ref: 502fe5af32a3d275aa89ffc834157bdbabc45c50
dir: /sys/src/9/teg2/coproc.c/
/* * arm co-processors * mainly to cope with arm hard-wiring register numbers into instructions. * * CP15 (system control) is the one that gets used the most in practice. * these routines must be callable from KZERO space or the 0 segment. */ #include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "arm.h" enum { /* alternates: 0xe12fff1e BX (R14); last e is R14 */ /* 0xe28ef000 B 0(R14); second e is R14 (ken) */ Retinst = 0xe1a0f00e, /* MOV R14, R15 */ Opmask = MASK(3), Regmask = MASK(4), }; typedef ulong (*Pufv)(void); typedef void (*Pvfu)(ulong); static void setupcpop(ulong instr[2], ulong opcode, int cp, int op1, int crn, int crm, int op2) { ulong instrsz[2]; op1 &= Opmask; op2 &= Opmask; crn &= Regmask; crm &= Regmask; cp &= Regmask; instr[0] = opcode | op1 << 21 | crn << 16 | cp << 8 | op2 << 5 | crm; instr[1] = Retinst; cachedwbse(instr, sizeof instrsz); cacheiinv(); } ulong cprd(int cp, int op1, int crn, int crm, int op2) { int s, r; volatile ulong instr[2]; Pufv fp; s = splhi(); /* * MRC. return value will be in R0, which is convenient. * Rt will be R0. */ setupcpop(instr, 0xee100010, cp, op1, crn, crm, op2); fp = (Pufv)instr; r = fp(); splx(s); return r; } void cpwr(int cp, int op1, int crn, int crm, int op2, ulong val) { int s; volatile ulong instr[2]; Pvfu fp; s = splhi(); setupcpop(instr, 0xee000010, cp, op1, crn, crm, op2); /* MCR, Rt is R0 */ fp = (Pvfu)instr; fp(val); coherence(); splx(s); } ulong cprdsc(int op1, int crn, int crm, int op2) { return cprd(CpSC, op1, crn, crm, op2); } void cpwrsc(int op1, int crn, int crm, int op2, ulong val) { cpwr(CpSC, op1, crn, crm, op2, val); } /* floating point */ /* fp coproc control */ static void setupfpctlop(ulong instr[2], int opcode, int fpctlreg) { ulong instrsz[2]; fpctlreg &= Nfpctlregs - 1; instr[0] = opcode | fpctlreg << 16 | 0 << 12 | CpFP << 8; instr[1] = Retinst; cachedwbse(instr, sizeof instrsz); cacheiinv(); } ulong fprd(int fpreg) { int s, r; volatile ulong instr[2]; Pufv fp; if (!m->fpon) { dumpstack(); panic("fprd: cpu%d fpu off", m->machno); } s = splhi(); /* * VMRS. return value will be in R0, which is convenient. * Rt will be R0. */ setupfpctlop(instr, 0xeef00010, fpreg); fp = (Pufv)instr; r = fp(); splx(s); return r; } void fpwr(int fpreg, ulong val) { int s; volatile ulong instr[2]; Pvfu fp; /* fpu might be off and this VMSR might enable it */ s = splhi(); setupfpctlop(instr, 0xeee00010, fpreg); /* VMSR, Rt is R0 */ fp = (Pvfu)instr; fp(val); coherence(); splx(s); } /* fp register access; don't bother with single precision */ static void setupfpop(ulong instr[2], int opcode, int fpreg) { ulong instrsz[2]; instr[0] = opcode | 0 << 16 | (fpreg & (16 - 1)) << 12; if (fpreg >= 16) instr[0] |= 1 << 22; /* high bit of dfp reg # */ instr[1] = Retinst; cachedwbse(instr, sizeof instrsz); cacheiinv(); } ulong fpsavereg(int fpreg, uvlong *fpp) { int s, r; volatile ulong instr[2]; ulong (*fp)(uvlong *); if (!m->fpon) panic("fpsavereg: cpu%d fpu off", m->machno); s = splhi(); /* * VSTR. pointer will be in R0, which is convenient. * Rt will be R0. */ setupfpop(instr, 0xed000000 | CpDFP << 8, fpreg); fp = (ulong (*)(uvlong *))instr; r = fp(fpp); splx(s); coherence(); return r; /* not too meaningful */ } void fprestreg(int fpreg, uvlong val) { int s; volatile ulong instr[2]; void (*fp)(uvlong *); if (!m->fpon) panic("fprestreg: cpu%d fpu off", m->machno); s = splhi(); setupfpop(instr, 0xed100000 | CpDFP << 8, fpreg); /* VLDR, Rt is R0 */ fp = (void (*)(uvlong *))instr; fp(&val); coherence(); splx(s); }