mirror of
https://github.com/yuzu-emu/unicorn.git
synced 2024-12-25 01:05:38 +00:00
b2f1326437
We've currently got 18 architectures in QEMU, and thus 18 target-xxx folders in the root folder of the QEMU source tree. More architectures (e.g. RISC-V, AVR) are likely to be included soon, too, so the main folder of the QEMU sources slowly gets quite overcrowded with the target-xxx folders. To disburden the main folder a little bit, let's move the target-xxx folders into a dedicated target/ folder, so that target-xxx/ simply becomes target/xxx/ instead. Backports commit fcf5ef2ab52c621a4617ebbef36bf43b4003f4c0 from qemu
220 lines
8.9 KiB
C
220 lines
8.9 KiB
C
/* Unicorn Emulator Engine */
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/* By Nguyen Anh Quynh <aquynh@gmail.com>, 2015 */
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#include "qemu/osdep.h"
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#include "cpu.h"
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#include "hw/boards.h"
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#include "hw/arm/arm.h"
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#include "sysemu/cpus.h"
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#include "unicorn.h"
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#include "unicorn_common.h"
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#include "uc_priv.h"
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const int ARM64_REGS_STORAGE_SIZE = offsetof(CPUARMState, tlb_table);
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static void arm64_set_pc(struct uc_struct *uc, uint64_t address)
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{
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((CPUARMState *)uc->current_cpu->env_ptr)->pc = address;
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}
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void arm64_release(void* ctx);
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void arm64_release(void* ctx)
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{
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struct uc_struct* uc;
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ARMCPU* cpu;
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TCGContext *s = (TCGContext *) ctx;
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g_free(s->tb_ctx.tbs);
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uc = s->uc;
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cpu = (ARMCPU*) uc->cpu;
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g_free(cpu->cpreg_indexes);
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g_free(cpu->cpreg_values);
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g_free(cpu->cpreg_vmstate_indexes);
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g_free(cpu->cpreg_vmstate_values);
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release_common(ctx);
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}
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void arm64_reg_reset(struct uc_struct *uc)
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{
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CPUArchState *env = uc->cpu->env_ptr;
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memset(env->xregs, 0, sizeof(env->xregs));
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env->pc = 0;
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}
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int arm64_reg_read(struct uc_struct *uc, unsigned int *regs, void **vals, int count)
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{
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CPUState *mycpu = uc->cpu;
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int i;
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for (i = 0; i < count; i++) {
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unsigned int regid = regs[i];
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void *value = vals[i];
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// V & Q registers are the same
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if (regid >= UC_ARM64_REG_V0 && regid <= UC_ARM64_REG_V31) {
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regid += UC_ARM64_REG_Q0 - UC_ARM64_REG_V0;
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}
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if (regid >= UC_ARM64_REG_X0 && regid <= UC_ARM64_REG_X28) {
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*(int64_t *)value = ARM_CPU(uc, mycpu)->env.xregs[regid - UC_ARM64_REG_X0];
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} else if (regid >= UC_ARM64_REG_W0 && regid <= UC_ARM64_REG_W30) {
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*(int32_t *)value = READ_DWORD(ARM_CPU(uc, mycpu)->env.xregs[regid - UC_ARM64_REG_W0]);
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} else if (regid >= UC_ARM64_REG_Q0 && regid <= UC_ARM64_REG_Q31) {
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float64 *dst = (float64*) value;
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uint32_t reg_index = 2*(regid - UC_ARM64_REG_Q0);
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dst[0] = ARM_CPU(uc, mycpu)->env.vfp.regs[reg_index];
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dst[1] = ARM_CPU(uc, mycpu)->env.vfp.regs[reg_index+1];
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} else if (regid >= UC_ARM64_REG_D0 && regid <= UC_ARM64_REG_D31) {
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*(float64*)value = ARM_CPU(uc, mycpu)->env.vfp.regs[2*(regid - UC_ARM64_REG_D0)];
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} else if (regid >= UC_ARM64_REG_S0 && regid <= UC_ARM64_REG_S31) {
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*(int32_t*)value = READ_DWORD(ARM_CPU(uc, mycpu)->env.vfp.regs[2*(regid - UC_ARM64_REG_S0)]);
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} else if (regid >= UC_ARM64_REG_H0 && regid <= UC_ARM64_REG_H31) {
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*(int16_t*)value = READ_WORD(ARM_CPU(uc, mycpu)->env.vfp.regs[2*(regid - UC_ARM64_REG_H0)]);
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} else if (regid >= UC_ARM64_REG_B0 && regid <= UC_ARM64_REG_B31) {
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*(int8_t*)value = READ_BYTE_L(ARM_CPU(uc, mycpu)->env.vfp.regs[2*(regid - UC_ARM64_REG_B0)]);
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} else {
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switch(regid) {
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default: break;
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case UC_ARM64_REG_CPACR_EL1:
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*(uint32_t *)value = ARM_CPU(uc, mycpu)->env.cp15.cpacr_el1;
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break;
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case UC_ARM64_REG_ESR:
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*(uint32_t *)value = ARM_CPU(uc, mycpu)->env.exception.syndrome;
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break;
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case UC_ARM64_REG_TPIDR_EL0:
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*(int64_t *)value = ARM_CPU(uc, mycpu)->env.cp15.tpidr_el[0];
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break;
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case UC_ARM64_REG_TPIDRRO_EL0:
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*(int64_t *)value = ARM_CPU(uc, mycpu)->env.cp15.tpidrro_el[0];
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break;
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case UC_ARM64_REG_TPIDR_EL1:
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*(int64_t *)value = ARM_CPU(uc, mycpu)->env.cp15.tpidr_el[1];
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break;
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case UC_ARM64_REG_X29:
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*(int64_t *)value = ARM_CPU(uc, mycpu)->env.xregs[29];
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break;
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case UC_ARM64_REG_X30:
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*(int64_t *)value = ARM_CPU(uc, mycpu)->env.xregs[30];
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break;
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case UC_ARM64_REG_PC:
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*(uint64_t *)value = ARM_CPU(uc, mycpu)->env.pc;
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break;
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case UC_ARM64_REG_SP:
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*(int64_t *)value = ARM_CPU(uc, mycpu)->env.xregs[31];
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break;
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case UC_ARM64_REG_NZCV:
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*(int32_t *)value = cpsr_read(&ARM_CPU(uc, mycpu)->env) & CPSR_NZCV;
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break;
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case UC_ARM64_REG_PSTATE:
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*(uint32_t *)value = pstate_read(&ARM_CPU(uc, mycpu)->env);
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break;
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case UC_ARM64_REG_FPCR:
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*(uint32_t *)value = vfp_get_fpcr(&ARM_CPU(uc, mycpu)->env);
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break;
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case UC_ARM64_REG_FPSR:
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*(uint32_t *)value = vfp_get_fpsr(&ARM_CPU(uc, mycpu)->env);
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break;
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}
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}
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}
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return 0;
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}
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int arm64_reg_write(struct uc_struct *uc, unsigned int *regs, void* const* vals, int count)
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{
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CPUState *mycpu = uc->cpu;
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int i;
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for (i = 0; i < count; i++) {
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unsigned int regid = regs[i];
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const void *value = vals[i];
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if (regid >= UC_ARM64_REG_V0 && regid <= UC_ARM64_REG_V31) {
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regid += UC_ARM64_REG_Q0 - UC_ARM64_REG_V0;
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}
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if (regid >= UC_ARM64_REG_X0 && regid <= UC_ARM64_REG_X28) {
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ARM_CPU(uc, mycpu)->env.xregs[regid - UC_ARM64_REG_X0] = *(uint64_t *)value;
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} else if (regid >= UC_ARM64_REG_W0 && regid <= UC_ARM64_REG_W30) {
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WRITE_DWORD(ARM_CPU(uc, mycpu)->env.xregs[regid - UC_ARM64_REG_W0], *(uint32_t *)value);
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} else if (regid >= UC_ARM64_REG_Q0 && regid <= UC_ARM64_REG_Q31) {
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float64 *src = (float64*) value;
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uint32_t reg_index = 2*(regid - UC_ARM64_REG_Q0);
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ARM_CPU(uc, mycpu)->env.vfp.regs[reg_index] = src[0];
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ARM_CPU(uc, mycpu)->env.vfp.regs[reg_index+1] = src[1];
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} else if (regid >= UC_ARM64_REG_D0 && regid <= UC_ARM64_REG_D31) {
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ARM_CPU(uc, mycpu)->env.vfp.regs[2*(regid - UC_ARM64_REG_D0)] = * (float64*) value;
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} else if (regid >= UC_ARM64_REG_S0 && regid <= UC_ARM64_REG_S31) {
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WRITE_DWORD(ARM_CPU(uc, mycpu)->env.vfp.regs[2*(regid - UC_ARM64_REG_S0)], *(int32_t*) value);
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} else if (regid >= UC_ARM64_REG_H0 && regid <= UC_ARM64_REG_H31) {
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WRITE_WORD(ARM_CPU(uc, mycpu)->env.vfp.regs[2*(regid - UC_ARM64_REG_H0)], *(int16_t*) value);
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} else if (regid >= UC_ARM64_REG_B0 && regid <= UC_ARM64_REG_B31) {
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WRITE_BYTE_L(ARM_CPU(uc, mycpu)->env.vfp.regs[2*(regid - UC_ARM64_REG_B0)], *(int8_t*) value);
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} else {
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switch(regid) {
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default: break;
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case UC_ARM64_REG_CPACR_EL1:
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ARM_CPU(uc, mycpu)->env.cp15.cpacr_el1 = *(uint32_t *)value;
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break;
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case UC_ARM64_REG_TPIDR_EL0:
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ARM_CPU(uc, mycpu)->env.cp15.tpidr_el[0] = *(uint64_t *)value;
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break;
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case UC_ARM64_REG_TPIDRRO_EL0:
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ARM_CPU(uc, mycpu)->env.cp15.tpidrro_el[0] = *(uint64_t *)value;
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break;
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case UC_ARM64_REG_TPIDR_EL1:
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ARM_CPU(uc, mycpu)->env.cp15.tpidr_el[1] = *(uint64_t *)value;
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break;
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case UC_ARM64_REG_X29:
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ARM_CPU(uc, mycpu)->env.xregs[29] = *(uint64_t *)value;
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break;
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case UC_ARM64_REG_X30:
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ARM_CPU(uc, mycpu)->env.xregs[30] = *(uint64_t *)value;
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break;
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case UC_ARM64_REG_PC:
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ARM_CPU(uc, mycpu)->env.pc = *(uint64_t *)value;
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// force to quit execution and flush TB
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uc->quit_request = true;
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uc_emu_stop(uc);
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break;
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case UC_ARM64_REG_SP:
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ARM_CPU(uc, mycpu)->env.xregs[31] = *(uint64_t *)value;
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break;
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case UC_ARM64_REG_NZCV:
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cpsr_write(&ARM_CPU(uc, mycpu)->env, *(uint32_t *) value, CPSR_NZCV, CPSRWriteRaw);
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break;
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case UC_ARM64_REG_PSTATE:
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pstate_write(&ARM_CPU(uc, mycpu)->env, *(uint32_t *)value);
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break;
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case UC_ARM64_REG_FPCR:
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vfp_set_fpcr(&ARM_CPU(uc, mycpu)->env, *(uint32_t *)value);
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break;
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case UC_ARM64_REG_FPSR:
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vfp_set_fpsr(&ARM_CPU(uc, mycpu)->env, *(uint32_t *)value);
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break;
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}
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}
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}
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return 0;
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}
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DEFAULT_VISIBILITY
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#ifdef TARGET_WORDS_BIGENDIAN
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void arm64eb_uc_init(struct uc_struct* uc)
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#else
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void arm64_uc_init(struct uc_struct* uc)
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#endif
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{
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register_accel_types(uc);
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arm_cpu_register_types(uc);
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aarch64_cpu_register_types(uc);
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machvirt_machine_init(uc);
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uc->reg_read = arm64_reg_read;
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uc->reg_write = arm64_reg_write;
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uc->reg_reset = arm64_reg_reset;
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uc->set_pc = arm64_set_pc;
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uc->release = arm64_release;
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uc_common_init(uc);
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}
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