Rev 2078 | Rev 4055 | Go to most recent revision | Details | Compare with Previous | Last modification | View Log | RSS feed
Rev | Author | Line No. | Line |
---|---|---|---|
418 | jermar | 1 | # |
2071 | jermar | 2 | # Copyright (c) 2005 Jakub Jermar |
418 | jermar | 3 | # All rights reserved. |
4 | # |
||
5 | # Redistribution and use in source and binary forms, with or without |
||
6 | # modification, are permitted provided that the following conditions |
||
7 | # are met: |
||
8 | # |
||
9 | # - Redistributions of source code must retain the above copyright |
||
10 | # notice, this list of conditions and the following disclaimer. |
||
11 | # - Redistributions in binary form must reproduce the above copyright |
||
12 | # notice, this list of conditions and the following disclaimer in the |
||
13 | # documentation and/or other materials provided with the distribution. |
||
14 | # - The name of the author may not be used to endorse or promote products |
||
15 | # derived from this software without specific prior written permission. |
||
16 | # |
||
17 | # THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR |
||
18 | # IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES |
||
19 | # OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. |
||
20 | # IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, |
||
21 | # INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT |
||
22 | # NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
||
23 | # DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
||
24 | # THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
||
25 | # (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF |
||
26 | # THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
||
27 | # |
||
28 | |||
1903 | jermar | 29 | #include <arch/arch.h> |
1789 | jermar | 30 | #include <arch/regdef.h> |
1823 | jermar | 31 | #include <arch/boot/boot.h> |
1917 | jermar | 32 | #include <arch/stack.h> |
846 | jermar | 33 | |
1823 | jermar | 34 | #include <arch/mm/mmu.h> |
35 | #include <arch/mm/tlb.h> |
||
36 | #include <arch/mm/tte.h> |
||
37 | |||
1903 | jermar | 38 | #ifdef CONFIG_SMP |
39 | #include <arch/context_offset.h> |
||
40 | #endif |
||
41 | |||
426 | jermar | 42 | .register %g2, #scratch |
43 | .register %g3, #scratch |
||
44 | |||
418 | jermar | 45 | .section K_TEXT_START, "ax" |
46 | |||
1978 | jermar | 47 | #define BSP_FLAG 1 |
48 | |||
847 | jermar | 49 | /* |
1978 | jermar | 50 | * Here is where the kernel is passed control from the boot loader. |
1790 | jermar | 51 | * |
52 | * The registers are expected to be in this state: |
||
1978 | jermar | 53 | * - %o0 starting address of physical memory + bootstrap processor flag |
54 | * bits 63...1: physical memory starting address / 2 |
||
55 | * bit 0: non-zero on BSP processor, zero on AP processors |
||
56 | * - %o1 bootinfo structure address (BSP only) |
||
57 | * - %o2 bootinfo structure size (BSP only) |
||
1792 | jermar | 58 | * |
1978 | jermar | 59 | * Moreover, we depend on boot having established the following environment: |
1792 | jermar | 60 | * - TLBs are on |
61 | * - identity mapping for the kernel image |
||
847 | jermar | 62 | */ |
63 | |||
418 | jermar | 64 | .global kernel_image_start |
65 | kernel_image_start: |
||
1978 | jermar | 66 | mov BSP_FLAG, %l0 |
2001 | jermar | 67 | and %o0, %l0, %l7 ! l7 <= bootstrap processor? |
68 | andn %o0, %l0, %l6 ! l6 <= start of physical memory |
||
846 | jermar | 69 | |
1982 | jermar | 70 | ! Get bits 40:13 of physmem_base. |
71 | srlx %l6, 13, %l5 |
||
72 | sllx %l5, 13 + (63 - 40), %l5 |
||
2001 | jermar | 73 | srlx %l5, 63 - 40, %l5 ! l5 <= physmem_base[40:13] |
1978 | jermar | 74 | |
75 | /* |
||
1823 | jermar | 76 | * Setup basic runtime environment. |
1790 | jermar | 77 | */ |
424 | jermar | 78 | |
1954 | jermar | 79 | wrpr %g0, NWINDOWS - 2, %cansave ! set maximum saveable windows |
2049 | jermar | 80 | wrpr %g0, 0, %canrestore ! get rid of windows we will |
81 | ! never need again |
||
82 | wrpr %g0, 0, %otherwin ! make sure the window state is |
||
83 | ! consistent |
||
84 | wrpr %g0, NWINDOWS - 1, %cleanwin ! prevent needless clean_window |
||
85 | ! traps for kernel |
||
1823 | jermar | 86 | |
2049 | jermar | 87 | wrpr %g0, 0, %tl ! TL = 0, primary context |
88 | ! register is used |
||
1823 | jermar | 89 | |
2049 | jermar | 90 | wrpr %g0, PSTATE_PRIV_BIT, %pstate ! disable interrupts and disable |
91 | ! 32-bit address masking |
||
1823 | jermar | 92 | |
1881 | jermar | 93 | wrpr %g0, 0, %pil ! intialize %pil |
94 | |||
1790 | jermar | 95 | /* |
1823 | jermar | 96 | * Switch to kernel trap table. |
97 | */ |
||
1880 | jermar | 98 | sethi %hi(trap_table), %g1 |
99 | wrpr %g1, %lo(trap_table), %tba |
||
1823 | jermar | 100 | |
101 | /* |
||
2078 | jermar | 102 | * Take over the DMMU by installing locked TTE entry identically |
2049 | jermar | 103 | * mapping the first 4M of memory. |
1792 | jermar | 104 | * |
2049 | jermar | 105 | * In case of DMMU, no FLUSH instructions need to be issued. Because of |
106 | * that, the old DTLB contents can be demapped pretty straightforwardly |
||
107 | * and without causing any traps. |
||
1792 | jermar | 108 | */ |
109 | |||
1823 | jermar | 110 | wr %g0, ASI_DMMU, %asi |
895 | jermar | 111 | |
1823 | jermar | 112 | #define SET_TLB_DEMAP_CMD(r1, context_id) \ |
2049 | jermar | 113 | set (TLB_DEMAP_CONTEXT << TLB_DEMAP_TYPE_SHIFT) | (context_id << \ |
114 | TLB_DEMAP_CONTEXT_SHIFT), %r1 |
||
1823 | jermar | 115 | |
116 | ! demap context 0 |
||
117 | SET_TLB_DEMAP_CMD(g1, TLB_DEMAP_NUCLEUS) |
||
118 | stxa %g0, [%g1] ASI_DMMU_DEMAP |
||
119 | membar #Sync |
||
120 | |||
121 | #define SET_TLB_TAG(r1, context) \ |
||
2049 | jermar | 122 | set VMA | (context << TLB_TAG_ACCESS_CONTEXT_SHIFT), %r1 |
1823 | jermar | 123 | |
124 | ! write DTLB tag |
||
125 | SET_TLB_TAG(g1, MEM_CONTEXT_KERNEL) |
||
126 | stxa %g1, [VA_DMMU_TAG_ACCESS] %asi |
||
127 | membar #Sync |
||
128 | |||
2009 | jermar | 129 | #ifdef CONFIG_VIRT_IDX_DCACHE |
1996 | jermar | 130 | #define TTE_LOW_DATA(imm) (TTE_CP | TTE_CV | TTE_P | LMA | (imm)) |
2009 | jermar | 131 | #else /* CONFIG_VIRT_IDX_DCACHE */ |
1996 | jermar | 132 | #define TTE_LOW_DATA(imm) (TTE_CP | TTE_P | LMA | (imm)) |
2009 | jermar | 133 | #endif /* CONFIG_VIRT_IDX_DCACHE */ |
1996 | jermar | 134 | |
1823 | jermar | 135 | #define SET_TLB_DATA(r1, r2, imm) \ |
1996 | jermar | 136 | set TTE_LOW_DATA(imm), %r1; \ |
1978 | jermar | 137 | or %r1, %l5, %r1; \ |
138 | mov PAGESIZE_4M, %r2; \ |
||
1823 | jermar | 139 | sllx %r2, TTE_SIZE_SHIFT, %r2; \ |
140 | or %r1, %r2, %r1; \ |
||
1880 | jermar | 141 | mov 1, %r2; \ |
1823 | jermar | 142 | sllx %r2, TTE_V_SHIFT, %r2; \ |
143 | or %r1, %r2, %r1; |
||
144 | |||
145 | ! write DTLB data and install the kernel mapping |
||
1887 | jermar | 146 | SET_TLB_DATA(g1, g2, TTE_L | TTE_W) ! use non-global mapping |
1823 | jermar | 147 | stxa %g1, [%g0] ASI_DTLB_DATA_IN_REG |
148 | membar #Sync |
||
1868 | jermar | 149 | |
150 | /* |
||
2049 | jermar | 151 | * Because we cannot use global mappings (because we want to have |
152 | * separate 64-bit address spaces for both the kernel and the |
||
153 | * userspace), we prepare the identity mapping also in context 1. This |
||
154 | * step is required by the code installing the ITLB mapping. |
||
1868 | jermar | 155 | */ |
156 | ! write DTLB tag of context 1 (i.e. MEM_CONTEXT_TEMP) |
||
157 | SET_TLB_TAG(g1, MEM_CONTEXT_TEMP) |
||
158 | stxa %g1, [VA_DMMU_TAG_ACCESS] %asi |
||
159 | membar #Sync |
||
160 | |||
161 | ! write DTLB data and install the kernel mapping in context 1 |
||
1887 | jermar | 162 | SET_TLB_DATA(g1, g2, TTE_W) ! use non-global mapping |
1868 | jermar | 163 | stxa %g1, [%g0] ASI_DTLB_DATA_IN_REG |
164 | membar #Sync |
||
1823 | jermar | 165 | |
166 | /* |
||
2049 | jermar | 167 | * Now is time to take over the IMMU. Unfortunatelly, it cannot be done |
168 | * as easily as the DMMU, because the IMMU is mapping the code it |
||
169 | * executes. |
||
1823 | jermar | 170 | * |
2049 | jermar | 171 | * [ Note that brave experiments with disabling the IMMU and using the |
172 | * DMMU approach failed after a dozen of desparate days with only little |
||
173 | * success. ] |
||
1823 | jermar | 174 | * |
2049 | jermar | 175 | * The approach used here is inspired from OpenBSD. First, the kernel |
176 | * creates IMMU mapping for itself in context 1 (MEM_CONTEXT_TEMP) and |
||
177 | * switches to it. Context 0 (MEM_CONTEXT_KERNEL) can be demapped |
||
178 | * afterwards and replaced with the kernel permanent mapping. Finally, |
||
179 | * the kernel switches back to context 0 and demaps context 1. |
||
1823 | jermar | 180 | * |
2049 | jermar | 181 | * Moreover, the IMMU requires use of the FLUSH instructions. But that |
182 | * is OK because we always use operands with addresses already mapped by |
||
183 | * the taken over DTLB. |
||
1823 | jermar | 184 | */ |
185 | |||
1852 | jermar | 186 | set kernel_image_start, %g5 |
1823 | jermar | 187 | |
188 | ! write ITLB tag of context 1 |
||
189 | SET_TLB_TAG(g1, MEM_CONTEXT_TEMP) |
||
1880 | jermar | 190 | mov VA_DMMU_TAG_ACCESS, %g2 |
1823 | jermar | 191 | stxa %g1, [%g2] ASI_IMMU |
1852 | jermar | 192 | flush %g5 |
1823 | jermar | 193 | |
194 | ! write ITLB data and install the temporary mapping in context 1 |
||
195 | SET_TLB_DATA(g1, g2, 0) ! use non-global mapping |
||
196 | stxa %g1, [%g0] ASI_ITLB_DATA_IN_REG |
||
1852 | jermar | 197 | flush %g5 |
1823 | jermar | 198 | |
199 | ! switch to context 1 |
||
1880 | jermar | 200 | mov MEM_CONTEXT_TEMP, %g1 |
1823 | jermar | 201 | stxa %g1, [VA_PRIMARY_CONTEXT_REG] %asi ! ASI_DMMU is correct here !!! |
1852 | jermar | 202 | flush %g5 |
1823 | jermar | 203 | |
204 | ! demap context 0 |
||
205 | SET_TLB_DEMAP_CMD(g1, TLB_DEMAP_NUCLEUS) |
||
206 | stxa %g0, [%g1] ASI_IMMU_DEMAP |
||
1852 | jermar | 207 | flush %g5 |
1823 | jermar | 208 | |
209 | ! write ITLB tag of context 0 |
||
210 | SET_TLB_TAG(g1, MEM_CONTEXT_KERNEL) |
||
1880 | jermar | 211 | mov VA_DMMU_TAG_ACCESS, %g2 |
1823 | jermar | 212 | stxa %g1, [%g2] ASI_IMMU |
1852 | jermar | 213 | flush %g5 |
1823 | jermar | 214 | |
215 | ! write ITLB data and install the permanent kernel mapping in context 0 |
||
1887 | jermar | 216 | SET_TLB_DATA(g1, g2, TTE_L) ! use non-global mapping |
1823 | jermar | 217 | stxa %g1, [%g0] ASI_ITLB_DATA_IN_REG |
1852 | jermar | 218 | flush %g5 |
1823 | jermar | 219 | |
1906 | jermar | 220 | ! enter nucleus - using context 0 |
1823 | jermar | 221 | wrpr %g0, 1, %tl |
222 | |||
223 | ! demap context 1 |
||
224 | SET_TLB_DEMAP_CMD(g1, TLB_DEMAP_PRIMARY) |
||
225 | stxa %g0, [%g1] ASI_IMMU_DEMAP |
||
1852 | jermar | 226 | flush %g5 |
1823 | jermar | 227 | |
228 | ! set context 0 in the primary context register |
||
229 | stxa %g0, [VA_PRIMARY_CONTEXT_REG] %asi ! ASI_DMMU is correct here !!! |
||
1852 | jermar | 230 | flush %g5 |
1823 | jermar | 231 | |
1906 | jermar | 232 | ! leave nucleus - using primary context, i.e. context 0 |
1823 | jermar | 233 | wrpr %g0, 0, %tl |
1864 | jermar | 234 | |
1903 | jermar | 235 | brz %l7, 1f ! skip if you are not the bootstrap CPU |
236 | nop |
||
1900 | jermar | 237 | |
1917 | jermar | 238 | /* |
1982 | jermar | 239 | * Save physmem_base for use by the mm subsystem. |
240 | * %l6 contains starting physical address |
||
241 | */ |
||
242 | sethi %hi(physmem_base), %l4 |
||
243 | stx %l6, [%l4 + %lo(physmem_base)] |
||
244 | |||
245 | /* |
||
246 | * Precompute kernel 8K TLB data template. |
||
247 | * %l5 contains starting physical address bits [40:13] |
||
248 | */ |
||
249 | sethi %hi(kernel_8k_tlb_data_template), %l4 |
||
250 | ldx [%l4 + %lo(kernel_8k_tlb_data_template)], %l3 |
||
251 | or %l3, %l5, %l3 |
||
252 | stx %l3, [%l4 + %lo(kernel_8k_tlb_data_template)] |
||
253 | |||
254 | /* |
||
2008 | jermar | 255 | * Flush D-Cache. |
256 | */ |
||
257 | call dcache_flush |
||
258 | nop |
||
259 | |||
260 | /* |
||
1917 | jermar | 261 | * So far, we have not touched the stack. |
1975 | jermar | 262 | * It is a good idea to set the kernel stack to a known state now. |
1917 | jermar | 263 | */ |
264 | sethi %hi(temporary_boot_stack), %sp |
||
265 | or %sp, %lo(temporary_boot_stack), %sp |
||
266 | sub %sp, STACK_BIAS, %sp |
||
267 | |||
1906 | jermar | 268 | sethi %hi(bootinfo), %o0 |
269 | call memcpy ! copy bootinfo |
||
270 | or %o0, %lo(bootinfo), %o0 |
||
271 | |||
1864 | jermar | 272 | call arch_pre_main |
273 | nop |
||
1823 | jermar | 274 | |
426 | jermar | 275 | call main_bsp |
276 | nop |
||
277 | |||
278 | /* Not reached. */ |
||
279 | |||
1903 | jermar | 280 | 0: |
281 | ba 0b |
||
282 | nop |
||
283 | |||
284 | |||
285 | /* |
||
286 | * Read MID from the processor. |
||
287 | */ |
||
288 | 1: |
||
289 | ldxa [%g0] ASI_UPA_CONFIG, %g1 |
||
290 | srlx %g1, UPA_CONFIG_MID_SHIFT, %g1 |
||
291 | and %g1, UPA_CONFIG_MID_MASK, %g1 |
||
292 | |||
1905 | jermar | 293 | #ifdef CONFIG_SMP |
1903 | jermar | 294 | /* |
2049 | jermar | 295 | * Active loop for APs until the BSP picks them up. A processor cannot |
296 | * leave the loop until the global variable 'waking_up_mid' equals its |
||
1903 | jermar | 297 | * MID. |
298 | */ |
||
299 | set waking_up_mid, %g2 |
||
424 | jermar | 300 | 2: |
1903 | jermar | 301 | ldx [%g2], %g3 |
302 | cmp %g3, %g1 |
||
303 | bne 2b |
||
424 | jermar | 304 | nop |
1903 | jermar | 305 | |
306 | /* |
||
307 | * Configure stack for the AP. |
||
308 | * The AP is expected to use the stack saved |
||
309 | * in the ctx global variable. |
||
310 | */ |
||
311 | set ctx, %g1 |
||
312 | add %g1, OFFSET_SP, %g1 |
||
313 | ldx [%g1], %o6 |
||
314 | |||
315 | call main_ap |
||
316 | nop |
||
317 | |||
318 | /* Not reached. */ |
||
1905 | jermar | 319 | #endif |
1903 | jermar | 320 | |
321 | 0: |
||
322 | ba 0b |
||
323 | nop |
||
1917 | jermar | 324 | |
325 | |||
326 | .section K_DATA_START, "aw", @progbits |
||
327 | |||
328 | /* |
||
2049 | jermar | 329 | * Create small stack to be used by the bootstrap processor. It is going to be |
330 | * used only for a very limited period of time, but we switch to it anyway, |
||
331 | * just to be sure we are properly initialized. |
||
1917 | jermar | 332 | */ |
333 | |||
334 | #define INITIAL_STACK_SIZE 1024 |
||
335 | |||
336 | .align STACK_ALIGNMENT |
||
1978 | jermar | 337 | .space INITIAL_STACK_SIZE |
1917 | jermar | 338 | .align STACK_ALIGNMENT |
339 | temporary_boot_stack: |
||
1978 | jermar | 340 | .space STACK_WINDOW_SAVE_AREA_SIZE |
341 | |||
342 | |||
343 | .data |
||
344 | |||
345 | .align 8 |
||
346 | .global physmem_base ! copy of the physical memory base address |
||
347 | physmem_base: |
||
348 | .quad 0 |
||
349 | |||
350 | /* |
||
2049 | jermar | 351 | * This variable is used by the fast_data_MMU_miss trap handler. In runtime, it |
352 | * is further modified to reflect the starting address of physical memory. |
||
1978 | jermar | 353 | */ |
354 | .global kernel_8k_tlb_data_template |
||
355 | kernel_8k_tlb_data_template: |
||
2009 | jermar | 356 | #ifdef CONFIG_VIRT_IDX_DCACHE |
2049 | jermar | 357 | .quad ((1 << TTE_V_SHIFT) | (PAGESIZE_8K << TTE_SIZE_SHIFT) | TTE_CP | \ |
358 | TTE_CV | TTE_P | TTE_W) |
||
2009 | jermar | 359 | #else /* CONFIG_VIRT_IDX_DCACHE */ |
2049 | jermar | 360 | .quad ((1 << TTE_V_SHIFT) | (PAGESIZE_8K << TTE_SIZE_SHIFT) | TTE_CP | \ |
361 | TTE_P | TTE_W) |
||
2009 | jermar | 362 | #endif /* CONFIG_VIRT_IDX_DCACHE */ |
2049 | jermar | 363 |