Files

MechaCat02 e6d43a23ac chore: add migration/ bundle for cross-machine setup

Bundles state that lives OUTSIDE the xenia-rs repo so a fresh clone on
another machine can be brought up to identical configuration via
migration/setup.sh:

  - claude-memory/             ~/.claude/projects/-home-fabi-RE-Project-Sylpheed/memory/
                               (103 files, 1.1 MB - MEMORY.md + every
                                project_xenia_rs_*.md from audits
                                addis_signext through audit-058)
  - project-root/dot-claude/   <project-root>/.claude/settings.json
                               (Stop hook + permissions)
  - project-root/ppc-manual/   <project-root>/ppc-manual/
                               (PowerPC reference docs, 397 files, 3.7 MB)
  - project-root/run-canary.sh <project-root>/run-canary.sh
  - README.md                  Human-readable setup checklist
  - setup.sh                   Idempotent installer (also reclones
                               xenia-canary at pinned HEAD 6de80dffe)
  - MANIFEST.md                Per-file mapping + per-file-not-bundled
                               restoration recipe

Excluded from bundle (not shippable via git):
  - Sylpheed ISO (7.8 GB; copyright; manual copy required)
  - sylpheed.db (395 MB; regenerable from XEX via analysis tooling)
  - target/ build artifacts (rebuild on target)
  - audit-runs probe firehoses (.log/.stdout/.stderr ~11 GB; rerun if needed)
  - audit-runs memory dumps (.bin ~4.5 GB; rerun audit-026/027/029 if needed)
  - xenia-canary checkout (setup.sh reclones from
    git.mc02.dev/fabi/Xenia-Canary.git at HEAD 6de80dffe)

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

2026-05-10 21:38:38 +02:00

6.9 KiB

Raw Blame History

`lvx` — Load Vector Indexed

Category: Memory · Form: X · Opcode: 0x7c0000ce

Assembler Mnemonics

Mnemonic	XML entry	Flags	Description
`lvx`	`lvx`	—	Load Vector Indexed
`lvx128`	`lvx128`	—	Load Vector Indexed 128

Syntax

lvx [VD], [RA0], [RB]
lvx128 [VD], [RA0], [RB]

Encoding

`lvx` — form `X`

Opcode word: 0x7c0000ce
Primary opcode (bits 0–5): 31
Extended opcode: 103
Synchronising: no

Bits	Field	Meaning
0–5	`OPCD`	primary opcode
6–10	`RT/FRT/VRT`	destination
11–15	`RA/FRA/VRA`	source A
16–20	`RB/FRB/VRB`	source B
21–30	`XO`	extended opcode (10 bits)
31	`Rc`	record-form flag

`lvx128` — form `VX128_1`

Opcode word: 0x100000c3
Primary opcode (bits 0–5): 4
Extended opcode: 195
Synchronising: no

Bits	Field	Meaning
0–5	`OPCD`	primary opcode (4)
6–10	`VD128l`	destination low 5 bits
11–15	`RA`	address register
16–20	`RB`	offset register
21–27	`XO`	extended opcode
28–29	`VD128h`	destination high 2 bits
30–31	`—`	reserved

Operands

Field	Role	Description
`RA0`	lvx: read; lvx128: read	Source GPR; when the encoded register number is 0 the operand is the literal 64-bit zero, not `r0`.
`RB`	lvx: read; lvx128: read	Source GPR.
`VD`	lvx: write; lvx128: write	Destination vector register.

Register Effects

`lvx`

Reads (always): RA0, RB
Reads (conditional): none
Writes (always): VD
Writes (conditional): none

`lvx128`

Reads (always): RA0, RB
Reads (conditional): none
Writes (always): VD
Writes (conditional): none

Status-Register Effects

No condition-register or status-register effects.

Operation (pseudocode)

EA <- ((RA|0) + (RB)) & ~0xF           ; align to 16
VD <- byteswap(MEM(EA, 16))

C Translation Example

/* lvx VD, RA, RB — 16-byte aligned load of a vector register      */
uint64_t base = (insn.RA == 0) ? 0 : r[insn.RA];
uint32_t ea   = (uint32_t)((base + r[insn.RB]) & ~(uint64_t)0xF);
v[insn.VD]    = mem_read_vec128_be(ea);

Implementation References

lvx

xenia-canary XML: tools/ppc-instructions.xml — search for mnem="lvx"
xenia-canary emit: src/xenia/cpu/ppc/ppc_emit_altivec.cc:139
xenia-rs opcode: crates/xenia-cpu/src/opcode.rs:47
xenia-rs decoder: crates/xenia-cpu/src/decoder.rs:775
xenia-rs interpreter: crates/xenia-cpu/src/interpreter.rs:1833-1840

xenia-rs interpreter body (frozen snapshot)

        PpcOpcode::lvx => {
            let ea = if instr.ra() == 0 { 0u64 } else { ctx.gpr[instr.ra()] };
            let ea = (ea.wrapping_add(ctx.gpr[instr.rb()]) & !0xF) as u32; // aligned
            let mut bytes = [0u8; 16];
            for i in 0..16 { bytes[i] = mem.read_u8(ea + i as u32); }
            ctx.vr[instr.rd()] = xenia_types::Vec128::from_bytes(bytes);
            ctx.pc += 4;
        }

lvx128

xenia-canary XML: tools/ppc-instructions.xml — search for mnem="lvx128"
xenia-canary emit: src/xenia/cpu/ppc/ppc_emit_altivec.cc:142
xenia-rs opcode: crates/xenia-cpu/src/opcode.rs:47
xenia-rs decoder: crates/xenia-cpu/src/decoder.rs:415
xenia-rs interpreter: crates/xenia-cpu/src/interpreter.rs:1841-1848

xenia-rs interpreter body (frozen snapshot)

        PpcOpcode::lvx128 => {
            let ea = if instr.ra() == 0 { 0u64 } else { ctx.gpr[instr.ra()] };
            let ea = (ea.wrapping_add(ctx.gpr[instr.rb()]) & !0xF) as u32;
            let mut bytes = [0u8; 16];
            for i in 0..16 { bytes[i] = mem.read_u8(ea + i as u32); }
            ctx.vr[instr.vd128()] = xenia_types::Vec128::from_bytes(bytes);
            ctx.pc += 4;
        }

Special Cases & Edge Conditions

Alignment is forced, not checked. The low four bits of the effective address are cleared before the load — passing an unaligned EA silently reads from EA & ~0xF rather than trapping. This differs from scalar loads (no alignment enforcement) and from lvewx etc. (which architecturally use the exact EA for lane placement).
Big-endian lane layout. The byte at the aligned base goes into vector lane 0 (most-significant byte); the byte at base+15 lands in lane 15. On little-endian hosts the 16-byte block is byte-swapped at the memory boundary so the PowerPC-visible layout is preserved.
RA0 semantics. When RA = 0, the base is the literal zero. Combined with the alignment mask this lets lvx VD, 0, RB load from RB & ~0xF.
No update form. Unlike scalar loads, VMX loads have no u variant that post-writes the base. Use lvxl for the cache-hint variant ("last" — the line is not expected to be reused soon).
VMX128 sibling (lvx128). Identical semantics; the only difference is the operand encoding. VMX128 uses a 7-bit register index split across three non-contiguous bit fields (VD128l ‖ VD128h), addressing v0..v127.
Atomic 16 bytes. The read is a single conceptual load; observers see either all 16 old bytes or all 16 new bytes (to the extent the surrounding cache coherency model allows).
Cache-line behaviour. A 16-byte aligned load fits within one Xenon 128-byte cache line; cold-line cost is one fill.

stvx, stvx128 — the store counterparts.
lvxl, lvxl128 — cache-hint "last-use" load variants.
lvebx, lvehx, lvewx — single-element loads at the exact (sub-aligned) address.
lvlx, lvrx — load-left / load-right for unaligned vector I/O (combine to read across alignment).

IBM Reference

AIX 7.3 — lvx (Load Vector Indexed)
PowerISA v2.07B Book I "Vector Facility" for full vector-load semantics; lvx128 is documented in the Xbox 360 XDK.

6.9 KiB Raw Blame History Unescape Escape

lvx — Load Vector Indexed

Assembler Mnemonics

Syntax

Encoding

lvx — form X

lvx128 — form VX128_1

Operands

Register Effects

lvx

lvx128

Status-Register Effects

Operation (pseudocode)

C Translation Example

Implementation References

Special Cases & Edge Conditions

Related Instructions

IBM Reference

6.9 KiB

Raw Blame History

`lvx` — Load Vector Indexed

`lvx` — form `X`

`lvx128` — form `VX128_1`

`lvx`

`lvx128`