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developer550bf5e2016-07-11 16:05:23 +08001/*
Jeenu Viswambharan2a9b8822017-02-21 14:40:44 +00002 * Copyright (c) 2016-2017, ARM Limited and Contributors. All rights reserved.
developer550bf5e2016-07-11 16:05:23 +08003 *
dp-armfa3cf0b2017-05-03 09:38:09 +01004 * SPDX-License-Identifier: BSD-3-Clause
developer550bf5e2016-07-11 16:05:23 +08005 */
6#include <arm_gic.h>
7#include <assert.h>
8#include <arch_helpers.h>
9#include <bl_common.h>
10#include <cci.h>
Masahiro Yamada0fac5af2016-12-28 16:11:41 +090011#include <common_def.h>
developer550bf5e2016-07-11 16:05:23 +080012#include <console.h>
13#include <context_mgmt.h>
14#include <debug.h>
15#include <generic_delay_timer.h>
16#include <mcucfg.h>
17#include <mmio.h>
18#include <mtk_sip_svc.h>
19#include <mtk_plat_common.h>
20#include <mt_cpuxgpt.h>
21#include <platform.h>
22#include <plat_private.h>
23#include <string.h>
24#include <xlat_tables.h>
25/*******************************************************************************
26 * Declarations of linker defined symbols which will help us find the layout
27 * of trusted SRAM
28 ******************************************************************************/
29unsigned long __RO_START__;
30unsigned long __RO_END__;
31
developer550bf5e2016-07-11 16:05:23 +080032/*
33 * The next 2 constants identify the extents of the code & RO data region.
34 * These addresses are used by the MMU setup code and therefore they must be
35 * page-aligned. It is the responsibility of the linker script to ensure that
36 * __RO_START__ and __RO_END__ linker symbols refer to page-aligned addresses.
37 */
38#define BL31_RO_BASE (unsigned long)(&__RO_START__)
39#define BL31_RO_LIMIT (unsigned long)(&__RO_END__)
40
41/*
developer550bf5e2016-07-11 16:05:23 +080042 * Placeholder variables for copying the arguments that have been passed to
43 * BL3-1 from BL2.
44 */
45static entry_point_info_t bl32_image_ep_info;
46static entry_point_info_t bl33_image_ep_info;
47
48static const int cci_map[] = {
49 PLAT_MT_CCI_CLUSTER0_SL_IFACE_IX,
50 PLAT_MT_CCI_CLUSTER1_SL_IFACE_IX
51};
52
53static uint32_t cci_map_length = ARRAY_SIZE(cci_map);
54
55/* Table of regions to map using the MMU. */
56static const mmap_region_t plat_mmap[] = {
57 /* for TF text, RO, RW */
58 MAP_REGION_FLAT(MTK_DEV_RNG0_BASE, MTK_DEV_RNG0_SIZE,
59 MT_DEVICE | MT_RW | MT_SECURE),
60 MAP_REGION_FLAT(MTK_DEV_RNG1_BASE, MTK_DEV_RNG1_SIZE,
61 MT_DEVICE | MT_RW | MT_SECURE),
62 MAP_REGION_FLAT(RAM_CONSOLE_BASE & ~(PAGE_SIZE_MASK), RAM_CONSOLE_SIZE,
63 MT_DEVICE | MT_RW | MT_NS),
64 { 0 }
65
66};
67
68/*******************************************************************************
69 * Macro generating the code for the function setting up the pagetables as per
70 * the platform memory map & initialize the mmu, for the given exception level
71 ******************************************************************************/
72#define DEFINE_CONFIGURE_MMU_EL(_el) \
73 void plat_configure_mmu_el ## _el(unsigned long total_base, \
74 unsigned long total_size, \
75 unsigned long ro_start, \
76 unsigned long ro_limit, \
77 unsigned long coh_start, \
78 unsigned long coh_limit) \
79 { \
80 mmap_add_region(total_base, total_base, \
81 total_size, \
82 MT_MEMORY | MT_RW | MT_SECURE); \
83 mmap_add_region(ro_start, ro_start, \
84 ro_limit - ro_start, \
85 MT_MEMORY | MT_RO | MT_SECURE); \
86 mmap_add_region(coh_start, coh_start, \
87 coh_limit - coh_start, \
88 MT_DEVICE | MT_RW | MT_SECURE); \
89 mmap_add(plat_mmap); \
90 init_xlat_tables(); \
91 \
92 enable_mmu_el ## _el(0); \
93 }
94
95/* Define EL3 variants of the function initialising the MMU */
96DEFINE_CONFIGURE_MMU_EL(3)
97
98unsigned int plat_get_syscnt_freq2(void)
99{
100 return SYS_COUNTER_FREQ_IN_TICKS;
101}
102
103void plat_cci_init(void)
104{
105 /* Initialize CCI driver */
106 cci_init(PLAT_MT_CCI_BASE, cci_map, cci_map_length);
107}
108
109void plat_cci_enable(void)
110{
111 /*
112 * Enable CCI coherency for this cluster.
113 * No need for locks as no other cpu is active at the moment.
114 */
115 cci_enable_snoop_dvm_reqs(MPIDR_AFFLVL1_VAL(read_mpidr()));
116}
117
118void plat_cci_disable(void)
119{
120 cci_disable_snoop_dvm_reqs(MPIDR_AFFLVL1_VAL(read_mpidr()));
121}
122
123
124static void platform_setup_cpu(void)
125{
126 /* setup big cores */
127 mmio_write_32((uintptr_t)&mt6795_mcucfg->mp1_config_res,
128 MP1_DIS_RGU0_WAIT_PD_CPUS_L1_ACK |
129 MP1_DIS_RGU1_WAIT_PD_CPUS_L1_ACK |
130 MP1_DIS_RGU2_WAIT_PD_CPUS_L1_ACK |
131 MP1_DIS_RGU3_WAIT_PD_CPUS_L1_ACK |
132 MP1_DIS_RGU_NOCPU_WAIT_PD_CPUS_L1_ACK);
133 mmio_setbits_32((uintptr_t)&mt6795_mcucfg->mp1_miscdbg, MP1_AINACTS);
134 mmio_setbits_32((uintptr_t)&mt6795_mcucfg->mp1_clkenm_div,
135 MP1_SW_CG_GEN);
136 mmio_clrbits_32((uintptr_t)&mt6795_mcucfg->mp1_rst_ctl,
137 MP1_L2RSTDISABLE);
138
139 /* set big cores arm64 boot mode */
140 mmio_setbits_32((uintptr_t)&mt6795_mcucfg->mp1_cpucfg,
141 MP1_CPUCFG_64BIT);
142
143 /* set LITTLE cores arm64 boot mode */
144 mmio_setbits_32((uintptr_t)&mt6795_mcucfg->mp0_rv_addr[0].rv_addr_hw,
145 MP0_CPUCFG_64BIT);
146}
147
148/*******************************************************************************
149 * Return a pointer to the 'entry_point_info' structure of the next image for
150 * the security state specified. BL33 corresponds to the non-secure image type
151 * while BL32 corresponds to the secure image type. A NULL pointer is returned
152 * if the image does not exist.
153 ******************************************************************************/
154entry_point_info_t *bl31_plat_get_next_image_ep_info(uint32_t type)
155{
156 entry_point_info_t *next_image_info;
157
158 next_image_info = (type == NON_SECURE) ?
159 &bl33_image_ep_info : &bl32_image_ep_info;
160
161 /* None of the images on this platform can have 0x0 as the entrypoint */
162 if (next_image_info->pc)
163 return next_image_info;
164 else
165 return NULL;
166}
167
168/*******************************************************************************
169 * Perform any BL3-1 early platform setup. Here is an opportunity to copy
170 * parameters passed by the calling EL (S-EL1 in BL2 & S-EL3 in BL1) before they
171 * are lost (potentially). This needs to be done before the MMU is initialized
172 * so that the memory layout can be used while creating page tables.
173 * BL2 has flushed this information to memory, so we are guaranteed to pick up
174 * good data.
175 ******************************************************************************/
176void bl31_early_platform_setup(bl31_params_t *from_bl2,
177 void *plat_params_from_bl2)
178{
179 struct mtk_bl_param_t *pmtk_bl_param =
180 (struct mtk_bl_param_t *)from_bl2;
181 struct atf_arg_t *teearg;
182 unsigned long long normal_base;
183 unsigned long long atf_base;
184
185 assert(from_bl2 != NULL);
186 /*
187 * Mediatek preloader(i.e, BL2) is in 32 bit state, high 32bits
188 * of 64 bit GP registers are UNKNOWN if CPU warm reset from 32 bit
189 * to 64 bit state. So we need to clear high 32bit,
190 * which may be random value.
191 */
192 pmtk_bl_param =
193 (struct mtk_bl_param_t *)((uint64_t)pmtk_bl_param & 0x00000000ffffffff);
194 plat_params_from_bl2 =
195 (void *)((uint64_t)plat_params_from_bl2 & 0x00000000ffffffff);
196
197 teearg = (struct atf_arg_t *)pmtk_bl_param->tee_info_addr;
198
199 console_init(teearg->atf_log_port, UART_CLOCK, UART_BAUDRATE);
200 memcpy((void *)&gteearg, (void *)teearg, sizeof(struct atf_arg_t));
201
202 normal_base = 0;
203 /* in ATF boot time, timer for cntpct_el0 is not initialized
204 * so it will not count now.
205 */
206 atf_base = read_cntpct_el0();
207 sched_clock_init(normal_base, atf_base);
208
209 VERBOSE("bl31_setup\n");
210
211 /* Populate entry point information for BL3-2 and BL3-3 */
212 SET_PARAM_HEAD(&bl32_image_ep_info,
213 PARAM_EP,
214 VERSION_1,
215 0);
216 SET_SECURITY_STATE(bl32_image_ep_info.h.attr, SECURE);
217 bl32_image_ep_info.pc = BL32_BASE;
218
219 SET_PARAM_HEAD(&bl33_image_ep_info,
220 PARAM_EP,
221 VERSION_1,
222 0);
223 /*
224 * Tell BL3-1 where the non-trusted software image
225 * is located and the entry state information
226 */
227 /* BL33_START_ADDRESS */
228 bl33_image_ep_info.pc = pmtk_bl_param->bl33_start_addr;
229 bl33_image_ep_info.spsr = plat_get_spsr_for_bl33_entry();
230 bl33_image_ep_info.args.arg4 = pmtk_bl_param->bootarg_loc;
231 bl33_image_ep_info.args.arg5 = pmtk_bl_param->bootarg_size;
232 SET_SECURITY_STATE(bl33_image_ep_info.h.attr, NON_SECURE);
233}
234/*******************************************************************************
235 * Perform any BL3-1 platform setup code
236 ******************************************************************************/
237
238void bl31_platform_setup(void)
239{
240 platform_setup_cpu();
241
242 generic_delay_timer_init();
243
244 plat_mt_gic_driver_init();
245 /* Initialize the gic cpu and distributor interfaces */
246 plat_mt_gic_init();
247
248 /* Topologies are best known to the platform. */
249 mt_setup_topology();
250}
251/*******************************************************************************
252 * Perform the very early platform specific architectural setup here. At the
253 * moment this is only intializes the mmu in a quick and dirty way.
254 * Init MTK propiartary log buffer control field.
255 ******************************************************************************/
256void bl31_plat_arch_setup(void)
257{
258 /* Enable non-secure access to CCI-400 registers */
259 mmio_write_32(CCI400_BASE + CCI_SEC_ACCESS_OFFSET, 0x1);
260
261 plat_cci_init();
262 plat_cci_enable();
263
264 if (gteearg.atf_log_buf_size != 0) {
265 INFO("mmap atf buffer : 0x%x, 0x%x\n\r",
266 gteearg.atf_log_buf_start,
267 gteearg.atf_log_buf_size);
268
269 mmap_add_region(
270 gteearg.atf_log_buf_start &
271 ~(PAGE_SIZE_2MB_MASK),
272 gteearg.atf_log_buf_start &
273 ~(PAGE_SIZE_2MB_MASK),
274 PAGE_SIZE_2MB,
275 MT_DEVICE | MT_RW | MT_NS);
276
277 INFO("mmap atf buffer (force 2MB aligned):0x%x, 0x%x\n",
278 (gteearg.atf_log_buf_start & ~(PAGE_SIZE_2MB_MASK)),
279 PAGE_SIZE_2MB);
280 }
281 /*
282 * add TZRAM_BASE to memory map
283 * then set RO and COHERENT to different attribute
284 */
285 plat_configure_mmu_el3(
286 (TZRAM_BASE & ~(PAGE_SIZE_MASK)),
287 (TZRAM_SIZE & ~(PAGE_SIZE_MASK)),
288 (BL31_RO_BASE & ~(PAGE_SIZE_MASK)),
289 BL31_RO_LIMIT,
Masahiro Yamada0fac5af2016-12-28 16:11:41 +0900290 BL_COHERENT_RAM_BASE,
291 BL_COHERENT_RAM_END);
developer550bf5e2016-07-11 16:05:23 +0800292 /* Initialize for ATF log buffer */
293 if (gteearg.atf_log_buf_size != 0) {
294 gteearg.atf_aee_debug_buf_size = ATF_AEE_BUFFER_SIZE;
295 gteearg.atf_aee_debug_buf_start =
296 gteearg.atf_log_buf_start +
297 gteearg.atf_log_buf_size - ATF_AEE_BUFFER_SIZE;
298 INFO("ATF log service is registered (0x%x, aee:0x%x)\n",
299 gteearg.atf_log_buf_start,
300 gteearg.atf_aee_debug_buf_start);
301 } else{
302 gteearg.atf_aee_debug_buf_size = 0;
303 gteearg.atf_aee_debug_buf_start = 0;
304 }
305
306 /* Platform code before bl31_main */
307 /* compatible to the earlier chipset */
308
309 /* Show to ATF log buffer & UART */
310 INFO("BL3-1: %s\n", version_string);
311 INFO("BL3-1: %s\n", build_message);
312
313}
314#if 0
315/* MTK Define */
316#define ACTLR_CPUECTLR_BIT (1 << 1)
317
318void enable_ns_access_to_cpuectlr(void)
319{
320 unsigned int next_actlr;
321
322
323 /* ACTLR_EL1 do not implement CUPECTLR */
324 next_actlr = read_actlr_el2();
325 next_actlr |= ACTLR_CPUECTLR_BIT;
326 write_actlr_el2(next_actlr);
327
328 next_actlr = read_actlr_el3();
329 next_actlr |= ACTLR_CPUECTLR_BIT;
330 write_actlr_el3(next_actlr);
331}
332#endif
333/*******************************************************************************
334 * This function prepare boot argument for 64 bit kernel entry
335 ******************************************************************************/
336static entry_point_info_t *bl31_plat_get_next_kernel64_ep_info(void)
337{
338 entry_point_info_t *next_image_info;
developer550bf5e2016-07-11 16:05:23 +0800339 unsigned int mode;
340
developer550bf5e2016-07-11 16:05:23 +0800341 mode = 0;
342
343 /* Kernel image is always non-secured */
344 next_image_info = &bl33_image_ep_info;
345
346 /* Figure out what mode we enter the non-secure world in */
Jeenu Viswambharan2a9b8822017-02-21 14:40:44 +0000347 if (EL_IMPLEMENTED(2)) {
developer550bf5e2016-07-11 16:05:23 +0800348 INFO("Kernel_EL2\n");
349 mode = MODE_EL2;
350 } else{
351 INFO("Kernel_EL1\n");
352 mode = MODE_EL1;
353 }
354
355 INFO("Kernel is 64Bit\n");
356 next_image_info->spsr =
357 SPSR_64(mode, MODE_SP_ELX, DISABLE_ALL_EXCEPTIONS);
358 next_image_info->pc = get_kernel_info_pc();
359 next_image_info->args.arg0 = get_kernel_info_r0();
360 next_image_info->args.arg1 = get_kernel_info_r1();
361
362 INFO("pc=0x%lx, r0=0x%lx, r1=0x%lx\n",
363 next_image_info->pc,
364 next_image_info->args.arg0,
365 next_image_info->args.arg1);
366
367
368 SET_SECURITY_STATE(next_image_info->h.attr, NON_SECURE);
369
370 /* None of the images on this platform can have 0x0 as the entrypoint */
371 if (next_image_info->pc)
372 return next_image_info;
373 else
374 return NULL;
375}
376
377/*******************************************************************************
378 * This function prepare boot argument for 32 bit kernel entry
379 ******************************************************************************/
380static entry_point_info_t *bl31_plat_get_next_kernel32_ep_info(void)
381{
382 entry_point_info_t *next_image_info;
383 unsigned int mode;
384
385 mode = 0;
386
387 /* Kernel image is always non-secured */
388 next_image_info = &bl33_image_ep_info;
389
390 /* Figure out what mode we enter the non-secure world in */
391 mode = MODE32_hyp;
392 /*
393 * TODO: Consider the possibility of specifying the SPSR in
394 * the FIP ToC and allowing the platform to have a say as
395 * well.
396 */
397
398 INFO("Kernel is 32Bit\n");
399 next_image_info->spsr =
400 SPSR_MODE32(mode, SPSR_T_ARM, SPSR_E_LITTLE,
401 (DAIF_FIQ_BIT | DAIF_IRQ_BIT | DAIF_ABT_BIT));
402 next_image_info->pc = get_kernel_info_pc();
403 next_image_info->args.arg0 = get_kernel_info_r0();
404 next_image_info->args.arg1 = get_kernel_info_r1();
405 next_image_info->args.arg2 = get_kernel_info_r2();
406
407 INFO("pc=0x%lx, r0=0x%lx, r1=0x%lx, r2=0x%lx\n",
408 next_image_info->pc,
409 next_image_info->args.arg0,
410 next_image_info->args.arg1,
411 next_image_info->args.arg2);
412
413
414 SET_SECURITY_STATE(next_image_info->h.attr, NON_SECURE);
415
416 /* None of the images on this platform can have 0x0 as the entrypoint */
417 if (next_image_info->pc)
418 return next_image_info;
419 else
420 return NULL;
421}
422
423/*******************************************************************************
424 * This function prepare boot argument for kernel entrypoint
425 ******************************************************************************/
426void bl31_prepare_kernel_entry(uint64_t k32_64)
427{
428 entry_point_info_t *next_image_info;
429 uint32_t image_type;
430
431 /* Determine which image to execute next */
432 /* image_type = bl31_get_next_image_type(); */
433 image_type = NON_SECURE;
434
435 /* Program EL3 registers to enable entry into the next EL */
436 if (k32_64 == 0)
437 next_image_info = bl31_plat_get_next_kernel32_ep_info();
438 else
439 next_image_info = bl31_plat_get_next_kernel64_ep_info();
440
441 assert(next_image_info);
442 assert(image_type == GET_SECURITY_STATE(next_image_info->h.attr));
443
444 INFO("BL3-1: Preparing for EL3 exit to %s world, Kernel\n",
445 (image_type == SECURE) ? "secure" : "normal");
446 INFO("BL3-1: Next image address = 0x%llx\n",
447 (unsigned long long) next_image_info->pc);
448 INFO("BL3-1: Next image spsr = 0x%x\n", next_image_info->spsr);
449 cm_init_context(read_mpidr_el1(), next_image_info);
450 cm_prepare_el3_exit(image_type);
451}