fpu.c revision 1.7
1 1.7 chs /* $NetBSD: fpu.c,v 1.7 2004/07/24 18:59:05 chs Exp $ */ 2 1.1 fredette 3 1.1 fredette /* 4 1.1 fredette * Copyright (c) 2002 The NetBSD Foundation, Inc. 5 1.1 fredette * All rights reserved. 6 1.1 fredette * 7 1.1 fredette * This code is derived from software contributed to The NetBSD Foundation 8 1.1 fredette * by Matthew Fredette. 9 1.1 fredette * 10 1.1 fredette * Redistribution and use in source and binary forms, with or without 11 1.1 fredette * modification, are permitted provided that the following conditions 12 1.1 fredette * are met: 13 1.1 fredette * 1. Redistributions of source code must retain the above copyright 14 1.1 fredette * notice, this list of conditions and the following disclaimer. 15 1.1 fredette * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 fredette * notice, this list of conditions and the following disclaimer in the 17 1.1 fredette * documentation and/or other materials provided with the distribution. 18 1.1 fredette * 3. All advertising materials mentioning features or use of this software 19 1.1 fredette * must display the following acknowledgement: 20 1.1 fredette * This product includes software developed by the NetBSD 21 1.1 fredette * Foundation, Inc. and its contributors. 22 1.1 fredette * 4. Neither the name of The NetBSD Foundation nor the names of its 23 1.1 fredette * contributors may be used to endorse or promote products derived 24 1.1 fredette * from this software without specific prior written permission. 25 1.1 fredette * 26 1.1 fredette * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 27 1.1 fredette * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 28 1.1 fredette * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 29 1.1 fredette * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 30 1.1 fredette * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 31 1.1 fredette * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 32 1.1 fredette * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 33 1.1 fredette * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 34 1.1 fredette * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 35 1.1 fredette * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 36 1.1 fredette * POSSIBILITY OF SUCH DAMAGE. 37 1.1 fredette */ 38 1.1 fredette 39 1.1 fredette /* 40 1.1 fredette * FPU handling for NetBSD/hppa. 41 1.1 fredette */ 42 1.1 fredette 43 1.1 fredette #include <sys/cdefs.h> 44 1.7 chs __KERNEL_RCSID(0, "$NetBSD: fpu.c,v 1.7 2004/07/24 18:59:05 chs Exp $"); 45 1.1 fredette 46 1.1 fredette #include <sys/param.h> 47 1.1 fredette #include <sys/systm.h> 48 1.1 fredette #include <sys/proc.h> 49 1.1 fredette #include <sys/signalvar.h> 50 1.1 fredette #include <sys/user.h> 51 1.1 fredette 52 1.1 fredette #include <machine/cpu.h> 53 1.1 fredette #include <machine/cpufunc.h> 54 1.1 fredette #include <machine/frame.h> 55 1.1 fredette #include <machine/reg.h> 56 1.1 fredette 57 1.1 fredette #include <hppa/hppa/machdep.h> 58 1.1 fredette 59 1.1 fredette #include "../spmath/float.h" 60 1.1 fredette #include "../spmath/fpudispatch.h" 61 1.1 fredette 62 1.1 fredette /* Some macros representing opcodes. */ 63 1.1 fredette #define OPCODE_NOP 0x08000240 64 1.1 fredette #define OPCODE_COPR_0_0 0x30000000 65 1.1 fredette 66 1.1 fredette /* Some macros representing fields in load/store opcodes. */ 67 1.1 fredette #define OPCODE_CMPLT_S 0x00002000 68 1.1 fredette #define OPCODE_CMPLT_M 0x00000020 69 1.1 fredette #define OPCODE_CMPLT_SM (OPCODE_CMPLT_S | OPCODE_CMPLT_M) 70 1.1 fredette #define OPCODE_CMPLT_MB OPCODE_CMPLT_M 71 1.1 fredette #define OPCODE_CMPLT_MA (OPCODE_CMPLT_S | OPCODE_CMPLT_M) 72 1.1 fredette #define OPCODE_CMPLT (OPCODE_CMPLT_S | OPCODE_CMPLT_M) 73 1.1 fredette #define OPCODE_DOUBLE 0x08000000 74 1.1 fredette #define OPCODE_STORE 0x00000200 75 1.1 fredette #define OPCODE_INDEXED 0x00001000 76 1.1 fredette 77 1.1 fredette /* This is nonzero iff we're using a hardware FPU. */ 78 1.1 fredette int fpu_present; 79 1.1 fredette 80 1.1 fredette /* If we have any FPU, this is its version. */ 81 1.1 fredette u_int fpu_version; 82 1.1 fredette 83 1.1 fredette /* The number of times we have had to switch the FPU context. */ 84 1.1 fredette u_int fpu_csw; 85 1.1 fredette 86 1.1 fredette /* The U-space physical address of the proc in the FPU, or zero. */ 87 1.1 fredette paddr_t fpu_cur_uspace; 88 1.1 fredette 89 1.1 fredette /* In locore.S, this swaps states in and out of the FPU. */ 90 1.6 chs void hppa_fpu_swap(struct pcb *, struct pcb *); 91 1.1 fredette 92 1.5 drochner /* XXX see trap.c */ 93 1.5 drochner void hppa_trapsignal_hack(struct lwp *, int, u_long); 94 1.5 drochner 95 1.1 fredette #ifdef FPEMUL 96 1.1 fredette /* 97 1.1 fredette * Given a trapframe and a general register number, the 98 1.1 fredette * FRAME_REG macro returns a pointer to that general 99 1.1 fredette * register. The _frame_reg_positions array is a lookup 100 1.1 fredette * table, since the general registers aren't in order 101 1.1 fredette * in a trapframe. 102 1.1 fredette * 103 1.1 fredette * NB: this more or less assumes that all members of 104 1.1 fredette * struct trapframe are u_ints. 105 1.1 fredette */ 106 1.1 fredette #define FRAME_REG(f, reg, r0) \ 107 1.1 fredette ((reg) == 0 ? (&r0) : ((&(f)->tf_t1) + _frame_reg_positions[reg])) 108 1.1 fredette #define _FRAME_POSITION(f) \ 109 1.1 fredette ((&((struct trapframe *) 0)->f) - (&((struct trapframe *) 0)->tf_t1)) 110 1.1 fredette const int _frame_reg_positions[32] = { 111 1.1 fredette -1, /* r0 */ 112 1.1 fredette _FRAME_POSITION(tf_r1), 113 1.1 fredette _FRAME_POSITION(tf_rp), /* r2 */ 114 1.1 fredette _FRAME_POSITION(tf_r3), 115 1.1 fredette _FRAME_POSITION(tf_r4), 116 1.1 fredette _FRAME_POSITION(tf_r5), 117 1.1 fredette _FRAME_POSITION(tf_r6), 118 1.1 fredette _FRAME_POSITION(tf_r7), 119 1.1 fredette _FRAME_POSITION(tf_r8), 120 1.1 fredette _FRAME_POSITION(tf_r9), 121 1.1 fredette _FRAME_POSITION(tf_r10), 122 1.1 fredette _FRAME_POSITION(tf_r11), 123 1.1 fredette _FRAME_POSITION(tf_r12), 124 1.1 fredette _FRAME_POSITION(tf_r13), 125 1.1 fredette _FRAME_POSITION(tf_r14), 126 1.1 fredette _FRAME_POSITION(tf_r15), 127 1.1 fredette _FRAME_POSITION(tf_r16), 128 1.1 fredette _FRAME_POSITION(tf_r17), 129 1.1 fredette _FRAME_POSITION(tf_r18), 130 1.1 fredette _FRAME_POSITION(tf_t4), /* r19 */ 131 1.1 fredette _FRAME_POSITION(tf_t3), /* r20 */ 132 1.1 fredette _FRAME_POSITION(tf_t2), /* r21 */ 133 1.1 fredette _FRAME_POSITION(tf_t1), /* r22 */ 134 1.1 fredette _FRAME_POSITION(tf_arg3), /* r23 */ 135 1.1 fredette _FRAME_POSITION(tf_arg2), /* r24 */ 136 1.1 fredette _FRAME_POSITION(tf_arg1), /* r25 */ 137 1.1 fredette _FRAME_POSITION(tf_arg0), /* r26 */ 138 1.1 fredette _FRAME_POSITION(tf_dp), /* r27 */ 139 1.1 fredette _FRAME_POSITION(tf_ret0), /* r28 */ 140 1.1 fredette _FRAME_POSITION(tf_ret1), /* r29 */ 141 1.1 fredette _FRAME_POSITION(tf_sp), /* r30 */ 142 1.1 fredette _FRAME_POSITION(tf_r31), 143 1.1 fredette }; 144 1.1 fredette #endif /* FPEMUL */ 145 1.1 fredette 146 1.1 fredette /* 147 1.1 fredette * Bootstraps the FPU. 148 1.1 fredette */ 149 1.1 fredette void 150 1.1 fredette hppa_fpu_bootstrap(u_int ccr_enable) 151 1.1 fredette { 152 1.1 fredette u_int32_t junk[2]; 153 1.1 fredette u_int32_t version[2]; 154 1.1 fredette extern u_int hppa_fpu_nop0; 155 1.1 fredette extern u_int hppa_fpu_nop1; 156 1.1 fredette 157 1.1 fredette /* See if we have a present and functioning hardware FPU. */ 158 1.1 fredette fpu_present = (ccr_enable & HPPA_FPUS) == HPPA_FPUS; 159 1.1 fredette 160 1.1 fredette /* Initialize the FPU and get its version. */ 161 1.1 fredette if (fpu_present) { 162 1.1 fredette 163 1.1 fredette /* 164 1.1 fredette * To somewhat optimize the emulation 165 1.1 fredette * assist trap handling and context 166 1.1 fredette * switching (to save them from having 167 1.1 fredette * to always load and check fpu_present), 168 1.1 fredette * there are two instructions in locore.S 169 1.1 fredette * that are replaced with nops when 170 1.1 fredette * there is a hardware FPU. 171 1.1 fredette */ 172 1.1 fredette hppa_fpu_nop0 = OPCODE_NOP; 173 1.1 fredette hppa_fpu_nop1 = OPCODE_NOP; 174 1.1 fredette fcacheall(); 175 1.1 fredette 176 1.1 fredette /* 177 1.1 fredette * We track what process has the FPU, 178 1.1 fredette * and how many times we have to swap 179 1.1 fredette * in and out. 180 1.1 fredette */ 181 1.1 fredette 182 1.1 fredette /* 183 1.1 fredette * The PA-RISC 1.1 Architecture manual is 184 1.1 fredette * pretty clear that the copr,0,0 must be 185 1.1 fredette * wrapped in double word stores of fr0, 186 1.1 fredette * otherwise its operation is undefined. 187 1.1 fredette */ 188 1.1 fredette __asm __volatile( 189 1.1 fredette " ldo %0, %%r22 \n" 190 1.1 fredette " fstds %%fr0, 0(%%r22) \n" 191 1.1 fredette " ldo %1, %%r22 \n" 192 1.1 fredette " copr,0,0 \n" 193 1.1 fredette " fstds %%fr0, 0(%%r22) \n" 194 1.1 fredette : "=m" (junk), "=m" (version) : : "r22"); 195 1.1 fredette 196 1.1 fredette /* 197 1.1 fredette * Now mark that no process has the FPU, 198 1.1 fredette * and disable it, so the first time it 199 1.1 fredette * gets used the process' state gets 200 1.1 fredette * swapped in. 201 1.1 fredette */ 202 1.1 fredette fpu_csw = 0; 203 1.1 fredette fpu_cur_uspace = 0; 204 1.1 fredette mtctl(ccr_enable & (CCR_MASK ^ HPPA_FPUS), CR_CCR); 205 1.1 fredette } 206 1.1 fredette #ifdef FPEMUL 207 1.1 fredette else 208 1.1 fredette /* 209 1.1 fredette * XXX This is a hack - to avoid 210 1.1 fredette * having to set up the emulator so 211 1.1 fredette * it can work for one instruction for 212 1.1 fredette * proc0, we dispatch the copr,0,0 opcode 213 1.1 fredette * into the emulator directly. 214 1.1 fredette */ 215 1.1 fredette decode_0c(OPCODE_COPR_0_0, 0, 0, version); 216 1.1 fredette #endif /* FPEMUL */ 217 1.1 fredette fpu_version = version[0]; 218 1.1 fredette } 219 1.1 fredette 220 1.1 fredette /* 221 1.2 chs * If the given LWP has its state in the FPU, 222 1.2 chs * flush that state out into the LWP's PCB. 223 1.1 fredette */ 224 1.1 fredette void 225 1.2 chs hppa_fpu_flush(struct lwp *l) 226 1.1 fredette { 227 1.2 chs struct trapframe *tf = l->l_md.md_regs; 228 1.1 fredette 229 1.1 fredette /* 230 1.2 chs * If we have a hardware FPU, and this process' 231 1.2 chs * state is currently in it, swap it out. 232 1.2 chs */ 233 1.2 chs 234 1.6 chs if (!fpu_present || fpu_cur_uspace == 0 || 235 1.6 chs fpu_cur_uspace != tf->tf_cr30) { 236 1.6 chs return; 237 1.6 chs } 238 1.6 chs 239 1.6 chs hppa_fpu_swap(&l->l_addr->u_pcb, NULL); 240 1.6 chs fpu_cur_uspace = 0; 241 1.1 fredette } 242 1.1 fredette 243 1.1 fredette #ifdef FPEMUL 244 1.1 fredette 245 1.1 fredette /* 246 1.1 fredette * This emulates a coprocessor load/store instruction. 247 1.1 fredette */ 248 1.4 chs static int hppa_fpu_ls(struct trapframe *, struct lwp *); 249 1.1 fredette static int 250 1.2 chs hppa_fpu_ls(struct trapframe *frame, struct lwp *l) 251 1.1 fredette { 252 1.1 fredette u_int inst, inst_b, inst_x, inst_s, inst_t; 253 1.1 fredette int log2size; 254 1.1 fredette u_int *base; 255 1.1 fredette u_int offset, index, im5; 256 1.1 fredette void *fpreg; 257 1.1 fredette u_int r0 = 0; 258 1.6 chs int error; 259 1.6 chs 260 1.1 fredette /* 261 1.1 fredette * Get the instruction that we're emulating, 262 1.1 fredette * and break it down. Using HP bit notation, 263 1.1 fredette * b is a five-bit field starting at bit 10, 264 1.1 fredette * x is a five-bit field starting at bit 15, 265 1.1 fredette * s is a two-bit field starting at bit 17, 266 1.7 chs * and t is a five-bit field starting at bit 31. 267 1.1 fredette */ 268 1.1 fredette inst = frame->tf_iir; 269 1.1 fredette __asm __volatile( 270 1.1 fredette " extru %4, 10, 5, %1 \n" 271 1.1 fredette " extru %4, 15, 5, %2 \n" 272 1.1 fredette " extru %4, 17, 2, %3 \n" 273 1.1 fredette " extru %4, 31, 5, %4 \n" 274 1.1 fredette : "=r" (inst_b), "=r" (inst_x), "=r" (inst_s), "=r" (inst_t) 275 1.1 fredette : "r" (inst)); 276 1.1 fredette 277 1.1 fredette /* 278 1.1 fredette * The space must be the user's space, else we 279 1.1 fredette * segfault. 280 1.1 fredette */ 281 1.2 chs if (inst_s != l->l_addr->u_pcb.pcb_space) 282 1.1 fredette return (EFAULT); 283 1.1 fredette 284 1.1 fredette /* See whether or not this is a doubleword load/store. */ 285 1.1 fredette log2size = (inst & OPCODE_DOUBLE) ? 3 : 2; 286 1.1 fredette 287 1.1 fredette /* Get the floating point register. */ 288 1.2 chs fpreg = ((caddr_t)l->l_addr->u_pcb.pcb_fpregs) + (inst_t << log2size); 289 1.1 fredette 290 1.1 fredette /* Get the base register. */ 291 1.1 fredette base = FRAME_REG(frame, inst_b, r0); 292 1.1 fredette 293 1.1 fredette /* Dispatch on whether or not this is an indexed load/store. */ 294 1.1 fredette if (inst & OPCODE_INDEXED) { 295 1.1 fredette 296 1.1 fredette /* Get the index register value. */ 297 1.1 fredette index = *FRAME_REG(frame, inst_x, r0); 298 1.1 fredette 299 1.1 fredette /* Dispatch on the completer. */ 300 1.1 fredette switch (inst & OPCODE_CMPLT) { 301 1.1 fredette case OPCODE_CMPLT_S: 302 1.1 fredette offset = *base + (index << log2size); 303 1.1 fredette break; 304 1.1 fredette case OPCODE_CMPLT_M: 305 1.1 fredette offset = *base; 306 1.1 fredette *base = *base + index; 307 1.1 fredette break; 308 1.1 fredette case OPCODE_CMPLT_SM: 309 1.1 fredette offset = *base; 310 1.1 fredette *base = *base + (index << log2size); 311 1.1 fredette break; 312 1.1 fredette default: 313 1.1 fredette offset = *base + index; 314 1.1 fredette break; 315 1.1 fredette } 316 1.1 fredette } else { 317 1.1 fredette 318 1.1 fredette /* Do a low_sign_ext(x, 5). */ 319 1.1 fredette im5 = inst_x >> 1; 320 1.1 fredette if (inst_x & 1) 321 1.1 fredette im5 |= 0xfffffff0; 322 1.1 fredette 323 1.1 fredette /* Dispatch on the completer. */ 324 1.1 fredette switch (inst & OPCODE_CMPLT) { 325 1.1 fredette case OPCODE_CMPLT_MB: 326 1.1 fredette offset = *base + im5; 327 1.1 fredette *base = *base + im5; 328 1.1 fredette break; 329 1.1 fredette case OPCODE_CMPLT_MA: 330 1.1 fredette offset = *base; 331 1.1 fredette *base = *base + im5; 332 1.1 fredette break; 333 1.1 fredette default: 334 1.1 fredette offset = *base + im5; 335 1.1 fredette break; 336 1.1 fredette } 337 1.1 fredette } 338 1.1 fredette 339 1.1 fredette /* 340 1.1 fredette * The offset we calculated must be the same as the 341 1.1 fredette * offset in the IOR. 342 1.1 fredette */ 343 1.1 fredette KASSERT(offset == frame->tf_ior); 344 1.1 fredette 345 1.1 fredette /* Perform the load or store. */ 346 1.6 chs error = (inst & OPCODE_STORE) ? 347 1.1 fredette copyout(fpreg, (void *) offset, 1 << log2size) : 348 1.1 fredette copyin((const void *) offset, fpreg, 1 << log2size); 349 1.6 chs fdcache(HPPA_SID_KERNEL, (vaddr_t)fpreg, 350 1.6 chs sizeof(l->l_addr->u_pcb.pcb_fpregs)); 351 1.6 chs return error; 352 1.1 fredette } 353 1.1 fredette 354 1.1 fredette /* 355 1.1 fredette * This is called to emulate an instruction. 356 1.1 fredette */ 357 1.1 fredette void 358 1.7 chs hppa_fpu_emulate(struct trapframe *frame, struct lwp *l, u_int inst) 359 1.1 fredette { 360 1.7 chs u_int opcode, class, sub; 361 1.1 fredette u_int *fpregs; 362 1.1 fredette int exception; 363 1.1 fredette 364 1.1 fredette /* 365 1.1 fredette * If the process' state is in any hardware FPU, 366 1.1 fredette * flush it out - we need to operate on it. 367 1.1 fredette */ 368 1.2 chs hppa_fpu_flush(l); 369 1.1 fredette 370 1.1 fredette /* 371 1.1 fredette * Get the instruction that we're emulating, 372 1.1 fredette * and break it down. Using HP bit notation, 373 1.1 fredette * the class is a two-bit field starting at 374 1.1 fredette * bit 22, the opcode is a 6-bit field starting 375 1.1 fredette * at bit 5, and sub for a class 1 instruction 376 1.1 fredette * is a two bit field starting at bit 16, else 377 1.1 fredette * it is a three bit field starting at bit 18. 378 1.1 fredette */ 379 1.7 chs #if 0 380 1.1 fredette __asm __volatile( 381 1.1 fredette " extru %3, 22, 2, %1 \n" 382 1.1 fredette " extru %3, 5, 6, %0 \n" 383 1.1 fredette " extru %3, 18, 3, %2 \n" 384 1.1 fredette " comib,<> 1, %1, 0 \n" 385 1.1 fredette " extru %3, 16, 2, %2 \n" 386 1.1 fredette : "=r" (opcode), "=r" (class), "=r" (sub) 387 1.1 fredette : "r" (inst)); 388 1.7 chs #else 389 1.7 chs opcode = (inst >> (31 - 5)) & 0x3f; 390 1.7 chs class = (inst >> (31 - 22)) & 0x3; 391 1.7 chs if (class == 1) { 392 1.7 chs sub = (inst >> (31 - 16)) & 3; 393 1.7 chs } else { 394 1.7 chs sub = (inst >> (31 - 18)) & 7; 395 1.7 chs } 396 1.7 chs #endif 397 1.1 fredette 398 1.2 chs /* Get this LWP's FPU registers. */ 399 1.2 chs fpregs = (u_int *) l->l_addr->u_pcb.pcb_fpregs; 400 1.1 fredette 401 1.1 fredette /* Dispatch on the opcode. */ 402 1.1 fredette switch (opcode) { 403 1.1 fredette case 0x09: 404 1.1 fredette case 0x0b: 405 1.2 chs if (hppa_fpu_ls(frame, l) != 0) 406 1.5 drochner hppa_trapsignal_hack(l, SIGSEGV, frame->tf_iioq_head); 407 1.1 fredette return; 408 1.1 fredette case 0x0c: 409 1.1 fredette exception = decode_0c(inst, class, sub, fpregs); 410 1.1 fredette break; 411 1.1 fredette case 0x0e: 412 1.1 fredette exception = decode_0e(inst, class, sub, fpregs); 413 1.1 fredette break; 414 1.1 fredette case 0x06: 415 1.1 fredette exception = decode_06(inst, fpregs); 416 1.1 fredette break; 417 1.1 fredette case 0x26: 418 1.1 fredette exception = decode_26(inst, fpregs); 419 1.1 fredette break; 420 1.1 fredette default: 421 1.1 fredette exception = UNIMPLEMENTEDEXCEPTION; 422 1.1 fredette break; 423 1.1 fredette } 424 1.1 fredette 425 1.6 chs fdcache(HPPA_SID_KERNEL, (vaddr_t)fpregs, 426 1.6 chs sizeof(l->l_addr->u_pcb.pcb_fpregs)); 427 1.1 fredette if (exception) 428 1.5 drochner hppa_trapsignal_hack(l, (exception & UNIMPLEMENTEDEXCEPTION) ? 429 1.1 fredette SIGILL : SIGFPE, frame->tf_iioq_head); 430 1.1 fredette } 431 1.1 fredette 432 1.1 fredette #endif /* FPEMUL */ 433
Indexes created Sun Sep 28 12:09:53 GMT 2025