/***************************************************************** * File automatically generated by rebuild_wrappers.py (v1.2.0.09) *****************************************************************/ #include #include #include #include "wrapper.h" #include "emu/x64emu_private.h" #include "emu/x87emu_private.h" #include "regs.h" #include "x64emu.h" typedef union ui64_s { int64_t i; uint64_t u; uint32_t d[2]; } ui64_t; typedef struct _2uint_struct_s { uint32_t a; uint32_t b; } _2uint_struct_t; extern void* my__IO_2_1_stderr_; extern void* my__IO_2_1_stdin_ ; extern void* my__IO_2_1_stdout_; static void* io_convert(void* v) { if(!v) return v; if(v==my__IO_2_1_stderr_) return stderr; if(v==my__IO_2_1_stdin_) return stdin; if(v==my__IO_2_1_stdout_) return stdout; return v; } typedef struct my_GValue_s { int g_type; union { int v_int; int64_t v_int64; uint64_t v_uint64; float v_float; double v_double; void* v_pointer; } data[2]; } my_GValue_t; static void alignGValue(my_GValue_t* v, void* value) { v->g_type = *(int*)value; memcpy(v->data, value+4, 2*sizeof(double)); } static void unalignGValue(void* value, my_GValue_t* v) { *(int*)value = v->g_type; memcpy(value+4, v->data, 2*sizeof(double)); } void* VulkanFromx86(void* src, void** save); void VulkanTox86(void* src, void* save); #define ST0val ST0.d int of_convert(int); typedef void (*vFE_t)(x64emu_t*); typedef void (*vFv_t)(void); typedef void (*vFp_t)(void*); typedef int32_t (*iFE_t)(x64emu_t*); typedef int32_t (*iFv_t)(void); typedef int32_t (*iFi_t)(int32_t); typedef int32_t (*iFu_t)(uint32_t); typedef int32_t (*iFf_t)(float); typedef int32_t (*iFd_t)(double); typedef int32_t (*iFp_t)(void*); typedef int64_t (*IFf_t)(float); typedef int64_t (*IFd_t)(double); typedef int64_t (*IFp_t)(void*); typedef uint64_t (*UFV_t)(void*); typedef float (*fFf_t)(float); typedef double (*dFd_t)(double); typedef double (*dFp_t)(void*); typedef intptr_t (*lFp_t)(void*); typedef uintptr_t (*LFv_t)(void); typedef void* (*pFE_t)(x64emu_t*); typedef void* (*pFL_t)(uintptr_t); typedef void* (*pFp_t)(void*); typedef void (*vFEp_t)(x64emu_t*, void*); typedef void (*vFpp_t)(void*, void*); typedef int32_t (*iFEp_t)(x64emu_t*, void*); typedef int32_t (*iFip_t)(int32_t, void*); typedef int32_t (*iFup_t)(uint32_t, void*); typedef int32_t (*iFLL_t)(uintptr_t, uintptr_t); typedef int32_t (*iFLp_t)(uintptr_t, void*); typedef int32_t (*iFpi_t)(void*, int32_t); typedef float (*fFif_t)(int32_t, float); typedef float (*fFfi_t)(float, int32_t); typedef float (*fFff_t)(float, float); typedef float (*fFfp_t)(float, void*); typedef double (*dFid_t)(int32_t, double); typedef double (*dFdi_t)(double, int32_t); typedef double (*dFdd_t)(double, double); typedef double (*dFdp_t)(double, void*); typedef void* (*pFEp_t)(x64emu_t*, void*); typedef void* (*pFLL_t)(uintptr_t, uintptr_t); typedef void* (*pFpV_t)(void*, void*); typedef void (*vFEpu_t)(x64emu_t*, void*, uint32_t); typedef void (*vFfpp_t)(float, void*, void*); typedef void (*vFdpp_t)(double, void*, void*); typedef int32_t (*iFEpp_t)(x64emu_t*, void*, void*); typedef int32_t (*iFEpV_t)(x64emu_t*, void*, void*); typedef int32_t (*iFpiu_t)(void*, int32_t, uint32_t); typedef float (*fFfff_t)(float, float, float); typedef float (*fFffp_t)(float, float, void*); typedef double (*dFddd_t)(double, double, double); typedef double (*dFddp_t)(double, double, void*); typedef void* (*pFEpi_t)(x64emu_t*, void*, int32_t); typedef void* (*pFEpp_t)(x64emu_t*, void*, void*); typedef void (*vFEpup_t)(x64emu_t*, void*, uint32_t, void*); typedef int32_t (*iFEupp_t)(x64emu_t*, uint32_t, void*, void*); typedef int32_t (*iFEpip_t)(x64emu_t*, void*, int32_t, void*); typedef int32_t (*iFEppp_t)(x64emu_t*, void*, void*, void*); typedef int32_t (*iFuipp_t)(uint32_t, int32_t, void*, void*); typedef void* (*pFEppi_t)(x64emu_t*, void*, void*, int32_t); typedef void* (*pFEppp_t)(x64emu_t*, void*, void*, void*); typedef int32_t (*iFEpppp_t)(x64emu_t*, void*, void*, void*, void*); typedef int32_t (*iFipppi_t)(int32_t, void*, void*, void*, int32_t); typedef int32_t (*iFEpippppp_t)(x64emu_t*, void*, int32_t, void*, void*, void*, void*, void*); #if defined(HAVE_LD80BITS) typedef long double (*DFD_t)(long double); typedef long double (*DFDD_t)(long double, long double); typedef long double (*DFDp_t)(long double, void*); #endif #if !defined(HAVE_LD80BITS) typedef double (*KFK_t)(double); typedef double (*KFKK_t)(double, double); typedef double (*KFKp_t)(double, void*); #endif void vFE(x64emu_t *emu, uintptr_t fcn) { vFE_t fn = (vFE_t)fcn; fn(emu); } void vFv(x64emu_t *emu, uintptr_t fcn) { vFv_t fn = (vFv_t)fcn; fn(); } void vFp(x64emu_t *emu, uintptr_t fcn) { vFp_t fn = (vFp_t)fcn; fn((void*)R_RDI); } void iFE(x64emu_t *emu, uintptr_t fcn) { iFE_t fn = (iFE_t)fcn; R_RAX=fn(emu); } void iFv(x64emu_t *emu, uintptr_t fcn) { iFv_t fn = (iFv_t)fcn; R_RAX=fn(); } void iFi(x64emu_t *emu, uintptr_t fcn) { iFi_t fn = (iFi_t)fcn; R_RAX=fn((int32_t)R_RDI); } void iFu(x64emu_t *emu, uintptr_t fcn) { iFu_t fn = (iFu_t)fcn; R_RAX=fn((uint32_t)R_RDI); } void iFf(x64emu_t *emu, uintptr_t fcn) { iFf_t fn = (iFf_t)fcn; R_RAX=fn(emu->xmm[0].f[0]); } void iFd(x64emu_t *emu, uintptr_t fcn) { iFd_t fn = (iFd_t)fcn; R_RAX=fn(emu->xmm[0].d[0]); } void iFp(x64emu_t *emu, uintptr_t fcn) { iFp_t fn = (iFp_t)fcn; R_RAX=fn((void*)R_RDI); } void IFf(x64emu_t *emu, uintptr_t fcn) { IFf_t fn = (IFf_t)fcn; R_RAX=(uint64_t)fn(emu->xmm[0].f[0]); } void IFd(x64emu_t *emu, uintptr_t fcn) { IFd_t fn = (IFd_t)fcn; R_RAX=(uint64_t)fn(emu->xmm[0].d[0]); } void IFp(x64emu_t *emu, uintptr_t fcn) { IFp_t fn = (IFp_t)fcn; R_RAX=(uint64_t)fn((void*)R_RDI); } void UFV(x64emu_t *emu, uintptr_t fcn) { UFV_t fn = (UFV_t)fcn; R_RAX=fn((void*)(R_RSP + 8)); } void fFf(x64emu_t *emu, uintptr_t fcn) { fFf_t fn = (fFf_t)fcn; emu->xmm[0].f[0]=fn(emu->xmm[0].f[0]); } void dFd(x64emu_t *emu, uintptr_t fcn) { dFd_t fn = (dFd_t)fcn; emu->xmm[0].d[0]=fn(emu->xmm[0].d[0]); } void dFp(x64emu_t *emu, uintptr_t fcn) { dFp_t fn = (dFp_t)fcn; emu->xmm[0].d[0]=fn((void*)R_RDI); } void lFp(x64emu_t *emu, uintptr_t fcn) { lFp_t fn = (lFp_t)fcn; R_RAX=(intptr_t)fn((void*)R_RDI); } void LFv(x64emu_t *emu, uintptr_t fcn) { LFv_t fn = (LFv_t)fcn; R_RAX=(uintptr_t)fn(); } void pFE(x64emu_t *emu, uintptr_t fcn) { pFE_t fn = (pFE_t)fcn; R_RAX=(uintptr_t)fn(emu); } void pFL(x64emu_t *emu, uintptr_t fcn) { pFL_t fn = (pFL_t)fcn; R_RAX=(uintptr_t)fn((uintptr_t)R_RDI); } void pFp(x64emu_t *emu, uintptr_t fcn) { pFp_t fn = (pFp_t)fcn; R_RAX=(uintptr_t)fn((void*)R_RDI); } void vFEp(x64emu_t *emu, uintptr_t fcn) { vFEp_t fn = (vFEp_t)fcn; fn(emu, (void*)R_RDI); } void vFpp(x64emu_t *emu, uintptr_t fcn) { vFpp_t fn = (vFpp_t)fcn; fn((void*)R_RDI, (void*)R_RSI); } void iFEp(x64emu_t *emu, uintptr_t fcn) { iFEp_t fn = (iFEp_t)fcn; R_RAX=fn(emu, (void*)R_RDI); } void iFip(x64emu_t *emu, uintptr_t fcn) { iFip_t fn = (iFip_t)fcn; R_RAX=fn((int32_t)R_RDI, (void*)R_RSI); } void iFup(x64emu_t *emu, uintptr_t fcn) { iFup_t fn = (iFup_t)fcn; R_RAX=fn((uint32_t)R_RDI, (void*)R_RSI); } void iFLL(x64emu_t *emu, uintptr_t fcn) { iFLL_t fn = (iFLL_t)fcn; R_RAX=fn((uintptr_t)R_RDI, (uintptr_t)R_RSI); } void iFLp(x64emu_t *emu, uintptr_t fcn) { iFLp_t fn = (iFLp_t)fcn; R_RAX=fn((uintptr_t)R_RDI, (void*)R_RSI); } void iFpi(x64emu_t *emu, uintptr_t fcn) { iFpi_t fn = (iFpi_t)fcn; R_RAX=fn((void*)R_RDI, (int32_t)R_RSI); } void fFif(x64emu_t *emu, uintptr_t fcn) { fFif_t fn = (fFif_t)fcn; emu->xmm[0].f[0]=fn((int32_t)R_RDI, emu->xmm[0].f[0]); } void fFfi(x64emu_t *emu, uintptr_t fcn) { fFfi_t fn = (fFfi_t)fcn; emu->xmm[0].f[0]=fn(emu->xmm[0].f[0], (int32_t)R_RDI); } void fFff(x64emu_t *emu, uintptr_t fcn) { fFff_t fn = (fFff_t)fcn; emu->xmm[0].f[0]=fn(emu->xmm[0].f[0], emu->xmm[1].f[0]); } void fFfp(x64emu_t *emu, uintptr_t fcn) { fFfp_t fn = (fFfp_t)fcn; emu->xmm[0].f[0]=fn(emu->xmm[0].f[0], (void*)R_RDI); } void dFid(x64emu_t *emu, uintptr_t fcn) { dFid_t fn = (dFid_t)fcn; emu->xmm[0].d[0]=fn((int32_t)R_RDI, emu->xmm[0].d[0]); } void dFdi(x64emu_t *emu, uintptr_t fcn) { dFdi_t fn = (dFdi_t)fcn; emu->xmm[0].d[0]=fn(emu->xmm[0].d[0], (int32_t)R_RDI); } void dFdd(x64emu_t *emu, uintptr_t fcn) { dFdd_t fn = (dFdd_t)fcn; emu->xmm[0].d[0]=fn(emu->xmm[0].d[0], emu->xmm[1].d[0]); } void dFdp(x64emu_t *emu, uintptr_t fcn) { dFdp_t fn = (dFdp_t)fcn; emu->xmm[0].d[0]=fn(emu->xmm[0].d[0], (void*)R_RDI); } void pFEp(x64emu_t *emu, uintptr_t fcn) { pFEp_t fn = (pFEp_t)fcn; R_RAX=(uintptr_t)fn(emu, (void*)R_RDI); } void pFLL(x64emu_t *emu, uintptr_t fcn) { pFLL_t fn = (pFLL_t)fcn; R_RAX=(uintptr_t)fn((uintptr_t)R_RDI, (uintptr_t)R_RSI); } void pFpV(x64emu_t *emu, uintptr_t fcn) { pFpV_t fn = (pFpV_t)fcn; R_RAX=(uintptr_t)fn((void*)R_RDI, (void*)(R_RSP + 8)); } void vFEpu(x64emu_t *emu, uintptr_t fcn) { vFEpu_t fn = (vFEpu_t)fcn; fn(emu, (void*)R_RDI, (uint32_t)R_RSI); } void vFfpp(x64emu_t *emu, uintptr_t fcn) { vFfpp_t fn = (vFfpp_t)fcn; fn(emu->xmm[0].f[0], (void*)R_RDI, (void*)R_RSI); } void vFdpp(x64emu_t *emu, uintptr_t fcn) { vFdpp_t fn = (vFdpp_t)fcn; fn(emu->xmm[0].d[0], (void*)R_RDI, (void*)R_RSI); } void iFEpp(x64emu_t *emu, uintptr_t fcn) { iFEpp_t fn = (iFEpp_t)fcn; R_RAX=fn(emu, (void*)R_RDI, (void*)R_RSI); } void iFEpV(x64emu_t *emu, uintptr_t fcn) { iFEpV_t fn = (iFEpV_t)fcn; R_RAX=fn(emu, (void*)R_RDI, (void*)(R_RSP + 8)); } void iFpiu(x64emu_t *emu, uintptr_t fcn) { iFpiu_t fn = (iFpiu_t)fcn; R_RAX=fn((void*)R_RDI, (int32_t)R_RSI, (uint32_t)R_RDX); } void fFfff(x64emu_t *emu, uintptr_t fcn) { fFfff_t fn = (fFfff_t)fcn; emu->xmm[0].f[0]=fn(emu->xmm[0].f[0], emu->xmm[1].f[0], emu->xmm[2].f[0]); } void fFffp(x64emu_t *emu, uintptr_t fcn) { fFffp_t fn = (fFffp_t)fcn; emu->xmm[0].f[0]=fn(emu->xmm[0].f[0], emu->xmm[1].f[0], (void*)R_RDI); } void dFddd(x64emu_t *emu, uintptr_t fcn) { dFddd_t fn = (dFddd_t)fcn; emu->xmm[0].d[0]=fn(emu->xmm[0].d[0], emu->xmm[1].d[0], emu->xmm[2].d[0]); } void dFddp(x64emu_t *emu, uintptr_t fcn) { dFddp_t fn = (dFddp_t)fcn; emu->xmm[0].d[0]=fn(emu->xmm[0].d[0], emu->xmm[1].d[0], (void*)R_RDI); } void pFEpi(x64emu_t *emu, uintptr_t fcn) { pFEpi_t fn = (pFEpi_t)fcn; R_RAX=(uintptr_t)fn(emu, (void*)R_RDI, (int32_t)R_RSI); } void pFEpp(x64emu_t *emu, uintptr_t fcn) { pFEpp_t fn = (pFEpp_t)fcn; R_RAX=(uintptr_t)fn(emu, (void*)R_RDI, (void*)R_RSI); } void vFEpup(x64emu_t *emu, uintptr_t fcn) { vFEpup_t fn = (vFEpup_t)fcn; fn(emu, (void*)R_RDI, (uint32_t)R_RSI, (void*)R_RDX); } void iFEupp(x64emu_t *emu, uintptr_t fcn) { iFEupp_t fn = (iFEupp_t)fcn; R_RAX=fn(emu, (uint32_t)R_RDI, (void*)R_RSI, (void*)R_RDX); } void iFEpip(x64emu_t *emu, uintptr_t fcn) { iFEpip_t fn = (iFEpip_t)fcn; R_RAX=fn(emu, (void*)R_RDI, (int32_t)R_RSI, (void*)R_RDX); } void iFEppp(x64emu_t *emu, uintptr_t fcn) { iFEppp_t fn = (iFEppp_t)fcn; R_RAX=fn(emu, (void*)R_RDI, (void*)R_RSI, (void*)R_RDX); } void iFuipp(x64emu_t *emu, uintptr_t fcn) { iFuipp_t fn = (iFuipp_t)fcn; R_RAX=fn((uint32_t)R_RDI, (int32_t)R_RSI, (void*)R_RDX, (void*)R_RCX); } void pFEppi(x64emu_t *emu, uintptr_t fcn) { pFEppi_t fn = (pFEppi_t)fcn; R_RAX=(uintptr_t)fn(emu, (void*)R_RDI, (void*)R_RSI, (int32_t)R_RDX); } void pFEppp(x64emu_t *emu, uintptr_t fcn) { pFEppp_t fn = (pFEppp_t)fcn; R_RAX=(uintptr_t)fn(emu, (void*)R_RDI, (void*)R_RSI, (void*)R_RDX); } void iFEpppp(x64emu_t *emu, uintptr_t fcn) { iFEpppp_t fn = (iFEpppp_t)fcn; R_RAX=fn(emu, (void*)R_RDI, (void*)R_RSI, (void*)R_RDX, (void*)R_RCX); } void iFipppi(x64emu_t *emu, uintptr_t fcn) { iFipppi_t fn = (iFipppi_t)fcn; R_RAX=fn((int32_t)R_RDI, (void*)R_RSI, (void*)R_RDX, (void*)R_RCX, (int32_t)R_R8); } void iFEpippppp(x64emu_t *emu, uintptr_t fcn) { iFEpippppp_t fn = (iFEpippppp_t)fcn; R_RAX=fn(emu, (void*)R_RDI, (int32_t)R_RSI, (void*)R_RDX, (void*)R_RCX, (void*)R_R8, (void*)R_R9, *(void**)(R_RSP + 8)); } #if defined(HAVE_LD80BITS) void DFD(x64emu_t *emu, uintptr_t fcn) { DFD_t fn = (DFD_t)fcn; long double ld=fn(*(long double*)(R_RSP + 8)); fpu_do_push(emu); ST0val = ld; } void DFDD(x64emu_t *emu, uintptr_t fcn) { DFDD_t fn = (DFDD_t)fcn; long double ld=fn(*(long double*)(R_RSP + 8), *(long double*)(R_RSP + 24)); fpu_do_push(emu); ST0val = ld; } void DFDp(x64emu_t *emu, uintptr_t fcn) { DFDp_t fn = (DFDp_t)fcn; long double ld=fn(*(long double*)(R_RSP + 8), (void*)R_RDI); fpu_do_push(emu); ST0val = ld; } #endif #if !defined(HAVE_LD80BITS) void KFK(x64emu_t *emu, uintptr_t fcn) { KFK_t fn = (KFK_t)fcn; double db=fn(FromLD((void*)(R_RSP + 8))); fpu_do_push(emu); ST0val = db; } void KFKK(x64emu_t *emu, uintptr_t fcn) { KFKK_t fn = (KFKK_t)fcn; double db=fn(FromLD((void*)(R_RSP + 8)), FromLD((void*)(R_RSP + 24))); fpu_do_push(emu); ST0val = db; } void KFKp(x64emu_t *emu, uintptr_t fcn) { KFKp_t fn = (KFKp_t)fcn; double db=fn(FromLD((void*)(R_RSP + 8)), (void*)R_RDI); fpu_do_push(emu); ST0val = db; } #endif void iFEv(x64emu_t *emu, uintptr_t fcn) { iFE_t fn = (iFE_t)fcn; R_RAX=fn(emu); } void pFEv(x64emu_t *emu, uintptr_t fcn) { pFE_t fn = (pFE_t)fcn; R_RAX=(uintptr_t)fn(emu); }