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Diffstat (limited to 'subx/022check_instruction.cc')
-rw-r--r-- | subx/022check_instruction.cc | 613 |
1 files changed, 613 insertions, 0 deletions
diff --git a/subx/022check_instruction.cc b/subx/022check_instruction.cc new file mode 100644 index 00000000..afa6329f --- /dev/null +++ b/subx/022check_instruction.cc @@ -0,0 +1,613 @@ +//: Beginning of "level 2": tagging bytes with metadata around what field of +//: an x86 instruction they're for. +//: +//: The x86 instruction set is variable-length, and how a byte is interpreted +//: affects later instruction boundaries. A lot of the pain in programming machine code +//: stems from computer and programmer going out of sync on what a byte +//: means. The miscommunication is usually not immediately caught, and +//: metastasizes at runtime into kilobytes of misinterpreted instructions. +//: Tagging bytes with what the programmer expects them to be interpreted as +//: helps the computer catch miscommunication immediately. +//: +//: This is one way SubX is going to be different from a 'language': we +//: typically think of languages as less verbose than machine code. Here we're +//: making machine code *more* verbose. +//: +//: --- +//: +//: While we're here, we'll also improve a couple of other things: +//: +//: a) Machine code often packs logically separate operands into bitfields of +//: a single byte. We'll start writing out each operand separately, and the +//: translator will construct the right bytes out of operands. +//: +//: SubX now gets still more verbose. What used to be a single byte, say 'c3', +//: can now expand to '3/mod 0/subop 3/rm32'. +//: +//: b) Since each operand is tagged, we can loosen ordering restrictions and +//: allow writing out the operands in any order, like keyword arguments. +//: +//: c) Operand values can be expressed in either decimal or hex (when prefixed +//: with '0x'. Raw 2-character hex bytes without the '0x' are only valid when +//: tagged without any operand metadata. (This may be a bad idea.) +//: +//: Coda: the actual opcodes (1-3 bytes) will continue to be at the start of +//: each line, in hex, and untagged. The x86 instruction set is a mess, and +//: instructions don't admit good names. + +:(before "End Help Texts") +put(Help, "instructions", + "Each x86 instruction consists of an instruction or opcode and some number of operands.\n" + "Each operand has a type. An instruction won't have more than one operand of any type.\n" + "Each instruction has some set of allowed operand types. It'll reject others.\n" + "The complete list of operand types: mod, subop, r32 (register), rm32 (register or memory), scale, index, base, disp8, disp16, disp32, imm8, imm32.\n" + "Each of these has its own help page. Try reading 'subx help mod' next.\n" +); +:(before "End Help Contents") +cerr << " instructions\n"; + +//:: Check for 'syntax errors'; missing or unexpected operands. + +:(scenario check_missing_imm8_operand) +% Hide_errors = true; +== 0x1 +# opcode ModR/M SIB displacement immediate +# instruction mod, reg, Reg/Mem bits scale, index, base +# 1-3 bytes 0/1 byte 0/1 byte 0/1/2/4 bytes 0/1/2/4 bytes + cd # int ?? ++error: 'cd' (software interrupt): missing imm8 operand + +:(before "End One-time Setup") +Transform.push_back(check_operands); + +:(code) +void check_operands(/*const*/ program& p) { + if (p.segments.empty()) return; + const segment& seg = p.segments.at(0); + for (int i = 0; i < SIZE(seg.lines); ++i) { + check_operands(seg.lines.at(i)); + if (trace_contains_errors()) return; // stop at the first mal-formed instruction + } +} + +void check_operands(const line& inst) { + uint8_t op = hex_byte(inst.words.at(0).data); + if (trace_contains_errors()) return; + if (op == 0x0f) { + check_operands_0f(inst); + return; + } + if (op == 0xf3) { + check_operands_f3(inst); + return; + } + if (!contains_key(name, op)) { + raise << "unknown opcode '" << HEXBYTE << NUM(op) << "'\n" << end(); + return; + } + check_operands(op, inst); +} + +//: To check the operands for an opcode, we'll track the permitted operands +//: for each supported opcode in a bitvector. That way we can often compute the +//: bitvector for each instruction's operands and compare it with the expected. + +:(before "End Types") +enum operand_type { + // start from the least significant bit + MODRM, // more complex, may also involve disp8 or disp32 + SUBOP, + DISP8, + DISP16, + DISP32, + IMM8, + IMM32, + NUM_OPERAND_TYPES +}; +:(before "End Globals") +vector<string> Operand_type_name; +map<string, operand_type> Operand_type; +:(before "End One-time Setup") +init_op_types(); +:(code) +void init_op_types() { + assert(NUM_OPERAND_TYPES <= /*bits in a uint8_t*/8); + Operand_type_name.resize(NUM_OPERAND_TYPES); + #define DEF(type) Operand_type_name.at(type) = tolower(#type), put(Operand_type, tolower(#type), type); + DEF(MODRM); + DEF(SUBOP); + DEF(DISP8); + DEF(DISP16); + DEF(DISP32); + DEF(IMM8); + DEF(IMM32); + #undef DEF +} + +:(before "End Globals") +map</*op*/uint8_t, /*bitvector*/uint8_t> Permitted_operands; +const uint8_t INVALID_OPERANDS = 0xff; // no instruction uses all the operands +:(before "End One-time Setup") +init_permitted_operands(); +:(code) +void init_permitted_operands() { + //// Class A: just op, no operands + // halt + put(Permitted_operands, 0xf4, 0x00); + // push + put(Permitted_operands, 0x50, 0x00); + put(Permitted_operands, 0x51, 0x00); + put(Permitted_operands, 0x52, 0x00); + put(Permitted_operands, 0x53, 0x00); + put(Permitted_operands, 0x54, 0x00); + put(Permitted_operands, 0x55, 0x00); + put(Permitted_operands, 0x56, 0x00); + put(Permitted_operands, 0x57, 0x00); + // pop + put(Permitted_operands, 0x58, 0x00); + put(Permitted_operands, 0x59, 0x00); + put(Permitted_operands, 0x5a, 0x00); + put(Permitted_operands, 0x5b, 0x00); + put(Permitted_operands, 0x5c, 0x00); + put(Permitted_operands, 0x5d, 0x00); + put(Permitted_operands, 0x5e, 0x00); + put(Permitted_operands, 0x5f, 0x00); + // return + put(Permitted_operands, 0xc3, 0x00); + + //// Class B: just op and disp8 + // imm32 imm8 disp32 |disp16 disp8 subop modrm + // 0 0 0 |0 1 0 0 + + // jump + put(Permitted_operands, 0xeb, 0x04); + put(Permitted_operands, 0x74, 0x04); + put(Permitted_operands, 0x75, 0x04); + put(Permitted_operands, 0x7c, 0x04); + put(Permitted_operands, 0x7d, 0x04); + put(Permitted_operands, 0x7e, 0x04); + put(Permitted_operands, 0x7f, 0x04); + + //// Class C: just op and disp16 + // imm32 imm8 disp32 |disp16 disp8 subop modrm + // 0 0 0 |1 0 0 0 + put(Permitted_operands, 0xe8, 0x08); // jump + + //// Class D: just op and disp32 + // imm32 imm8 disp32 |disp16 disp8 subop modrm + // 0 0 1 |0 0 0 0 + put(Permitted_operands, 0xe9, 0x10); // call + + //// Class E: just op and imm8 + // imm32 imm8 disp32 |disp16 disp8 subop modrm + // 0 1 0 |0 0 0 0 + put(Permitted_operands, 0xcd, 0x20); // software interrupt + + //// Class F: just op and imm32 + // imm32 imm8 disp32 |disp16 disp8 subop modrm + // 1 0 0 |0 0 0 0 + put(Permitted_operands, 0x05, 0x40); // add + put(Permitted_operands, 0x2d, 0x40); // subtract + put(Permitted_operands, 0x25, 0x40); // and + put(Permitted_operands, 0x0d, 0x40); // or + put(Permitted_operands, 0x35, 0x40); // xor + put(Permitted_operands, 0x3d, 0x40); // compare + put(Permitted_operands, 0x68, 0x40); // push + // copy + put(Permitted_operands, 0xb8, 0x40); + put(Permitted_operands, 0xb9, 0x40); + put(Permitted_operands, 0xba, 0x40); + put(Permitted_operands, 0xbb, 0x40); + put(Permitted_operands, 0xbc, 0x40); + put(Permitted_operands, 0xbd, 0x40); + put(Permitted_operands, 0xbe, 0x40); + put(Permitted_operands, 0xbf, 0x40); + + //// Class M: using ModR/M byte + // imm32 imm8 disp32 |disp16 disp8 subop modrm + // 0 0 0 |0 0 0 1 + + // add + put(Permitted_operands, 0x01, 0x01); + put(Permitted_operands, 0x03, 0x01); + // subtract + put(Permitted_operands, 0x29, 0x01); + put(Permitted_operands, 0x2b, 0x01); + // and + put(Permitted_operands, 0x21, 0x01); + put(Permitted_operands, 0x23, 0x01); + // or + put(Permitted_operands, 0x09, 0x01); + put(Permitted_operands, 0x0b, 0x01); + // complement + put(Permitted_operands, 0xf7, 0x01); + // xor + put(Permitted_operands, 0x31, 0x01); + put(Permitted_operands, 0x33, 0x01); + // compare + put(Permitted_operands, 0x39, 0x01); + put(Permitted_operands, 0x3b, 0x01); + // copy + put(Permitted_operands, 0x89, 0x01); + put(Permitted_operands, 0x8b, 0x01); + // swap + put(Permitted_operands, 0x87, 0x01); + // pop + put(Permitted_operands, 0x8f, 0x01); + + //// Class O: op, ModR/M and subop (not r32) + // imm32 imm8 disp32 |disp16 disp8 subop modrm + // 0 0 0 |0 0 1 1 + put(Permitted_operands, 0xff, 0x03); // jump/push/call + + //// Class N: op, ModR/M and imm32 + // imm32 imm8 disp32 |disp16 disp8 subop modrm + // 1 0 0 |0 0 0 1 + put(Permitted_operands, 0xc7, 0x41); // copy + + //// Class P: op, ModR/M, subop (not r32) and imm32 + // imm32 imm8 disp32 |disp16 disp8 subop modrm + // 1 0 0 |0 0 1 1 + put(Permitted_operands, 0x81, 0x43); // combine +} + +:(before "End Includes") +#define HAS(bitvector, bit) ((bitvector) & (1 << (bit))) +#define SET(bitvector, bit) ((bitvector) | (1 << (bit))) +#define CLEAR(bitvector, bit) ((bitvector) & (~(1 << (bit)))) + +:(code) +void check_operands(uint8_t op, const line& inst) { + uint8_t expected_bitvector = get(Permitted_operands, op); + if (HAS(expected_bitvector, MODRM)) + check_operands_modrm(inst, op); + compare_bitvector(op, inst, CLEAR(expected_bitvector, MODRM)); +} + +//: Many instructions can be checked just by comparing bitvectors. + +void compare_bitvector(uint8_t op, const line& inst, uint8_t expected) { + if (all_raw_hex_bytes(inst) && has_operands(inst)) return; // deliberately programming in raw hex; we'll raise a warning elsewhere + uint8_t bitvector = compute_operand_bitvector(inst); + if (trace_contains_errors()) return; // duplicate operand type + if (bitvector == expected) return; // all good with this instruction + for (int i = 0; i < NUM_OPERAND_TYPES; ++i, bitvector >>= 1, expected >>= 1) { +//? cerr << "comparing " << HEXBYTE << NUM(bitvector) << " with " << NUM(expected) << '\n'; + if ((bitvector & 0x1) == (expected & 0x1)) continue; // all good with this operand + const string& optype = Operand_type_name.at(i); + if ((bitvector & 0x1) > (expected & 0x1)) + raise << "'" << to_string(inst) << "' (" << get(name, op) << "): unexpected " << optype << " operand\n" << end(); + else + raise << "'" << to_string(inst) << "' (" << get(name, op) << "): missing " << optype << " operand\n" << end(); + // continue giving all errors for a single instruction + } + // ignore settings in any unused bits +} + +uint32_t compute_operand_bitvector(const line& inst) { + uint32_t bitvector = 0; + for (int i = /*skip op*/1; i < SIZE(inst.words); ++i) { + bitvector = bitvector | bitvector_for_operand(inst.words.at(i)); + if (trace_contains_errors()) return INVALID_OPERANDS; // duplicate operand type + } + return bitvector; +} + +bool has_operands(const line& inst) { + return SIZE(inst.words) > first_operand(inst); +} + +int first_operand(const line& inst) { + if (inst.words.at(0).data == "0f") return 2; + if (inst.words.at(0).data == "f3") { + if (inst.words.at(1).data == "0f") + return 3; + else + return 2; + } + return 1; +} + +bool all_raw_hex_bytes(const line& inst) { + for (int i = 0; i < SIZE(inst.words); ++i) { + const word& curr = inst.words.at(i); + if (contains_any_operand_metadata(curr)) + return false; + if (SIZE(curr.data) != 2) + return false; + if (curr.data.find_first_not_of("0123456789abcdefABCDEF") != string::npos) + return false; + } + return true; +} + +bool contains_any_operand_metadata(const word& word) { + for (int i = 0; i < SIZE(word.metadata); ++i) + if (Instruction_operands.find(word.metadata.at(i)) != Instruction_operands.end()) + return true; + return false; +} + +// Scan the metadata of 'w' and return the bit corresponding to any operand type. +// Also raise an error if metadata contains multiple operand types. +uint32_t bitvector_for_operand(const word& w) { + uint32_t bv = 0; + bool found = false; + for (int i = 0; i < SIZE(w.metadata); ++i) { + const string& curr = w.metadata.at(i); + if (!contains_key(Operand_type, curr)) continue; // ignore unrecognized metadata + if (found) { + raise << "'" << w.original << "' has conflicting operand types; it should have only one\n" << end(); + return INVALID_OPERANDS; + } + bv = (1 << get(Operand_type, curr)); + found = true; + } + return bv; +} + +:(scenario conflicting_operand_type) +% Hide_errors = true; +== 0x1 +cd/software-interrupt 80/imm8/imm32 ++error: '80/imm8/imm32' has conflicting operand types; it should have only one + +//: Instructions computing effective addresses have more complex rules, so +//: we'll hard-code a common set of instruction-decoding rules. + +:(scenario check_missing_mod_operand) +% Hide_errors = true; +== 0x1 +81 0/add/subop 3/rm32/ebx 1/imm32 ++error: '81 0/add/subop 3/rm32/ebx 1/imm32' (combine rm32 with imm32 based on subop): missing mod operand + +:(before "End Globals") +set<string> Instruction_operands; +:(before "End One-time Setup") +Instruction_operands.insert("subop"); +Instruction_operands.insert("mod"); +Instruction_operands.insert("rm32"); +Instruction_operands.insert("base"); +Instruction_operands.insert("index"); +Instruction_operands.insert("scale"); +Instruction_operands.insert("r32"); +Instruction_operands.insert("disp8"); +Instruction_operands.insert("disp16"); +Instruction_operands.insert("disp32"); +Instruction_operands.insert("imm8"); +Instruction_operands.insert("imm32"); + +:(code) +void check_operands_modrm(const line& inst, uint8_t op) { + if (all_raw_hex_bytes(inst)) return; // deliberately programming in raw hex; we'll raise a warning elsewhere + check_metadata_present(inst, "mod", op); + check_metadata_present(inst, "rm32", op); + // no check for r32; some instructions don't use it; just assume it's 0 if missing + if (op == 0x81 || op == 0x8f || op == 0xff) { // keep sync'd with 'help subop' + check_metadata_present(inst, "subop", op); + check_metadata_absent(inst, "r32", op, "should be replaced by subop"); + } + if (trace_contains_errors()) return; + if (metadata(inst, "rm32").data != "4") return; + // SIB byte checks + uint8_t mod = hex_byte(metadata(inst, "mod").data); + if (mod != /*direct*/3) { + check_metadata_present(inst, "base", op); + check_metadata_present(inst, "index", op); // otherwise why go to SIB? + } + else { + check_metadata_absent(inst, "base", op, "direct mode"); + check_metadata_absent(inst, "index", op, "direct mode"); + } + // no check for scale; 0 (2**0 = 1) by default +} + +void check_metadata_present(const line& inst, const string& type, uint8_t op) { + if (!has_metadata(inst, type)) + raise << "'" << to_string(inst) << "' (" << get(name, op) << "): missing " << type << " operand\n" << end(); +} + +void check_metadata_absent(const line& inst, const string& type, uint8_t op, const string& msg) { + if (has_metadata(inst, type)) + raise << "'" << to_string(inst) << "' (" << get(name, op) << "): unexpected " << type << " operand (" << msg << ")\n" << end(); +} + +bool has_metadata(const line& inst, const string& m) { + bool result = false; + for (int i = 0; i < SIZE(inst.words); ++i) { + if (!has_metadata(inst.words.at(i), m)) continue; + if (result) { + raise << "'" << to_string(inst) << "' has conflicting " << m << " operands\n" << end(); + return false; + } + result = true; + } + return result; +} + +bool has_metadata(const word& w, const string& m) { + bool result = false; + bool metadata_found = false; + for (int i = 0; i < SIZE(w.metadata); ++i) { + const string& curr = w.metadata.at(i); + if (!contains_key(Instruction_operands, curr)) continue; // ignore unrecognized metadata + if (metadata_found) { + raise << "'" << w.original << "' has conflicting operand types; it should have only one\n" << end(); + return false; + } + metadata_found = true; + result = (curr == m); + } + return result; +} + +word metadata(const line& inst, const string& m) { + for (int i = 0; i < SIZE(inst.words); ++i) + if (has_metadata(inst.words.at(i), m)) + return inst.words.at(i); + assert(false); +} + +:(scenario conflicting_operands_in_modrm_instruction) +% Hide_errors = true; +== 0x1 +01/add 0/mod 3/mod ++error: '01/add 0/mod 3/mod' has conflicting mod operands + +:(scenario conflicting_operand_type_modrm) +% Hide_errors = true; +== 0x1 +01/add 0/mod 3/rm32/r32 ++error: '3/rm32/r32' has conflicting operand types; it should have only one + +:(scenario check_missing_rm32_operand) +% Hide_errors = true; +== 0x1 +81 0/add/subop 0/mod 1/imm32 ++error: '81 0/add/subop 0/mod 1/imm32' (combine rm32 with imm32 based on subop): missing rm32 operand + +:(scenario check_missing_subop_operand) +% Hide_errors = true; +== 0x1 +81 0/mod 3/rm32/ebx 1/imm32 ++error: '81 0/mod 3/rm32/ebx 1/imm32' (combine rm32 with imm32 based on subop): missing subop operand + +:(scenario check_missing_base_operand) +% Hide_errors = true; +== 0x1 +81 0/add/subop 0/mod/indirect 4/rm32/use-sib 1/imm32 ++error: '81 0/add/subop 0/mod/indirect 4/rm32/use-sib 1/imm32' (combine rm32 with imm32 based on subop): missing base operand + +:(scenario check_missing_index_operand) +% Hide_errors = true; +== 0x1 +81 0/add/subop 0/mod/indirect 4/rm32/use-sib 0/base 1/imm32 ++error: '81 0/add/subop 0/mod/indirect 4/rm32/use-sib 0/base 1/imm32' (combine rm32 with imm32 based on subop): missing index operand + +:(scenario check_missing_base_operand_2) +% Hide_errors = true; +== 0x1 +81 0/add/subop 0/mod/indirect 4/rm32/use-sib 2/index 3/scale 1/imm32 ++error: '81 0/add/subop 0/mod/indirect 4/rm32/use-sib 2/index 3/scale 1/imm32' (combine rm32 with imm32 based on subop): missing base operand + +:(scenario check_base_operand_not_needed_in_direct_mode) +== 0x1 +81 0/add/subop 3/mod/indirect 4/rm32/use-sib 1/imm32 +$error: 0 + +//:: similarly handle multi-byte opcodes + +:(code) +void check_operands_0f(const line& inst) { + assert(inst.words.at(0).data == "0f"); + if (SIZE(inst.words) == 1) { + raise << "no 2-byte opcode specified starting with '0f'\n" << end(); + return; + } + uint8_t op = hex_byte(inst.words.at(1).data); + if (!contains_key(name_0f, op)) { + raise << "unknown 2-byte opcode '0f " << HEXBYTE << NUM(op) << "'\n" << end(); + return; + } + check_operands_0f(op, inst); +} + +void check_operands_f3(const line& /*unused*/) { + raise << "no supported opcodes starting with f3\n" << end(); +} + +void check_operands_0f(uint8_t /*op*/, const line& /*inst*/) { +} + +string to_string(const line& inst) { + ostringstream out; + for (int i = 0; i < SIZE(inst.words); ++i) { + if (i > 0) out << ' '; + out << inst.words.at(i).original; + } + return out.str(); +} + +string tolower(const char* s) { + ostringstream out; + for (/*nada*/; *s; ++s) + out << static_cast<char>(tolower(*s)); + return out.str(); +} + +//:: docs on each operand type + +:(before "End Help Texts") +init_operand_type_help(); +:(code) +void init_operand_type_help() { + put(Help, "mod", + "2-bit operand controlling the _addressing mode_ of many instructions,\n" + "to determine how to compute the _effective address_ to look up memory at\n" + "based on the 'rm32' operand and potentially others.\n" + "\n" + "If mod = 3, just operate on the contents of the register specified by rm32 (direct mode).\n" + "If mod = 2, effective address is usually* rm32 + disp32 (indirect mode with displacement).\n" + "If mod = 1, effective address is usually* rm32 + disp8 (indirect mode with displacement).\n" + "If mod = 0, effective address is usually* rm32 (indirect mode).\n" + "(* - The exception is when rm32 is '4'. Register 4 is the stack pointer (ESP). Using it as an address gets more involved.\n" + " For more details, try reading the help pages for 'base', 'index' and 'scale'.)\n" + "\n" + "For complete details consult the IA-32 software developer's manual, table 2-2,\n" + "\"32-bit addressing forms with the ModR/M byte\".\n" + " https://www.intel.com/content/dam/www/public/us/en/documents/manuals/64-ia-32-architectures-software-developer-instruction-set-reference-manual-325383.pdf\n" + ); + put(Help, "subop", + "Additional 3-bit operand for determining the instruction when the opcode is 81, 8f or ff.\n" + "Can't coexist with operand of type 'r32' in a single instruction, because the two use the same bits.\n" + ); + put(Help, "r32", + "3-bit operand specifying a register operand used directly, without any further addressing modes.\n" + ); + put(Help, "rm32", + "3-bit operand specifying a register operand whose precise interpretation interacts with 'mod'.\n" + "For complete details consult the IA-32 software developer's manual, table 2-2,\n" + "\"32-bit addressing forms with the ModR/M byte\".\n" + " https://www.intel.com/content/dam/www/public/us/en/documents/manuals/64-ia-32-architectures-software-developer-instruction-set-reference-manual-325383.pdf\n" + ); + put(Help, "base", + "Additional 3-bit operand (when 'rm32' is 4 unless 'mod' is 3) specifying the register containing an address to look up.\n" + "This address may be further modified by 'index' and 'scale' operands.\n" + " effective address = base + index*scale + displacement (disp8 or disp32)\n" + "For complete details consult the IA-32 software developer's manual, table 2-3,\n" + "\"32-bit addressing forms with the SIB byte\".\n" + " https://www.intel.com/content/dam/www/public/us/en/documents/manuals/64-ia-32-architectures-software-developer-instruction-set-reference-manual-325383.pdf\n" + ); + put(Help, "index", + "Optional 3-bit operand (when 'rm32' is 4 unless 'mod' is 3) that can be added to the 'base' operand to compute the 'effective address' at which to look up memory.\n" + " effective address = base + index*scale + displacement (disp8 or disp32)\n" + "For complete details consult the IA-32 software developer's manual, table 2-3,\n" + "\"32-bit addressing forms with the SIB byte\".\n" + " https://www.intel.com/content/dam/www/public/us/en/documents/manuals/64-ia-32-architectures-software-developer-instruction-set-reference-manual-325383.pdf\n" + ); + put(Help, "scale", + "Optional 2-bit operand (when 'rm32' is 4 unless 'mod' is 3) that can be multiplied to the 'index' operand before adding the result to the 'base' operand to compute the _effective address_ to operate on.\n" + " effective address = base + index * scale + displacement (disp8 or disp32)\n" + "For complete details consult the IA-32 software developer's manual, table 2-3,\n" + "\"32-bit addressing forms with the SIB byte\".\n" + " https://www.intel.com/content/dam/www/public/us/en/documents/manuals/64-ia-32-architectures-software-developer-instruction-set-reference-manual-325383.pdf\n" + ); + put(Help, "disp8", + "8-bit value to be added in many instructions.\n" + ); + put(Help, "disp16", + "16-bit value to be added in many instructions.\n" + ); + put(Help, "disp32", + "32-bit value to be added in many instructions.\n" + ); + put(Help, "imm8", + "8-bit value for many instructions.\n" + ); + put(Help, "imm32", + "32-bit value for many instructions.\n" + ); +} + +:(before "End Includes") +#include<cctype> |