// SPDX-License-Identifier: GPL-2.0-only /* * * Copyright Novell Inc 2010 * * Authors: Alexander Graf <agraf@suse.de> */ #include <asm/kvm.h> #include <asm/kvm_ppc.h> #include <asm/disassemble.h> #include <asm/kvm_book3s.h> #include <asm/kvm_fpu.h> #include <asm/reg.h> #include <asm/cacheflush.h> #include <asm/switch_to.h> #include <linux/vmalloc.h> /* #define DEBUG */ #ifdef DEBUG #define dprintk printk #else #define dprintk(...) do { } while(0); #endif #define OP_LFS 48 #define OP_LFSU 49 #define OP_LFD 50 #define OP_LFDU 51 #define OP_STFS 52 #define OP_STFSU 53 #define OP_STFD 54 #define OP_STFDU 55 #define OP_PSQ_L 56 #define OP_PSQ_LU 57 #define OP_PSQ_ST 60 #define OP_PSQ_STU 61 #define OP_31_LFSX 535 #define OP_31_LFSUX 567 #define OP_31_LFDX 599 #define OP_31_LFDUX 631 #define OP_31_STFSX 663 #define OP_31_STFSUX 695 #define OP_31_STFX 727 #define OP_31_STFUX 759 #define OP_31_LWIZX 887 #define OP_31_STFIWX 983 #define OP_59_FADDS 21 #define OP_59_FSUBS 20 #define OP_59_FSQRTS 22 #define OP_59_FDIVS 18 #define OP_59_FRES 24 #define OP_59_FMULS 25 #define OP_59_FRSQRTES 26 #define OP_59_FMSUBS 28 #define OP_59_FMADDS 29 #define OP_59_FNMSUBS 30 #define OP_59_FNMADDS 31 #define OP_63_FCMPU 0 #define OP_63_FCPSGN 8 #define OP_63_FRSP 12 #define OP_63_FCTIW 14 #define OP_63_FCTIWZ 15 #define OP_63_FDIV 18 #define OP_63_FADD 21 #define OP_63_FSQRT 22 #define OP_63_FSEL 23 #define OP_63_FRE 24 #define OP_63_FMUL 25 #define OP_63_FRSQRTE 26 #define OP_63_FMSUB 28 #define OP_63_FMADD 29 #define OP_63_FNMSUB 30 #define OP_63_FNMADD 31 #define OP_63_FCMPO 32 #define OP_63_MTFSB1 38 // XXX #define OP_63_FSUB 20 #define OP_63_FNEG 40 #define OP_63_MCRFS 64 #define OP_63_MTFSB0 70 #define OP_63_FMR 72 #define OP_63_MTFSFI 134 #define OP_63_FABS 264 #define OP_63_MFFS 583 #define OP_63_MTFSF 711 #define OP_4X_PS_CMPU0 0 #define OP_4X_PSQ_LX 6 #define OP_4XW_PSQ_STX 7 #define OP_4A_PS_SUM0 10 #define OP_4A_PS_SUM1 11 #define OP_4A_PS_MULS0 12 #define OP_4A_PS_MULS1 13 #define OP_4A_PS_MADDS0 14 #define OP_4A_PS_MADDS1 15 #define OP_4A_PS_DIV 18 #define OP_4A_PS_SUB 20 #define OP_4A_PS_ADD 21 #define OP_4A_PS_SEL 23 #define OP_4A_PS_RES 24 #define OP_4A_PS_MUL 25 #define OP_4A_PS_RSQRTE 26 #define OP_4A_PS_MSUB 28 #define OP_4A_PS_MADD 29 #define OP_4A_PS_NMSUB 30 #define OP_4A_PS_NMADD 31 #define OP_4X_PS_CMPO0 32 #define OP_4X_PSQ_LUX 38 #define OP_4XW_PSQ_STUX 39 #define OP_4X_PS_NEG 40 #define OP_4X_PS_CMPU1 64 #define OP_4X_PS_MR 72 #define OP_4X_PS_CMPO1 96 #define OP_4X_PS_NABS 136 #define OP_4X_PS_ABS 264 #define OP_4X_PS_MERGE00 528 #define OP_4X_PS_MERGE01 560 #define OP_4X_PS_MERGE10 592 #define OP_4X_PS_MERGE11 624 #define SCALAR_NONE 0 #define SCALAR_HIGH (1 << 0) #define SCALAR_LOW (1 << 1) #define SCALAR_NO_PS0 (1 << 2) #define SCALAR_NO_PS1 (1 << 3) #define GQR_ST_TYPE_MASK 0x00000007 #define GQR_ST_TYPE_SHIFT 0 #define GQR_ST_SCALE_MASK 0x00003f00 #define GQR_ST_SCALE_SHIFT 8 #define GQR_LD_TYPE_MASK 0x00070000 #define GQR_LD_TYPE_SHIFT 16 #define GQR_LD_SCALE_MASK 0x3f000000 #define GQR_LD_SCALE_SHIFT 24 #define GQR_QUANTIZE_FLOAT 0 #define GQR_QUANTIZE_U8 4 #define GQR_QUANTIZE_U16 5 #define GQR_QUANTIZE_S8 6 #define GQR_QUANTIZE_S16 7 #define FPU_LS_SINGLE 0 #define FPU_LS_DOUBLE 1 #define FPU_LS_SINGLE_LOW 2 static inline void kvmppc_sync_qpr(struct kvm_vcpu *vcpu, int rt) { kvm_cvt_df(&VCPU_FPR(vcpu, rt), &vcpu->arch.qpr[rt]); } static void kvmppc_inject_pf(struct kvm_vcpu *vcpu, ulong eaddr, bool is_store) { u32 dsisr; u64 msr = kvmppc_get_msr(vcpu); msr = kvmppc_set_field(msr, 33, 36, 0); msr = kvmppc_set_field(msr, 42, 47, 0); kvmppc_set_msr(vcpu, msr); kvmppc_set_dar(vcpu, eaddr); /* Page Fault */ dsisr = kvmppc_set_field(0, 33, 33, 1); if (is_store) dsisr = kvmppc_set_field(dsisr, 38, 38, 1); kvmppc_set_dsisr(vcpu, dsisr); kvmppc_book3s_queue_irqprio(vcpu, BOOK3S_INTERRUPT_DATA_STORAGE); } static int kvmppc_emulate_fpr_load(struct kvm_vcpu *vcpu, int rs, ulong addr, int ls_type) { int emulated = EMULATE_FAIL; int r; char tmp[8]; int len = sizeof(u32); if (ls_type == FPU_LS_DOUBLE) len = sizeof(u64); /* read from memory */ r = kvmppc_ld(vcpu, &addr, len, tmp, true); vcpu->arch.paddr_accessed = addr; if (r < 0) { kvmppc_inject_pf(vcpu, addr, false); goto done_load; } else if (r == EMULATE_DO_MMIO) { emulated = kvmppc_handle_load(vcpu, KVM_MMIO_REG_FPR | rs, len, 1); goto done_load; } emulated = EMULATE_DONE; /* put in registers */ switch (ls_type) { case FPU_LS_SINGLE: kvm_cvt_fd((u32*)tmp, &VCPU_FPR(vcpu, rs)); vcpu->arch.qpr[rs] = *((u32*)tmp); break; case FPU_LS_DOUBLE: VCPU_FPR(vcpu, rs) = *((u64*)tmp); break; } dprintk(KERN_INFO "KVM: FPR_LD [0x%llx] at 0x%lx (%d)\n", *(u64*)tmp, addr, len); done_load: return emulated; } static int kvmppc_emulate_fpr_store(struct kvm_vcpu *vcpu, int rs, ulong addr, int ls_type) { int emulated = EMULATE_FAIL; int r; char tmp[8]; u64 val; int len; switch (ls_type) { case FPU_LS_SINGLE: kvm_cvt_df(&VCPU_FPR(vcpu, rs), (u32*)tmp); val = *((u32*)tmp); len = sizeof(u32); break; case FPU_LS_SINGLE_LOW: *((u32*)tmp) = VCPU_FPR(vcpu, rs); val = VCPU_FPR(vcpu, rs) & 0xffffffff; len = sizeof(u32); break; case FPU_LS_DOUBLE: *((u64*)tmp) = VCPU_FPR(vcpu, rs); val = VCPU_FPR(vcpu, rs); len = sizeof(u64); break; default: val = 0; len = 0; } r = kvmppc_st(vcpu, &addr, len, tmp, true); vcpu->arch.paddr_accessed = addr; if (r < 0) { kvmppc_inject_pf(vcpu, addr, true); } else if (r == EMULATE_DO_MMIO) { emulated = kvmppc_handle_store(vcpu, val, len, 1); } else { emulated = EMULATE_DONE; } dprintk(KERN_INFO "KVM: FPR_ST [0x%llx] at 0x%lx (%d)\n", val, addr, len); return emulated; } static int kvmppc_emulate_psq_load(struct kvm_vcpu *vcpu, int rs, ulong addr, bool w, int i) { int emulated = EMULATE_FAIL; int r; float one = 1.0; u32 tmp[2]; /* read from memory */ if (w) { r = kvmppc_ld(vcpu, &addr, sizeof(u32), tmp, true); memcpy(&tmp[1], &one, sizeof(u32)); } else { r = kvmppc_ld(vcpu, &addr, sizeof(u32) * 2, tmp, true); } vcpu->arch.paddr_accessed = addr; if (r < 0) { kvmppc_inject_pf(vcpu, addr, false); goto done_load; } else if ((r == EMULATE_DO_MMIO) && w) { emulated = kvmppc_handle_load(vcpu, KVM_MMIO_REG_FPR | rs, 4, 1); vcpu->arch.qpr[rs] = tmp[1]; goto done_load; } else if (r == EMULATE_DO_MMIO) { emulated = kvmppc_handle_load(vcpu, KVM_MMIO_REG_FQPR | rs, 8, 1); goto done_load; } emulated = EMULATE_DONE; /* put in registers */ kvm_cvt_fd(&tmp[0], &VCPU_FPR(vcpu, rs)); vcpu->arch.qpr[rs] = tmp[1]; dprintk(KERN_INFO "KVM: PSQ_LD [0x%x, 0x%x] at 0x%lx (%d)\n", tmp[0], tmp[1], addr, w ? 4 : 8); done_load: return emulated; } static int kvmppc_emulate_psq_store(struct kvm_vcpu *vcpu, int rs, ulong addr, bool w, int i) { int emulated = EMULATE_FAIL; int r; u32 tmp[2]; int len = w ? sizeof(u32) : sizeof(u64); kvm_cvt_df(&VCPU_FPR(vcpu, rs), &tmp[0]); tmp[1] = vcpu->arch.qpr[rs]; r = kvmppc_st(vcpu, &addr, len, tmp, true); vcpu->arch.paddr_accessed = addr; if (r < 0) { kvmppc_inject_pf(vcpu, addr, true); } else if ((r == EMULATE_DO_MMIO) && w) { emulated = kvmppc_handle_store(vcpu, tmp[0], 4, 1); } else if (r == EMULATE_DO_MMIO) { u64 val = ((u64)tmp[0] << 32) | tmp[1]; emulated = kvmppc_handle_store(vcpu, val, 8, 1); } else { emulated = EMULATE_DONE; } dprintk(KERN_INFO "KVM: PSQ_ST [0x%x, 0x%x] at 0x%lx (%d)\n", tmp[0], tmp[1], addr, len); return emulated; } /* * Cuts out inst bits with ordering according to spec. * That means the leftmost bit is zero. All given bits are included. */ static inline u32 inst_get_field(u32 inst, int msb, int lsb) { return kvmppc_get_field(inst, msb + 32, lsb + 32); } static bool kvmppc_inst_is_paired_single(struct kvm_vcpu *vcpu, u32 inst) { if (!(vcpu->arch.hflags & BOOK3S_HFLAG_PAIRED_SINGLE)) return false; switch (get_op(inst)) { case OP_PSQ_L: case OP_PSQ_LU: case OP_PSQ_ST: case OP_PSQ_STU: case OP_LFS: case OP_LFSU: case OP_LFD: case OP_LFDU: case OP_STFS: case OP_STFSU: case OP_STFD: case OP_STFDU: return true; case 4: /* X form */ switch (inst_get_field(inst, 21, 30)) { case OP_4X_PS_CMPU0: case OP_4X_PSQ_LX: case OP_4X_PS_CMPO0: case OP_4X_PSQ_LUX: case OP_4X_PS_NEG: case OP_4X_PS_CMPU1: case OP_4X_PS_MR: case OP_4X_PS_CMPO1: case OP_4X_PS_NABS: case OP_4X_PS_ABS: case OP_4X_PS_MERGE00: case OP_4X_PS_MERGE01: case OP_4X_PS_MERGE10: case OP_4X_PS_MERGE11: return true; } /* XW form */ switch (inst_get_field(inst, 25, 30)) { case OP_4XW_PSQ_STX: case OP_4XW_PSQ_STUX: return true; } /* A form */ switch (inst_get_field(inst, 26, 30)) { case OP_4A_PS_SUM1: case OP_4A_PS_SUM0: case OP_4A_PS_MULS0: case OP_4A_PS_MULS1: case OP_4A_PS_MADDS0: case OP_4A_PS_MADDS1: case OP_4A_PS_DIV: case OP_4A_PS_SUB: case OP_4A_PS_ADD: case OP_4A_PS_SEL: case OP_4A_PS_RES: case OP_4A_PS_MUL: case OP_4A_PS_RSQRTE: case OP_4A_PS_MSUB: case OP_4A_PS_MADD: case OP_4A_PS_NMSUB: case OP_4A_PS_NMADD: return true; } break; case 59: switch (inst_get_field(inst, 21, 30)) { case OP_59_FADDS: case OP_59_FSUBS: case OP_59_FDIVS: case OP_59_FRES: case OP_59_FRSQRTES: return true; } switch (inst_get_field(inst, 26, 30)) { case OP_59_FMULS: case OP_59_FMSUBS: case OP_59_FMADDS: case OP_59_FNMSUBS: case OP_59_FNMADDS: return true; } break; case 63: switch (inst_get_field(inst, 21, 30)) { case OP_63_MTFSB0: case OP_63_MTFSB1: case OP_63_MTFSF: case OP_63_MTFSFI: case OP_63_MCRFS: case OP_63_MFFS: case OP_63_FCMPU: case OP_63_FCMPO: case OP_63_FNEG: case OP_63_FMR: case OP_63_FABS: case OP_63_FRSP: case OP_63_FDIV: case OP_63_FADD: case OP_63_FSUB: case OP_63_FCTIW: case OP_63_FCTIWZ: case OP_63_FRSQRTE: case OP_63_FCPSGN: return true; } switch (inst_get_field(inst, 26, 30)) { case OP_63_FMUL: case OP_63_FSEL: case OP_63_FMSUB: case OP_63_FMADD: case OP_63_FNMSUB: case OP_63_FNMADD: return true; } break; case 31: switch (inst_get_field(inst, 21, 30)) { case OP_31_LFSX: case OP_31_LFSUX: case OP_31_LFDX: case OP_31_LFDUX: case OP_31_STFSX: case OP_31_STFSUX: case OP_31_STFX: case OP_31_STFUX: case OP_31_STFIWX: return true; } break; } return false; } static int get_d_signext(u32 inst) { int d = inst & 0x8ff; if (d & 0x800) return -(d & 0x7ff); return (d & 0x7ff); } static int kvmppc_ps_three_in(struct kvm_vcpu *vcpu, bool rc, int reg_out, int reg_in1, int reg_in2, int reg_in3, int scalar, void (*func)(u64 *fpscr, u32 *dst, u32 *src1, u32 *src2, u32 *src3)) { u32 *qpr = vcpu->arch.qpr; u32 ps0_out; u32 ps0_in1, ps0_in2, ps0_in3; u32 ps1_in1, ps1_in2, ps1_in3; /* RC */ WARN_ON(rc); /* PS0 */ kvm_cvt_df(&VCPU_FPR(vcpu, reg_in1), &ps0_in1); kvm_cvt_df(&VCPU_FPR(vcpu, reg_in2), &ps0_in2); kvm_cvt_df(&VCPU_FPR(vcpu, reg_in3), &ps0_in3); if (scalar & SCALAR_LOW) ps0_in2 = qpr[reg_in2]; func(&vcpu->arch.fp.fpscr, &ps0_out, &ps0_in1, &ps0_in2, &ps0_in3); dprintk(KERN_INFO "PS3 ps0 -> f(0x%x, 0x%x, 0x%x) = 0x%x\n", ps0_in1, ps0_in2, ps0_in3, ps0_out); if (!(scalar & SCALAR_NO_PS0)) kvm_cvt_fd(&ps0_out, &VCPU_FPR(vcpu, reg_out)); /* PS1 */ ps1_in1 = qpr[reg_in1]; ps1_in2 = qpr[reg_in2]; ps1_in3 = qpr[reg_in3]; if (scalar & SCALAR_HIGH) ps1_in2 = ps0_in2; if (!(scalar & SCALAR_NO_PS1)) func(&vcpu->arch.fp.fpscr, &qpr[reg_out], &ps1_in1, &ps1_in2, &ps1_in3); dprintk(KERN_INFO "PS3 ps1 -> f(0x%x, 0x%x, 0x%x) = 0x%x\n", ps1_in1, ps1_in2, ps1_in3, qpr[reg_out]); return EMULATE_DONE; } static int kvmppc_ps_two_in(struct kvm_vcpu *vcpu, bool rc, int reg_out, int reg_in1, int reg_in2, int scalar, void (*func)(u64 *fpscr, u32 *dst, u32 *src1, u32 *src2)) { u32 *qpr = vcpu->arch.qpr; u32 ps0_out; u32 ps0_in1, ps0_in2; u32 ps1_out; u32 ps1_in1, ps1_in2; /* RC */ WARN_ON(rc); /* PS0 */ kvm_cvt_df(&VCPU_FPR(vcpu, reg_in1), &ps0_in1); if (scalar & SCALAR_LOW) ps0_in2 = qpr[reg_in2]; else kvm_cvt_df(&VCPU_FPR(vcpu, reg_in2), &ps0_in2); func(&vcpu->arch.fp.fpscr, &ps0_out, &ps0_in1, &ps0_in2); if (!(scalar & SCALAR_NO_PS0)) { dprintk(KERN_INFO "PS2 ps0 -> f(0x%x, 0x%x) = 0x%x\n", ps0_in1, ps0_in2, ps0_out); kvm_cvt_fd(&ps0_out, &VCPU_FPR(vcpu, reg_out)); } /* PS1 */ ps1_in1 = qpr[reg_in1]; ps1_in2 = qpr[reg_in2]; if (scalar & SCALAR_HIGH) ps1_in2 = ps0_in2; func(&vcpu->arch.fp.fpscr, &ps1_out, &ps1_in1, &ps1_in2); if (!(scalar & SCALAR_NO_PS1)) { qpr[reg_out] = ps1_out; dprintk(KERN_INFO "PS2 ps1 -> f(0x%x, 0x%x) = 0x%x\n", ps1_in1, ps1_in2, qpr[reg_out]); } return EMULATE_DONE; } static int kvmppc_ps_one_in(struct kvm_vcpu *vcpu, bool rc, int reg_out, int reg_in, void (*func)(u64 *t, u32 *dst, u32 *src1)) { u32 *qpr = vcpu->arch.qpr; u32 ps0_out, ps0_in; u32 ps1_in; /* RC */ WARN_ON(rc); /* PS0 */ kvm_cvt_df(&VCPU_FPR(vcpu, reg_in), &ps0_in); func(&vcpu->arch.fp.fpscr, &ps0_out, &ps0_in); dprintk(KERN_INFO "PS1 ps0 -> f(0x%x) = 0x%x\n", ps0_in, ps0_out); kvm_cvt_fd(&ps0_out, &VCPU_FPR(vcpu, reg_out)); /* PS1 */ ps1_in = qpr[reg_in]; func(&vcpu->arch.fp.fpscr, &qpr[reg_out], &ps1_in); dprintk(KERN_INFO "PS1 ps1 -> f(0x%x) = 0x%x\n", ps1_in, qpr[reg_out]); return EMULATE_DONE; } int kvmppc_emulate_paired_single(struct kvm_vcpu *vcpu) { u32 inst; ppc_inst_t pinst; enum emulation_result emulated = EMULATE_DONE; int ax_rd, ax_ra, ax_rb, ax_rc; short full_d; u64 *fpr_d, *fpr_a, *fpr_b, *fpr_c; bool rcomp; u32 cr; #ifdef DEBUG int i; #endif emulated = kvmppc_get_last_inst(vcpu, INST_GENERIC, &pinst); inst = ppc_inst_val(pinst); if (emulated != EMULATE_DONE) return emulated; ax_rd = inst_get_field(inst, 6, 10); ax_ra = inst_get_field(inst, 11, 15); ax_rb = inst_get_field(inst, 16, 20); ax_rc = inst_get_field(inst, 21, 25); full_d = inst_get_field(inst, 16, 31); fpr_d = &VCPU_FPR(vcpu, ax_rd); fpr_a = &VCPU_FPR(vcpu, ax_ra); fpr_b = &VCPU_FPR(vcpu, ax_rb); fpr_c = &VCPU_FPR(vcpu, ax_rc); rcomp = (inst & 1) ? true : false; cr = kvmppc_get_cr(vcpu); if (!kvmppc_inst_is_paired_single(vcpu, inst)) return EMULATE_FAIL; if (!(kvmppc_get_msr(vcpu) & MSR_FP)) { kvmppc_book3s_queue_irqprio(vcpu, BOOK3S_INTERRUPT_FP_UNAVAIL); return EMULATE_AGAIN; } kvmppc_giveup_ext(vcpu, MSR_FP); preempt_disable(); enable_kernel_fp(); /* Do we need to clear FE0 / FE1 here? Don't think so. */ #ifdef DEBUG for (i = 0; i < ARRAY_SIZE(vcpu->arch.fp.fpr); i++) { u32 f; kvm_cvt_df(&VCPU_FPR(vcpu, i), &f); dprintk(KERN_INFO "FPR[%d] = 0x%x / 0x%llx QPR[%d] = 0x%x\n", i, f, VCPU_FPR(vcpu, i), i, vcpu->arch.qpr[i]); } #endif switch (get_op(inst)) { case OP_PSQ_L: { ulong addr = ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0; bool w = inst_get_field(inst, 16, 16) ? true : false; int i = inst_get_field(inst, 17, 19); addr += get_d_signext(inst); emulated = kvmppc_emulate_psq_load(vcpu, ax_rd, addr, w, i); break; } case OP_PSQ_LU: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra); bool w = inst_get_field(inst, 16, 16) ? true : false; int i = inst_get_field(inst, 17, 19); addr += get_d_signext(inst); emulated = kvmppc_emulate_psq_load(vcpu, ax_rd, addr, w, i); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case OP_PSQ_ST: { ulong addr = ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0; bool w = inst_get_field(inst, 16, 16) ? true : false; int i = inst_get_field(inst, 17, 19); addr += get_d_signext(inst); emulated = kvmppc_emulate_psq_store(vcpu, ax_rd, addr, w, i); break; } case OP_PSQ_STU: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra); bool w = inst_get_field(inst, 16, 16) ? true : false; int i = inst_get_field(inst, 17, 19); addr += get_d_signext(inst); emulated = kvmppc_emulate_psq_store(vcpu, ax_rd, addr, w, i); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case 4: /* X form */ switch (inst_get_field(inst, 21, 30)) { case OP_4X_PS_CMPU0: /* XXX */ emulated = EMULATE_FAIL; break; case OP_4X_PSQ_LX: { ulong addr = ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0; bool w = inst_get_field(inst, 21, 21) ? true : false; int i = inst_get_field(inst, 22, 24); addr += kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_psq_load(vcpu, ax_rd, addr, w, i); break; } case OP_4X_PS_CMPO0: /* XXX */ emulated = EMULATE_FAIL; break; case OP_4X_PSQ_LUX: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra); bool w = inst_get_field(inst, 21, 21) ? true : false; int i = inst_get_field(inst, 22, 24); addr += kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_psq_load(vcpu, ax_rd, addr, w, i); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case OP_4X_PS_NEG: VCPU_FPR(vcpu, ax_rd) = VCPU_FPR(vcpu, ax_rb); VCPU_FPR(vcpu, ax_rd) ^= 0x8000000000000000ULL; vcpu->arch.qpr[ax_rd] = vcpu->arch.qpr[ax_rb]; vcpu->arch.qpr[ax_rd] ^= 0x80000000; break; case OP_4X_PS_CMPU1: /* XXX */ emulated = EMULATE_FAIL; break; case OP_4X_PS_MR: WARN_ON(rcomp); VCPU_FPR(vcpu, ax_rd) = VCPU_FPR(vcpu, ax_rb); vcpu->arch.qpr[ax_rd] = vcpu->arch.qpr[ax_rb]; break; case OP_4X_PS_CMPO1: /* XXX */ emulated = EMULATE_FAIL; break; case OP_4X_PS_NABS: WARN_ON(rcomp); VCPU_FPR(vcpu, ax_rd) = VCPU_FPR(vcpu, ax_rb); VCPU_FPR(vcpu, ax_rd) |= 0x8000000000000000ULL; vcpu->arch.qpr[ax_rd] = vcpu->arch.qpr[ax_rb]; vcpu->arch.qpr[ax_rd] |= 0x80000000; break; case OP_4X_PS_ABS: WARN_ON(rcomp); VCPU_FPR(vcpu, ax_rd) = VCPU_FPR(vcpu, ax_rb); VCPU_FPR(vcpu, ax_rd) &= ~0x8000000000000000ULL; vcpu->arch.qpr[ax_rd] = vcpu->arch.qpr[ax_rb]; vcpu->arch.qpr[ax_rd] &= ~0x80000000; break; case OP_4X_PS_MERGE00: WARN_ON(rcomp); VCPU_FPR(vcpu, ax_rd) = VCPU_FPR(vcpu, ax_ra); /* vcpu->arch.qpr[ax_rd] = VCPU_FPR(vcpu, ax_rb); */ kvm_cvt_df(&VCPU_FPR(vcpu, ax_rb), &vcpu->arch.qpr[ax_rd]); break; case OP_4X_PS_MERGE01: WARN_ON(rcomp); VCPU_FPR(vcpu, ax_rd) = VCPU_FPR(vcpu, ax_ra); vcpu->arch.qpr[ax_rd] = vcpu->arch.qpr[ax_rb]; break; case OP_4X_PS_MERGE10: WARN_ON(rcomp); /* VCPU_FPR(vcpu, ax_rd) = vcpu->arch.qpr[ax_ra]; */ kvm_cvt_fd(&vcpu->arch.qpr[ax_ra], &VCPU_FPR(vcpu, ax_rd)); /* vcpu->arch.qpr[ax_rd] = VCPU_FPR(vcpu, ax_rb); */ kvm_cvt_df(&VCPU_FPR(vcpu, ax_rb), &vcpu->arch.qpr[ax_rd]); break; case OP_4X_PS_MERGE11: WARN_ON(rcomp); /* VCPU_FPR(vcpu, ax_rd) = vcpu->arch.qpr[ax_ra]; */ kvm_cvt_fd(&vcpu->arch.qpr[ax_ra], &VCPU_FPR(vcpu, ax_rd)); vcpu->arch.qpr[ax_rd] = vcpu->arch.qpr[ax_rb]; break; } /* XW form */ switch (inst_get_field(inst, 25, 30)) { case OP_4XW_PSQ_STX: { ulong addr = ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0; bool w = inst_get_field(inst, 21, 21) ? true : false; int i = inst_get_field(inst, 22, 24); addr += kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_psq_store(vcpu, ax_rd, addr, w, i); break; } case OP_4XW_PSQ_STUX: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra); bool w = inst_get_field(inst, 21, 21) ? true : false; int i = inst_get_field(inst, 22, 24); addr += kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_psq_store(vcpu, ax_rd, addr, w, i); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } } /* A form */ switch (inst_get_field(inst, 26, 30)) { case OP_4A_PS_SUM1: emulated = kvmppc_ps_two_in(vcpu, rcomp, ax_rd, ax_rb, ax_ra, SCALAR_NO_PS0 | SCALAR_HIGH, fps_fadds); VCPU_FPR(vcpu, ax_rd) = VCPU_FPR(vcpu, ax_rc); break; case OP_4A_PS_SUM0: emulated = kvmppc_ps_two_in(vcpu, rcomp, ax_rd, ax_ra, ax_rb, SCALAR_NO_PS1 | SCALAR_LOW, fps_fadds); vcpu->arch.qpr[ax_rd] = vcpu->arch.qpr[ax_rc]; break; case OP_4A_PS_MULS0: emulated = kvmppc_ps_two_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, SCALAR_HIGH, fps_fmuls); break; case OP_4A_PS_MULS1: emulated = kvmppc_ps_two_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, SCALAR_LOW, fps_fmuls); break; case OP_4A_PS_MADDS0: emulated = kvmppc_ps_three_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, ax_rb, SCALAR_HIGH, fps_fmadds); break; case OP_4A_PS_MADDS1: emulated = kvmppc_ps_three_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, ax_rb, SCALAR_LOW, fps_fmadds); break; case OP_4A_PS_DIV: emulated = kvmppc_ps_two_in(vcpu, rcomp, ax_rd, ax_ra, ax_rb, SCALAR_NONE, fps_fdivs); break; case OP_4A_PS_SUB: emulated = kvmppc_ps_two_in(vcpu, rcomp, ax_rd, ax_ra, ax_rb, SCALAR_NONE, fps_fsubs); break; case OP_4A_PS_ADD: emulated = kvmppc_ps_two_in(vcpu, rcomp, ax_rd, ax_ra, ax_rb, SCALAR_NONE, fps_fadds); break; case OP_4A_PS_SEL: emulated = kvmppc_ps_three_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, ax_rb, SCALAR_NONE, fps_fsel); break; case OP_4A_PS_RES: emulated = kvmppc_ps_one_in(vcpu, rcomp, ax_rd, ax_rb, fps_fres); break; case OP_4A_PS_MUL: emulated = kvmppc_ps_two_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, SCALAR_NONE, fps_fmuls); break; case OP_4A_PS_RSQRTE: emulated = kvmppc_ps_one_in(vcpu, rcomp, ax_rd, ax_rb, fps_frsqrte); break; case OP_4A_PS_MSUB: emulated = kvmppc_ps_three_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, ax_rb, SCALAR_NONE, fps_fmsubs); break; case OP_4A_PS_MADD: emulated = kvmppc_ps_three_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, ax_rb, SCALAR_NONE, fps_fmadds); break; case OP_4A_PS_NMSUB: emulated = kvmppc_ps_three_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, ax_rb, SCALAR_NONE, fps_fnmsubs); break; case OP_4A_PS_NMADD: emulated = kvmppc_ps_three_in(vcpu, rcomp, ax_rd, ax_ra, ax_rc, ax_rb, SCALAR_NONE, fps_fnmadds); break; } break; /* Real FPU operations */ case OP_LFS: { ulong addr = (ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0) + full_d; emulated = kvmppc_emulate_fpr_load(vcpu, ax_rd, addr, FPU_LS_SINGLE); break; } case OP_LFSU: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra) + full_d; emulated = kvmppc_emulate_fpr_load(vcpu, ax_rd, addr, FPU_LS_SINGLE); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case OP_LFD: { ulong addr = (ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0) + full_d; emulated = kvmppc_emulate_fpr_load(vcpu, ax_rd, addr, FPU_LS_DOUBLE); break; } case OP_LFDU: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra) + full_d; emulated = kvmppc_emulate_fpr_load(vcpu, ax_rd, addr, FPU_LS_DOUBLE); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case OP_STFS: { ulong addr = (ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0) + full_d; emulated = kvmppc_emulate_fpr_store(vcpu, ax_rd, addr, FPU_LS_SINGLE); break; } case OP_STFSU: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra) + full_d; emulated = kvmppc_emulate_fpr_store(vcpu, ax_rd, addr, FPU_LS_SINGLE); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case OP_STFD: { ulong addr = (ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0) + full_d; emulated = kvmppc_emulate_fpr_store(vcpu, ax_rd, addr, FPU_LS_DOUBLE); break; } case OP_STFDU: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra) + full_d; emulated = kvmppc_emulate_fpr_store(vcpu, ax_rd, addr, FPU_LS_DOUBLE); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case 31: switch (inst_get_field(inst, 21, 30)) { case OP_31_LFSX: { ulong addr = ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0; addr += kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_fpr_load(vcpu, ax_rd, addr, FPU_LS_SINGLE); break; } case OP_31_LFSUX: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra) + kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_fpr_load(vcpu, ax_rd, addr, FPU_LS_SINGLE); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case OP_31_LFDX: { ulong addr = (ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0) + kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_fpr_load(vcpu, ax_rd, addr, FPU_LS_DOUBLE); break; } case OP_31_LFDUX: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra) + kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_fpr_load(vcpu, ax_rd, addr, FPU_LS_DOUBLE); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case OP_31_STFSX: { ulong addr = (ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0) + kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_fpr_store(vcpu, ax_rd, addr, FPU_LS_SINGLE); break; } case OP_31_STFSUX: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra) + kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_fpr_store(vcpu, ax_rd, addr, FPU_LS_SINGLE); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case OP_31_STFX: { ulong addr = (ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0) + kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_fpr_store(vcpu, ax_rd, addr, FPU_LS_DOUBLE); break; } case OP_31_STFUX: { ulong addr = kvmppc_get_gpr(vcpu, ax_ra) + kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_fpr_store(vcpu, ax_rd, addr, FPU_LS_DOUBLE); if (emulated == EMULATE_DONE) kvmppc_set_gpr(vcpu, ax_ra, addr); break; } case OP_31_STFIWX: { ulong addr = (ax_ra ? kvmppc_get_gpr(vcpu, ax_ra) : 0) + kvmppc_get_gpr(vcpu, ax_rb); emulated = kvmppc_emulate_fpr_store(vcpu, ax_rd, addr, FPU_LS_SINGLE_LOW); break; } break; } break; case 59: switch (inst_get_field(inst, 21, 30)) { case OP_59_FADDS: fpd_fadds(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; case OP_59_FSUBS: fpd_fsubs(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; case OP_59_FDIVS: fpd_fdivs(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; case OP_59_FRES: fpd_fres(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; case OP_59_FRSQRTES: fpd_frsqrtes(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; } switch (inst_get_field(inst, 26, 30)) { case OP_59_FMULS: fpd_fmuls(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c); kvmppc_sync_qpr(vcpu, ax_rd); break; case OP_59_FMSUBS: fpd_fmsubs(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; case OP_59_FMADDS: fpd_fmadds(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; case OP_59_FNMSUBS: fpd_fnmsubs(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; case OP_59_FNMADDS: fpd_fnmadds(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; } break; case 63: switch (inst_get_field(inst, 21, 30)) { case OP_63_MTFSB0: case OP_63_MTFSB1: case OP_63_MCRFS: case OP_63_MTFSFI: /* XXX need to implement */ break; case OP_63_MFFS: /* XXX missing CR */ *fpr_d = vcpu->arch.fp.fpscr; break; case OP_63_MTFSF: /* XXX missing fm bits */ /* XXX missing CR */ vcpu->arch.fp.fpscr = *fpr_b; break; case OP_63_FCMPU: { u32 tmp_cr; u32 cr0_mask = 0xf0000000; u32 cr_shift = inst_get_field(inst, 6, 8) * 4; fpd_fcmpu(&vcpu->arch.fp.fpscr, &tmp_cr, fpr_a, fpr_b); cr &= ~(cr0_mask >> cr_shift); cr |= (cr & cr0_mask) >> cr_shift; break; } case OP_63_FCMPO: { u32 tmp_cr; u32 cr0_mask = 0xf0000000; u32 cr_shift = inst_get_field(inst, 6, 8) * 4; fpd_fcmpo(&vcpu->arch.fp.fpscr, &tmp_cr, fpr_a, fpr_b); cr &= ~(cr0_mask >> cr_shift); cr |= (cr & cr0_mask) >> cr_shift; break; } case OP_63_FNEG: fpd_fneg(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_b); break; case OP_63_FMR: *fpr_d = *fpr_b; break; case OP_63_FABS: fpd_fabs(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_b); break; case OP_63_FCPSGN: fpd_fcpsgn(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_b); break; case OP_63_FDIV: fpd_fdiv(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_b); break; case OP_63_FADD: fpd_fadd(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_b); break; case OP_63_FSUB: fpd_fsub(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_b); break; case OP_63_FCTIW: fpd_fctiw(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_b); break; case OP_63_FCTIWZ: fpd_fctiwz(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_b); break; case OP_63_FRSP: fpd_frsp(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_b); kvmppc_sync_qpr(vcpu, ax_rd); break; case OP_63_FRSQRTE: { double one = 1.0f; /* fD = sqrt(fB) */ fpd_fsqrt(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_b); /* fD = 1.0f / fD */ fpd_fdiv(&vcpu->arch.fp.fpscr, &cr, fpr_d, (u64*)&one, fpr_d); break; } } switch (inst_get_field(inst, 26, 30)) { case OP_63_FMUL: fpd_fmul(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c); break; case OP_63_FSEL: fpd_fsel(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c, fpr_b); break; case OP_63_FMSUB: fpd_fmsub(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c, fpr_b); break; case OP_63_FMADD: fpd_fmadd(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c, fpr_b); break; case OP_63_FNMSUB: fpd_fnmsub(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c, fpr_b); break; case OP_63_FNMADD: fpd_fnmadd(&vcpu->arch.fp.fpscr, &cr, fpr_d, fpr_a, fpr_c, fpr_b); break; } break; } #ifdef DEBUG for (i = 0; i < ARRAY_SIZE(vcpu->arch.fp.fpr); i++) { u32 f; kvm_cvt_df(&VCPU_FPR(vcpu, i), &f); dprintk(KERN_INFO "FPR[%d] = 0x%x\n", i, f); } #endif if (rcomp) kvmppc_set_cr(vcpu, cr); disable_kernel_fp(); preempt_enable(); return emulated; }