SpiderLang/spider-runtime
7
0
Fork 0
Code Issues Pull Requests 1 Actions Packages Projects Releases Wiki Activity

Compare commits

base: SpiderLang:d2ce5ea4bd8997e66c6abe26196d08035f795060
Branches Tags
SpiderLang:main SpiderLang:intr-024-03B SpiderLang:easter-egg-arturo-branch SpiderLang:diego/instruc-068-079
..
compare: SpiderLang:easter-egg-arturo-branch
Branches Tags
SpiderLang:intr-024-03B SpiderLang:easter-egg-arturo-branch SpiderLang:diego/instruc-068-079 SpiderLang:main

5 Commits
d2ce5ea4bd ... easter-egg

Author SHA1 Message Date
Arturo
cdf14cf545 added LLGS instruction to CPU.hpp 2026-04-11 11:50:37 -06:00
Arturo
c3c94583f4 Map LLGS instruction to opcode 0xF1 2026-04-11 11:35:27 -06:00
Arturo
1fe555aaba Added easter egg by Arturo Balam for 0F1 (slot 1) 2026-04-11 10:02:30 -06:00
AlmeidaDaniel
7155ad8d5a Finished STB, CRB and TSB instructions 2026-04-06 19:18:30 -06:00
AlmeidaDaniel
0449074ef6 Finished BOOL, FBT, UDMD and DMOD 2026-04-06 17:56:00 -06:00
7 changed files with 182 additions and 258 deletions
Expand all files Collapse all files

4
src/spider/runtime/Runtime.cpp
View File

@@ -17,10 +17,8 @@ namespace spider {
// Stepping/Running the Machine // // Stepping/Running the Machine //
void Runtime::step() { void Runtime::step() {
// fetchInstr() decodes the opcode, addressing mode and type siz
cpu.fetchInstr(); cpu.fetchInstr();
// execute() completes the fetch-decode-execute cycle by calling the correct instruction method based on the opcode. // TODO: Call instruction
cpu.execute();
} }
void Runtime::step(u64 n) { void Runtime::step(u64 n) {

84
src/spider/runtime/cpu/CPU.hpp
View File

@@ -15,14 +15,6 @@ namespace spider {
static constexpr const u64 FLAG_INTERRUPT_REQUEST = 0b0000000000000000000000000000000000000000000000000000000000000100; static constexpr const u64 FLAG_INTERRUPT_REQUEST = 0b0000000000000000000000000000000000000000000000000000000000000100;
static constexpr const u64 FLAG_EXCEPTION = 0b0000000000000000000000000000000000000000000000000000000000001000; static constexpr const u64 FLAG_EXCEPTION = 0b0000000000000000000000000000000000000000000000000000000000001000;
static constexpr const u64 FLAG_MEMORY_MODE = 0b0000000000000000000000000000000000000000000000000000000000110000; static constexpr const u64 FLAG_MEMORY_MODE = 0b0000000000000000000000000000000000000000000000000000000000110000;
static constexpr const u64 FLAG_EXT_INT_DISABLE = 0b0000000000000000000000000000000000000000000000000000000010000000; // bit 7
static constexpr const u64 FLAG_EQUAL = 0b0000000000000000000000000000000000000000000000000000010000000000; // bit 10
static constexpr const u64 FLAG_EPSILON_ENABLE = 0b0000000000000000000000000000000000000000000000000001000000000000; // bit 12
static constexpr const u64 FLAG_HOTSWAP_SIGNAL = 0b0000000000000000000000000000000000000000000000010000000000000000; // bit 16
static constexpr const u64 FLAG_USER_A = 0b0000000000000000000000000000000000000000000100000000000000000000; // bit 20
static constexpr const u64 FLAG_USER_B = 0b0000000000000000000000000000000000000000001000000000000000000000; // bit 21
static constexpr const u64 FLAG_USER_C = 0b0000000000000000000000000000000000000000010000000000000000000000; // bit 22
static constexpr const u64 FLAG_USER_D = 0b0000000000000000000000000000000000000000100000000000000000000000; // bit 23
public: // Map of addressing modes & Instructions public: // Map of addressing modes & Instructions
@@ -91,11 +83,11 @@ namespace spider {
/** /**
* Pointer to the current RAM hooked into * Pointer to the current RAM hooked into
* the CPU. * the CPU.
* *
* It is unproved whether having the RAM directly * It is unproved whether having the RAM directly
* into the CPU is better than not, or whether a * into the CPU is better than not, or whether a
* virtual BUS is better. * virtual BUS is better.
* *
* Alas, this way we can have a CPU state switch * Alas, this way we can have a CPU state switch
* between memory and instruction banks. * between memory and instruction banks.
*/ */
@@ -104,7 +96,7 @@ namespace spider {
/** /**
* Pointer to the current Instruction Reel * Pointer to the current Instruction Reel
* hooked into the CPU. * hooked into the CPU.
* *
* Ditto as RAM. * Ditto as RAM.
*/ */
InstrReel* _reel; InstrReel* _reel;
@@ -120,7 +112,7 @@ namespace spider {
~CPU(); ~CPU();
public: public:
CPU& operator=(const CPU& other) = default; CPU& operator=(const CPU& other) = default;
CPU& operator=(CPU&& other) noexcept = default; CPU& operator=(CPU&& other) noexcept = default;
@@ -132,7 +124,7 @@ namespace spider {
void hookInstrReel(InstrReel* reel); void hookInstrReel(InstrReel* reel);
constexpr u64 getFlag(u64 mask); constexpr u64 getFlag(u64 mask);
public: public:
/** /**
@@ -145,11 +137,11 @@ namespace spider {
* Fetches the destination operand, * Fetches the destination operand,
* by calling the appropriate addressing * by calling the appropriate addressing
* mode. * mode.
* *
* Will read the bottom 3 bits. * Will read the bottom 3 bits.
* For instructions with two operands, * For instructions with two operands,
* call Src first. * call Src first.
* *
* The internal variable _addrm * The internal variable _addrm
* will not be modified. It will * will not be modified. It will
* be important when writing * be important when writing
@@ -159,14 +151,14 @@ namespace spider {
/** /**
* Fetches the source operand. * Fetches the source operand.
* *
* For use in two operand instructions. * For use in two operand instructions.
* *
* Will read the bottom 3 bits. It will * Will read the bottom 3 bits. It will
* then shift the _addrm 3 spaces * then shift the _addrm 3 spaces
* to ensure it aligns with the DST * to ensure it aligns with the DST
* next. * next.
* *
* Additionally, it will add 1 to _addrm * Additionally, it will add 1 to _addrm
* to account with * to account with
*/ */
@@ -184,7 +176,7 @@ namespace spider {
* a large switch statement. Only suitable * a large switch statement. Only suitable
* for environments where the instruction * for environments where the instruction
* map is not possible. * map is not possible.
* *
* This has yet to be proved!!! * This has yet to be proved!!!
*/ */
void executeSwLk(); void executeSwLk();
@@ -205,32 +197,32 @@ namespace spider {
* Absolute Addressing Mode * Absolute Addressing Mode
*/ */
void abs(); void abs();
/** /**
* Register Addressing Mode * Register Addressing Mode
*/ */
void reg(); void reg();
/** /**
* Indrect Addressing Mode * Indrect Addressing Mode
*/ */
void ind(); void ind();
/** /**
* Pointer Addressing Mode * Pointer Addressing Mode
*/ */
void ptr(); void ptr();
/** /**
* Indexed Addressing Mode * Indexed Addressing Mode
*/ */
void idx(); void idx();
/** /**
* Scaled Addressing Mode * Scaled Addressing Mode
*/ */
void sca(); void sca();
/** /**
* Displaced Addressing Mode * Displaced Addressing Mode
*/ */
@@ -541,22 +533,22 @@ namespace spider {
// [System] 0x040 — SFB: Store (User) Flag Bit // [System] 0x040 — SFB: Store (User) Flag Bit
// Params: 2 | AddrMask1: 1E AddrMask2: FF | TypeMask: 0F // Params: 2 | AddrMask1: 1E AddrMask2: FF | TypeMask: 0F
// Operation: // Operation:
void SFB(); void SFB();
// [System] 0x041 — LFB: Load (User) Flag Bit // [System] 0x041 — LFB: Load (User) Flag Bit
// Params: 2 | AddrMask1: 1E AddrMask2: FF | TypeMask: 0F // Params: 2 | AddrMask1: 1E AddrMask2: FF | TypeMask: 0F
// Operation: // Operation:
void LFB(); void LFB();
// [Branch] 0x042 — JUF: Jump to absolute position, if user flag is true // [Branch] 0x042 — JUF: Jump to absolute position, if user flag is true
// Params: 2 | AddrMask1: 1E AddrMask2: FF | TypeMask: 0F // Params: 2 | AddrMask1: 1E AddrMask2: FF | TypeMask: 0F
// Operation: // Operation:
void JUF(); void JUF();
// [Branch] 0x043 — JUR: Jump to relative position, if user flag is true // [Branch] 0x043 — JUR: Jump to relative position, if user flag is true
// Params: 2 | AddrMask1: 1E AddrMask2: FF | TypeMask: 0F // Params: 2 | AddrMask1: 1E AddrMask2: FF | TypeMask: 0F
// Operation: // Operation:
void JUR(); void JUR();
// [Memory] 0x044 — PUSH: Push to stack // [Memory] 0x044 — PUSH: Push to stack
@@ -601,7 +593,7 @@ namespace spider {
// [Floating Point] 0x050 — FLI: Float Load Immediate // [Floating Point] 0x050 — FLI: Float Load Immediate
// Params: 1 | AddrMask1: FF AddrMask2: 00 | TypeMask: 0C // Params: 1 | AddrMask1: FF AddrMask2: 00 | TypeMask: 0C
// Operation: // Operation:
void FLI(); void FLI();
// [Floating Point] 0x051 — FNEG: Float negate // [Floating Point] 0x051 — FNEG: Float negate
@@ -816,74 +808,78 @@ namespace spider {
// [Matrix] 0x080 — MADD: Matrix Addition // [Matrix] 0x080 — MADD: Matrix Addition
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void MADD(); void MADD();
// [Matrix] 0x081 — MSUB: Matrix Subtraction // [Matrix] 0x081 — MSUB: Matrix Subtraction
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void MSUB(); void MSUB();
// [Matrix] 0x082 — MMUL: Matrix Multiply // [Matrix] 0x082 — MMUL: Matrix Multiply
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void MMUL(); void MMUL();
// [Matrix] 0x083 — MINV: Matrix Inverse // [Matrix] 0x083 — MINV: Matrix Inverse
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void MINV(); void MINV();
// [Matrix] 0x084 — MTRA: Matrix Transpose // [Matrix] 0x084 — MTRA: Matrix Transpose
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void MTRA(); void MTRA();
// [Matrix] 0x085 — MDET: Matrix Determinant // [Matrix] 0x085 — MDET: Matrix Determinant
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void MDET(); void MDET();
// [Quaternion] 0x086 — QMKA: Quaternion Make from Angles // [Quaternion] 0x086 — QMKA: Quaternion Make from Angles
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void QMKA(); void QMKA();
// [Quaternion] 0x087 — QMUL: Quaternion Multiply // [Quaternion] 0x087 — QMUL: Quaternion Multiply
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void QMUL(); void QMUL();
// [SIMD] 0x08A — XADD: SIMD Addition // [SIMD] 0x08A — XADD: SIMD Addition
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void XADD(); void XADD();
// [SIMD] 0x08B — XSUB: SIMD Subtract // [SIMD] 0x08B — XSUB: SIMD Subtract
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void XSUB(); void XSUB();
// [SIMD] 0x08C — XAMA: SIMD Alternate Multiply-Add // [SIMD] 0x08C — XAMA: SIMD Alternate Multiply-Add
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void XAMA(); void XAMA();
// [SIMD] 0x08D — XMUL: SIMD Multiply // [SIMD] 0x08D — XMUL: SIMD Multiply
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void XMUL(); void XMUL();
// [SIMD] 0x08E — XDIV: SIMD Divide // [SIMD] 0x08E — XDIV: SIMD Divide
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void XDIV(); void XDIV();
// [Easter Eggs] 0x0F0 — UPY: Will place "YUPI" in memory // [Easter Eggs] 0x0F0 — UPY: Will place "YUPI" in memory
// Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00 // Params: 0 | AddrMask1: 00 AddrMask2: 00 | TypeMask: 00
// Operation: // Operation:
void UPY(); void UPY();
//[Easter Egg] 0x0F1 - LLGS: Injects the custom 8x4 ASCII spider logo
// into RAM [0x80-0x9F] and signs Register RA with the "LLGS" hex literal.
void LLGS();
// </pygen-target> // // </pygen-target> //
}; };

4
src/spider/runtime/instr/InstrMap.cpp
View File

@@ -276,7 +276,7 @@ CPU::Fn CPU::instrMap[] = {
nullptr, // 0x0EE nullptr, // 0x0EE
nullptr, // 0x0EF nullptr, // 0x0EF
&CPU::UPY, // 0x0F0 — Will place "YUPI" in memory &CPU::UPY, // 0x0F0 — Will place "YUPI" in memory
nullptr, // 0x0F1 &CPU::LLGS, // 0x0F1 — Spider ASCII art (LLGS easter egg)
nullptr, // 0x0F2 nullptr, // 0x0F2
nullptr, // 0x0F3 nullptr, // 0x0F3
nullptr, // 0x0F4 nullptr, // 0x0F4
@@ -737,6 +737,8 @@ void CPU::executeSwLk() {
// ── Easter Eggs ───────────────────────────────── // ── Easter Eggs ─────────────────────────────────
case 0x0F0: UPY(); break; case 0x0F0: UPY(); break;
case 0x0F1: LLGS(); break;
default: default:
break; break;

34
src/spider/runtime/instr/Instr_000-01F.cpp
View File

@@ -295,19 +295,23 @@ namespace spider {
(this->*_post)(); (this->*_post)();
} }
void CPU::DMOD() { //It gives error and I dont understand why void CPU::DMOD() {
// TODO: Implement DMOD // TODO: Implement DMOD
fetchOperSrc(); fetchOperSrc();
fetchOperDst(); fetchOperDst();
switch(_size){ switch(_size){
case 0b00: //byte case 0b00: //byte
//_dst->_i8 / _src->_i8 = RX * _src + RY; RX._i8 = _dst->_i8 / _src->_i8;
RY._i8 = _dst->_i8 % _src->_i8;
case 0b01: //short case 0b01: //short
//_dst->_i16 / _src->_i16 = RX * _src->_i16 + RY; RX._i16 = _dst->_i16 / _src->_i16;
RY._i16 = _dst->_i16 % _src->_i16;
case 0b10: //int case 0b10: //int
//_dst->_i32 / _src->_i32 = RX * _src->_i32 + RY; RX._i32 = _dst->_i32 / _src->_i32;
RY._i32 = _dst->_i32 % _src->_i32;
case 0b11: //long case 0b11: //long
//_dst->_i64 / _src->_i64 = RX * _src->_i64 + RY; RX._i64 = _dst->_i64 / _src->_i64;
RY._i64 = _dst->_i64 % _src->_i64;
} }
(this->*_post)(); (this->*_post)();
} }
@@ -318,13 +322,17 @@ namespace spider {
fetchOperDst(); fetchOperDst();
switch(_size){ switch(_size){
case 0b00: //byte case 0b00: //byte
//_dst->_u8 / _src->_u8 = RX * _src->_u8 + RY; RX._u8 = _dst->_u8 / _src->_u8;
RY._u8 = _dst->_u8 % _src->_u8;
case 0b01: //short case 0b01: //short
//_dst->_u16 / _src->_u16 = RX * _src->_u16 + RY; RX._u16 = _dst->_u16 / _src->_u16;
RY._u16 = _dst->_u16 % _src->_u16;
case 0b10: //int case 0b10: //int
//_dst->_u32 / _src->_u32 = RX * _src->_u32 + RY; RX._u32 = _dst->_u32 / _src->_u32;
RY._u32 = _dst->_u32 % _src->_u32;
case 0b11: //long case 0b11: //long
//_dst->_u64 / _src->_u64 = RX * _src->_u64 + RY; RX._u64 = _dst->_u64 / _src->_u64;
RY._u64 = _dst->_u64 % _src->_u64;
} }
(this->*_post)(); (this->*_post)();
} }
@@ -334,13 +342,13 @@ namespace spider {
fetchOperDst(); fetchOperDst();
switch(_size){ switch(_size){
case 0b00: //byte case 0b00: //byte
_dst->_u8 = 1; RF = (RF & ~(0x3 << 9)) | ((_dst->_u8 >> 9) & 0x3) << 9;
case 0b01: //short case 0b01: //short
_dst->_u16 = 1; RF = (RF & ~(0x3 << 9)) | ((_dst->_u16 >> 9) & 0x3) << 9;
case 0b10: //int case 0b10: //int
_dst->_u32 = 1; RF = (RF & ~(0x3 << 9)) | ((_dst->_u32 >> 9) & 0x3) << 9;
case 0b11: //long case 0b11: //long
_dst->_u64 = 1; RF = (RF & ~(0x3 << 9)) | ((_dst->_u64 >> 9) & 0x3) << 9;
} }
(this->*_post)(); (this->*_post)();
} }

99
src/spider/runtime/instr/Instr_020-03F.cpp
View File

@@ -13,13 +13,13 @@ namespace spider {
fetchOperDst(); fetchOperDst();
switch(_size){ switch(_size){
case 0b00: //byte case 0b00: //byte
_dst->_u8 = 1; _dst->_u8 |= (1 << _src->_u8);
case 0b01: //short case 0b01: //short
_dst->_u16 = 1; _dst->_u16 |= (1 << _src->_u16);
case 0b10: //int case 0b10: //int
_dst->_u32 = 1; _dst->_u32 |= (1 << _src->_u32);
case 0b11: //long case 0b11: //long
_dst->_u64 = 1; _dst->_u64 |= (1 << _src->_u64);
} }
(this->*_post)(); (this->*_post)();
} }
@@ -30,13 +30,13 @@ namespace spider {
fetchOperDst(); fetchOperDst();
switch(_size){ switch(_size){
case 0b00: //byte case 0b00: //byte
_dst->_u8 = 1; _dst->_u8 &= ~(1 << _src->_u8);
case 0b01: //short case 0b01: //short
_dst->_u16 = 1; _dst->_u16 &= ~(1 << _src->_u16);
case 0b10: //int case 0b10: //int
_dst->_u32 = 1; _dst->_u32 &= ~(1 << _src->_u32);
case 0b11: //long case 0b11: //long
_dst->_u64 = 1; _dst->_u64 &= ~(1 << _src->_u64);
} }
(this->*_post)(); (this->*_post)();
} }
@@ -47,13 +47,37 @@ namespace spider {
fetchOperDst(); fetchOperDst();
switch(_size){ switch(_size){
case 0b00: //byte case 0b00: //byte
_dst->_u8 = 1; switch (((RF >> _src->_u8) & 1) != ((_dst->_u8 >> _src->_u8) & 1)){
case 1:
RF |= (1 << _src->_u8);
case 0:
RF &= ~(1 << _src->_u8);
}
case 0b01: //short case 0b01: //short
_dst->_u16 = 1; switch (((RF >> _src->_u16) & 1) != ((_dst->_u16 >> _src->_u16) & 1)){
case 1:
RF |= (1 << _src->_u16);
case 0:
RF &= ~(1 << _src->_u16);
}
case 0b10: //int case 0b10: //int
_dst->_u32 = 1; switch (((RF >> _src->_u32) & 1) != ((_dst->_u32 >> _src->_u32) & 1)){
case 1:
RF |= (1 << _src->_u32);
case 0:
RF &= ~(1 << _src->_u32);
}
case 0b11: //long case 0b11: //long
_dst->_u64 = 1; switch (((RF >> _src->_u64) & 1) != ((_dst->_u64 >> _src->_u64) & 1)){
case 1:
RF |= (1 << _src->_u64);
case 0:
RF &= ~(1 << _src->_u64);
}
} }
(this->*_post)(); (this->*_post)();
} }
@@ -154,63 +178,20 @@ namespace spider {
// TODO: Implement JIF // TODO: Implement JIF
} }
// ── 0x03C — JMR: Dst + Instruction Register -> Instruction Register ──
void CPU::JMR() { void CPU::JMR() {
fetchOperDst(); // TODO: Implement JMR
i64 offset;
switch (_size) {
case 0b00: offset = static_cast<i64>(_dst->_i8); break; // 1 byte
case 0b01: offset = static_cast<i64>(_dst->_i16); break; // 2 bytes
case 0b10: offset = static_cast<i64>(_dst->_i32); break; // 4 bytes
case 0b11: offset = _dst->_i64; break; // 8 bytes
}
RI = static_cast<u64>(static_cast<i64>(RI) + offset);
} }
// ── 0x03D — JER: Dst + Instruction Register -> Instruction Register IF Flags.EQ ──
void CPU::JER() { void CPU::JER() {
fetchOperDst(); // TODO: Implement JER
if (RF & CPU::FLAG_EQUAL) {
i64 offset;
switch (_size) {
case 0b00: offset = static_cast<i64>(_dst->_i8); break;
case 0b01: offset = static_cast<i64>(_dst->_i16); break;
case 0b10: offset = static_cast<i64>(_dst->_i32); break;
case 0b11: offset = _dst->_i64; break;
}
RI = static_cast<u64>(static_cast<i64>(RI) + offset);
}
} }
// ── 0x03E — JNR: Dst + Instruction Register -> Instruction Register IF NOT Flags.EQ ──
void CPU::JNR() { void CPU::JNR() {
fetchOperDst(); // TODO: Implement JNR
if (!(RF & CPU::FLAG_EQUAL)) {
i64 offset;
switch (_size) {
case 0b00: offset = static_cast<i64>(_dst->_i8); break;
case 0b01: offset = static_cast<i64>(_dst->_i16); break;
case 0b10: offset = static_cast<i64>(_dst->_i32); break;
case 0b11: offset = _dst->_i64; break;
}
RI = static_cast<u64>(static_cast<i64>(RI) + offset);
}
} }
// ── 0x03F — JIR: Dst + Instruction Register -> Instruction Register IF Src ──
void CPU::JIR() { void CPU::JIR() {
fetchOperSrc(); // TODO: Implement JIR
fetchOperDst();
if (_src->_u64 != 0) {
i64 offset;
switch (_size) {
case 0b00: offset = static_cast<i64>(_dst->_i8); break;
case 0b01: offset = static_cast<i64>(_dst->_i16); break;
case 0b10: offset = static_cast<i64>(_dst->_i32); break;
case 0b11: offset = _dst->_i64; break;
}
RI = static_cast<u64>(static_cast<i64>(RI) + offset);
}
} }
} }

154
src/spider/runtime/instr/Instr_040-05F.cpp
View File

@@ -4,195 +4,73 @@
*/ */
#include <spider/runtime/cpu/CPU.hpp> #include <spider/runtime/cpu/CPU.hpp>
#include <spider/runtime/memory/RAM.hpp>
#include <cmath> // provides std::fmod, std::fma and cast support #include <cmath> // provides std::fmod, std::fma and cast support
namespace spider { namespace spider {
// ── 0x040 — SFB: Store (User) Flag Bit ──────────────────────────────
void CPU::SFB() { void CPU::SFB() {
fetchOperSrc(); // TODO: Implement SFB
fetchOperDst();
u8 flag_idx = _dst->_u8 & 0x3;
u64 flag_bit = CPU::FLAG_USER_A << flag_idx;
if (_src->_u64 != 0) {
RF |= flag_bit;
} else {
RF &= ~flag_bit;
}
} }
// ── 0x041 — LFB: Load (User) Flag Bit ──────────────────────────────
void CPU::LFB() { void CPU::LFB() {
fetchOperSrc(); // TODO: Implement LFB
fetchOperDst();
u8 flag_idx = _src->_u8 & 0x3;
u64 flag_bit = CPU::FLAG_USER_A << flag_idx;
_dst->_u64 = (RF & flag_bit) ? 1 : 0;
(this->*_post)();
} }
// ── 0x042 — JUF: Jump to absolute position, if user flag is true ────
void CPU::JUF() { void CPU::JUF() {
fetchOperSrc(); // TODO: Implement JUF
fetchOperDst();
u8 flag_idx = _src->_u8 & 0x3;
u64 flag_bit = CPU::FLAG_USER_A << flag_idx;
if (RF & flag_bit) {
RI = _dst->_u64;
}
} }
// ── 0x043 — JUR: Jump to relative position, if user flag is true ────
void CPU::JUR() { void CPU::JUR() {
fetchOperSrc(); // TODO: Implement JUR
fetchOperDst();
u8 flag_idx = _src->_u8 & 0x3;
u64 flag_bit = CPU::FLAG_USER_A << flag_idx;
if (RF & flag_bit) {
i64 offset;
switch (_size) {
case 0b00: offset = static_cast<i64>(_dst->_i8); break;
case 0b01: offset = static_cast<i64>(_dst->_i16); break;
case 0b10: offset = static_cast<i64>(_dst->_i32); break;
case 0b11: offset = _dst->_i64; break;
default: offset = 0; break;
}
RI = static_cast<u64>(static_cast<i64>(RI) + offset);
}
} }
// ── 0x044 — PUSH: Dst -> pushed into stack ──────────────────────────
void CPU::PUSH() { void CPU::PUSH() {
fetchOperDst(); // TODO: Implement PUSH
u8 bytes = 1 << _size;
for (u8 i = 0; i < bytes; i++) {
_ram->at(RS + i) = (*_dst)[i];
}
RS += bytes;
} }
// ── 0x045 — POP: popped from stack -> Dst ───────────────────────────
void CPU::POP() { void CPU::POP() {
fetchOperDst(); // TODO: Implement POP
u8 bytes = 1 << _size;
RS -= bytes;
_ram->loadRegister(RS, _size, _dst);
(this->*_post)();
} }
// ── 0x046 — ALLOC: Dst -> heap ptr of size Dst ──────────────────────
void CPU::ALLOC() { void CPU::ALLOC() {
fetchOperDst(); // TODO: Implement ALLOC
// TODO: Proper heap allocation with gap tracking.
_dst->_u64 = 0;
(this->*_post)();
} }
// ── 0x047 — HFREE: Frees heap ptr in Dst ────────────────────────────
void CPU::HFREE() { void CPU::HFREE() {
fetchOperDst(); // TODO: Implement HFREE
// TODO: Proper heap deallocation.
} }
// ── 0x04A — CALL: Performs a function call, step XX ──────────────────
void CPU::CALL() { void CPU::CALL() {
fetchOperDst(); // TODO: Implement CALL
u64 target = _dst->_u64;
register_t rz_save;
rz_save._u64 = RZ;
for (u8 i = 0; i < 8; i++) {
_ram->at(RS + i) = rz_save[i];
}
RS += 8;
register_t ri_save;
ri_save._u64 = RI;
for (u8 i = 0; i < 8; i++) {
_ram->at(RS + i) = ri_save[i];
}
RS += 8;
RZ = RS;
RI = target;
} }
// ── 0x04B — RET: Undoes a function call, step XX ────────────────────
void CPU::RET() { void CPU::RET() {
RS = RZ; // TODO: Implement RET
RS -= 8;
register_t ri_restore;
_ram->loadRegister(RS, 0b11, &ri_restore);
RI = ri_restore._u64;
RS -= 8;
register_t rz_restore;
_ram->loadRegister(RS, 0b11, &rz_restore);
RZ = rz_restore._u64;
} }
// ── 0x04C — EDI: bool( Dst ) -> Enable External Interrupts Bit ─────
void CPU::EDI() { void CPU::EDI() {
fetchOperDst(); // TODO: Implement EDI
if (_dst->_u64 != 0) {
RF &= ~CPU::FLAG_EXT_INT_DISABLE;
} else {
RF |= CPU::FLAG_EXT_INT_DISABLE;
}
} }
// ── 0x04D — SHSS: bool( Dst ) -> Hot Swap Signal Bit ────────────────
void CPU::SHSS() { void CPU::SHSS() {
fetchOperDst(); // TODO: Implement SHSS
if (_dst->_u64 != 0) {
RF |= CPU::FLAG_HOTSWAP_SIGNAL;
} else {
RF &= ~CPU::FLAG_HOTSWAP_SIGNAL;
}
} }
// ── 0x050 — FLI: Float Load Immediate ───────────────────────────────
void CPU::FLI() { void CPU::FLI() {
fetchOperDst(); // TODO: Implement FLI
(this->*_post)();
} }
// ── 0x051 — FNEG: - Dst -> Dst ──────────────────────────────────────
void CPU::FNEG() { void CPU::FNEG() {
fetchOperDst(); // TODO: Implement FNEG
switch (_size) {
case 0b10: _dst->_f32 = -_dst->_f32; break;
case 0b11: _dst->_f64 = -_dst->_f64; break;
default: break;
}
(this->*_post)();
} }
// ── 0x052 — FADD: Dst + Src -> Dst ──────────────────────────────────
void CPU::FADD() { void CPU::FADD() {
fetchOperSrc(); // TODO: Implement FADD
fetchOperDst();
switch (_size) {
case 0b10: _dst->_f32 += _src->_f32; break;
case 0b11: _dst->_f64 += _src->_f64; break;
default: break;
}
(this->*_post)();
} }
// ── 0x053 — FSUB: Dst - Src -> Dst ──────────────────────────────────
void CPU::FSUB() { void CPU::FSUB() {
fetchOperSrc(); // TODO: Implement FSUB
fetchOperDst();
switch (_size) {
case 0b10: _dst->_f32 -= _src->_f32; break;
case 0b11: _dst->_f64 -= _src->_f64; break;
default: break;
}
(this->*_post)();
} }
// ── 0x054 — FMUL: Float Multiplication ─────────────────────────────────── // ── 0x054 — FMUL: Float Multiplication ───────────────────────────────────

61
src/spider/runtime/instr/Instr_LLGS.cpp Normal file
View File

@@ -0,0 +1,61 @@
/**
* @brief LLGS — Easter egg by Arturo Balam (Data - 7A)
*
* Opcode: 0x0F1
*
* Writes a Spider ASCII art into RAM starting at address 0x00,
* and loads the author signature into RA as a packed ASCII string.
* This version matches the custom mechanical spider design
* and is formatted to fit an 8-byte RAM viewer width.
*
* RAM layout after LLGS executes (8 characters per row, 4 rows total):
* 0x00: "// _ \\" (Row 1)
* 0x08: "\\( )// " (Row 2)
* 0x10: " //()\\ " (Row 3)
* 0x18: " \\ // " (Row 4)
*
* RA after execution: 0x4C4C475300000000ULL ("LLGS" in ASCII, zero-padded)
* (L=0x4C, L=0x4C, G=0x47, S=0x53)
*/
#include <spider/runtime/cpu/CPU.hpp>
#include <spider/runtime/memory/RAM.hpp>
namespace spider {
void CPU::LLGS() {
// -- Write Spider ASCII art into RAM ---------------------------------
// Padded with exact spaces to ensure it never wraps in an 8-byte viewer
// Row 0: "// _ \\ "
_ram->at(0x00) = '/'; _ram->at(0x01) = '/';
_ram->at(0x02) = ' '; _ram->at(0x03) = '_';
_ram->at(0x04) = ' '; _ram->at(0x05) = '\\';
_ram->at(0x06) = '\\'; _ram->at(0x07) = ' ';
// Row 1: "\\( )// "
_ram->at(0x08) = '\\'; _ram->at(0x09) = '\\';
_ram->at(0x0A) = '('; _ram->at(0x0B) = ' ';
_ram->at(0x0C) = ')'; _ram->at(0x0D) = '/';
_ram->at(0x0E) = '/'; _ram->at(0x0F) = ' ';
// Row 2: " //()\\ "
_ram->at(0x10) = ' '; _ram->at(0x11) = '/';
_ram->at(0x12) = '/'; _ram->at(0x13) = '(';
_ram->at(0x14) = ')'; _ram->at(0x15) = '\\';
_ram->at(0x16) = '\\'; _ram->at(0x17) = ' ';
// Row 3: " \\ // "
_ram->at(0x18) = ' '; _ram->at(0x19) = '\\';
_ram->at(0x1A) = '\\'; _ram->at(0x1B) = ' ';
_ram->at(0x1C) = ' '; _ram->at(0x1D) = '/';
_ram->at(0x1E) = '/'; _ram->at(0x1F) = ' ';
// -- Load mnemonic into RA ------------------------
// "LLGS" packed as ASCII bytes into RA
RA._u64 = 0x4C4C475300000000ULL;
}
} // namespace spider