1 |~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 1 |~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 2 |MOTOROLA MICROPROCESSOR & MEMORY TECHNOLOGY G 2 |MOTOROLA MICROPROCESSOR & MEMORY TECHNOLOGY GROUP 3 |M68000 Hi-Performance Microprocessor Division 3 |M68000 Hi-Performance Microprocessor Division 4 |M68060 Software Package 4 |M68060 Software Package 5 |Production Release P1.00 -- October 10, 1994 5 |Production Release P1.00 -- October 10, 1994 6 | 6 | 7 |M68060 Software Package Copyright © 1993, 19 7 |M68060 Software Package Copyright © 1993, 1994 Motorola Inc. All rights reserved. 8 | 8 | 9 |THE SOFTWARE is provided on an "AS IS" basis 9 |THE SOFTWARE is provided on an "AS IS" basis and without warranty. 10 |To the maximum extent permitted by applicable 10 |To the maximum extent permitted by applicable law, 11 |MOTOROLA DISCLAIMS ALL WARRANTIES WHETHER EXP 11 |MOTOROLA DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED, 12 |INCLUDING IMPLIED WARRANTIES OF MERCHANTABILI 12 |INCLUDING IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE 13 |and any warranty against infringement with re 13 |and any warranty against infringement with regard to the SOFTWARE 14 |(INCLUDING ANY MODIFIED VERSIONS THEREOF) and 14 |(INCLUDING ANY MODIFIED VERSIONS THEREOF) and any accompanying written materials. 15 | 15 | 16 |To the maximum extent permitted by applicable 16 |To the maximum extent permitted by applicable law, 17 |IN NO EVENT SHALL MOTOROLA BE LIABLE FOR ANY 17 |IN NO EVENT SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER 18 |(INCLUDING WITHOUT LIMITATION, DAMAGES FOR LO 18 |(INCLUDING WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, 19 |BUSINESS INTERRUPTION, LOSS OF BUSINESS INFOR 19 |BUSINESS INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY LOSS) 20 |ARISING OF THE USE OR INABILITY TO USE THE SO 20 |ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE. 21 |Motorola assumes no responsibility for the ma 21 |Motorola assumes no responsibility for the maintenance and support of the SOFTWARE. 22 | 22 | 23 |You are hereby granted a copyright license to 23 |You are hereby granted a copyright license to use, modify, and distribute the SOFTWARE 24 |so long as this entire notice is retained wit 24 |so long as this entire notice is retained without alteration in any modified and/or 25 |redistributed versions, and that such modifie 25 |redistributed versions, and that such modified versions are clearly identified as such. 26 |No licenses are granted by implication, estop 26 |No licenses are granted by implication, estoppel or otherwise under any patents 27 |or trademarks of Motorola, Inc. 27 |or trademarks of Motorola, Inc. 28 |~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 28 |~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 29 | os.s 29 | os.s 30 | 30 | 31 | This file contains: 31 | This file contains: 32 | - example "Call-Out"s required by both 32 | - example "Call-Out"s required by both the ISP and FPSP. 33 | 33 | 34 34 35 #include <linux/linkage.h> 35 #include <linux/linkage.h> 36 36 37 |################################ 37 |################################ 38 | EXAMPLE CALL-OUTS # 38 | EXAMPLE CALL-OUTS # 39 | # 39 | # 40 | _060_dmem_write() # 40 | _060_dmem_write() # 41 | _060_dmem_read() # 41 | _060_dmem_read() # 42 | _060_imem_read() # 42 | _060_imem_read() # 43 | _060_dmem_read_byte() # 43 | _060_dmem_read_byte() # 44 | _060_dmem_read_word() # 44 | _060_dmem_read_word() # 45 | _060_dmem_read_long() # 45 | _060_dmem_read_long() # 46 | _060_imem_read_word() # 46 | _060_imem_read_word() # 47 | _060_imem_read_long() # 47 | _060_imem_read_long() # 48 | _060_dmem_write_byte() # 48 | _060_dmem_write_byte() # 49 | _060_dmem_write_word() # 49 | _060_dmem_write_word() # 50 | _060_dmem_write_long() # 50 | _060_dmem_write_long() # 51 | # 51 | # 52 | _060_real_trace() # 52 | _060_real_trace() # 53 | _060_real_access() # 53 | _060_real_access() # 54 |################################ 54 |################################ 55 55 56 | 56 | 57 | Each IO routine checks to see if the memory 57 | Each IO routine checks to see if the memory write/read is to/from user 58 | or supervisor application space. The example 58 | or supervisor application space. The examples below use simple "move" 59 | instructions for supervisor mode application 59 | instructions for supervisor mode applications and call _copyin()/_copyout() 60 | for user mode applications. 60 | for user mode applications. 61 | When installing the 060SP, the _copyin()/_co 61 | When installing the 060SP, the _copyin()/_copyout() equivalents for a 62 | given operating system should be substituted 62 | given operating system should be substituted. 63 | 63 | 64 | The addresses within the 060SP are guarantee 64 | The addresses within the 060SP are guaranteed to be on the stack. 65 | The result is that Unix processes are allowe 65 | The result is that Unix processes are allowed to sleep as a consequence 66 | of a page fault during a _copyout. 66 | of a page fault during a _copyout. 67 | 67 | 68 | Linux/68k: The _060_[id]mem_{read,write}_{by 68 | Linux/68k: The _060_[id]mem_{read,write}_{byte,word,long} functions 69 | (i.e. all the known length <= 4) are impleme 69 | (i.e. all the known length <= 4) are implemented by single moves 70 | statements instead of (more expensive) copy{ 70 | statements instead of (more expensive) copy{in,out} calls, if 71 | working in user space 71 | working in user space 72 72 73 | 73 | 74 | _060_dmem_write(): 74 | _060_dmem_write(): 75 | 75 | 76 | Writes to data memory while in supervisor mo 76 | Writes to data memory while in supervisor mode. 77 | 77 | 78 | INPUTS: 78 | INPUTS: 79 | a0 - supervisor source address 79 | a0 - supervisor source address 80 | a1 - user destination address 80 | a1 - user destination address 81 | d0 - number of bytes to write 81 | d0 - number of bytes to write 82 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 82 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 83 | OUTPUTS: 83 | OUTPUTS: 84 | d1 - 0 = success, !0 = failure 84 | d1 - 0 = success, !0 = failure 85 | 85 | 86 .global _060_dmem_write 86 .global _060_dmem_write 87 _060_dmem_write: 87 _060_dmem_write: 88 subq.l #1,%d0 88 subq.l #1,%d0 89 btst #0x5,0x4(%a6) 89 btst #0x5,0x4(%a6) | check for supervisor state 90 beqs user_write 90 beqs user_write 91 super_write: 91 super_write: 92 move.b (%a0)+,(%a1)+ 92 move.b (%a0)+,(%a1)+ | copy 1 byte 93 dbra %d0,super_write 93 dbra %d0,super_write | quit if --ctr < 0 94 clr.l %d1 94 clr.l %d1 | return success 95 rts 95 rts 96 user_write: 96 user_write: 97 move.b (%a0)+,%d1 97 move.b (%a0)+,%d1 | copy 1 byte 98 copyoutae: 98 copyoutae: 99 movs.b %d1,(%a1)+ 99 movs.b %d1,(%a1)+ 100 dbra %d0,user_write 100 dbra %d0,user_write | quit if --ctr < 0 101 clr.l %d1 101 clr.l %d1 | return success 102 rts 102 rts 103 103 104 | 104 | 105 | _060_imem_read(), _060_dmem_read(): 105 | _060_imem_read(), _060_dmem_read(): 106 | 106 | 107 | Reads from data/instruction memory while in 107 | Reads from data/instruction memory while in supervisor mode. 108 | 108 | 109 | INPUTS: 109 | INPUTS: 110 | a0 - user source address 110 | a0 - user source address 111 | a1 - supervisor destination address 111 | a1 - supervisor destination address 112 | d0 - number of bytes to read 112 | d0 - number of bytes to read 113 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 113 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 114 | OUTPUTS: 114 | OUTPUTS: 115 | d1 - 0 = success, !0 = failure 115 | d1 - 0 = success, !0 = failure 116 | 116 | 117 .global _060_imem_read 117 .global _060_imem_read 118 .global _060_dmem_read 118 .global _060_dmem_read 119 _060_imem_read: 119 _060_imem_read: 120 _060_dmem_read: 120 _060_dmem_read: 121 subq.l #1,%d0 121 subq.l #1,%d0 122 btst #0x5,0x4(%a6) 122 btst #0x5,0x4(%a6) | check for supervisor state 123 beqs user_read 123 beqs user_read 124 super_read: 124 super_read: 125 move.b (%a0)+,(%a1)+ 125 move.b (%a0)+,(%a1)+ | copy 1 byte 126 dbra %d0,super_read 126 dbra %d0,super_read | quit if --ctr < 0 127 clr.l %d1 127 clr.l %d1 | return success 128 rts 128 rts 129 user_read: 129 user_read: 130 copyinae: 130 copyinae: 131 movs.b (%a0)+,%d1 131 movs.b (%a0)+,%d1 132 move.b %d1,(%a1)+ 132 move.b %d1,(%a1)+ | copy 1 byte 133 dbra %d0,user_read 133 dbra %d0,user_read | quit if --ctr < 0 134 clr.l %d1 134 clr.l %d1 | return success 135 rts 135 rts 136 136 137 | 137 | 138 | _060_dmem_read_byte(): 138 | _060_dmem_read_byte(): 139 | 139 | 140 | Read a data byte from user memory. 140 | Read a data byte from user memory. 141 | 141 | 142 | INPUTS: 142 | INPUTS: 143 | a0 - user source address 143 | a0 - user source address 144 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 144 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 145 | OUTPUTS: 145 | OUTPUTS: 146 | d0 - data byte in d0 146 | d0 - data byte in d0 147 | d1 - 0 = success, !0 = failure 147 | d1 - 0 = success, !0 = failure 148 | 148 | 149 .global _060_dmem_read_byte 149 .global _060_dmem_read_byte 150 _060_dmem_read_byte: 150 _060_dmem_read_byte: 151 clr.l %d0 151 clr.l %d0 | clear whole longword 152 clr.l %d1 152 clr.l %d1 | assume success 153 btst #0x5,0x4(%a6) 153 btst #0x5,0x4(%a6) | check for supervisor state 154 bnes dmrbs 154 bnes dmrbs | supervisor 155 dmrbuae:movs.b (%a0),%d0 155 dmrbuae:movs.b (%a0),%d0 | fetch user byte 156 rts 156 rts 157 dmrbs: move.b (%a0),%d0 157 dmrbs: move.b (%a0),%d0 | fetch super byte 158 rts 158 rts 159 159 160 | 160 | 161 | _060_dmem_read_word(): 161 | _060_dmem_read_word(): 162 | 162 | 163 | Read a data word from user memory. 163 | Read a data word from user memory. 164 | 164 | 165 | INPUTS: 165 | INPUTS: 166 | a0 - user source address 166 | a0 - user source address 167 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 167 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 168 | OUTPUTS: 168 | OUTPUTS: 169 | d0 - data word in d0 169 | d0 - data word in d0 170 | d1 - 0 = success, !0 = failure 170 | d1 - 0 = success, !0 = failure 171 | 171 | 172 | _060_imem_read_word(): 172 | _060_imem_read_word(): 173 | 173 | 174 | Read an instruction word from user memory. 174 | Read an instruction word from user memory. 175 | 175 | 176 | INPUTS: 176 | INPUTS: 177 | a0 - user source address 177 | a0 - user source address 178 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 178 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 179 | OUTPUTS: 179 | OUTPUTS: 180 | d0 - instruction word in d0 180 | d0 - instruction word in d0 181 | d1 - 0 = success, !0 = failure 181 | d1 - 0 = success, !0 = failure 182 | 182 | 183 .global _060_dmem_read_word 183 .global _060_dmem_read_word 184 .global _060_imem_read_word 184 .global _060_imem_read_word 185 _060_dmem_read_word: 185 _060_dmem_read_word: 186 _060_imem_read_word: 186 _060_imem_read_word: 187 clr.l %d1 187 clr.l %d1 | assume success 188 clr.l %d0 188 clr.l %d0 | clear whole longword 189 btst #0x5,0x4(%a6) 189 btst #0x5,0x4(%a6) | check for supervisor state 190 bnes dmrws 190 bnes dmrws | supervisor 191 dmrwuae:movs.w (%a0), %d0 191 dmrwuae:movs.w (%a0), %d0 | fetch user word 192 rts 192 rts 193 dmrws: move.w (%a0), %d0 193 dmrws: move.w (%a0), %d0 | fetch super word 194 rts 194 rts 195 195 196 | 196 | 197 | _060_dmem_read_long(): 197 | _060_dmem_read_long(): 198 | 198 | 199 199 200 | 200 | 201 | INPUTS: 201 | INPUTS: 202 | a0 - user source address 202 | a0 - user source address 203 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 203 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 204 | OUTPUTS: 204 | OUTPUTS: 205 | d0 - data longword in d0 205 | d0 - data longword in d0 206 | d1 - 0 = success, !0 = failure 206 | d1 - 0 = success, !0 = failure 207 | 207 | 208 | _060_imem_read_long(): 208 | _060_imem_read_long(): 209 | 209 | 210 | Read an instruction longword from user memor 210 | Read an instruction longword from user memory. 211 | 211 | 212 | INPUTS: 212 | INPUTS: 213 | a0 - user source address 213 | a0 - user source address 214 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 214 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 215 | OUTPUTS: 215 | OUTPUTS: 216 | d0 - instruction longword in d0 216 | d0 - instruction longword in d0 217 | d1 - 0 = success, !0 = failure 217 | d1 - 0 = success, !0 = failure 218 | 218 | 219 .global _060_dmem_read_long 219 .global _060_dmem_read_long 220 .global _060_imem_read_long 220 .global _060_imem_read_long 221 _060_dmem_read_long: 221 _060_dmem_read_long: 222 _060_imem_read_long: 222 _060_imem_read_long: 223 clr.l %d1 223 clr.l %d1 | assume success 224 btst #0x5,0x4(%a6) 224 btst #0x5,0x4(%a6) | check for supervisor state 225 bnes dmrls 225 bnes dmrls | supervisor 226 dmrluae:movs.l (%a0),%d0 226 dmrluae:movs.l (%a0),%d0 | fetch user longword 227 rts 227 rts 228 dmrls: move.l (%a0),%d0 228 dmrls: move.l (%a0),%d0 | fetch super longword 229 rts 229 rts 230 230 231 | 231 | 232 | _060_dmem_write_byte(): 232 | _060_dmem_write_byte(): 233 | 233 | 234 | Write a data byte to user memory. 234 | Write a data byte to user memory. 235 | 235 | 236 | INPUTS: 236 | INPUTS: 237 | a0 - user destination address 237 | a0 - user destination address 238 | d0 - data byte in d0 238 | d0 - data byte in d0 239 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 239 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 240 | OUTPUTS: 240 | OUTPUTS: 241 | d1 - 0 = success, !0 = failure 241 | d1 - 0 = success, !0 = failure 242 | 242 | 243 .global _060_dmem_write_byte 243 .global _060_dmem_write_byte 244 _060_dmem_write_byte: 244 _060_dmem_write_byte: 245 clr.l %d1 245 clr.l %d1 | assume success 246 btst #0x5,0x4(%a6) 246 btst #0x5,0x4(%a6) | check for supervisor state 247 bnes dmwbs 247 bnes dmwbs | supervisor 248 dmwbuae:movs.b %d0,(%a0) 248 dmwbuae:movs.b %d0,(%a0) | store user byte 249 rts 249 rts 250 dmwbs: move.b %d0,(%a0) 250 dmwbs: move.b %d0,(%a0) | store super byte 251 rts 251 rts 252 252 253 | 253 | 254 | _060_dmem_write_word(): 254 | _060_dmem_write_word(): 255 | 255 | 256 | Write a data word to user memory. 256 | Write a data word to user memory. 257 | 257 | 258 | INPUTS: 258 | INPUTS: 259 | a0 - user destination address 259 | a0 - user destination address 260 | d0 - data word in d0 260 | d0 - data word in d0 261 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 261 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 262 | OUTPUTS: 262 | OUTPUTS: 263 | d1 - 0 = success, !0 = failure 263 | d1 - 0 = success, !0 = failure 264 | 264 | 265 .global _060_dmem_write_word 265 .global _060_dmem_write_word 266 _060_dmem_write_word: 266 _060_dmem_write_word: 267 clr.l %d1 267 clr.l %d1 | assume success 268 btst #0x5,0x4(%a6) 268 btst #0x5,0x4(%a6) | check for supervisor state 269 bnes dmwws 269 bnes dmwws | supervisor 270 dmwwu: 270 dmwwu: 271 dmwwuae:movs.w %d0,(%a0) 271 dmwwuae:movs.w %d0,(%a0) | store user word 272 bras dmwwr 272 bras dmwwr 273 dmwws: move.w %d0,(%a0) 273 dmwws: move.w %d0,(%a0) | store super word 274 dmwwr: clr.l %d1 274 dmwwr: clr.l %d1 | return success 275 rts 275 rts 276 276 277 | 277 | 278 | _060_dmem_write_long(): 278 | _060_dmem_write_long(): 279 | 279 | 280 | Write a data longword to user memory. 280 | Write a data longword to user memory. 281 | 281 | 282 | INPUTS: 282 | INPUTS: 283 | a0 - user destination address 283 | a0 - user destination address 284 | d0 - data longword in d0 284 | d0 - data longword in d0 285 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 285 | 0x4(%a6),bit5 - 1 = supervisor mode, 0 = user mode 286 | OUTPUTS: 286 | OUTPUTS: 287 | d1 - 0 = success, !0 = failure 287 | d1 - 0 = success, !0 = failure 288 | 288 | 289 .global _060_dmem_write_long 289 .global _060_dmem_write_long 290 _060_dmem_write_long: 290 _060_dmem_write_long: 291 clr.l %d1 291 clr.l %d1 | assume success 292 btst #0x5,0x4(%a6) 292 btst #0x5,0x4(%a6) | check for supervisor state 293 bnes dmwls 293 bnes dmwls | supervisor 294 dmwluae:movs.l %d0,(%a0) 294 dmwluae:movs.l %d0,(%a0) | store user longword 295 rts 295 rts 296 dmwls: move.l %d0,(%a0) 296 dmwls: move.l %d0,(%a0) | store super longword 297 rts 297 rts 298 298 299 299 300 #if 0 300 #if 0 301 |############################################# 301 |############################################### 302 302 303 | 303 | 304 | Use these routines if your kernel doesn't ha 304 | Use these routines if your kernel doesn't have _copyout/_copyin equivalents. 305 | Assumes that D0/D1/A0/A1 are scratch registe 305 | Assumes that D0/D1/A0/A1 are scratch registers. The _copyin/_copyout 306 | below assume that the SFC/DFC have been set 306 | below assume that the SFC/DFC have been set previously. 307 | 307 | 308 | Linux/68k: These are basically non-inlined v 308 | Linux/68k: These are basically non-inlined versions of 309 | memcpy_{to,from}fs, but without long-transfe 309 | memcpy_{to,from}fs, but without long-transfer optimization 310 | Note: Assumed that SFC/DFC are pointing corr 310 | Note: Assumed that SFC/DFC are pointing correctly to user data 311 | space... Should be right, or are there any e 311 | space... Should be right, or are there any exceptions? 312 312 313 | 313 | 314 | int _copyout(supervisor_addr, user_addr, nby 314 | int _copyout(supervisor_addr, user_addr, nbytes) 315 | 315 | 316 .global _copyout 316 .global _copyout 317 _copyout: 317 _copyout: 318 move.l 4(%sp),%a0 318 move.l 4(%sp),%a0 | source 319 move.l 8(%sp),%a1 319 move.l 8(%sp),%a1 | destination 320 move.l 12(%sp),%d0 320 move.l 12(%sp),%d0 | count 321 subq.l #1,%d0 321 subq.l #1,%d0 322 moreout: 322 moreout: 323 move.b (%a0)+,%d1 323 move.b (%a0)+,%d1 | fetch supervisor byte 324 copyoutae: 324 copyoutae: 325 movs.b %d1,(%a1)+ 325 movs.b %d1,(%a1)+ | store user byte 326 dbra %d0,moreout 326 dbra %d0,moreout | are we through yet? 327 moveq #0,%d0 327 moveq #0,%d0 | return success 328 rts 328 rts 329 329 330 | 330 | 331 | int _copyin(user_addr, supervisor_addr, nbyt 331 | int _copyin(user_addr, supervisor_addr, nbytes) 332 | 332 | 333 .global _copyin 333 .global _copyin 334 _copyin: 334 _copyin: 335 move.l 4(%sp),%a0 335 move.l 4(%sp),%a0 | source 336 move.l 8(%sp),%a1 336 move.l 8(%sp),%a1 | destination 337 move.l 12(%sp),%d0 337 move.l 12(%sp),%d0 | count 338 subq.l #1,%d0 338 subq.l #1,%d0 339 morein: 339 morein: 340 copyinae: 340 copyinae: 341 movs.b (%a0)+,%d1 341 movs.b (%a0)+,%d1 | fetch user byte 342 move.b %d1,(%a1)+ 342 move.b %d1,(%a1)+ | write supervisor byte 343 dbra %d0,morein 343 dbra %d0,morein | are we through yet? 344 moveq #0,%d0 344 moveq #0,%d0 | return success 345 rts 345 rts 346 #endif 346 #endif 347 347 348 |############################################# 348 |########################################################################### 349 349 350 | 350 | 351 | _060_real_trace(): 351 | _060_real_trace(): 352 | 352 | 353 | This is the exit point for the 060FPSP when 353 | This is the exit point for the 060FPSP when an instruction is being traced 354 | and there are no other higher priority excep 354 | and there are no other higher priority exceptions pending for this instruction 355 | or they have already been processed. 355 | or they have already been processed. 356 | 356 | 357 | The sample code below simply executes an "rt 357 | The sample code below simply executes an "rte". 358 | 358 | 359 .global _060_real_trace 359 .global _060_real_trace 360 _060_real_trace: 360 _060_real_trace: 361 bral trap 361 bral trap 362 362 363 | 363 | 364 | _060_real_access(): 364 | _060_real_access(): 365 | 365 | 366 | This is the exit point for the 060FPSP when 366 | This is the exit point for the 060FPSP when an access error exception 367 | is encountered. The routine below should poi 367 | is encountered. The routine below should point to the operating system 368 | handler for access error exceptions. The exc 368 | handler for access error exceptions. The exception stack frame is an 369 | 8-word access error frame. 369 | 8-word access error frame. 370 | 370 | 371 | The sample routine below simply executes an 371 | The sample routine below simply executes an "rte" instruction which 372 | is most likely the incorrect thing to do and 372 | is most likely the incorrect thing to do and could put the system 373 | into an infinite loop. 373 | into an infinite loop. 374 | 374 | 375 .global _060_real_access 375 .global _060_real_access 376 _060_real_access: 376 _060_real_access: 377 bral buserr 377 bral buserr 378 378 379 379 380 380 381 | Execption handling for movs access to illega 381 | Execption handling for movs access to illegal memory 382 .section .fixup,"ax" 382 .section .fixup,"ax" 383 .even 383 .even 384 1: moveq #-1,%d1 384 1: moveq #-1,%d1 385 rts 385 rts 386 .section __ex_table,"a" 386 .section __ex_table,"a" 387 .align 4 387 .align 4 388 .long dmrbuae,1b 388 .long dmrbuae,1b 389 .long dmrwuae,1b 389 .long dmrwuae,1b 390 .long dmrluae,1b 390 .long dmrluae,1b 391 .long dmwbuae,1b 391 .long dmwbuae,1b 392 .long dmwwuae,1b 392 .long dmwwuae,1b 393 .long dmwluae,1b 393 .long dmwluae,1b 394 .long copyoutae,1b 394 .long copyoutae,1b 395 .long copyinae,1b 395 .long copyinae,1b 396 .text 396 .text
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