mirrors/Odin
1
0
Fork 0
mirror of https://github.com/odin-lang/Odin.git synced 2026-06-19 16:42:33 +00:00
Code Issues Packages Projects Releases Wiki Activity
Files
fae15847a35d5ae889dbfa65bb7274b2918f97e4
Odin/core/rexcode/isa/mos6502/decoder.odin
Brendan Punsky fae15847a3 rexcode: buffer-sizing helpers across all ISAs + naming-contract doc 
Roll the encode/decode buffer-sizing helpers (added for x86 in 49787b7de) out
to every other ISA, and document them in the cross-arch naming contract.

Per arch (arm32, arm64, mips, riscv, ppc, ppc_vle, rsp, mos6502, mos65816):
  - encode_max_code_size / encode_max_relocation_count now key off the
    []Instruction slice (were int counts); bodies unchanged (* MAX_INST_SIZE).
  - encode_reserve(code, relocs, instructions): grows the caller's code []u8 by
    length and reserves relocs by capacity; allocates no new buffers.
  - decode_max_instruction_count / decode_estimate_instruction_count: exact
    ceiling and typical estimate, keyed off the min/avg instruction size per
    arch (fixed-4: arm64/mips/ppc/rsp; min-2: arm32/riscv/ppc_vle; min-1: mos).
  - decode_reserve(instructions, inst_info, label_defs, data, exact=false).

docs/cross_arch_design.md: helpers added to the naming contract.

No behavior change to the existing size helpers (signature only). All 10 ISAs
check + test green (x86 2282, arm32 600, arm64 461, mips 281, riscv 154, ppc 31,
ppc_vle 281, rsp 70, mos6502 148, mos65816 53).
2026-06-19 04:11:30 -04:00

275 lines
8.7 KiB
Odin
Raw Blame History

// rexcode · Brendan Punsky (dotbmp@github), original author
package rexcode_mos6502
import "core:rexcode/isa"
// =============================================================================
// MOS 6502 DECODER
// =============================================================================
//
// Two passes, mirroring MIPS/RSP. The 6502-specific bits:
//
// - Variable length 1..7 bytes per instruction. The matched entry tells
// us the byte count via `entry.length`.
//
// - CPU-tier filtering: the same opcode byte means different things on
// NMOS vs 65C02 vs HuC6280 (e.g. $07 = SLO on NMOS-undoc, RMB0 on
// 65C02). The caller passes a target `CPU` value and the matcher
// skips entries above that tier.
//
// - Tier rule:
// NMOS accepts NMOS only
// NMOS_UNDOC accepts NMOS + NMOS_UNDOC
// CMOS_65C02 accepts NMOS + CMOS_65C02 (NOT NMOS_UNDOC -- those
// opcodes mean RMB/SMB/etc. on 65C02)
// HUC6280 accepts NMOS + CMOS_65C02 + HUC6280 (also not undoc)
//
// - Operand extraction is the inverse of pack_operand_inline in
// encoder.odin: pull each operand from its known offset+size in the
// instruction byte stream.
Instruction_Info :: struct {
offset: u32,
decode_entry: u16,
_: u16,
}
#assert(size_of(Instruction_Info) == 8)
decode :: proc(
data: []u8,
relocs: []Relocation,
instructions: ^[dynamic]Instruction,
inst_info: ^[dynamic]Instruction_Info,
label_defs: ^[dynamic]Label_Definition,
errors: ^[dynamic]Error,
cpu: CPU = .NMOS,
) -> (byte_count: u32, ok: bool) {
n_bytes := u32(len(data))
errors_start := u32(len(errors))
pending_branches: [dynamic]isa.Branch_Target
defer delete(pending_branches)
for byte_count < n_bytes {
inst: Instruction
info: Instruction_Info
entry_idx, consumed := decode_one_inline(data, byte_count, n_bytes, cpu, &inst, &info)
if entry_idx < 0 {
append(errors, Error{inst_idx = byte_count, code = .INVALID_OPCODE})
inst = Instruction{mnemonic = .INVALID, length = 1}
info = Instruction_Info{offset = byte_count}
consumed = 1
} else {
inst_idx_for_branches := u32(len(instructions))
for slot in 0..<inst.operand_count {
op := &inst.ops[slot]
if op.kind == .RELATIVE && op.relative >= 0 {
append(&pending_branches, isa.Branch_Target{
inst_idx = inst_idx_for_branches,
op_idx = slot,
target = u32(op.relative),
})
}
}
}
append(instructions, inst)
append(inst_info, info)
byte_count += consumed
}
isa.infer_labels_from_branches(pending_branches[:], byte_count, label_defs, relocs)
ok = u32(len(errors)) == errors_start
return
}
// =============================================================================
// Internal: decode one instruction starting at data[pc]
// =============================================================================
//
// Returns the matched DECODE_ENTRIES index (or -1) and the number of bytes
// consumed (always >= 1 to make forward progress).
@(private="file")
decode_one_inline :: #force_inline proc "contextless" (
data: []u8, pc: u32, n_bytes: u32, cpu: CPU,
inst: ^Instruction, info: ^Instruction_Info,
) -> (entry_idx: int, consumed: u32) {
opcode := data[pc]
range := DECODE_INDEX_OPCODE[opcode]
if range.count == 0 { return -1, 1 }
base := int(range.start)
cnt := int(range.count)
matched_idx := -1
for i in 0..<cnt {
e := &DECODE_ENTRIES[base + i]
if cpu_accepts(cpu, e.cpu) {
matched_idx = base + i
break
}
}
if matched_idx < 0 { return -1, 1 }
entry := &DECODE_ENTRIES[matched_idx]
length := u32(entry.length)
if pc + length > n_bytes {
// Truncated instruction at end of buffer.
return -1, 1
}
inst.mnemonic = entry.mnemonic
inst.length = entry.length
inst.flags = {}
cnt_used: u8 = 0
if entry.ops[0] != .NONE {
inst.ops[0] = extract_operand_inline(data, pc, entry.ops[0], entry.enc[0])
cnt_used = 1
if entry.ops[1] != .NONE {
inst.ops[1] = extract_operand_inline(data, pc, entry.ops[1], entry.enc[1])
cnt_used = 2
if entry.ops[2] != .NONE {
inst.ops[2] = extract_operand_inline(data, pc, entry.ops[2], entry.enc[2])
cnt_used = 3
}
}
}
inst.operand_count = cnt_used
info.offset = pc
info.decode_entry = u16(matched_idx)
return matched_idx, length
}
// CPU tier acceptance check (see top-of-file docstring).
@(private="file")
cpu_accepts :: #force_inline proc "contextless" (target, entry: CPU) -> bool {
switch target {
case .NMOS:
return entry == .NMOS
case .NMOS_UNDOC:
return entry == .NMOS || entry == .NMOS_UNDOC
case .CMOS_65C02:
return entry == .NMOS || entry == .CMOS_65C02
case .HUC6280:
return entry == .NMOS || entry == .CMOS_65C02 || entry == .HUC6280
}
return false
}
// -----------------------------------------------------------------------------
// Operand extraction (inverse of pack_operand_inline)
// -----------------------------------------------------------------------------
@(private="file")
extract_operand_inline :: #force_inline proc "contextless" (
data: []u8, pc: u32, ot: Operand_Type, en: Operand_Encoding,
) -> Operand {
switch en {
case .NONE:
return {}
case .IMPL:
// The accumulator-implicit forms (ASL A, ROL A, ...) tag the
// operand as REGISTER=A so the printer reproduces "A".
if ot == .A_IMPL {
return Operand{reg = A, kind = .REGISTER, size = 1}
}
return {}
case .BYTE_1_IMM:
return Operand{immediate = i64(data[pc+1]), kind = .IMMEDIATE, size = 1}
case .BYTE_1_ADDR:
return mem_operand(u16(data[pc+1]), ot)
case .BYTE_1_REL:
// PC-relative branch: target = (PC + 2) + signed_imm8
rel := i32(i8(data[pc+1]))
target := u32(i32(pc) + 2 + rel)
return Operand{relative = i64(target), kind = .RELATIVE, size = 1}
case .WORD_1_ADDR:
addr := u16(data[pc+1]) | (u16(data[pc+2]) << 8)
return mem_operand(addr, ot)
case .BYTE_2_REL:
// BBR/BBS rel byte at offset 2; instruction is 3 bytes long.
rel := i32(i8(data[pc+2]))
target := u32(i32(pc) + 3 + rel)
return Operand{relative = i64(target), kind = .RELATIVE, size = 1}
case .WORD_1:
v := u16(data[pc+1]) | (u16(data[pc+2]) << 8)
return Operand{immediate = i64(v), kind = .IMMEDIATE, size = 2}
case .WORD_3:
v := u16(data[pc+3]) | (u16(data[pc+4]) << 8)
return Operand{immediate = i64(v), kind = .IMMEDIATE, size = 2}
case .WORD_5:
v := u16(data[pc+5]) | (u16(data[pc+6]) << 8)
return Operand{immediate = i64(v), kind = .IMMEDIATE, size = 2}
case .BYTE_2_ADDR:
return mem_operand(u16(data[pc+2]), ot)
case .WORD_2_ADDR:
addr := u16(data[pc+2]) | (u16(data[pc+3]) << 8)
return mem_operand(addr, ot)
}
return {}
}
// Build a MEMORY operand with the addressing mode implied by Operand_Type.
@(private="file")
mem_operand :: #force_inline proc "contextless" (addr: u16, ot: Operand_Type) -> Operand {
mode: Address_Mode
size: u8 = 1
#partial switch ot {
case .MEM_ZP: mode = .ZP
case .MEM_ZP_X: mode = .ZP_X
case .MEM_ZP_Y: mode = .ZP_Y
case .MEM_ABS: mode = .ABS; size = 2
case .MEM_ABS_X: mode = .ABS_X; size = 2
case .MEM_ABS_Y: mode = .ABS_Y; size = 2
case .MEM_IND: mode = .IND; size = 2
case .MEM_IND_X: mode = .IND_X
case .MEM_IND_Y: mode = .IND_Y
case .MEM_IND_ZP: mode = .IND_ZP
case .MEM_IND_ABS_X: mode = .IND_ABS_X; size = 2
}
return Operand{
mem = Memory{address = addr, mode = mode},
kind = .MEMORY,
size = size,
}
}
// -----------------------------------------------------------------------------
// Buffer-Sizing Helpers (let callers pre-size so the decode hot path never
// reallocates; allocates no new buffers -- only the caller's arrays grow).
// -----------------------------------------------------------------------------
// Instruction-count ceiling for `data` (shortest instruction is 1 byte).
@(require_results)
decode_max_instruction_count :: #force_inline proc "contextless" (data: []u8) -> int {
return len(data)
}
// Typical-case estimate of the instruction count for `data`.
@(require_results)
decode_estimate_instruction_count :: #force_inline proc "contextless" (data: []u8) -> int {
return len(data) / 2 + 8
}
// Pre-size the caller's decode output arrays for `data` (reserves on top of any
// existing elements; nil to skip; exact=true for the ceiling, else the estimate).
decode_reserve :: proc(instructions: ^[dynamic]Instruction, inst_info: ^[dynamic]Instruction_Info, label_defs: ^[dynamic]Label_Definition, data: []u8, exact: bool = false) {
n := exact ? decode_max_instruction_count(data) : decode_estimate_instruction_count(data)
if instructions != nil { reserve(instructions, len(instructions) + n) }
if inst_info != nil { reserve(inst_info, len(inst_info) + n) }
if label_defs != nil { reserve(label_defs, len(label_defs) + n) }
}
Reference in New Issue View Git Blame Copy Permalink