_SIZE,		\
263 					MT_MEMORY | MT_RW | MT_NS)
264 
265 #define ARM_MAP_DRAM2		MAP_REGION_FLAT(			\
266 					ARM_DRAM2_BASE,			\
267 					ARM_DRAM2_SIZE,			\
268 					MT_MEMORY | MT_RW | MT_NS)
269 
270 #define ARM_MAP_TSP_SEC_MEM	MAP_REGION_FLAT(			\
271 					TSP_SEC_MEM_BASE,		\
272 					TSP_SEC_MEM_SIZE,		\
273 					MT_MEMORY | MT_RW | MT_SECURE)
274 
275 #if ARM_BL31_IN_DRAM
276 #define ARM_MAP_BL31_SEC_DRAM	MAP_REGION_FLAT(			\
277 					BL31_BASE,			\
278 					PLAT_ARM_MAX_BL31_SIZE,		\
279 					MT_MEMORY | MT_RW | MT_SECURE)
280 #endif
281 
282 #define ARM_MAP_EL3_TZC_DRAM	MAP_REGION_FLAT(			\
283 					ARM_EL3_TZC_DRAM1_BASE,		\
284 					ARM_EL3_TZC_DRAM1_SIZE,		\
285 					MT_MEMORY | MT_RW | EL3_PAS)
286 
287 #if defined(SPD_spmd)
288 #define ARM_MAP_TRUSTED_DRAM	MAP_REGION_FLAT(			\
289 					PLAT_ARM_TRUSTED_DRAM_BASE,	\
290 					PLAT_ARM_TRUSTED_DRAM_SIZE,	\
291 					MT_MEMORY | MT_RW | MT_SECURE)
292 #endif
293 
294 #if ENABLE_RME
295 #define ARM_MAP_RMM_DRAM	MAP_REGION_FLAT(			\
296 					PLAT_ARM_RMM_BASE,		\
297 					PLAT_ARM_RMM_SIZE,		\
298 					MT_MEMORY | MT_RW | MT_REALM)
299 
300 
301 #define ARM_MAP_GPT_L1_DRAM	MAP_REGION_FLAT(			\
302 					ARM_L1_GPT_ADDR_BASE,		\
303 					ARM_L1_GPT_SIZE,		\
304 					MT_MEMORY | MT_RW | EL3_PAS)
305 
306 #endif /* ENABLE_RME */
307 
308 /*
309  * Mapping for the BL1 RW region. This mapping is needed by BL2 in order to
310  * share the Mbed TLS heap. Since the heap is allocated inside BL1, it resides
311  * in the BL1 RW region. Hence, BL2 needs access to the BL1 RW region in order
312  * to be able to access the heap.
313  */
314 #define ARM_MAP_BL1_RW		MAP_REGION_FLAT(	\
315 					BL1_RW_BASE,	\
316 					BL1_RW_LIMIT - BL1_RW_BASE, \
317 					MT_MEMORY | MT_RW | EL3_PAS)
318 
319 /*
320  * If SEPARATE_CODE_AND_RODATA=1 we define a region for each section
321  * otherwise one region is defined containing both.
322  */
323 #if SEPARATE_CODE_AND_RODATA
324 #define ARM_MAP_BL_RO			MAP_REGION_FLAT(			\
325 						BL_CODE_BASE,			\
326 						BL_CODE_END - BL_CODE_BASE,	\
327 						MT_CODE | EL3_PAS),		\
328 					MAP_REGION_FLAT(			\
329 						BL_RO_DATA_BASE,		\
330 						BL_RO_DATA_END			\
331 							- BL_RO_DATA_BASE,	\
332 						MT_RO_DATA | EL3_PAS)
333 #else
334 #define ARM_MAP_BL_RO			MAP_REGION_FLAT(			\
335 						BL_CODE_BASE,			\
336 						BL_CODE_END - BL_CODE_BASE,	\
337 						MT_CODE | EL3_PAS)
338 #endif
339 #if USE_COHERENT_MEM
340 #define ARM_MAP_BL_COHERENT_RAM		MAP_REGION_FLAT(			\
341 						BL_COHERENT_RAM_BASE,		\
342 						BL_COHERENT_RAM_END		\
343 							- BL_COHERENT_RAM_BASE, \
344 						MT_DEVICE | MT_RW | EL3_PAS)
345 #endif
346 #if USE_ROMLIB
347 #define ARM_MAP_ROMLIB_CODE		MAP_REGION_FLAT(			\
348 						ROMLIB_RO_BASE,			\
349 						ROMLIB_RO_LIMIT	- ROMLIB_RO_BASE,\
350 						MT_CODE | EL3_PAS)
351 
352 #define ARM_MAP_ROMLIB_DATA		MAP_REGION_FLAT(			\
353 						ROMLIB_RW_BASE,			\
354 						ROMLIB_RW_END	- ROMLIB_RW_BASE,\
355 						MT_MEMORY | MT_RW | EL3_PAS)
356 #endif
357 
358 /*
359  * Map mem_protect flash region with read and write permissions
360  */
361 #define ARM_V2M_MAP_MEM_PROTECT		MAP_REGION_FLAT(PLAT_ARM_MEM_PROT_ADDR,	\
362 						V2M_FLASH_BLOCK_SIZE,		\
363 						MT_DEVICE | MT_RW | MT_SECURE)
364 /*
365  * Map the region for device tree configuration with read and write permissions
366  */
367 #define ARM_MAP_BL_CONFIG_REGION	MAP_REGION_FLAT(ARM_BL_RAM_BASE,	\
368 						(ARM_FW_CONFIGS_LIMIT		\
369 							- ARM_BL_RAM_BASE),	\
370 						MT_MEMORY | MT_RW | EL3_PAS)
371 /*
372  * Map L0_GPT with read and write permissions
373  */
374 #if ENABLE_RME
375 #define ARM_MAP_L0_GPT_REGION		MAP_REGION_FLAT(ARM_L0_GPT_ADDR_BASE,	\
376 						ARM_L0_GPT_SIZE,		\
377 						MT_MEMORY | MT_RW | MT_ROOT)
378 #endif
379 
380 /*
381  * The max number of regions like RO(code), coherent and data required by
382  * different BL stages which need to be mapped in the MMU.
383  */
384 #define ARM_BL_REGIONS			6
385 
386 #define MAX_MMAP_REGIONS		(PLAT_ARM_MMAP_ENTRIES +	\
387 					 ARM_BL_REGIONS)
388 
389 /* Memory mapped Generic timer interfaces  */
390 #ifdef PLAT_ARM_SYS_CNTCTL_BASE
391 #define ARM_SYS_CNTCTL_BASE		PLAT_ARM_SYS_CNTCTL_BASE
392 #else
393 #define ARM_SYS_CNTCTL_BASE		UL(0x2a430000)
394 #endif
395 
396 #ifdef PLAT_ARM_SYS_CNTREAD_BASE
397 #define ARM_SYS_CNTREAD_BASE		PLAT_ARM_SYS_CNTREAD_BASE
398 #else
399 #define ARM_SYS_CNTREAD_BASE		UL(0x2a800000)
400 #endif
401 
402 #ifdef PLAT_ARM_SYS_TIMCTL_BASE
403 #define ARM_SYS_TIMCTL_BASE		PLAT_ARM_SYS_TIMCTL_BASE
404 #else
405 #define ARM_SYS_TIMCTL_BASE		UL(0x2a810000)
406 #endif
407 
408 #ifdef PLAT_ARM_SYS_CNT_BASE_S
409 #define ARM_SYS_CNT_BASE_S		PLAT_ARM_SYS_CNT_BASE_S
410 #else
411 #define ARM_SYS_CNT_BASE_S		UL(0x2a820000)
412 #endif
413 
414 #ifdef PLAT_ARM_SYS_CNT_BASE_NS
415 #define ARM_SYS_CNT_BASE_NS		PLAT_ARM_SYS_CNT_BASE_NS
416 #else
417 #define ARM_SYS_CNT_BASE_NS		UL(0x2a830000)
418 #endif
419 
420 #define ARM_CONSOLE_BAUDRATE		115200
421 
422 /* Trusted Watchdog constants */
423 #ifdef PLAT_ARM_SP805_TWDG_BASE
424 #define ARM_SP805_TWDG_BASE		PLAT_ARM_SP805_TWDG_BASE
425 #else
426 #define ARM_SP805_TWDG_BASE		UL(0x2a490000)
427 #endif
428 #define ARM_SP805_TWDG_CLK_HZ		32768
429 /* The TBBR document specifies a watchdog timeout of 256 seconds. SP805
430  * asserts reset after two consecutive countdowns (2 x 128 = 256 sec) */
431 #define ARM_TWDG_TIMEOUT_SEC		128
432 #define ARM_TWDG_LOAD_VAL		(ARM_SP805_TWDG_CLK_HZ * 	\
433 					 ARM_TWDG_TIMEOUT_SEC)
434 
435 /******************************************************************************
436  * Required platform porting definitions common to all ARM standard platforms
437  *****************************************************************************/
438 
439 /*
440  * This macro defines the deepest retention state possible. A higher state
441  * id will represent an invalid or a power down state.
442  */
443 #define PLAT_MAX_RET_STATE		ARM_LOCAL_STATE_RET
444 
445 /*
446  * This macro defines the deepest power down states possible. Any state ID
447  * higher than this is invalid.
448  */
449 #define PLAT_MAX_OFF_STATE		ARM_LOCAL_STATE_OFF
450 
451 /*
452  * Some data must be aligned on the biggest cache line size in the platform.
453  * This is known only to the platform as it might have a combination of
454  * integrated and external caches.
455  */
456 #define CACHE_WRITEBACK_GRANULE		(U(1) << ARM_CACHE_WRITEBACK_SHIFT)
457 
458 /*
459  * To enable FW_CONFIG to be loaded by BL1, define the corresponding base
460  * and limit. Leave enough space of BL2 meminfo.
461  */
462 #define ARM_FW_CONFIG_BASE		(ARM_BL_RAM_BASE + sizeof(meminfo_t))
463 #define ARM_FW_CONFIG_LIMIT		((ARM_BL_RAM_BASE + PAGE_SIZE) \
464 					+ (PAGE_SIZE / 2U))
465 
466 /*
467  * Boot parameters passed from BL2 to BL31/BL32 are stored here
468  */
469 #define ARM_BL2_MEM_DESC_BASE		(ARM_FW_CONFIG_LIMIT)
470 #define ARM_BL2_MEM_DESC_LIMIT		(ARM_BL2_MEM_DESC_BASE \
471 					+ (PAGE_SIZE / 2U))
472 
473 /*
474  * Define limit of firmware configuration memory:
475  * ARM_FW_CONFIG + ARM_BL2_MEM_DESC memory
476  */
477 #define ARM_FW_CONFIGS_LIMIT		(ARM_BL_RAM_BASE + (PAGE_SIZE * 2))
478 
479 #if ENABLE_RME
480 /*
481  * Store the L0 GPT on Trusted SRAM next to firmware
482  * configuration memory, 4KB aligned.
483  */
484 #define ARM_L0_GPT_SIZE			(PAGE_SIZE)
485 #define ARM_L0_GPT_ADDR_BASE		(ARM_FW_CONFIGS_LIMIT)
486 #define ARM_L0_GPT_LIMIT		(ARM_L0_GPT_ADDR_BASE + ARM_L0_GPT_SIZE)
487 #else
488 #define ARM_L0_GPT_SIZE			U(0)
489 #endif
490 
491 /*******************************************************************************
492  * BL1 specific defines.
493  * BL1 RW data is relocated from ROM to RAM at runtime so we need 2 sets of
494  * addresses.
495  ******************************************************************************/
496 #define BL1_RO_BASE			PLAT_ARM_TRUSTED_ROM_BASE
497 #ifdef PLAT_BL1_RO_LIMIT
498 #define BL1_RO_LIMIT			PLAT_BL1_RO_LIMIT
499 #else
500 #define BL1_RO_LIMIT			(PLAT_ARM_TRUSTED_ROM_BASE	\
501 					 + (PLAT_ARM_TRUSTED_ROM_SIZE - \
502 					    PLAT_ARM_MAX_ROMLIB_RO_SIZE))
503 #endif
504 
505 /*
506  * Put BL1 RW at the top of the Trusted SRAM.
507  */
508 #define BL1_RW_BASE			(ARM_BL_RAM_BASE +		\
509 						ARM_BL_RAM_SIZE -	\
510 						(PLAT_ARM_MAX_BL1_RW_SIZE +\
511 						 PLAT_ARM_MAX_ROMLIB_RW_SIZE))
512 #define BL1_RW_LIMIT			(ARM_BL_RAM_BASE + 		\
513 					    (ARM_BL_RAM_SIZE - PLAT_ARM_MAX_ROMLIB_RW_SIZE))
514 
515 #define ROMLIB_RO_BASE			BL1_RO_LIMIT
516 #define ROMLIB_RO_LIMIT			(PLAT_ARM_TRUSTED_ROM_BASE + PLAT_ARM_TRUSTED_ROM_SIZE)
517 
518 #define ROMLIB_RW_BASE			(BL1_RW_BASE + PLAT_ARM_MAX_BL1_RW_SIZE)
519 #define ROMLIB_RW_END			(ROMLIB_RW_BASE + PLAT_ARM_MAX_ROMLIB_RW_SIZE)
520 
521 /*******************************************************************************
522  * BL2 specific defines.
523  ******************************************************************************/
524 #if BL2_AT_EL3
525 /* Put BL2 towards the middle of the Trusted SRAM */
526 #define BL2_BASE			(ARM_TRUSTED_SRAM_BASE + \
527 						(PLAT_ARM_TRUSTED_SRAM_SIZE >> 1) + 0x2000)
528 #define BL2_LIMIT			(ARM_BL_RAM_BASE + ARM_BL_RAM_SIZE)
529 
530 #else
531 /*
532  * Put BL2 just below BL1.
533  */
534 #define BL2_BASE			(BL1_RW_BASE - PLAT_ARM_MAX_BL2_SIZE)
535 #define BL2_LIMIT			BL1_RW_BASE
536 #endif
537 
538 /*******************************************************************************
539  * BL31 specific defines.
540  ******************************************************************************/
541 #if ARM_BL31_IN_DRAM || SEPARATE_NOBITS_REGION
542 /*
543  * Put BL31 at the bottom of TZC secured DRAM
544  */
545 #define BL31_BASE			ARM_AP_TZC_DRAM1_BASE
546 #define BL31_LIMIT			(ARM_AP_TZC_DRAM1_BASE +	\
547 						PLAT_ARM_MAX_BL31_SIZE)
548 /*
549  * For SEPARATE_NOBITS_REGION, BL31 PROGBITS are loaded in TZC secured DRAM.
550  * And BL31 NOBITS are loaded in Trusted SRAM such that BL2 is overwritten.
551  */
552 #if SEPARATE_NOBITS_REGION
553 #define BL31_NOBITS_BASE		BL2_BASE
554 #define BL31_NOBITS_LIMIT		BL2_LIMIT
555 #endif /* SEPARATE_NOBITS_REGION */
556 #elif (RESET_TO_BL31)
557 /* Ensure Position Independent support (PIE) is enabled for this config.*/
558 # if !ENABLE_PIE
559 #  error "BL31 must be a PIE if RESET_TO_BL31=1."
560 #endif
561 /*
562  * Since this is PIE, we can define BL31_BASE to 0x0 since this macro is solely
563  * used for building BL31 and not used for loading BL31.
564  */
565 #  define BL31_BASE			0x0
566 #  define BL31_LIMIT			PLAT_ARM_MAX_BL31_SIZE
567 #else
568 /* Put BL31 below BL2 in the Trusted SRAM.*/
569 #define BL31_BASE			((ARM_BL_RAM_BASE + ARM_BL_RAM_SIZE)\
570 						- PLAT_ARM_MAX_BL31_SIZE)
571 #define BL31_PROGBITS_LIMIT		BL2_BASE
572 /*
573  * For BL2_AT_EL3 make sure the BL31 can grow up until BL2_BASE. This is
574  * because in the BL2_AT_EL3 configuration, BL2 is always resident.
575  */
576 #if BL2_AT_EL3
577 #define BL31_LIMIT			BL2_BASE
578 #else
579 #define BL31_LIMIT			(ARM_BL_RAM_BASE + ARM_BL_RAM_SIZE)
580 #endif
581 #endif
582 
583 /******************************************************************************
584  * RMM specific defines
585  *****************************************************************************/
586 #if ENABLE_RME
587 #define RMM_BASE			(ARM_REALM_BASE)
588 #define RMM_LIMIT			(RMM_BASE + ARM_REALM_SIZE)
589 #endif
590 
591 #if !defined(__aarch64__) || JUNO_AARCH32_EL3_RUNTIME
592 /*******************************************************************************
593  * BL32 specific defines for EL3 runtime in AArch32 mode
594  ******************************************************************************/
595 # if RESET_TO_SP_MIN && !JUNO_AARCH32_EL3_RUNTIME
596 /* Ensure Position Independent support (PIE) is enabled for this config.*/
597 # if !ENABLE_PIE
598 #  error "BL32 must be a PIE if RESET_TO_SP_MIN=1."
599 #endif
600 /*
601  * Since this is PIE, we can define BL32_BASE to 0x0 since this macro is solely
602  * used for building BL32 and not used for loading BL32.
603  */
604 #  define BL32_BASE			0x0
605 #  define BL32_LIMIT			PLAT_ARM_MAX_BL32_SIZE
606 # else
607 /* Put BL32 below BL2 in the Trusted SRAM.*/
608 #  define BL32_BASE			((ARM_BL_RAM_BASE + ARM_BL_RAM_SIZE)\
609 						- PLAT_ARM_MAX_BL32_SIZE)
610 #  define BL32_PROGBITS_LIMIT		BL2_BASE
611 #  define BL32_LIMIT			(ARM_BL_RAM_BASE + ARM_BL_RAM_SIZE)
612 # endif /* RESET_TO_SP_MIN && !JUNO_AARCH32_EL3_RUNTIME */
613 
614 #else
615 /*******************************************************************************
616  * BL32 specific defines for EL3 runtime in AArch64 mode
617  ******************************************************************************/
618 /*
619  * On ARM standard platforms, the TSP can execute from Trusted SRAM,
620  * Trusted DRAM (if available) or the DRAM region secured by the TrustZone
621  * controller.
622  */
623 # if SPM_MM
624 #  define TSP_SEC_MEM_BASE		(ARM_AP_TZC_DRAM1_BASE + ULL(0x200000))
625 #  define TSP_SEC_MEM_SIZE		(ARM_AP_TZC_DRAM1_SIZE - ULL(0x200000))
626 #  define BL32_BASE			(ARM_AP_TZC_DRAM1_BASE + ULL(0x200000))
627 #  define BL32_LIMIT			(ARM_AP_TZC_DRAM1_BASE +	\
628 						ARM_AP_TZC_DRAM1_SIZE)
629 # elif defined(SPD_spmd)
630 #  define TSP_SEC_MEM_BASE		(ARM_AP_TZC_DRAM1_BASE + ULL(0x200000))
631 #  define TSP_SEC_MEM_SIZE		(ARM_AP_TZC_DRAM1_SIZE - ULL(0x200000))
632 #  define BL32_BASE			PLAT_ARM_SPMC_BASE
633 #  define BL32_LIMIT			(PLAT_ARM_SPMC_BASE +		\
634 						 PLAT_ARM_SPMC_SIZE)
635 # elif ARM_BL31_IN_DRAM
636 #  define TSP_SEC_MEM_BASE		(ARM_AP_TZC_DRAM1_BASE +	\
637 						PLAT_ARM_MAX_BL31_SIZE)
638 #  define TSP_SEC_MEM_SIZE		(ARM_AP_TZC_DRAM1_SIZE -	\
639 						PLAT_ARM_MAX_BL31_SIZE)
640 #  define BL32_BASE			(ARM_AP_TZC_DRAM1_BASE +	\
641 						PLAT_ARM_MAX_BL31_SIZE)
642 #  define BL32_LIMIT			(ARM_AP_TZC_DRAM1_BASE +	\
643 						ARM_AP_TZC_DRAM1_SIZE)
644 # elif ARM_TSP_RAM_LOCATION_ID == ARM_TRUSTED_SRAM_ID
645 #  define TSP_SEC_MEM_BASE		ARM_BL_RAM_BASE
646 #  define TSP_SEC_MEM_SIZE		ARM_BL_RAM_SIZE
647 #  define TSP_PROGBITS_LIMIT		BL31_BASE
648 #  define BL32_BASE			ARM_FW_CONFIGS_LIMIT
649 #  define BL32_LIMIT			BL31_BASE
650 # elif ARM_TSP_RAM_LOCATION_ID == ARM_TRUSTED_DRAM_ID
651 #  define TSP_SEC_MEM_BASE		PLAT_ARM_TRUSTED_DRAM_BASE
652 #  define TSP_SEC_MEM_SIZE		PLAT_ARM_TRUSTED_DRAM_SIZE
653 #  define BL32_BASE			PLAT_ARM_TRUSTED_DRAM_BASE
654 #  define BL32_LIMIT			(PLAT_ARM_TRUSTED_DRAM_BASE	\
655 						+ (UL(1) << 21))
656 # elif ARM_TSP_RAM_LOCATION_ID == ARM_DRAM_ID
657 #  define TSP_SEC_MEM_BASE		ARM_AP_TZC_DRAM1_BASE
658 #  define TSP_SEC_MEM_SIZE		ARM_AP_TZC_DRAM1_SIZE
659 #  define BL32_BASE			ARM_AP_TZC_DRAM1_BASE
660 #  define BL32_LIMIT			(ARM_AP_TZC_DRAM1_BASE +	\
661 						ARM_AP_TZC_DRAM1_SIZE)
662 # else
663 #  error "Unsupported ARM_TSP_RAM_LOCATION_ID value"
664 # endif
665 #endif /* !__aarch64__ || JUNO_AARCH32_EL3_RUNTIME */
666 
667 /*
668  * BL32 is mandatory in AArch32. In AArch64, undefine BL32_BASE if there is no
669  * SPD and no SPM-MM, as they are the only ones that can be used as BL32.
670  */
671 #if defined(__aarch64__) && !JUNO_AARCH32_EL3_RUNTIME
672 # if defined(SPD_none) && !SPM_MM
673 #  undef BL32_BASE
674 # endif /* defined(SPD_none) && !SPM_MM */
675 #endif /* defined(__aarch64__) && !JUNO_AARCH32_EL3_RUNTIME */
676 
677 /*******************************************************************************
678  * FWU Images: NS_BL1U, BL2U & NS_BL2U defines.
679  ******************************************************************************/
680 #define BL2U_BASE			BL2_BASE
681 #define BL2U_LIMIT			BL2_LIMIT
682 
683 #define NS_BL2U_BASE			ARM_NS_DRAM1_BASE
684 #define NS_BL1U_BASE			(PLAT_ARM_NVM_BASE + UL(0x03EB8000))
685 
686 /*
687  * ID of the secure physical generic timer interrupt used by the TSP.
688  */
689 #define TSP_IRQ_SEC_PHY_TIMER		ARM_IRQ_SEC_PHY_TIMER
690 
691 
692 /*
693  * One cache line needed for bakery locks on ARM platforms
694  */
695 #define PLAT_PERCPU_BAKERY_LOCK_SIZE		(1 * CACHE_WRITEBACK_GRANULE)
696 
697 /* Priority levels for ARM platforms */
698 #define PLAT_RAS_PRI			0x10
699 #define PLAT_SDEI_CRITICAL_PRI		0x60
700 #define PLAT_SDEI_NORMAL_PRI		0x70
701 
702 /* ARM platforms use 3 upper bits of secure interrupt priority */
703 #define PLAT_PRI_BITS			3
704 
705 /* SGI used for SDEI signalling */
706 #define ARM_SDEI_SGI			ARM_IRQ_SEC_SGI_0
707 
708 #if SDEI_IN_FCONF
709 /* ARM SDEI dynamic private event max count */
710 #define ARM_SDEI_DP_EVENT_MAX_CNT	3
711 
712 /* ARM SDEI dynamic shared event max count */
713 #define ARM_SDEI_DS_EVENT_MAX_CNT	3
714 #else
715 /* ARM SDEI dynamic private event numbers */
716 #define ARM_SDEI_DP_EVENT_0		1000
717 #define ARM_SDEI_DP_EVENT_1		1001
718 #define ARM_SDEI_DP_EVENT_2		1002
719 
720 /* ARM SDEI dynamic shared event numbers */
721 #define ARM_SDEI_DS_EVENT_0		2000
722 #define ARM_SDEI_DS_EVENT_1		2001
723 #define ARM_SDEI_DS_EVENT_2		2002
724 
725 #define ARM_SDEI_PRIVATE_EVENTS \
726 	SDEI_DEFINE_EVENT_0(ARM_SDEI_SGI), \
727 	SDEI_PRIVATE_EVENT(ARM_SDEI_DP_EVENT_0, SDEI_DYN_IRQ, SDEI_MAPF_DYNAMIC), \
728 	SDEI_PRIVATE_EVENT(ARM_SDEI_DP_EVENT_1, SDEI_DYN_IRQ, SDEI_MAPF_DYNAMIC), \
729 	SDEI_PRIVATE_EVENT(ARM_SDEI_DP_EVENT_2, SDEI_DYN_IRQ, SDEI_MAPF_DYNAMIC)
730 
731 #define ARM_SDEI_SHARED_EVENTS \
732 	SDEI_SHARED_EVENT(ARM_SDEI_DS_EVENT_0, SDEI_DYN_IRQ, SDEI_MAPF_DYNAMIC), \
733 	SDEI_SHARED_EVENT(ARM_SDEI_DS_EVENT_1, SDEI_DYN_IRQ, SDEI_MAPF_DYNAMIC), \
734 	SDEI_SHARED_EVENT(ARM_SDEI_DS_EVENT_2, SDEI_DYN_IRQ, SDEI_MAPF_DYNAMIC)
735 #endif /* SDEI_IN_FCONF */
736 
737 #endif /* ARM_DEF_H */
738