/* * ARM micro operations * * Copyright (c) 2003 Fabrice Bellard * Copyright (c) 2005 CodeSourcery, LLC * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "exec.h" #define REGNAME r0 #define REG (env->regs[0]) #include "op_template.h" #define REGNAME r1 #define REG (env->regs[1]) #include "op_template.h" #define REGNAME r2 #define REG (env->regs[2]) #include "op_template.h" #define REGNAME r3 #define REG (env->regs[3]) #include "op_template.h" #define REGNAME r4 #define REG (env->regs[4]) #include "op_template.h" #define REGNAME r5 #define REG (env->regs[5]) #include "op_template.h" #define REGNAME r6 #define REG (env->regs[6]) #include "op_template.h" #define REGNAME r7 #define REG (env->regs[7]) #include "op_template.h" #define REGNAME r8 #define REG (env->regs[8]) #include "op_template.h" #define REGNAME r9 #define REG (env->regs[9]) #include "op_template.h" #define REGNAME r10 #define REG (env->regs[10]) #include "op_template.h" #define REGNAME r11 #define REG (env->regs[11]) #include "op_template.h" #define REGNAME r12 #define REG (env->regs[12]) #include "op_template.h" #define REGNAME r13 #define REG (env->regs[13]) #include "op_template.h" #define REGNAME r14 #define REG (env->regs[14]) #include "op_template.h" #define REGNAME r15 #define REG (env->regs[15]) #define SET_REG(x) REG = x & ~(uint32_t)1 #include "op_template.h" void OPPROTO op_bx_T0(void) { env->regs[15] = T0 & ~(uint32_t)1; env->thumb = (T0 & 1) != 0; } void OPPROTO op_movl_T0_0(void) { T0 = 0; } void OPPROTO op_movl_T0_im(void) { T0 = PARAM1; } void OPPROTO op_movl_T0_T1(void) { T0 = T1; } void OPPROTO op_movl_T1_im(void) { T1 = PARAM1; } void OPPROTO op_mov_CF_T1(void) { env->CF = ((uint32_t)T1) >> 31; } void OPPROTO op_movl_T2_im(void) { T2 = PARAM1; } void OPPROTO op_addl_T1_im(void) { T1 += PARAM1; } void OPPROTO op_addl_T1_T2(void) { T1 += T2; } void OPPROTO op_subl_T1_T2(void) { T1 -= T2; } void OPPROTO op_addl_T0_T1(void) { T0 += T1; } void OPPROTO op_addl_T0_T1_cc(void) { unsigned int src1; src1 = T0; T0 += T1; env->NZF = T0; env->CF = T0 < src1; env->VF = (src1 ^ T1 ^ -1) & (src1 ^ T0); } void OPPROTO op_adcl_T0_T1(void) { T0 += T1 + env->CF; } void OPPROTO op_adcl_T0_T1_cc(void) { unsigned int src1; src1 = T0; if (!env->CF) { T0 += T1; env->CF = T0 < src1; } else { T0 += T1 + 1; env->CF = T0 <= src1; } env->VF = (src1 ^ T1 ^ -1) & (src1 ^ T0); env->NZF = T0; FORCE_RET(); } #define OPSUB(sub, sbc, res, T0, T1) \ \ void OPPROTO op_ ## sub ## l_T0_T1(void) \ { \ res = T0 - T1; \ } \ \ void OPPROTO op_ ## sub ## l_T0_T1_cc(void) \ { \ unsigned int src1; \ src1 = T0; \ T0 -= T1; \ env->NZF = T0; \ env->CF = src1 >= T1; \ env->VF = (src1 ^ T1) & (src1 ^ T0); \ res = T0; \ } \ \ void OPPROTO op_ ## sbc ## l_T0_T1(void) \ { \ res = T0 - T1 + env->CF - 1; \ } \ \ void OPPROTO op_ ## sbc ## l_T0_T1_cc(void) \ { \ unsigned int src1; \ src1 = T0; \ if (!env->CF) { \ T0 = T0 - T1 - 1; \ env->CF = src1 > T1; \ } else { \ T0 = T0 - T1; \ env->CF = src1 >= T1; \ } \ env->VF = (src1 ^ T1) & (src1 ^ T0); \ env->NZF = T0; \ res = T0; \ FORCE_RET(); \ } OPSUB(sub, sbc, T0, T0, T1) OPSUB(rsb, rsc, T0, T1, T0) void OPPROTO op_andl_T0_T1(void) { T0 &= T1; } void OPPROTO op_xorl_T0_T1(void) { T0 ^= T1; } void OPPROTO op_orl_T0_T1(void) { T0 |= T1; } void OPPROTO op_bicl_T0_T1(void) { T0 &= ~T1; } void OPPROTO op_notl_T1(void) { T1 = ~T1; } void OPPROTO op_logic_T0_cc(void) { env->NZF = T0; } void OPPROTO op_logic_T1_cc(void) { env->NZF = T1; } #define EIP (env->regs[15]) void OPPROTO op_test_eq(void) { if (env->NZF == 0) GOTO_LABEL_PARAM(1);; FORCE_RET(); } void OPPROTO op_test_ne(void) { if (env->NZF != 0) GOTO_LABEL_PARAM(1);; FORCE_RET(); } void OPPROTO op_test_cs(void) { if (env->CF != 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_cc(void) { if (env->CF == 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_mi(void) { if ((env->NZF & 0x80000000) != 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_pl(void) { if ((env->NZF & 0x80000000) == 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_vs(void) { if ((env->VF & 0x80000000) != 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_vc(void) { if ((env->VF & 0x80000000) == 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_hi(void) { if (env->CF != 0 && env->NZF != 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_ls(void) { if (env->CF == 0 || env->NZF == 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_ge(void) { if (((env->VF ^ env->NZF) & 0x80000000) == 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_lt(void) { if (((env->VF ^ env->NZF) & 0x80000000) != 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_gt(void) { if (env->NZF != 0 && ((env->VF ^ env->NZF) & 0x80000000) == 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_test_le(void) { if (env->NZF == 0 || ((env->VF ^ env->NZF) & 0x80000000) != 0) GOTO_LABEL_PARAM(1); FORCE_RET(); } void OPPROTO op_goto_tb0(void) { GOTO_TB(op_goto_tb0, PARAM1, 0); } void OPPROTO op_goto_tb1(void) { GOTO_TB(op_goto_tb1, PARAM1, 1); } void OPPROTO op_exit_tb(void) { EXIT_TB(); } void OPPROTO op_movl_T0_cpsr(void) { T0 = cpsr_read(env); FORCE_RET(); } void OPPROTO op_movl_T0_spsr(void) { T0 = env->spsr; } void OPPROTO op_movl_spsr_T0(void) { uint32_t mask = PARAM1; env->spsr = (env->spsr & ~mask) | (T0 & mask); } void OPPROTO op_movl_cpsr_T0(void) { cpsr_write(env, T0, PARAM1); FORCE_RET(); } void OPPROTO op_mul_T0_T1(void) { T0 = T0 * T1; } /* 64 bit unsigned mul */ void OPPROTO op_mull_T0_T1(void) { uint64_t res; res = (uint64_t)T0 * (uint64_t)T1; T1 = res >> 32; T0 = res; } /* 64 bit signed mul */ void OPPROTO op_imull_T0_T1(void) { uint64_t res; res = (int64_t)((int32_t)T0) * (int64_t)((int32_t)T1); T1 = res >> 32; T0 = res; } /* 48 bit signed mul, top 32 bits */ void OPPROTO op_imulw_T0_T1(void) { uint64_t res; res = (int64_t)((int32_t)T0) * (int64_t)((int32_t)T1); T0 = res >> 16; } void OPPROTO op_addq_T0_T1(void) { uint64_t res; res = ((uint64_t)T1 << 32) | T0; res += ((uint64_t)(env->regs[PARAM2]) << 32) | (env->regs[PARAM1]); T1 = res >> 32; T0 = res; } void OPPROTO op_addq_lo_T0_T1(void) { uint64_t res; res = ((uint64_t)T1 << 32) | T0; res += (uint64_t)(env->regs[PARAM1]); T1 = res >> 32; T0 = res; } void OPPROTO op_logicq_cc(void) { env->NZF = (T1 & 0x80000000) | ((T0 | T1) != 0); } /* memory access */ #define MEMSUFFIX _raw #include "op_mem.h" #if !defined(CONFIG_USER_ONLY) #define MEMSUFFIX _user #include "op_mem.h" #define MEMSUFFIX _kernel #include "op_mem.h" #endif /* shifts */ /* T1 based */ void OPPROTO op_shll_T1_im(void) { T1 = T1 << PARAM1; } void OPPROTO op_shrl_T1_im(void) { T1 = (uint32_t)T1 >> PARAM1; } void OPPROTO op_shrl_T1_0(void) { T1 = 0; } void OPPROTO op_sarl_T1_im(void) { T1 = (int32_t)T1 >> PARAM1; } void OPPROTO op_sarl_T1_0(void) { T1 = (int32_t)T1 >> 31; } void OPPROTO op_rorl_T1_im(void) { int shift; shift = PARAM1; T1 = ((uint32_t)T1 >> shift) | (T1 << (32 - shift)); } void OPPROTO op_rrxl_T1(void) { T1 = ((uint32_t)T1 >> 1) | ((uint32_t)env->CF << 31); } /* T1 based, set C flag */ void OPPROTO op_shll_T1_im_cc(void) { env->CF = (T1 >> (32 - PARAM1)) & 1; T1 = T1 << PARAM1; } void OPPROTO op_shrl_T1_im_cc(void) { env->CF = (T1 >> (PARAM1 - 1)) & 1; T1 = (uint32_t)T1 >> PARAM1; } void OPPROTO op_shrl_T1_0_cc(void) { env->CF = (T1 >> 31) & 1; T1 = 0; } void OPPROTO op_sarl_T1_im_cc(void) { env->CF = (T1 >> (PARAM1 - 1)) & 1; T1 = (int32_t)T1 >> PARAM1; } void OPPROTO op_sarl_T1_0_cc(void) { env->CF = (T1 >> 31) & 1; T1 = (int32_t)T1 >> 31; } void OPPROTO op_rorl_T1_im_cc(void) { int shift; shift = PARAM1; env->CF = (T1 >> (shift - 1)) & 1; T1 = ((uint32_t)T1 >> shift) | (T1 << (32 - shift)); } void OPPROTO op_rrxl_T1_cc(void) { uint32_t c; c = T1 & 1; T1 = ((uint32_t)T1 >> 1) | ((uint32_t)env->CF << 31); env->CF = c; } /* T2 based */ void OPPROTO op_shll_T2_im(void) { T2 = T2 << PARAM1; } void OPPROTO op_shrl_T2_im(void) { T2 = (uint32_t)T2 >> PARAM1; } void OPPROTO op_shrl_T2_0(void) { T2 = 0; } void OPPROTO op_sarl_T2_im(void) { T2 = (int32_t)T2 >> PARAM1; } void OPPROTO op_sarl_T2_0(void) { T2 = (int32_t)T2 >> 31; } void OPPROTO op_rorl_T2_im(void) { int shift; shift = PARAM1; T2 = ((uint32_t)T2 >> shift) | (T2 << (32 - shift)); } void OPPROTO op_rrxl_T2(void) { T2 = ((uint32_t)T2 >> 1) | ((uint32_t)env->CF << 31); } /* T1 based, use T0 as shift count */ void OPPROTO op_shll_T1_T0(void) { int shift; shift = T0 & 0xff; if (shift >= 32) T1 = 0; else T1 = T1 << shift; FORCE_RET(); } void OPPROTO op_shrl_T1_T0(void) { int shift; shift = T0 & 0xff; if (shift >= 32) T1 = 0; else T1 = (uint32_t)T1 >> shift; FORCE_RET(); } void OPPROTO op_sarl_T1_T0(void) { int shift; shift = T0 & 0xff; if (shift >= 32) shift = 31; T1 = (int32_t)T1 >> shift; } void OPPROTO op_rorl_T1_T0(void) { int shift; shift = T0 & 0x1f; if (shift) { T1 = ((uint32_t)T1 >> shift) | (T1 << (32 - shift)); } FORCE_RET(); } /* T1 based, use T0 as shift count and compute CF */ void OPPROTO op_shll_T1_T0_cc(void) { int shift; shift = T0 & 0xff; if (shift >= 32) { if (shift == 32) env->CF = T1 & 1; else env->CF = 0; T1 = 0; } else if (shift != 0) { env->CF = (T1 >> (32 - shift)) & 1; T1 = T1 << shift; } FORCE_RET(); } void OPPROTO op_shrl_T1_T0_cc(void) { int shift; shift = T0 & 0xff; if (shift >= 32) { if (shift == 32) env->CF = (T1 >> 31) & 1; else env->CF = 0; T1 = 0; } else if (shift != 0) { env->CF = (T1 >> (shift - 1)) & 1; T1 = (uint32_t)T1 >> shift; } FORCE_RET(); } void OPPROTO op_sarl_T1_T0_cc(void) { int shift; shift = T0 & 0xff; if (shift >= 32) { env->CF = (T1 >> 31) & 1; T1 = (int32_t)T1 >> 31; } else { env->CF = (T1 >> (shift - 1)) & 1; T1 = (int32_t)T1 >> shift; } FORCE_RET(); } void OPPROTO op_rorl_T1_T0_cc(void) { int shift1, shift; shift1 = T0 & 0xff; shift = shift1 & 0x1f; if (shift == 0) { if (shift1 != 0) env->CF = (T1 >> 31) & 1; } else { env->CF = (T1 >> (shift - 1)) & 1; T1 = ((uint32_t)T1 >> shift) | (T1 << (32 - shift)); } FORCE_RET(); } /* misc */ void OPPROTO op_clz_T0(void) { int count; for (count = 32; T0 > 0; count--) T0 = T0 >> 1; T0 = count; FORCE_RET(); } void OPPROTO op_sarl_T0_im(void) { T0 = (int32_t)T0 >> PARAM1; } /* Sign/zero extend */ void OPPROTO op_sxth_T0(void) { T0 = (int16_t)T0; } void OPPROTO op_sxth_T1(void) { T1 = (int16_t)T1; } void OPPROTO op_sxtb_T1(void) { T1 = (int8_t)T1; } void OPPROTO op_uxtb_T1(void) { T1 = (uint8_t)T1; } void OPPROTO op_uxth_T1(void) { T1 = (uint16_t)T1; } void OPPROTO op_sxtb16_T1(void) { uint32_t res; res = (uint16_t)(int8_t)T1; res |= (uint32_t)(int8_t)(T1 >> 16) << 16; T1 = res; } void OPPROTO op_uxtb16_T1(void) { uint32_t res; res = (uint16_t)(uint8_t)T1; res |= (uint32_t)(uint8_t)(T1 >> 16) << 16; T1 = res; } #define SIGNBIT (uint32_t)0x80000000 /* saturating arithmetic */ void OPPROTO op_addl_T0_T1_setq(void) { uint32_t res; res = T0 + T1; if (((res ^ T0) & SIGNBIT) && !((T0 ^ T1) & SIGNBIT)) env->QF = 1; T0 = res; FORCE_RET(); } void OPPROTO op_addl_T0_T1_saturate(void) { uint32_t res; res = T0 + T1; if (((res ^ T0) & SIGNBIT) && !((T0 ^ T1) & SIGNBIT)) { env->QF = 1; if (T0 & SIGNBIT) T0 = 0x80000000; else T0 = 0x7fffffff; } else T0 = res; FORCE_RET(); } void OPPROTO op_subl_T0_T1_saturate(void) { uint32_t res; res = T0 - T1; if (((res ^ T0) & SIGNBIT) && ((T0 ^ T1) & SIGNBIT)) { env->QF = 1; if (T0 & SIGNBIT) T0 = 0x8000000; else T0 = 0x7fffffff; } else T0 = res; FORCE_RET(); } void OPPROTO op_double_T1_saturate(void) { int32_t val; val = T1; if (val >= 0x40000000) { T1 = 0x7fffffff; env->QF = 1; } else if (val <= (int32_t)0xc0000000) { T1 = 0x80000000; env->QF = 1; } else { T1 = val << 1; } FORCE_RET(); } /* thumb shift by immediate */ void OPPROTO op_shll_T0_im_thumb(void) { int shift; shift = PARAM1; if (shift != 0) { env->CF = (T1 >> (32 - shift)) & 1; T0 = T0 << shift; } env->NZF = T0; FORCE_RET(); } void OPPROTO op_shrl_T0_im_thumb(void) { int shift; shift = PARAM1; if (shift == 0) { env->CF = ((uint32_t)shift) >> 31; T0 = 0; } else { env->CF = (T0 >> (shift - 1)) & 1; T0 = T0 >> shift; } env->NZF = T0; FORCE_RET(); } void OPPROTO op_sarl_T0_im_thumb(void) { int shift; shift = PARAM1; if (shift == 0) { T0 = ((int32_t)T0) >> 31; env->CF = T0 & 1; } else { env->CF = (T0 >> (shift - 1)) & 1; T0 = ((int32_t)T0) >> shift; } env->NZF = T0; FORCE_RET(); } /* exceptions */ void OPPROTO op_swi(void) { env->exception_index = EXCP_SWI; cpu_loop_exit(); } void OPPROTO op_undef_insn(void) { env->exception_index = EXCP_UDEF; cpu_loop_exit(); } void OPPROTO op_debug(void) { env->exception_index = EXCP_DEBUG; cpu_loop_exit(); } void OPPROTO op_wfi(void) { env->exception_index = EXCP_HLT; env->halted = 1; cpu_loop_exit(); } void OPPROTO op_bkpt(void) { env->exception_index = EXCP_BKPT; cpu_loop_exit(); } /* VFP support. We follow the convention used for VFP instrunctions: Single precition routines have a "s" suffix, double precision a "d" suffix. */ #define VFP_OP(name, p) void OPPROTO op_vfp_##name##p(void) #define VFP_BINOP(name) \ VFP_OP(name, s) \ { \ FT0s = float32_ ## name (FT0s, FT1s, &env->vfp.fp_status); \ } \ VFP_OP(name, d) \ { \ FT0d = float64_ ## name (FT0d, FT1d, &env->vfp.fp_status); \ } VFP_BINOP(add) VFP_BINOP(sub) VFP_BINOP(mul) VFP_BINOP(div) #undef VFP_BINOP #define VFP_HELPER(name) \ VFP_OP(name, s) \ { \ do_vfp_##name##s(); \ } \ VFP_OP(name, d) \ { \ do_vfp_##name##d(); \ } VFP_HELPER(abs) VFP_HELPER(sqrt) VFP_HELPER(cmp) VFP_HELPER(cmpe) #undef VFP_HELPER /* XXX: Will this do the right thing for NANs. Should invert the signbit without looking at the rest of the value. */ VFP_OP(neg, s) { FT0s = float32_chs(FT0s); } VFP_OP(neg, d) { FT0d = float64_chs(FT0d); } VFP_OP(F1_ld0, s) { union { uint32_t i; float32 s; } v; v.i = 0; FT1s = v.s; } VFP_OP(F1_ld0, d) { union { uint64_t i; float64 d; } v; v.i = 0; FT1d = v.d; } /* Helper routines to perform bitwise copies between float and int. */ static inline float32 vfp_itos(uint32_t i) { union { uint32_t i; float32 s; } v; v.i = i; return v.s; } static inline uint32_t vfp_stoi(float32 s) { union { uint32_t i; float32 s; } v; v.s = s; return v.i; } /* Integer to float conversion. */ VFP_OP(uito, s) { FT0s = uint32_to_float32(vfp_stoi(FT0s), &env->vfp.fp_status); } VFP_OP(uito, d) { FT0d = uint32_to_float64(vfp_stoi(FT0s), &env->vfp.fp_status); } VFP_OP(sito, s) { FT0s = int32_to_float32(vfp_stoi(FT0s), &env->vfp.fp_status); } VFP_OP(sito, d) { FT0d = int32_to_float64(vfp_stoi(FT0s), &env->vfp.fp_status); } /* Float to integer conversion. */ VFP_OP(toui, s) { FT0s = vfp_itos(float32_to_uint32(FT0s, &env->vfp.fp_status)); } VFP_OP(toui, d) { FT0s = vfp_itos(float64_to_uint32(FT0d, &env->vfp.fp_status)); } VFP_OP(tosi, s) { FT0s = vfp_itos(float32_to_int32(FT0s, &env->vfp.fp_status)); } VFP_OP(tosi, d) { FT0s = vfp_itos(float64_to_int32(FT0d, &env->vfp.fp_status)); } /* TODO: Set rounding mode properly. */ VFP_OP(touiz, s) { FT0s = vfp_itos(float32_to_uint32_round_to_zero(FT0s, &env->vfp.fp_status)); } VFP_OP(touiz, d) { FT0s = vfp_itos(float64_to_uint32_round_to_zero(FT0d, &env->vfp.fp_status)); } VFP_OP(tosiz, s) { FT0s = vfp_itos(float32_to_int32_round_to_zero(FT0s, &env->vfp.fp_status)); } VFP_OP(tosiz, d) { FT0s = vfp_itos(float64_to_int32_round_to_zero(FT0d, &env->vfp.fp_status)); } /* floating point conversion */ VFP_OP(fcvtd, s) { FT0d = float32_to_float64(FT0s, &env->vfp.fp_status); } VFP_OP(fcvts, d) { FT0s = float64_to_float32(FT0d, &env->vfp.fp_status); } /* Get and Put values from registers. */ VFP_OP(getreg_F0, d) { FT0d = *(float64 *)((char *) env + PARAM1); } VFP_OP(getreg_F0, s) { FT0s = *(float32 *)((char *) env + PARAM1); } VFP_OP(getreg_F1, d) { FT1d = *(float64 *)((char *) env + PARAM1); } VFP_OP(getreg_F1, s) { FT1s = *(float32 *)((char *) env + PARAM1); } VFP_OP(setreg_F0, d) { *(float64 *)((char *) env + PARAM1) = FT0d; } VFP_OP(setreg_F0, s) { *(float32 *)((char *) env + PARAM1) = FT0s; } void OPPROTO op_vfp_movl_T0_fpscr(void) { do_vfp_get_fpscr (); } void OPPROTO op_vfp_movl_T0_fpscr_flags(void) { T0 = env->vfp.fpscr & (0xf << 28); } void OPPROTO op_vfp_movl_fpscr_T0(void) { do_vfp_set_fpscr(); } /* Move between FT0s to T0 */ void OPPROTO op_vfp_mrs(void) { T0 = vfp_stoi(FT0s); } void OPPROTO op_vfp_msr(void) { FT0s = vfp_itos(T0); } /* Move between FT0d and {T0,T1} */ void OPPROTO op_vfp_mrrd(void) { CPU_DoubleU u; u.d = FT0d; T0 = u.l.lower; T1 = u.l.upper; } void OPPROTO op_vfp_mdrr(void) { CPU_DoubleU u; u.l.lower = T0; u.l.upper = T1; FT0d = u.d; } /* Copy the most significant bit to T0 to all bits of T1. */ void OPPROTO op_signbit_T1_T0(void) { T1 = (int32_t)T0 >> 31; } void OPPROTO op_movl_cp15_T0(void) { helper_set_cp15(env, PARAM1, T0); FORCE_RET(); } void OPPROTO op_movl_T0_cp15(void) { T0 = helper_get_cp15(env, PARAM1); FORCE_RET(); } /* Access to user mode registers from privileged modes. */ void OPPROTO op_movl_T0_user(void) { int regno = PARAM1; if (regno == 13) { T0 = env->banked_r13[0]; } else if (regno == 14) { T0 = env->banked_r14[0]; } else if ((env->uncached_cpsr & 0x1f) == ARM_CPU_MODE_FIQ) { T0 = env->usr_regs[regno - 8]; } else { T0 = env->regs[regno]; } FORCE_RET(); } void OPPROTO op_movl_user_T0(void) { int regno = PARAM1; if (regno == 13) { env->banked_r13[0] = T0; } else if (regno == 14) { env->banked_r14[0] = T0; } else if ((env->uncached_cpsr & 0x1f) == ARM_CPU_MODE_FIQ) { env->usr_regs[regno - 8] = T0; } else { env->regs[regno] = T0; } FORCE_RET(); } void OPPROTO op_movl_T2_T0(void) { T2 = T0; } void OPPROTO op_movl_T0_T2(void) { T0 = T2; }