RandomWOW/tests/rx2c.py

import random
import sys
import os

PROGRAM_SIZE = 512
INSTRUCTION_COUNT = 1024 * 1024
INSTRUCTION_WEIGHTS = [
    ("ADD_64", 16),
    ("ADD_32", 8),
    ("SUB_64", 16),
    ("SUB_32", 8),
    ("MUL_64", 7),
    ("MULH_64", 7),
    ("MUL_32", 7),
    ("IMUL_32", 7),
    ("IMULH_64", 7),
    ("DIV_64", 1),
    ("IDIV_64", 1),
    ("AND_64", 4),
    ("AND_32", 3),
    ("OR_64", 4),
    ("OR_32", 3),
    ("XOR_64", 4),
    ("XOR_32", 3),
    ("SHL_64", 6),
    ("SHR_64", 6),
    ("SAR_64", 6),
    ("ROL_64", 9),
    ("ROR_64", 9),
    ("FADD", 22),
    ("FSUB", 22),
    ("FMUL", 22),
    ("FDIV", 8),
    ("FSQRT", 6),
    ("FROUND", 2),
    ("CALL", 17),
    ("RET", 15),
]
        
def genBytes(count):
    return ', '.join(str(random.getrandbits(8)) for i in range(count))
        
class OperandType:
    INT32 = 0
    UINT32 = 1
    INT64 = 2
    UINT64 = 3
    FLOAT = 4
    SHIFT = 5

def declareType(type):
    converters = {
        0: "int32_t",
        1: "uint32_t",
        2: "int64_t",
        3: "uint64_t",
        4: "double",
        5: "int32_t"
    }
    return converters.get(type)
    
def toSigned32(x):
    return x - ((x & 0x80000000) << 1)
    
def toSigned64(x):
    return x - ((x & 0x8000000000000000) << 1)

def immediateTo(symbol, type):
    converters = {
        0: toSigned32(symbol.imm1),
        1: symbol.imm1,
        2: toSigned32(symbol.imm1),
        3: symbol.imm1,
        4: float(toSigned32(symbol.imm1) << 32),
        5: symbol.imm0 & 63
    }
    return repr(converters.get(type))
    
def registerTo(expr, type):
    converters = {
        0: "(int64_t){0}",
        1: "{0}",
        2: "(int64_t){0}",
        3: "{0}",
        4: "{0}",
        5: "({0} & 63)"
    }
    return converters.get(type).format(expr)
    
def registerFrom(num, type):
    converters = {
        0: "r{0}",
        1: "r{0}",
        2: "r{0}",
        3: "r{0}",
        4: "((convertible_t)f{0}).u64",
        5: "r{0}"
    }
    return converters.get(type).format(num)
    
def convertibleTo(expr, type):
    converters = {
        0: "{0}.i32",
        1: "{0}.u32",
        2: "{0}.i64",
        3: "{0}.u64",
        4: "(double){0}.i64",
        5: "({0}.u64 & 63)"
    }
    return converters.get(type).format(expr)
    
def convertibleFrom(expr, type):
    converters = {
        0: "{0}.i32",
        1: "{0}.u32",
        2: "{0}.i64",
        3: "{0}.u64",
        4: "{0}.f64",
        5: "({0}.u64 & 63)"
    }
    return converters.get(type).format(expr)

def getRegister(num, type):
    registers = {
        0: "r{0}",
        1: "r{0}",
        2: "r{0}",
        3: "r{0}",
        4: "f{0}",
        5: "r{0}"
    }
    return registers.get(type).format(num)

def writeInitialValues(file):
    file.write("#ifdef RAM\n")
    file.write("\tmmu.buffer = (char*)_mm_malloc(DRAM_SIZE, 16);\n")
    file.write("\tif(!mmu.buffer) {\n")
    file.write('\t\tprintf("DRAM buffer allocation failed\\n");\n')
    file.write("\t\treturn 1;\n")
    file.write("\t}\n")
    file.write('\tprintf("Initializing DRAM buffer...\\n");\n')
    file.write("\taesInitialize((__m128i*)aesKey, (__m128i*)aesSeed, (__m128i*)mmu.buffer, DRAM_SIZE);\n")
    file.write("#endif\n")
    file.write("\tclock_t clockStart = clock(), clockEnd;\n")
    for i in range(8):
        file.write("\tr{0} = *(uint64_t*)(aesSeed + {1});\n".format(i, i * 8))
    for i in range(8):
        file.write("\tf{0} = *(int64_t*)(aesSeed + {1});\n".format(i, 64 + i * 8))
    file.write("\taesInitialize((__m128i*)aesKey, (__m128i*)aesSeed, (__m128i*)scratchpad, SCRATCHPAD_SIZE);\n")
    file.write("\tmmu.ma = *(addr_t*)(aesKey + 8) & ~7U;\n")
    file.write("#ifdef PRNTADDR\n")
    file.write('\tprintf("DRAM address = %#010x\\n", mmu.ma);\n')
    file.write("#endif\n")
    file.write("\tmmu.mx = 0;\n")
    file.write("\tsp = 0;\n")
    file.write("\tic = {0};\n".format(INSTRUCTION_COUNT))
    file.write("\tmxcsr = (_mm_getcsr() | _MM_FLUSH_ZERO_ON) & ~_MM_ROUND_MASK; //flush denormals to zero, round to nearest\n")
    file.write("\t_mm_setcsr(mxcsr);\n")
    
def writeEpilog(file):
    file.write("\tend:\n")
    file.write("\t\tclockEnd = clock();\n")
    for i in range(8):
        file.write('\t\tprintf("r{0} = %-36" PRIu64 " f{0} = %g\\n", r{0}, f{0});\n'.format(i))
    file.write(("\t\tuint64_t spadsum = 0;\n"
        "\t\tfor(int i = 0; i < SCRATCHPAD_LENGTH; ++i) {\n"
        "\t\t	spadsum += scratchpad[i].u64;\n"
        "\t\t}\n"
        '\t\tprintf("scratchpad sum = %" PRIu64 "\\n", spadsum);\n'
        '\t\tprintf("runtime: %f\\n", (clockEnd - clockStart) / (double)CLOCKS_PER_SEC);\n'
        "#ifdef RAM\n"
        "\t\t_mm_free((void*)mmu.buffer);\n"
        "#endif\n"))
    file.write("\t\treturn 0;")
    file.write("}")

def writeCommon(file, i, symbol, type, name):
    file.write("\ti_{0}: {{ //{1}\n".format(i, name))
    file.write("\t\tif(0 == ic--) goto end;\n")
    file.write("\t\tr{0} ^= {1};\n".format(symbol.rega, symbol.addr0))
    file.write("\t\taddr_t addr = r{0};\n".format(symbol.rega))

def readA(symbol, type):
    location = {
        0: "readDram(&mmu, addr)",
        1: "readDram(&mmu, addr)",
        2: "readDram(&mmu, addr)",
        3: "readDram(&mmu, addr)",
        4: "SCRATCHPAD_256K(addr)",
        5: "SCRATCHPAD_16K(addr)",
        6: "SCRATCHPAD_16K(addr)",
        7: "SCRATCHPAD_16K(addr)",
    }
    return convertibleTo(location.get(symbol.loca), type)

def writeC(symbol, type):
    location = {
        0: "SCRATCHPAD_256K(r{0} ^ {1})",
        1: "SCRATCHPAD_16K(r{0} ^ {1})",
        2: "SCRATCHPAD_16K(r{0} ^ {1})",
        3: "SCRATCHPAD_16K(r{0} ^ {1})",
        4: "",
        5: "",
        6: "",
        7: ""
    }
    c = location.get(symbol.locc)
    if c == "":
        c = getRegister(symbol.regc, type)
    else:
        c = convertibleFrom(c.format(symbol.regc, symbol.addr1), type)
    return c

def readB(symbol, type):
    if symbol.locb < 6:
        return registerTo(getRegister(symbol.regb, type), type)
    else:
        return immediateTo(symbol, type)

class CodeSymbol:
    def __init__(self, qi):
        self.opcode = qi & 255
        self.loca = (qi >> 8) & 7
        self.rega = (qi >> 16) & 7
        self.locb = (qi >> 24) & 7
        self.regb = (qi >> 32) & 7
        self.locc = (qi >> 40) & 7
        self.regc = (qi >> 48) & 7
        self.imm0 = (qi >> 56) & 255
        self.addr0 = (qi >> 64) & 0xFFFFFFFF
        self.addr1 = self.imm1 = qi >> 96

def writeOperation(file, i, symbol, type, name, op):
    writeCommon(file, i, symbol, type, name)
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(type), readB(symbol, type)))
    file.write("\t\t{0} = A {1} B; }}\n".format(writeC(symbol, type), op))

def write_ADD_64(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT64, 'ADD_64', '+');

def write_ADD_32(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT32, 'ADD_32', '+');

def write_SUB_64(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT64, 'SUB_64', '-');

def write_SUB_32(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT32, 'SUB_32', '-');

def write_MUL_64(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT64, 'MUL_64', '*');

def write_MULH_64(file, i, symbol):
    type = OperandType.UINT64
    writeCommon(file, i, symbol, type, 'MULH_64')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(type), readB(symbol, type)))
    file.write("\t\t{0} = ((uint128_t)A * B) >> 64; }}\n".format(writeC(symbol, type)))

def write_MUL_32(file, i, symbol):
    type = OperandType.UINT32
    writeCommon(file, i, symbol, type, 'MUL_32')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(type), readB(symbol, type)))
    file.write("\t\t{0} = (uint64_t)A * B; }}\n".format(writeC(symbol, OperandType.UINT64)))

def write_IMUL_32(file, i, symbol):
    type = OperandType.INT32
    writeCommon(file, i, symbol, type, 'IMUL_32')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(type), readB(symbol, type)))
    file.write("\t\t{0} = (int64_t)A * B; }}\n".format(writeC(symbol, OperandType.INT64)))

def write_IMULH_64(file, i, symbol):
    type = OperandType.INT64
    writeCommon(file, i, symbol, type, 'IMULH_64')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(type), readB(symbol, type)))
    file.write("\t\t{0} = ((int128_t)A * B) >> 64; }}\n".format(writeC(symbol, type)))

def write_DIV_64(file, i, symbol):
    type = OperandType.UINT64
    writeCommon(file, i, symbol, type, 'DIV_64')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(OperandType.UINT32), readB(symbol, OperandType.UINT32)))
    file.write("\t\tif(B == 0) B = 1;\n".format(declareType(type), readB(symbol, type)))
    file.write("\t\t{0} = A / B; }}\n".format(writeC(symbol, type)))

def write_IDIV_64(file, i, symbol):
    type = OperandType.INT64
    writeCommon(file, i, symbol, type, 'IDIV_64')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(OperandType.INT32), readB(symbol, OperandType.INT32)))
    file.write("\t\tif(B == 0) B = 1;\n".format(declareType(type), readB(symbol, type)))
    file.write("\t\t{0} = A / B; }}\n".format(writeC(symbol, type)))

def write_AND_64(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT64, 'AND_64', '&');

def write_AND_32(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT32, 'AND_32', '&');

def write_OR_64(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT64, 'OR_64', '|');

def write_OR_32(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT32, 'OR_32', '|');

def write_XOR_64(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT64, 'XOR_64', '^');

def write_XOR_32(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.UINT32, 'XOR_32', '^');

def write_SHL_64(file, i, symbol):
    type = OperandType.UINT64
    writeCommon(file, i, symbol, type, 'SHL_64')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(OperandType.SHIFT), readB(symbol, OperandType.SHIFT)))
    file.write("\t\t{0} = A << B; }}\n".format(writeC(symbol, type)))

def write_SHR_64(file, i, symbol):
    type = OperandType.UINT64
    writeCommon(file, i, symbol, type, 'SHR_64')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(OperandType.SHIFT), readB(symbol, OperandType.SHIFT)))
    file.write("\t\t{0} = A >> B; }}\n".format(writeC(symbol, type)))

def write_SAR_64(file, i, symbol):
    type = OperandType.INT64
    writeCommon(file, i, symbol, type, 'SAR_64')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(OperandType.SHIFT), readB(symbol, OperandType.SHIFT)))
    file.write("\t\t{0} = A >> B; }}\n".format(writeC(symbol, type)))

def write_ROL_64(file, i, symbol):
    type = OperandType.UINT64
    writeCommon(file, i, symbol, type, 'ROL_64')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(OperandType.SHIFT), readB(symbol, OperandType.SHIFT)))
    file.write("\t\t{0} = __rolq(A, B); }}\n".format(writeC(symbol, type)))

def write_ROR_64(file, i, symbol):
    type = OperandType.UINT64
    writeCommon(file, i, symbol, type, 'ROR_64')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} B = {1};\n".format(declareType(OperandType.SHIFT), readB(symbol, OperandType.SHIFT)))
    file.write("\t\t{0} = __rorq(A, B); }}\n".format(writeC(symbol, type)))

def write_FADD(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.FLOAT, 'FADD', '+');

def write_FSUB(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.FLOAT, 'FSUB', '-');

def write_FMUL(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.FLOAT, 'FMUL', '*');

def write_FDIV(file, i, symbol):
    writeOperation(file, i, symbol, OperandType.FLOAT, 'FDIV', '/');

def write_FSQRT(file, i, symbol):
    type = OperandType.FLOAT
    writeCommon(file, i, symbol, type, 'FSQRT')
    file.write("\t\t{0} A = fabs({1});\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\t{0} = _mm_cvtsd_f64(_mm_sqrt_sd(_mm_setzero_pd(), _mm_load_pd(&A))); }}\n".format(writeC(symbol, type)))

def write_FROUND(file, i, symbol):
    type = OperandType.FLOAT
    writeCommon(file, i, symbol, type, 'FROUND')
    file.write("\t\t{0} A = {1};\n".format(declareType(OperandType.INT64), readA(symbol, OperandType.INT64)))
    file.write("\t\t{0} = A;\n".format(writeC(symbol, type)))
    file.write("\t\t_mm_setcsr(mxcsr | ((uint32_t)(A << 13) & _MM_ROUND_MASK)); }\n")

def write_CALL(file, i, symbol):
    type = OperandType.UINT64
    writeCommon(file, i, symbol, type, 'CALL')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    if symbol.locb < 6:
        file.write("\t\tif((uint32_t)r{0} <= {1}) {{\n".format(symbol.regb, symbol.imm1))
    file.write("\t\t\tPUSH_VALUE(A);\n");
    file.write("\t\t\tPUSH_ADDRESS(&&i_{0});\n".format((i + 1) & (PROGRAM_SIZE - 1)));
    file.write("\t\t\tgoto i_{0};\n".format((i + 1 + (symbol.imm0 & ((PROGRAM_SIZE >> 2) - 1))) & (PROGRAM_SIZE - 1)));
    if symbol.locb < 6:
        file.write("\t\t}}\n\t\t{0} = A;".format(writeC(symbol, type)))
    file.write("\t\t}\n")

def write_RET(file, i, symbol):
    type = OperandType.UINT64
    writeCommon(file, i, symbol, type, 'RET')
    file.write("\t\t{0} A = {1};\n".format(declareType(type), readA(symbol, type)))
    file.write("\t\tif(!STACK_IS_EMPTY()")
    if symbol.locb < 6:
        file.write(" && (uint32_t)r{0} <= {1}".format(symbol.regb, symbol.imm1))
    file.write(") {\n")
    file.write("\t\t\tvoid* target = POP_ADDRESS();\n")
    file.write("\t\t\tuint64_t C = POP_VALUE();\n")
    file.write("\t\t\t{0} = A ^ C;\n".format(writeC(symbol, type)))
    file.write("\t\t\tgoto *target;\n")
    file.write("\t\t}}\n\t\t{0} = A; }}\n".format(writeC(symbol, type)))

opcodeMap = { }

def buildOpcodeMap():
    functions = globals()
    totalWeight = 0;
    for instruction, weight in INSTRUCTION_WEIGHTS:
        func = functions['write_' + instruction]
        for i in range(weight):
            opcodeMap[totalWeight] = func
            totalWeight = totalWeight + 1
    assert totalWeight == 256

def writeCode(file, i, symbol):
    opcodeMap.get(symbol.opcode)(file, i, symbol)

def writeMain(file):
    file.write(('__attribute__((optimize("Os"))) int main() {\n'
                "	register uint64_t r0, r1, r2, r3, r4, r5, r6, r7;\n"
                "	register double f0, f1, f2, f3, f4, f5, f6, f7;\n"
                "	register uint64_t ic, sp;\n"
                "	stack_t stack[STACK_LENGTH];\n"
                "	convertible_t scratchpad[SCRATCHPAD_LENGTH] __attribute__ ((aligned (16)));\n"
                "	mmu_t mmu;\n"
                "	uint32_t mxcsr;\n"
                ))

def writeProlog(file):
    file.write(("#include <stdint.h>\n"
                "#include <time.h>\n"
                "#include <stdio.h>\n"
                "#include <x86intrin.h>\n"
                "#include <emmintrin.h>\n"
                "#include <wmmintrin.h>\n"
                "#include <math.h>\n"
                "#include <inttypes.h>\n"
                "typedef uint32_t addr_t;\n"
                "typedef unsigned __int128 uint128_t;\n"
                "typedef __int128 int128_t;\n"
                "typedef unsigned char byte;\n"
                "typedef union {\n"
                "	double f64;\n"
                "	int64_t i64;\n"
                "	uint64_t u64;\n"
                "	int32_t i32;\n"
                "	uint32_t u32;\n"
                "} convertible_t;\n"
                "typedef union {\n"
                "	uint64_t value;\n"
                "	void* address;\n"
                "} stack_t;\n"
                "typedef struct {\n"
                "	addr_t ma;\n"
                "	addr_t mx;\n"
                "#ifdef RAM\n"
                "	const char* buffer;\n"
                "#endif\n"
                "} mmu_t;\n"
                "#define DRAM_SIZE (1ULL << 32)\n"
                "#define SCRATCHPAD_SIZE (256 * 1024)\n"
                "#define SCRATCHPAD_LENGTH (SCRATCHPAD_SIZE / sizeof(convertible_t))\n"
                "#define SCRATCHPAD_MASK14 (16 * 1024 / sizeof(convertible_t) - 1)\n"
                "#define SCRATCHPAD_MASK18 (SCRATCHPAD_LENGTH - 1)\n"
                "#define SCRATCHPAD_16K(x) scratchpad[(x) & SCRATCHPAD_MASK14]\n"
                "#define SCRATCHPAD_256K(x) scratchpad[(x) & SCRATCHPAD_MASK18]\n"
                "#define STACK_LENGTH (128 * 1024)\n"
                "#ifdef RAM\n"
                "#define DRAM_READ(mmu) (convertible_t)*(uint64_t*)((mmu)->buffer + (mmu)->ma)\n"
                "#define PREFETCH(mmu) _mm_prefetch(((mmu)->buffer + (mmu)->ma), _MM_HINT_T0)\n"
                "#else\n"
                "#define DRAM_READ(mmu) (convertible_t)(uint64_t)__rolq(6364136223846793005ULL*((mmu)->ma)+1442695040888963407ULL,32)\n"
                "#define PREFETCH(mmu)\n"
                "#endif\n"
                "#define PUSH_VALUE(x) stack[sp++].value = x\n"
                "#define PUSH_ADDRESS(x) stack[sp++].address = x\n"
                "#define STACK_IS_EMPTY() (sp == 0)\n"
                "#define POP_VALUE() stack[--sp].value\n"
                "#define POP_ADDRESS() stack[--sp].address\n"
                "static convertible_t readDram(mmu_t* mmu, addr_t addr) {\n"
                "	convertible_t data;\n"
                "	data = DRAM_READ(mmu);\n"
                "	mmu->ma += 8;\n"
                "	mmu->mx ^= addr;\n"
                "	if((mmu->mx & 0x1FFF) == 0) {\n"
                "#ifdef PRNTADDR\n"
                '		printf("DRAM jump %#010x -> %#010x\\n", mmu->ma, mmu->mx);\n'
                "#endif\n"
                "		mmu->ma = mmu->mx;\n"
                "#ifdef PREF\n"
                "		PREFETCH(mmu);\n"
                "#endif\n"
                "	}\n"
                "	return data;\n"
                "}\n"
                "static inline __m128i sl_xor(__m128i tmp1) {\n"
                "	__m128i tmp4;\n"
                "	tmp4 = _mm_slli_si128(tmp1, 0x04);\n"
                "	tmp1 = _mm_xor_si128(tmp1, tmp4);\n"
                "	tmp4 = _mm_slli_si128(tmp4, 0x04);\n"
                "	tmp1 = _mm_xor_si128(tmp1, tmp4);\n"
                "	tmp4 = _mm_slli_si128(tmp4, 0x04);\n"
                "	tmp1 = _mm_xor_si128(tmp1, tmp4);\n"
                "	return tmp1;\n"
                "}\n"
                "#define AES_GENKEY_SUB(rcon) do { \\\n"
                "	__m128i xout1 = _mm_aeskeygenassist_si128(xout2, rcon);	\\\n"
                "	xout1 = _mm_shuffle_epi32(xout1, 0xFF);	\\\n"
                "	xout0 = sl_xor(xout0);  \\\n"
                "	xout0 = _mm_xor_si128(xout0, xout1); \\\n"
                "	xout1 = _mm_aeskeygenassist_si128(xout0, 0x00); \\\n"
                "	xout1 = _mm_shuffle_epi32(xout1, 0xAA); \\\n"
                "	xout2 = sl_xor(xout2); \\\n"
                "	xout2 = _mm_xor_si128(xout2, xout1); } while(0)\n"
                "static inline void aes_genkey(const __m128i* memory, __m128i* k0, __m128i* k1, __m128i* k2, __m128i* k3, __m128i* k4, __m128i* k5, __m128i* k6, __m128i* k7, __m128i* k8, __m128i* k9) {\n"
                "	__m128i xout0, xout2;\n"
                "	xout0 = _mm_load_si128(memory);\n"
                "	xout2 = _mm_load_si128(memory+1);\n"
                "	*k0 = xout0;\n"
                "	*k1 = xout2;\n"
                "	AES_GENKEY_SUB(0x01);\n"
                "	*k2 = xout0;\n"
                "	*k3 = xout2;\n"
                "	AES_GENKEY_SUB(0x02);\n"
                "	*k4 = xout0;\n"
                "	*k5 = xout2;\n"
                "	AES_GENKEY_SUB(0x04);\n"
                "	*k6 = xout0;\n"
                "	*k7 = xout2;\n"
                "	AES_GENKEY_SUB(0x08);\n"
                "	*k8 = xout0;\n"
                "	*k9 = xout2;\n"
                "}\n"
                "static inline void aes_round(__m128i key, __m128i* x0, __m128i* x1, __m128i* x2, __m128i* x3, __m128i* x4, __m128i* x5, __m128i* x6, __m128i* x7) {\n"
                "	*x0 = _mm_aesenc_si128(*x0, key);\n"
                "	*x1 = _mm_aesenc_si128(*x1, key);\n"
                "	*x2 = _mm_aesenc_si128(*x2, key);\n"
                "	*x3 = _mm_aesenc_si128(*x3, key);\n"
                "	*x4 = _mm_aesenc_si128(*x4, key);\n"
                "	*x5 = _mm_aesenc_si128(*x5, key);\n"
                "	*x6 = _mm_aesenc_si128(*x6, key);\n"
                "	*x7 = _mm_aesenc_si128(*x7, key);\n"
                "}\n"
                "static void aesInitialize(__m128i* key, __m128i* seed, __m128i* output, size_t count) {\n"
                "	\n"
                "	__m128i xin0, xin1, xin2, xin3, xin4, xin5, xin6, xin7;\n"
                "	__m128i k0, k1, k2, k3, k4, k5, k6, k7, k8, k9;\n"
                "	\n"
                "	aes_genkey(key, &k0, &k1, &k2, &k3, &k4, &k5, &k6, &k7, &k8, &k9);\n"
                "	\n"
                "	xin0 = _mm_load_si128(seed + 0);\n"
                "	xin1 = _mm_load_si128(seed + 1);\n"
                "	xin2 = _mm_load_si128(seed + 2);\n"
                "	xin3 = _mm_load_si128(seed + 3);\n"
                "	xin4 = _mm_load_si128(seed + 4);\n"
                "	xin5 = _mm_load_si128(seed + 5);\n"
                "	xin6 = _mm_load_si128(seed + 6);\n"
                "	xin7 = _mm_load_si128(seed + 7);\n"
                "	\n"
                "	for (size_t i = 0; i < count / sizeof(__m128i); i += 8)\n"
                "	{\n"
                "		aes_round(k0, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		aes_round(k1, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		aes_round(k2, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		aes_round(k3, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		aes_round(k4, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		aes_round(k5, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		aes_round(k6, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		aes_round(k7, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		aes_round(k8, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		aes_round(k9, &xin0, &xin1, &xin2, &xin3, &xin4, &xin5, &xin6, &xin7);\n"
                "		\n"
                "		_mm_store_si128(output + i + 0, xin0);\n"
                "		_mm_store_si128(output + i + 1, xin1);\n"
                "		_mm_store_si128(output + i + 2, xin2);\n"
                "		_mm_store_si128(output + i + 3, xin3);\n"
                "		_mm_store_si128(output + i + 4, xin4);\n"
                "		_mm_store_si128(output + i + 5, xin5);\n"
                "		_mm_store_si128(output + i + 6, xin6);\n"
                "		_mm_store_si128(output + i + 7, xin7);\n"
                "	}\n"
                "}\n"))

with sys.stdout as file:
    buildOpcodeMap()
    writeProlog(file)
    file.write("const byte aesKey[32] = {{ {0} }};\n".format(genBytes(32)))
    file.write("const byte aesSeed[128] = {{ {0} }};\n".format(genBytes(128)))
    writeMain(file)
    writeInitialValues(file)
    for i in range(PROGRAM_SIZE):
        writeCode(file, i, CodeSymbol(random.getrandbits(128)))
    if PROGRAM_SIZE > 0:
        file.write("\t\tgoto i_0;\n")
    writeEpilog(file)