Compiles, runs, and hangs in normal wait.

This commit is contained in:
Ben Vanik 2013-05-23 18:46:09 -07:00
parent 1b833b6789
commit 12444f6305
9 changed files with 3960 additions and 3887 deletions

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File diff suppressed because it is too large Load Diff

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@ -15,6 +15,8 @@
using namespace xe::cpu;
using namespace xe::cpu::ppc;
using namespace AsmJit;
namespace xe {
namespace cpu {
@ -23,67 +25,67 @@ namespace x64 {
// Floating-point arithmetic (A-8)
XEEMITTER(faddx, 0xFC00002A, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(faddx, 0xFC00002A, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(faddsx, 0xEC00002A, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(faddsx, 0xEC00002A, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fdivx, 0xFC000024, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fdivx, 0xFC000024, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fdivsx, 0xEC000024, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fdivsx, 0xEC000024, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fmulx, 0xFC000032, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fmulx, 0xFC000032, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fmulsx, 0xEC000032, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fmulsx, 0xEC000032, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fresx, 0xEC000030, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fresx, 0xEC000030, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(frsqrtex, 0xFC000034, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(frsqrtex, 0xFC000034, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fsubx, 0xFC000028, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fsubx, 0xFC000028, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fsubsx, 0xEC000028, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fsubsx, 0xEC000028, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fselx, 0xFC00002E, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fselx, 0xFC00002E, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fsqrtx, 0xFC00002C, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fsqrtx, 0xFC00002C, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fsqrtsx, 0xEC00002C, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fsqrtsx, 0xEC00002C, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
@ -91,42 +93,42 @@ XEEMITTER(fsqrtsx, 0xEC00002C, A )(X64Emitter& e, jit_function_t f, InstrD
// Floating-point multiply-add (A-9)
XEEMITTER(fmaddx, 0xFC00003A, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fmaddx, 0xFC00003A, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fmaddsx, 0xEC00003A, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fmaddsx, 0xEC00003A, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fmsubx, 0xFC000038, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fmsubx, 0xFC000038, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fmsubsx, 0xEC000038, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fmsubsx, 0xEC000038, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fnmaddx, 0xFC00003E, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fnmaddx, 0xFC00003E, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fnmaddsx, 0xEC00003E, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fnmaddsx, 0xEC00003E, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fnmsubx, 0xFC00003C, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fnmsubx, 0xFC00003C, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fnmsubsx, 0xEC00003C, A )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fnmsubsx, 0xEC00003C, A )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
@ -134,32 +136,32 @@ XEEMITTER(fnmsubsx, 0xEC00003C, A )(X64Emitter& e, jit_function_t f, InstrD
// Floating-point rounding and conversion (A-10)
XEEMITTER(fcfidx, 0xFC00069C, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fcfidx, 0xFC00069C, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fctidx, 0xFC00065C, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fctidx, 0xFC00065C, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fctidzx, 0xFC00065E, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fctidzx, 0xFC00065E, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fctiwx, 0xFC00001C, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fctiwx, 0xFC00001C, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fctiwzx, 0xFC00001E, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fctiwzx, 0xFC00001E, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(frspx, 0xFC000018, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(frspx, 0xFC000018, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
@ -167,12 +169,12 @@ XEEMITTER(frspx, 0xFC000018, X )(X64Emitter& e, jit_function_t f, InstrD
// Floating-point compare (A-11)
XEEMITTER(fcmpo, 0xFC000040, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fcmpo, 0xFC000040, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fcmpu, 0xFC000000, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fcmpu, 0xFC000000, X )(X64Emitter& e, Compiler& c, InstrData& i) {
// if (FRA) is a NaN or (FRB) is a NaN then
// c <- 0b0001
// else if (FRA) < (FRB) then
@ -193,32 +195,32 @@ XEEMITTER(fcmpu, 0xFC000000, X )(X64Emitter& e, jit_function_t f, InstrD
// Floating-point status and control register (A
XEEMITTER(mcrfs, 0xFC000080, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(mcrfs, 0xFC000080, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(mffsx, 0xFC00048E, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(mffsx, 0xFC00048E, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(mtfsb0x, 0xFC00008C, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(mtfsb0x, 0xFC00008C, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(mtfsb1x, 0xFC00004C, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(mtfsb1x, 0xFC00004C, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(mtfsfx, 0xFC00058E, XFL)(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(mtfsfx, 0xFC00058E, XFL)(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(mtfsfix, 0xFC00010C, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(mtfsfix, 0xFC00010C, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
@ -226,22 +228,22 @@ XEEMITTER(mtfsfix, 0xFC00010C, X )(X64Emitter& e, jit_function_t f, InstrD
// Floating-point move (A-21)
XEEMITTER(fabsx, 0xFC000210, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fabsx, 0xFC000210, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fmrx, 0xFC000090, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fmrx, 0xFC000090, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fnabsx, 0xFC000110, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fnabsx, 0xFC000110, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}
XEEMITTER(fnegx, 0xFC000050, X )(X64Emitter& e, jit_function_t f, InstrData& i) {
XEEMITTER(fnegx, 0xFC000050, X )(X64Emitter& e, Compiler& c, InstrData& i) {
XEINSTRNOTIMPLEMENTED();
return 1;
}

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@ -24,125 +24,125 @@ namespace x64 {
class X64Emitter {
public:
X64Emitter(xe_memory_ref memory, jit_context_t context);
X64Emitter(xe_memory_ref memory);
~X64Emitter();
jit_context_t context();
// jit_context_t context();
int PrepareFunction(sdb::FunctionSymbol* symbol);
int MakeFunction(sdb::FunctionSymbol* symbol, jit_function_t fn);
// int PrepareFunction(sdb::FunctionSymbol* symbol);
// int MakeFunction(sdb::FunctionSymbol* symbol, jit_function_t fn);
sdb::FunctionSymbol* symbol();
jit_function_t fn();
sdb::FunctionBlock* fn_block();
// sdb::FunctionSymbol* symbol();
// jit_function_t fn();
// sdb::FunctionBlock* fn_block();
jit_value_t get_int32(int32_t value);
jit_value_t get_uint32(uint32_t value);
jit_value_t get_int64(int64_t value);
jit_value_t get_uint64(uint64_t value);
jit_value_t make_signed(jit_value_t value);
jit_value_t make_unsigned(jit_value_t value);
jit_value_t sign_extend(jit_value_t value, jit_type_t target_type);
jit_value_t zero_extend(jit_value_t value, jit_type_t target_type);
jit_value_t trunc_to_sbyte(jit_value_t value);
jit_value_t trunc_to_ubyte(jit_value_t value);
jit_value_t trunc_to_short(jit_value_t value);
jit_value_t trunc_to_int(jit_value_t value);
// jit_value_t get_int32(int32_t value);
// jit_value_t get_uint32(uint32_t value);
// jit_value_t get_int64(int64_t value);
// jit_value_t get_uint64(uint64_t value);
// jit_value_t make_signed(jit_value_t value);
// jit_value_t make_unsigned(jit_value_t value);
// jit_value_t sign_extend(jit_value_t value, jit_type_t target_type);
// jit_value_t zero_extend(jit_value_t value, jit_type_t target_type);
// jit_value_t trunc_to_sbyte(jit_value_t value);
// jit_value_t trunc_to_ubyte(jit_value_t value);
// jit_value_t trunc_to_short(jit_value_t value);
// jit_value_t trunc_to_int(jit_value_t value);
int branch_to_block(uint32_t address);
int branch_to_block_if(uint32_t address, jit_value_t value);
int branch_to_block_if_not(uint32_t address, jit_value_t value);
int branch_to_return();
int branch_to_return_if(jit_value_t value);
int branch_to_return_if_not(jit_value_t value);
int call_function(sdb::FunctionSymbol* target_symbol, jit_value_t lr,
bool tail);
// int branch_to_block(uint32_t address);
// int branch_to_block_if(uint32_t address, jit_value_t value);
// int branch_to_block_if_not(uint32_t address, jit_value_t value);
// int branch_to_return();
// int branch_to_return_if(jit_value_t value);
// int branch_to_return_if_not(jit_value_t value);
// int call_function(sdb::FunctionSymbol* target_symbol, jit_value_t lr,
// bool tail);
void TraceBranch(uint32_t cia);
int GenerateIndirectionBranch(uint32_t cia, jit_value_t target,
bool lk, bool likely_local);
// void TraceBranch(uint32_t cia);
// int GenerateIndirectionBranch(uint32_t cia, jit_value_t target,
// bool lk, bool likely_local);
jit_value_t LoadStateValue(size_t offset, jit_type_t type,
const char* name = "");
void StoreStateValue(size_t offset, jit_type_t type, jit_value_t value);
// jit_value_t LoadStateValue(size_t offset, jit_type_t type,
// const char* name = "");
// void StoreStateValue(size_t offset, jit_type_t type, jit_value_t value);
jit_value_t SetupLocal(jit_type_t type, const char* name);
void FillRegisters();
void SpillRegisters();
// jit_value_t SetupLocal(jit_type_t type, const char* name);
// void FillRegisters();
// void SpillRegisters();
jit_value_t xer_value();
void update_xer_value(jit_value_t value);
void update_xer_with_overflow(jit_value_t value);
void update_xer_with_carry(jit_value_t value);
void update_xer_with_overflow_and_carry(jit_value_t value);
// jit_value_t xer_value();
// void update_xer_value(jit_value_t value);
// void update_xer_with_overflow(jit_value_t value);
// void update_xer_with_carry(jit_value_t value);
// void update_xer_with_overflow_and_carry(jit_value_t value);
jit_value_t lr_value();
void update_lr_value(jit_value_t value);
// jit_value_t lr_value();
// void update_lr_value(jit_value_t value);
jit_value_t ctr_value();
void update_ctr_value(jit_value_t value);
// jit_value_t ctr_value();
// void update_ctr_value(jit_value_t value);
jit_value_t cr_value(uint32_t n);
void update_cr_value(uint32_t n, jit_value_t value);
void update_cr_with_cond(uint32_t n, jit_value_t lhs, jit_value_t rhs,
bool is_signed);
// jit_value_t cr_value(uint32_t n);
// void update_cr_value(uint32_t n, jit_value_t value);
// void update_cr_with_cond(uint32_t n, jit_value_t lhs, jit_value_t rhs,
// bool is_signed);
jit_value_t gpr_value(uint32_t n);
void update_gpr_value(uint32_t n, jit_value_t value);
jit_value_t fpr_value(uint32_t n);
void update_fpr_value(uint32_t n, jit_value_t value);
// jit_value_t gpr_value(uint32_t n);
// void update_gpr_value(uint32_t n, jit_value_t value);
// jit_value_t fpr_value(uint32_t n);
// void update_fpr_value(uint32_t n, jit_value_t value);
jit_value_t TouchMemoryAddress(uint32_t cia, jit_value_t addr);
jit_value_t ReadMemory(
uint32_t cia, jit_value_t addr, uint32_t size, bool acquire = false);
void WriteMemory(
uint32_t cia, jit_value_t addr, uint32_t size, jit_value_t value,
bool release = false);
// jit_value_t TouchMemoryAddress(uint32_t cia, jit_value_t addr);
// jit_value_t ReadMemory(
// uint32_t cia, jit_value_t addr, uint32_t size, bool acquire = false);
// void WriteMemory(
// uint32_t cia, jit_value_t addr, uint32_t size, jit_value_t value,
// bool release = false);
private:
int MakeUserFunction();
int MakePresentImportFunction();
int MakeMissingImportFunction();
// int MakeUserFunction();
// int MakePresentImportFunction();
// int MakeMissingImportFunction();
void GenerateBasicBlocks();
void GenerateSharedBlocks();
int PrepareBasicBlock(sdb::FunctionBlock* block);
void GenerateBasicBlock(sdb::FunctionBlock* block);
void SetupLocals();
// void GenerateBasicBlocks();
// void GenerateSharedBlocks();
// int PrepareBasicBlock(sdb::FunctionBlock* block);
// void GenerateBasicBlock(sdb::FunctionBlock* block);
// void SetupLocals();
xe_memory_ref memory_;
jit_context_t context_;
jit_type_t fn_signature_;
jit_type_t shim_signature_;
GlobalExports global_exports_;
jit_type_t global_export_signature_2_;
jit_type_t global_export_signature_3_;
jit_type_t global_export_signature_4_;
sdb::FunctionSymbol* symbol_;
jit_function_t fn_;
sdb::FunctionBlock* fn_block_;
jit_label_t return_block_;
jit_label_t internal_indirection_block_;
jit_label_t external_indirection_block_;
// jit_type_t fn_signature_;
// jit_type_t shim_signature_;
// jit_type_t global_export_signature_2_;
// jit_type_t global_export_signature_3_;
// jit_type_t global_export_signature_4_;
std::map<uint32_t, jit_label_t> bbs_;
// sdb::FunctionSymbol* symbol_;
// jit_function_t fn_;
// sdb::FunctionBlock* fn_block_;
// jit_label_t return_block_;
// jit_label_t internal_indirection_block_;
// jit_label_t external_indirection_block_;
// Address of the instruction being generated.
uint32_t cia_;
// std::map<uint32_t, jit_label_t> bbs_;
ppc::InstrAccessBits access_bits_;
struct {
jit_value_t indirection_target;
jit_value_t indirection_cia;
// // Address of the instruction being generated.
// uint32_t cia_;
jit_value_t xer;
jit_value_t lr;
jit_value_t ctr;
jit_value_t cr[8];
jit_value_t gpr[32];
jit_value_t fpr[32];
} locals_;
// ppc::InstrAccessBits access_bits_;
// struct {
// jit_value_t indirection_target;
// jit_value_t indirection_cia;
// jit_value_t xer;
// jit_value_t lr;
// jit_value_t ctr;
// jit_value_t cr[8];
// jit_value_t gpr[32];
// jit_value_t fpr[32];
// } locals_;
};

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@ -13,44 +13,114 @@
#include <xenia/cpu/exec_module.h>
#include <xenia/cpu/sdb.h>
#include <asmjit/asmjit.h>
using namespace xe;
using namespace xe::cpu;
using namespace xe::cpu::sdb;
using namespace xe::cpu::x64;
using namespace AsmJit;
X64JIT::X64JIT(xe_memory_ref memory, SymbolTable* sym_table) :
JIT(memory, sym_table),
context_(NULL), emitter_(NULL) {
emitter_(NULL) {
}
X64JIT::~X64JIT() {
delete emitter_;
if (context_) {
jit_context_destroy(context_);
}
}
int X64JIT::Setup() {
int result_code = 1;
// Shared libjit context.
context_ = jit_context_create();
XEEXPECTNOTNULL(context_);
XELOGCPU("Initializing x64 JIT backend...");
// Check processor for support.
result_code = CheckProcessor();
if (result_code) {
XELOGE("Processor check failed, aborting...");
}
XEEXPECTZERO(result_code);
// Create the emitter used to generate functions.
emitter_ = new X64Emitter(memory_, context_);
// Inject global functions/variables/etc.
XEEXPECTZERO(InjectGlobals());
emitter_ = new X64Emitter(memory_);
result_code = 0;
XECLEANUP:
return result_code;
}
int X64JIT::InjectGlobals() {
namespace {
struct BitDescription {
uint32_t mask;
const char* description;
};
static const BitDescription x86Features[] = {
{ kX86FeatureRdtsc , "RDTSC" },
{ kX86FeatureRdtscP , "RDTSCP" },
{ kX86FeatureCMov , "CMOV" },
{ kX86FeatureCmpXchg8B , "CMPXCHG8B" },
{ kX86FeatureCmpXchg16B , "CMPXCHG16B" },
{ kX86FeatureClFlush , "CLFLUSH" },
{ kX86FeaturePrefetch , "PREFETCH" },
{ kX86FeatureLahfSahf , "LAHF/SAHF" },
{ kX86FeatureFXSR , "FXSAVE/FXRSTOR" },
{ kX86FeatureFFXSR , "FXSAVE/FXRSTOR Optimizations" },
{ kX86FeatureMmx , "MMX" },
{ kX86FeatureMmxExt , "MMX Extensions" },
{ kX86Feature3dNow , "3dNow!" },
{ kX86Feature3dNowExt , "3dNow! Extensions" },
{ kX86FeatureSse , "SSE" },
{ kX86FeatureSse2 , "SSE2" },
{ kX86FeatureSse3 , "SSE3" },
{ kX86FeatureSsse3 , "SSSE3" },
{ kX86FeatureSse4A , "SSE4A" },
{ kX86FeatureSse41 , "SSE4.1" },
{ kX86FeatureSse42 , "SSE4.2" },
{ kX86FeatureAvx , "AVX" },
{ kX86FeatureMSse , "Misaligned SSE" },
{ kX86FeatureMonitorMWait , "MONITOR/MWAIT" },
{ kX86FeatureMovBE , "MOVBE" },
{ kX86FeaturePopCnt , "POPCNT" },
{ kX86FeatureLzCnt , "LZCNT" },
{ kX86FeaturePclMulDQ , "PCLMULDQ" },
{ kX86FeatureMultiThreading , "Multi-Threading" },
{ kX86FeatureExecuteDisableBit , "Execute-Disable Bit" },
{ kX86Feature64Bit , "64-Bit Processor" },
{ 0, NULL },
};
}
int X64JIT::CheckProcessor() {
const CpuInfo* cpu = CpuInfo::getGlobal();
const X86CpuInfo* x86Cpu = static_cast<const X86CpuInfo*>(cpu);
XELOGCPU("Processor Info:");
XELOGCPU(" Vendor string : %s", cpu->getVendorString());
XELOGCPU(" Brand string : %s", cpu->getBrandString());
XELOGCPU(" Family : %u", cpu->getFamily());
XELOGCPU(" Model : %u", cpu->getModel());
XELOGCPU(" Stepping : %u", cpu->getStepping());
XELOGCPU(" Number of Processors : %u", cpu->getNumberOfProcessors());
XELOGCPU(" Features : 0x%08X", cpu->getFeatures());
XELOGCPU(" Bugs : 0x%08X", cpu->getBugs());
XELOGCPU(" Processor Type : %u", x86Cpu->getProcessorType());
XELOGCPU(" Brand Index : %u", x86Cpu->getBrandIndex());
XELOGCPU(" CL Flush Cache Line : %u", x86Cpu->getFlushCacheLineSize());
XELOGCPU(" Max logical Processors: %u", x86Cpu->getMaxLogicalProcessors());
XELOGCPU(" APIC Physical ID : %u", x86Cpu->getApicPhysicalId());
XELOGCPU(" Features:");
uint32_t mask = cpu->getFeatures();
for (const BitDescription* d = x86Features; d->mask; d++) {
if (mask & d->mask) {
XELOGCPU(" %s", d->description);
}
}
// TODO(benvanik): ensure features we want are supported.
return 0;
}
@ -65,29 +135,29 @@ int X64JIT::UninitModule(ExecModule* module) {
int X64JIT::Execute(xe_ppc_state_t* ppc_state, FunctionSymbol* fn_symbol) {
XELOGCPU("Execute(%.8X): %s...", fn_symbol->start_address, fn_symbol->name());
// Check function.
jit_function_t jit_fn = (jit_function_t)fn_symbol->impl_value;
if (!jit_fn) {
// Function hasn't been prepped yet - prep it.
if (emitter_->PrepareFunction(fn_symbol)) {
XELOGCPU("Execute(%.8X): unable to make function %s",
fn_symbol->start_address, fn_symbol->name());
return 1;
}
jit_fn = (jit_function_t)fn_symbol->impl_value;
XEASSERTNOTNULL(jit_fn);
}
// // Check function.
// jit_function_t jit_fn = (jit_function_t)fn_symbol->impl_value;
// if (!jit_fn) {
// // Function hasn't been prepped yet - prep it.
// if (emitter_->PrepareFunction(fn_symbol)) {
// XELOGCPU("Execute(%.8X): unable to make function %s",
// fn_symbol->start_address, fn_symbol->name());
// return 1;
// }
// jit_fn = (jit_function_t)fn_symbol->impl_value;
// XEASSERTNOTNULL(jit_fn);
// }
// Call into the function. This will compile it if needed.
jit_nuint lr = ppc_state->lr;
void* args[] = {&ppc_state, &lr};
uint64_t return_value;
int apply_result = jit_function_apply(jit_fn, (void**)&args, &return_value);
if (!apply_result) {
XELOGCPU("Execute(%.8X): apply failed with %d",
fn_symbol->start_address, apply_result);
return 1;
}
// // Call into the function. This will compile it if needed.
// jit_nuint lr = ppc_state->lr;
// void* args[] = {&ppc_state, &lr};
// uint64_t return_value;
// int apply_result = jit_function_apply(jit_fn, (void**)&args, &return_value);
// if (!apply_result) {
// XELOGCPU("Execute(%.8X): apply failed with %d",
// fn_symbol->start_address, apply_result);
// return 1;
// }
return 0;
}

View File

@ -17,8 +17,6 @@
#include <xenia/cpu/sdb.h>
#include <xenia/cpu/x64/x64_emitter.h>
#include <jit/jit.h>
namespace xe {
namespace cpu {
@ -39,10 +37,9 @@ public:
sdb::FunctionSymbol* fn_symbol);
protected:
int InjectGlobals();
int CheckProcessor();
jit_context_t context_;
X64Emitter* emitter_;
X64Emitter* emitter_;
};

View File

@ -11,11 +11,13 @@
],
'defines': [
'ASMJIT_X64=',
'ASMJIT_API=',
],
},
'defines': [
'ASMJIT_X64=',
'ASMJIT_API=',
],
'include_dirs': [