ref: 1a55b8d1f0253b4d39b1972978b469a352f0f94b
dir: /sys/src/9/bcm/vfp3.c/
/* * VFPv2 or VFPv3 floating point unit */ #include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "ureg.h" #include "arm.h" /* subarchitecture code in m->havefp */ enum { VFPv2 = 2, VFPv3 = 3, }; /* fp control regs. most are read-only */ enum { Fpsid = 0, Fpscr = 1, /* rw */ Mvfr1 = 6, Mvfr0 = 7, Fpexc = 8, /* rw */ Fpinst= 9, /* optional, for exceptions */ Fpinst2=10, }; enum { /* Fpexc bits */ Fpex = 1u << 31, Fpenabled = 1 << 30, Fpdex = 1 << 29, /* defined synch exception */ // Fp2v = 1 << 28, /* Fpinst2 reg is valid */ // Fpvv = 1 << 27, /* if Fpdex, vecitr is valid */ // Fptfv = 1 << 26, /* trapped fault is valid */ // Fpvecitr = MASK(3) << 8, /* FSR bits appear here */ Fpmbc = Fpdex, /* bits exception handler must clear */ /* Fpscr bits; see u.h for more */ Stride = MASK(2) << 20, Len = MASK(3) << 16, Dn= 1 << 25, Fz= 1 << 24, /* trap exception enables (not allowed in vfp3) */ FPIDNRM = 1 << 15, /* input denormal */ Alltraps = FPIDNRM | FPINEX | FPUNFL | FPOVFL | FPZDIV | FPINVAL, /* pending exceptions */ FPAIDNRM = 1 << 7, /* input denormal */ Allexc = FPAIDNRM | FPAINEX | FPAUNFL | FPAOVFL | FPAZDIV | FPAINVAL, /* condition codes */ Allcc = MASK(4) << 28, }; enum { /* CpCPaccess bits */ Cpaccnosimd = 1u << 31, Cpaccd16 = 1 << 30, }; static char * subarch(int impl, uint sa) { static char *armarchs[] = { "VFPv1 (unsupported)", "VFPv2", "VFPv3+ with common VFP subarch v2", "VFPv3+ with null subarch", "VFPv3+ with common VFP subarch v3", }; if (impl != 'A' || sa >= nelem(armarchs)) return "GOK"; else return armarchs[sa]; } static char * implement(uchar impl) { if (impl == 'A') return "arm"; else return "unknown"; } static int havefp(void) { int gotfp; ulong acc, sid; if (m->havefpvalid) return m->havefp; m->havefp = 0; gotfp = 1 << CpFP | 1 << CpDFP; cpwrsc(0, CpCONTROL, 0, CpCPaccess, MASK(28)); acc = cprdsc(0, CpCONTROL, 0, CpCPaccess); if ((acc & (MASK(2) << (2*CpFP))) == 0) { gotfp &= ~(1 << CpFP); print("fpon: no single FP coprocessor\n"); } if ((acc & (MASK(2) << (2*CpDFP))) == 0) { gotfp &= ~(1 << CpDFP); print("fpon: no double FP coprocessor\n"); } if (!gotfp) { print("fpon: no FP coprocessors\n"); m->havefpvalid = 1; return 0; } m->fpon = 1; /* don't panic */ sid = fprd(Fpsid); m->fpon = 0; switch((sid >> 16) & MASK(7)){ case 0: /* VFPv1 */ break; case 1: /* VFPv2 */ m->havefp = VFPv2; m->fpnregs = 16; break; default: /* VFPv3 or later */ m->havefp = VFPv3; m->fpnregs = (acc & Cpaccd16) ? 16 : 32; break; } if (m->machno == 0) print("fp: %d registers, %s simd\n", m->fpnregs, (acc & Cpaccnosimd? " no": "")); m->havefpvalid = 1; return 1; } /* * these can be called to turn the fpu on or off for user procs, * not just at system start up or shutdown. */ void fpoff(void) { if (m->fpon) { fpwr(Fpexc, 0); m->fpon = 0; } } void fpononly(void) { if (!m->fpon && havefp()) { /* enable fp. must be first operation on the FPUs. */ fpwr(Fpexc, Fpenabled); m->fpon = 1; } } static void fpcfg(void) { int impl; ulong sid; static int printed; /* clear pending exceptions; no traps in vfp3; all v7 ops are scalar */ m->fpscr = Dn | FPRNR | (FPINVAL | FPZDIV | FPOVFL) & ~Alltraps; /* VFPv2 needs software support for underflows, so force them to zero */ if(m->havefp == VFPv2) m->fpscr |= Fz; fpwr(Fpscr, m->fpscr); m->fpconfiged = 1; if (printed) return; sid = fprd(Fpsid); impl = sid >> 24; print("fp: %s arch %s; rev %ld\n", implement(impl), subarch(impl, (sid >> 16) & MASK(7)), sid & MASK(4)); printed = 1; } void fpinit(void) { if (havefp()) { fpononly(); fpcfg(); } } void fpon(void) { if (havefp()) { fpononly(); if (m->fpconfiged) fpwr(Fpscr, (fprd(Fpscr) & Allcc) | m->fpscr); else fpcfg(); /* 1st time on this fpu; configure it */ } } void fpclear(void) { // ulong scr; fpon(); // scr = fprd(Fpscr); // m->fpscr = scr & ~Allexc; // fpwr(Fpscr, m->fpscr); fpwr(Fpexc, fprd(Fpexc) & ~Fpmbc); } /* * Called when a note is about to be delivered to a * user process, usually at the end of a system call. * Note handlers are not allowed to use the FPU so * the state is marked (after saving if necessary) and * checked in the Device Not Available handler. */ void fpunotify(Ureg*) { if(up->fpstate == FPactive){ fpsave(up->fpsave); up->fpstate = FPinactive; } up->fpstate |= FPillegal; } /* * Called from sysnoted() via the machine-dependent * noted() routine. * Clear the flag set above in fpunotify(). */ void fpunoted(void) { up->fpstate &= ~FPillegal; } /* should only be called if p->fpstate == FPactive */ void fpsave(FPsave *fps) { int n; fpon(); fps->control = fps->status = fprd(Fpscr); assert(m->fpnregs); for (n = 0; n < m->fpnregs; n++) fpsavereg(n, (uvlong *)fps->regs[n]); fpoff(); } static void fprestore(Proc *p) { int n; fpon(); fpwr(Fpscr, p->fpsave->control); m->fpscr = fprd(Fpscr) & ~Allcc; assert(m->fpnregs); for (n = 0; n < m->fpnregs; n++) fprestreg(n, *(uvlong *)p->fpsave->regs[n]); } /* * Called from sched() and sleep() via the machine-dependent * procsave() routine. * About to go in to the scheduler. * If the process wasn't using the FPU * there's nothing to do. */ void fpuprocsave(Proc *p) { if(p->fpstate == FPactive){ if(p->state == Moribund) fpoff(); else{ /* * Fpsave() stores without handling pending * unmasked exeptions. Postnote() can't be called * here as sleep() already has up->rlock, so * the handling of pending exceptions is delayed * until the process runs again and generates an * emulation fault to activate the FPU. */ fpsave(p->fpsave); } p->fpstate = FPinactive; } } /* * The process has been rescheduled and is about to run. * Nothing to do here right now. If the process tries to use * the FPU again it will cause a Device Not Available * exception and the state will then be restored. */ void fpuprocrestore(Proc *) { } /* * The current process has been forked, * save and copy neccesary state to child. */ void fpuprocfork(Proc *p) { int s; s = splhi(); switch(up->fpstate & ~FPillegal){ case FPactive: fpsave(up->fpsave); up->fpstate = FPinactive; /* no break */ case FPinactive: memmove(p->fpsave, up->fpsave, sizeof(FPsave)); p->fpstate = FPinactive; } splx(s); } /* * Disable the FPU. * Called from sysexec() via sysprocsetup() to * set the FPU for the new process. */ void fpusysprocsetup(Proc *p) { p->fpstate = FPinit; fpoff(); } static void mathnote(void) { ulong status; char *msg, note[ERRMAX]; status = up->fpsave->status; /* * Some attention should probably be paid here to the * exception masks and error summary. */ if (status & FPAINEX) msg = "inexact"; else if (status & FPAOVFL) msg = "overflow"; else if (status & FPAUNFL) msg = "underflow"; else if (status & FPAZDIV) msg = "divide by zero"; else if (status & FPAINVAL) msg = "bad operation"; else msg = "spurious"; snprint(note, sizeof note, "sys: fp: %s fppc=%#p status=%#lux", msg, up->fpsave->pc, status); postnote(up, 1, note, NDebug); } static void mathemu(Ureg *) { switch(up->fpstate){ case FPemu: error("illegal instruction: VFP opcode in emulated mode"); case FPinit: fpinit(); up->fpstate = FPactive; break; case FPinactive: /* * Before restoring the state, check for any pending * exceptions. There's no way to restore the state without * generating an unmasked exception. * More attention should probably be paid here to the * exception masks and error summary. */ if(up->fpsave->status & (FPAINEX|FPAUNFL|FPAOVFL|FPAZDIV|FPAINVAL)){ mathnote(); break; } fprestore(up); up->fpstate = FPactive; break; case FPactive: error("illegal instruction: bad vfp fpu opcode"); break; } fpclear(); } void fpstuck(uintptr pc) { if (m->fppc == pc && m->fppid == up->pid) { m->fpcnt++; if (m->fpcnt > 4) panic("fpuemu: cpu%d stuck at pid %ld %s pc %#p " "instr %#8.8lux", m->machno, up->pid, up->text, pc, *(ulong *)pc); } else { m->fppid = up->pid; m->fppc = pc; m->fpcnt = 0; } } enum { N = 1<<31, Z = 1<<30, C = 1<<29, V = 1<<28, REGPC = 15, }; static int condok(int cc, int c) { switch(c){ case 0: /* Z set */ return cc&Z; case 1: /* Z clear */ return (cc&Z) == 0; case 2: /* C set */ return cc&C; case 3: /* C clear */ return (cc&C) == 0; case 4: /* N set */ return cc&N; case 5: /* N clear */ return (cc&N) == 0; case 6: /* V set */ return cc&V; case 7: /* V clear */ return (cc&V) == 0; case 8: /* C set and Z clear */ return cc&C && (cc&Z) == 0; case 9: /* C clear or Z set */ return (cc&C) == 0 || cc&Z; case 10: /* N set and V set, or N clear and V clear */ return (~cc&(N|V))==0 || (cc&(N|V)) == 0; case 11: /* N set and V clear, or N clear and V set */ return (cc&(N|V))==N || (cc&(N|V))==V; case 12: /* Z clear, and either N set and V set or N clear and V clear */ return (cc&Z) == 0 && ((~cc&(N|V))==0 || (cc&(N|V))==0); case 13: /* Z set, or N set and V clear or N clear and V set */ return (cc&Z) || (cc&(N|V))==N || (cc&(N|V))==V; case 14: /* always */ return 1; case 15: /* never (reserved) */ return 0; } return 0; /* not reached */ } /* only called to deal with user-mode instruction faults */ int fpuemu(Ureg* ureg) { int s, nfp, cop, op; uintptr pc; static int already; if(waserror()){ postnote(up, 1, up->errstr, NDebug); return 1; } if(up->fpstate & FPillegal) error("floating point in note handler"); nfp = 0; pc = ureg->pc; validaddr(pc, 4, 0); op = (*(ulong *)pc >> 24) & MASK(4); cop = (*(ulong *)pc >> 8) & MASK(4); if(m->fpon) fpstuck(pc); /* debugging; could move down 1 line */ if (ISFPAOP(cop, op)) { /* old arm 7500 fpa opcode? */ s = spllo(); if(!already++) pprint("warning: emulated arm7500 fpa instr %#8.8lux at %#p\n", *(ulong *)pc, pc); if(waserror()){ splx(s); nexterror(); } nfp = fpiarm(ureg); /* advances pc past emulated instr(s) */ if (nfp > 1) /* could adjust this threshold */ m->fppc = m->fpcnt = 0; splx(s); poperror(); } else if (ISVFPOP(cop, op)) { /* if vfp, fpu off or unsupported instruction */ mathemu(ureg); /* enable fpu & retry */ nfp = 1; } poperror(); return nfp; }