/* toy vm register A, B : 32bit PC : program counter mem_ 4byte x 65536 すべての命令は4byte固定 即値は全て16bit R = A or B vldiR, imm ; R = imm vldR, idx ; R = mem_[idx] vstR, idx ; mem_[idx] = R vaddiR, imm ; R += imm vsubiR, imm ; R -= imm vaddR, idx ; R += mem_[idx] vsubR, idx ; R -= mem_[idx] vputR ; print R vjnzR, offset; if (R != 0) then jmp(PC += offset(signed)) */ #if defined(_MSC_VER) && (_MSC_VER <= 1200) #pragma warning(disable:4514) #pragma warning(disable:4786) #endif #include #include #include #include #define XBYAK_NO_OP_NAMES #include "xbyak/xbyak.h" #include "xbyak/xbyak_util.h" #define NUM_OF_ARRAY(x) (sizeof(x) / sizeof(x[0])) #ifdef XBYAK64 #error "only 32bit" #endif using namespace Xbyak; class ToyVm : public Xbyak::CodeGenerator { typedef std::vector Buffer; public: enum Reg { A, B }; enum Code { LD, LDI, ST, ADD, ADDI, SUB, SUBI, PUT, JNZ, END_OF_CODE }; ToyVm() : mark_(0) { ::memset(mem_, 0, sizeof(mem_)); } void vldi(Reg r, uint16 imm) { encode(LDI, r, imm); } void vld(Reg r, uint16 idx) { encode(LD, r, idx); } void vst(Reg r, uint16 idx) { encode(ST, r, idx); } void vadd(Reg r, uint16 idx) { encode(ADD, r, idx); } void vaddi(Reg r, uint16 imm) { encode(ADDI, r, imm); } void vsub(Reg r, uint16 idx) { encode(SUB, r, idx); } void vsubi(Reg r, uint16 imm) { encode(SUBI, r, imm); } void vjnz(Reg r, int offset) { encode(JNZ, r, static_cast(offset)); } void vput(Reg r) { encode(PUT, r); } void setMark() { mark_ = (int)code_.size(); } int getMarkOffset() { return mark_ - (int)code_.size() - 1; } void run() { bool debug = false;//true; uint32 reg[2] = { 0, 0 }; const size_t end = code_.size(); uint32 pc = 0; for (;;) { uint32 x = code_[pc]; uint32 code, r, imm; decode(code, r, imm, x); if (debug) { printf("---\n"); printf("A %08x B %08x\n", reg[0], reg[1]); printf("mem_[] = %08x %08x %08x\n", mem_[0], mem_[1], mem_[2]); printf("pc=%4d, code=%02x, r=%d, imm=%04x\n", pc, code, r, imm); } switch (code) { case LDI: reg[r] = imm; break; case LD: reg[r] = mem_[imm]; break; case ST: mem_[imm] = reg[r]; break; case ADD: reg[r] += mem_[imm]; break; case ADDI: reg[r] += imm; break; case SUB: reg[r] -= mem_[imm]; break; case SUBI: reg[r] -= imm; break; case PUT: printf("%c %8d(0x%08x)\n", 'A' + r, reg[r], reg[r]); break; case JNZ: if (reg[r] != 0) pc += static_cast(imm); break; default: assert(0); break; } pc++; if (pc >= end) break; } // for (;;) } void recompile() { using namespace Xbyak; /* esi : A edi : B ebx : mem_ for speed up mem_[0] : eax mem_[1] : ecx mem_[2] : edx */ push(ebx); push(esi); push(edi); const Reg32 reg[2] = { esi, edi }; const Reg32 mem(ebx); const Reg32 memTbl[] = { eax, ecx, edx }; const size_t memTblNum = NUM_OF_ARRAY(memTbl); for (size_t i = 0; i < memTblNum; i++) xor_(memTbl[i], memTbl[i]); xor_(esi, esi); xor_(edi, edi); mov(mem, (size_t)mem_); const size_t end = code_.size(); uint32 pc = 0; uint32 labelNum = 0; for (;;) { uint32 x = code_[pc]; uint32 code, r, imm; decode(code, r, imm, x); L(Label::toStr(labelNum++)); switch (code) { case LDI: mov(reg[r], imm); break; case LD: if (imm < memTblNum) { mov(reg[r], memTbl[imm]); } else { mov(reg[r], ptr[mem + imm * 4]); } break; case ST: if (imm < memTblNum) { mov(memTbl[imm], reg[r]); } else { mov(ptr [mem + imm * 4], reg[r]); } break; case ADD: if (imm < memTblNum) { add(reg[r], memTbl[imm]); } else { add(reg[r], ptr [mem + imm * 4]); } break; case ADDI: add(reg[r], imm); break; case SUB: if (imm < memTblNum) { sub(reg[r], memTbl[imm]); } else { sub(reg[r], ptr [mem + imm * 4]); } break; case SUBI: sub(reg[r], imm); break; case PUT: { static const char *str = "%c %8d(0x%08x)\n"; push(eax); push(edx); push(ecx); push(reg[r]); push(reg[r]); push('A' + r); push((int)str); call(Xbyak::CastTo(printf)); add(esp, 4 * 4); pop(ecx); pop(edx); pop(eax); } break; case JNZ: test(reg[r], reg[r]); jnz(Label::toStr(labelNum + static_cast(imm))); break; default: assert(0); break; } pc++; if (pc >= end) break; } // for (;;) pop(edi); pop(esi); pop(ebx); ret(); } private: uint32 mem_[65536]; Buffer code_; int mark_; void decode(uint32& code, uint32& r, uint32& imm, uint32 x) { code = x >> 24; r = (x >> 16) & 0xff; imm = x & 0xffff; } void encode(Code code, Reg r, uint16 imm = 0) { uint32 x = (code << 24) | (r << 16) | imm; code_.push_back(x); } }; class Fib : public ToyVm { public: Fib(int n) { if (n >= 65536) { fprintf(stderr, "current version support only imm16\n"); return; } /* A : c B : temporary mem_[0] : p mem_[1] : t mem_[2] : n */ vldi(A, 1); // c vst(A, 0); // p(1) vldi(B, static_cast(n)); vst(B, 2); // n // lp setMark(); vst(A, 1); // t = c vadd(A, 0); // c += p vld(B, 1); vst(B, 0); // p = t // vput(A); vld(B, 2); vsubi(B, 1); vst(B, 2); // n-- vjnz(B, getMarkOffset()); vput(A); } void runByJIT() { getCode(); } }; void fibC(uint32 n) { uint32 p, c, t; p = 1; c = 1; lp: t = c; c += p; p = t; n--; if (n != 0) goto lp; printf("c=%d(0x%08x)\n", c, c); } int main() { try { const int n = 10000; Fib fib(n); fib.recompile(); { Xbyak::util::Clock clk; clk.begin(); fib.run(); clk.end(); printf("vm %.2fKclk\n", clk.getClock() * 1e-3); } { Xbyak::util::Clock clk; clk.begin(); fib.runByJIT(); clk.end(); printf("jit %.2fKclk\n", clk.getClock() * 1e-3); } { Xbyak::util::Clock clk; clk.begin(); fibC(n); clk.end(); printf("native C %.2fKclk\n", clk.getClock() * 1e-3); } } catch (std::exception& e) { printf("ERR:%s\n", e.what()); } catch (...) { printf("unknown error\n"); } return 0; } /* the code generated by Xbyak push ebx push esi push edi xor eax,eax xor ecx,ecx xor edx,edx xor esi,esi xor edi,edi mov ebx,0EFF58h mov esi,1 mov eax,esi mov edi,2710h mov edx,edi .lp: mov ecx,esi add esi,eax mov edi,ecx mov eax,edi mov edi,edx sub edi,1 mov edx,edi test edi,edi jne .lp push eax push edx push ecx push esi push esi push 41h push 42C434h call printf (409342h) add esp,10h pop ecx pop edx pop eax pop edi pop esi pop ebx ret */