#!/usr/bin/env python
# Moshe Kravchik
from __future__ import print_function
from unicorn import *
from unicorn.arm_const import *
import binascii
import regress
# code to be emulated
#enable VFP
'''
00000016 f44f0370 mov.w r3, #0xf00000
0000001a ee013f50 mcr p15, #0x0, r3, c1, c0, #0x2
0000bfb6 f3bf8f6f isb sy
0000bfba f04f4380 mov.w r3, #0x40000000
0000bfbe eee83a10 vmsr fpexc, r3
'''
ENABLE_VFP_CODE = "\x4f\xf4\x70\x03\x01\xee\x50\x3f\xbf\xf3\x6f\x8f\x4f\xf0\x80\x43\xe8\xee\x10\x3a"
VLD_CODE = "\x21\xf9\x0f\x6a"
#0000002a f9216a0f vld1.8 {d6, d7}, [r1]
VST_CODE = "\x00\xf9\x0f\x6a"
#0000002e f9006a0f vst1.8 {d6, d7}, [r0]
# memory address where emulation starts
ADDRESS = 0x10000
SCRATCH_ADDRESS = 0x1000
class SIMDNotReadArm(regress.RegressTest):
def runTest(self):
code = ENABLE_VFP_CODE+VLD_CODE+VST_CODE
print("Emulate THUMB code")
try:
# Initialize emulator in thumb mode
mu = Uc(UC_ARCH_ARM, UC_MODE_THUMB)
# map 2MB memory for this emulation
mu.mem_map(ADDRESS, 2 * 1024 * 1024)
# write machine code to be emulated to memory
mu.mem_write(ADDRESS, code)
# map 10K scratch memory for this emulation
mu.mem_map(SCRATCH_ADDRESS, 10 * 1024)
# write dummy data to be emulated to memory
mu.mem_write(SCRATCH_ADDRESS, "\x01"*64)
# initialize machine registers
for i in range(UC_ARM_REG_R0, UC_ARM_REG_R12):
val = mu.reg_write(i, i - UC_ARM_REG_R0)
mu.reg_write(UC_ARM_REG_R1, SCRATCH_ADDRESS)
mu.reg_write(UC_ARM_REG_R0, SCRATCH_ADDRESS + 0x100)
mu.reg_write(UC_ARM_REG_SP, 0x1234)
mu.reg_write(UC_ARM_REG_D6, UC_ARM_REG_D6)
mu.reg_write(UC_ARM_REG_D7, UC_ARM_REG_D7)
print(">>> Before emulation ")
print("\tD6 = 0x%x" % mu.reg_read(UC_ARM_REG_D6))
print("\tD7 = 0x%x" % mu.reg_read(UC_ARM_REG_D7))
for i in range(UC_ARM_REG_R0, UC_ARM_REG_R12):
val = mu.reg_read(i)
print("\t %s = 0x%x" % ("R" + str(i-UC_ARM_REG_R0),val))
self.assertEqual(UC_ARM_REG_D6, mu.reg_read(UC_ARM_REG_D6))
self.assertEqual(UC_ARM_REG_D7, mu.reg_read(UC_ARM_REG_D7))
try:
content = mu.mem_read(SCRATCH_ADDRESS, 100)
print("Memory at addr 0x%X %s" % (SCRATCH_ADDRESS, binascii.hexlify(content)))
content = mu.mem_read(SCRATCH_ADDRESS+0x100, 100)
print("Memory at addr 0x%X %s" % (SCRATCH_ADDRESS+0x100, binascii.hexlify(content)))
except Exception, errtxt:
print (errtxt)
# emulate machine code in infinite time
mu.emu_start(ADDRESS, ADDRESS + len(code))
# now print out some registers
print(">>> Emulation done. Below is the CPU context")
sp = mu.reg_read(UC_ARM_REG_SP)
print(">>> SP = 0x%x" %sp)
val = mu.reg_read(UC_ARM_REG_PC)
print(">>> PC = 0x%x" %val)
for i in range(UC_ARM_REG_R0, UC_ARM_REG_R12):
val = mu.reg_read(i)
print(">>> %s = 0x%x" % ("R" + str(i-UC_ARM_REG_R0),val))
print("\tD6 = 0x%x" % mu.reg_read(UC_ARM_REG_D6))
print("\tD7 = 0x%x" % mu.reg_read(UC_ARM_REG_D7))
try:
content = mu.mem_read(SCRATCH_ADDRESS, 100)
print("Memory at addr 0x%X %s" % (SCRATCH_ADDRESS, binascii.hexlify(content)))
content = mu.mem_read(SCRATCH_ADDRESS+0x100, 100)
print("Memory at addr 0x%X %s" % (SCRATCH_ADDRESS+0x100, binascii.hexlify(content)))
except Exception, errtxt:
print (errtxt)
self.assertEqual(mu.reg_read(UC_ARM_REG_D6), 0x0101010101010101)
self.assertEqual(mu.reg_read(UC_ARM_REG_D7), 0x0101010101010101)
except UcError as e:
print("ERROR: %s" % e)
if __name__ == '__main__':
regress.main()