//: Core data structures for simulating the SubX VM (subset of an x86 processor)
//:
//: At the lowest level ("level 1") of abstraction, SubX executes x86
//: instructions provided in the form of an array of bytes, loaded into memory
//: starting at a specific address.
//:: registers
//: assume segment registers are hard-coded to 0
//: no floating-point, MMX, etc. yet
:(before "End Types")
enum {
EAX,
ECX,
EDX,
EBX,
ESP,
EBP,
ESI,
EDI,
NUM_INT_REGISTERS,
};
union reg {
int32_t i;
uint32_t u;
};
:(before "End Globals")
reg Reg[NUM_INT_REGISTERS] = { {0} };
uint32_t EIP = 1; // preserve null pointer
:(before "End Reset")
bzero(Reg, sizeof(Reg));
EIP = 1; // preserve null pointer
:(before "End Help Contents")
cerr << " registers\n";
:(before "End Help Texts")
put(Help, "registers",
"SubX currently supports eight 32-bit integer registers: R0 to R7.\n"
"R4 (ESP) contains the top of the stack.\n"
"\n"
"There's also a register for the address of the currently executing\n"
"instruction. It is modified by jumps.\n"
"\n"
"Various instructions modify one or more of three 1-bit 'flag' registers,\n"
"as a side-effect:\n"
"- the sign flag (SF): usually set if an arithmetic result is negative, or\n"
" reset if not.\n"
"- the zero flag (ZF): usually set if a result is zero, or reset if not.\n"
"- the overflow flag (OF): usually set if an arithmetic result overflows.\n"
"The flag bits are read by conditional jumps.\n"
"\n"
"We don't support non-integer (floating-point) registers yet.\n"
);
:(before "End Globals")
// the subset of x86 flag registers we care about
bool SF = false; // sign flag
bool ZF = false; // zero flag
bool OF = false; // overflow flag
:(before "End Reset")
SF = ZF = OF = false;
//: how the flag registers are updated after each instruction
:(before "End Includes")
// Combine 'arg1' and 'arg2' with arithmetic operation 'op' and store the
// result in 'arg1', then update flags.
// beware: no side-effects in args
#define BINARY_ARITHMETIC_OP(op, arg1, arg2) { \
/* arg1 and arg2 must be signed */ \
int64_t tmp = arg1 op arg2; \
arg1 = arg1 op arg2; \
trace(90, "run") << "storing 0x" << HEXWORD << arg1 << end(); \
SF = (arg1 < 0); \
ZF = (arg1 == 0); \
OF = (arg1 != tmp); \
}
// Combine 'arg1' and 'arg2' with bitwise operation 'op' and store the result
// in 'arg1', then update flags.
#define BINARY_BITWISE_OP(op, arg1, arg2) { \
/* arg1 and arg2 must be unsigned */ \
arg1 = arg1 op arg2; \
trace(90, "run") << "storing 0x" << HEXWORD << arg1 << end(); \
SF = (arg1 >> 31); \
ZF = (arg1 == 0); \
OF = false; \
}
//:: simulated RAM
:(before "End Types")
const uint32_t INITIAL_SEGMENT_SIZE = 0x1000 - 1;
// Subtract one just so we can start the first segment at address 1 without
// overflowing the first segment. Other segments will learn to adjust.
// Like in real-world Linux, we'll allocate RAM for our programs in disjoint
// slabs called VMAs or Virtual Memory Areas.
struct vma {
uint32_t start; // inclusive
uint32_t end; // exclusive
vector<uint8_t> _data;
vma(uint32_t s, uint32_t e) :start(s), end(e) {
_data.resize(end-start);
}
vma(uint32_t s) :start(s), end(s+INITIAL_SEGMENT_SIZE) {
_data.resize(end-start);
}
bool match(uint32_t a) {
return a >= start && a < end;
}
bool match32(uint32_t a) {
return a >= start && a+4 <= end;
}
uint8_t& data(uint32_t a) {
assert(match(a));
return _data.at(a-start);
}
void grow_until(uint32_t new_end_address) {
if (new_end_address < end) return;
end = new_end_address;
_data.resize(new_end_address - start);
}
// End vma Methods
};
:(before "End Globals")
// RAM is made of VMAs.
//
// We currently have zero tests for overlapping VMAs. Particularly after
// growing segments.
vector<vma> Mem;
:(code)
// The first 3 VMAs are special. When loading ELF binaries in later layers,
// we'll assume that the first VMA is for code, the second is for data
// (including the heap), and the third for the stack.
void grow_code_segment(uint32_t new_end_address) {
assert(!Mem.empty());
Mem.at(0).grow_until(new_end_address);
}
void grow_data_segment(uint32_t new_end_address) {
assert(SIZE(Mem) > 1);
Mem.at(1).grow_until(new_end_address);
}
:(before "End Globals")
uint32_t End_of_program = 0; // when the program executes past this address in tests we'll stop the test
// The stack grows downward. Can't increase its size for now.
:(before "End Reset")
Mem.clear();
End_of_program = 0;
:(code)
// These helpers depend on Mem being laid out contiguously (so you can't use a
// map, etc.) and on the host also being little-endian.
inline uint8_t read_mem_u8(uint32_t addr) {
uint8_t* handle = mem_addr_u8(addr); // error messages get printed here
return handle ? *handle : 0;
}
inline int8_t read_mem_i8(uint32_t addr) {
return static_cast<int8_t>(read_mem_u8(addr));
}
inline uint32_t read_mem_u32(uint32_t addr) {
uint32_t* handle = mem_addr_u32(addr); // error messages get printed here
return handle ? *handle : 0;
}
inline int32_t read_mem_i32(uint32_t addr) {
return static_cast<int32_t>(read_mem_u32(addr));
}
inline uint8_t* mem_addr_u8(uint32_t addr) {
uint8_t* result = NULL;
for (int i = 0; i < SIZE(Mem); ++i) {
if (Mem.at(i).match(addr)) {
if (result)
raise << "address 0x" << HEXWORD << addr << " is in two segments\n" << end();
result = &Mem.at(i).data(addr);
}
}
if (result == NULL)
raise << "Tried to access uninitialized memory at address 0x" << HEXWORD << addr << '\n' << end();
return result;
}
inline int8_t* mem_addr_i8(uint32_t addr) {
return reinterpret_cast<int8_t*>(mem_addr_u8(addr));
}
inline uint32_t* mem_addr_u32(uint32_t addr) {
uint32_t* result = NULL;
for (int i = 0; i < SIZE(Mem); ++i) {
if (Mem.at(i).match32(addr)) {
if (result)
raise << "address 0x" << HEXWORD << addr << " is in two segments\n" << end();
result = reinterpret_cast<uint32_t*>(&Mem.at(i).data(addr));
}
}
if (result == NULL) {
raise << "Tried to access uninitialized memory at address 0x" << HEXWORD << addr << '\n' << end();
raise << "The entire 4-byte word should be initialized and lie in a single segment.\n" << end();
}
return result;
}
inline int32_t* mem_addr_i32(uint32_t addr) {
return reinterpret_cast<int32_t*>(mem_addr_u32(addr));
}
// helper for some syscalls. But read-only.
inline const char* mem_addr_string(uint32_t addr) {
return reinterpret_cast<const char*>(mem_addr_u8(addr));
}
inline void write_mem_u8(uint32_t addr, uint8_t val) {
uint8_t* handle = mem_addr_u8(addr);
if (handle != NULL) *handle = val;
}
inline void write_mem_i8(uint32_t addr, int8_t val) {
int8_t* handle = mem_addr_i8(addr);
if (handle != NULL) *handle = val;
}
inline void write_mem_u32(uint32_t addr, uint32_t val) {
uint32_t* handle = mem_addr_u32(addr);
if (handle != NULL) *handle = val;
}
inline void write_mem_i32(uint32_t addr, int32_t val) {
int32_t* handle = mem_addr_i32(addr);
if (handle != NULL) *handle = val;
}
inline bool already_allocated(uint32_t addr) {
bool result = false;
for (int i = 0; i < SIZE(Mem); ++i) {
if (Mem.at(i).match(addr)) {
if (result)
raise << "address 0x" << HEXWORD << addr << " is in two segments\n" << end();
result = true;
}
}
return result;
}
//:: core interpreter loop
:(code)
// skeleton of how x86 instructions are decoded
void run_one_instruction() {
uint8_t op=0, op2=0, op3=0;
trace(90, "run") << "inst: 0x" << HEXWORD << EIP << end();
//? dump_registers();
//? cerr << "inst: 0x" << EIP << " => ";
op = next();
//? cerr << HEXBYTE << NUM(op) << '\n';
switch (op) {
case 0xf4: // hlt
EIP = End_of_program;
break;
// End Single-Byte Opcodes
case 0x0f:
switch(op2 = next()) {
// End Two-Byte Opcodes Starting With 0f
default:
cerr << "unrecognized second opcode after 0f: " << HEXBYTE << NUM(op2) << '\n';
DUMP("");
exit(1);
}
break;
case 0xf2:
switch(op2 = next()) {
// End Two-Byte Opcodes Starting With f2
case 0x0f:
switch(op3 = next()) {
// End Three-Byte Opcodes Starting With f2 0f
default:
cerr << "unrecognized third opcode after f2 0f: " << HEXBYTE << NUM(op3) << '\n';
DUMP("");
exit(1);
}
break;
default:
cerr << "unrecognized second opcode after f2: " << HEXBYTE << NUM(op2) << '\n';
DUMP("");
exit(1);
}
break;
case 0xf3:
switch(op2 = next()) {
// End Two-Byte Opcodes Starting With f3
case 0x0f:
switch(op3 = next()) {
// End Three-Byte Opcodes Starting With f3 0f
default:
cerr << "unrecognized third opcode after f3 0f: " << HEXBYTE << NUM(op3) << '\n';
DUMP("");
exit(1);
}
break;
default:
cerr << "unrecognized second opcode after f3: " << HEXBYTE << NUM(op2) << '\n';
DUMP("");
exit(1);
}
break;
default:
cerr << "unrecognized opcode: " << HEXBYTE << NUM(op) << '\n';
DUMP("");
exit(1);
}
}
inline uint8_t next() {
return read_mem_u8(EIP++);
}
void dump_registers() {
for (int i = 0; i < NUM_INT_REGISTERS; ++i) {
if (i > 0) cerr << "; ";
cerr << " " << i << ": " << std::hex << std::setw(8) << std::setfill('_') << Reg[i].u;
}
cerr << " -- SF: " << SF << "; ZF: " << ZF << "; OF: " << OF << '\n';
}
//: start tracking supported opcodes
:(before "End Globals")
map</*op*/string, string> name;
map</*op*/string, string> name_0f;
map</*op*/string, string> name_f3;
map</*op*/string, string> name_f3_0f;
:(before "End One-time Setup")
init_op_names();
:(code)
void init_op_names() {
put(name, "f4", "halt");
// End Initialize Op Names(name)
}
:(before "End Help Special-cases(key)")
if (key == "opcodes") {
cerr << "Opcodes currently supported by SubX:\n";
for (map<string, string>::iterator p = name.begin(); p != name.end(); ++p)
cerr << " " << p->first << ": " << p->second << '\n';
for (map<string, string>::iterator p = name_0f.begin(); p != name_0f.end(); ++p)
cerr << " 0f " << p->first << ": " << p->second << '\n';
for (map<string, string>::iterator p = name_f3.begin(); p != name_f3.end(); ++p)
cerr << " f3 " << p->first << ": " << p->second << '\n';
for (map<string, string>::iterator p = name_f3_0f.begin(); p != name_f3_0f.end(); ++p)
cerr << " f3 0f " << p->first << ": " << p->second << '\n';
cerr << "Run `subx help instructions` for details on words like 'r32' and 'disp8'.\n";
return 0;
}
:(before "End Help Contents")
cerr << " opcodes\n";
:(before "End Includes")
#include <iomanip>
#define HEXBYTE std::hex << std::setw(2) << std::setfill('0')
#define HEXWORD std::hex << std::setw(8) << std::setfill('0')
// ugly that iostream doesn't print uint8_t as an integer
#define NUM(X) static_cast<int>(X)
#include <stdint.h>