52c30d82a7
Round-37 anchor reframe: both engines install the SAME static .rdata vtable
0x820A183C at [0x828E1F08]. Instance VAs differ only because of ε-class
allocator divergence (audit-043). vtable bytes byte-identical; the user
prompt's "factory/registry" framing was falsified.
Phase A walkthrough (rounds A1..A8):
- A.1 canary --audit_jit_prolog_pc=0x821741C8: tid=6, r3=0xBCCC4A80 (= inner
sub-object of [0x828E1F08]'s singleton), LR=0x822F1D5C (return-from-bctrl
inside sub_822F1AA8)
- A.2 found tid=6 spawn site sub_821746B0 at PC 0x82174824 spawning
entry=sub_821748F0 ctx=BC365700/BC366DA0. sub_822F1AA8 ALSO spawns a
second thread (entry=sub_822F1EE0 ctx=BCE24A40) at PC 0x822F1B08
- A.3 sub_822F1AA8 has 2 callers, both in sub_8216EA68 (its sole caller is
sub_824AB748 = entry_point)
- A.4 ours mirror probe: sub_821746B0 enters, [0x828E2B14] gate passes,
ExCreateThread fires returning handle 0x1070 (= tid=13). Ours' tid=13
IS the same logical thread as canary's spawned silph initializer
- A.5 canary --audit_jit_prolog_pc=0x821749C0: fires only 2× on short-lived
tid=17, tid=26 (the spawned initializers — NOT tid=6)
- A.6 canary --audit_jit_prolog_pc=0x822F1AA8: fires 1× on tid=6 with
r3=0xBCE24A40 LR=0x8216EE14 (the second sub_822F1AA8 call site)
- A.7 canary --audit_jit_prolog_pc=0x824AB748 (entry_point): fires on
tid=00000006. CONFIRMS canary's tid=6 = canary's main thread.
Verdict: identical call chain entry_point → sub_8216EA68 → sub_822F1AA8 in
both engines; same controller (ε-divergent VA, byte-identical fields).
Canary's main thread stays in sub_822F1AA8's dispatcher loop firing
sub_821741C8 ~1678×/30s. Ours' main thread exits the loop and thread-joins
on the spawned initializer (tid=13), which is itself wedged on handle 0x1078
forever.
Loop exit is gated by bit 28 of [r30+0] (the controller's flag word). Same
value 0x21 at function entry in both engines. Some code between entry and
loop check sets bit 28 in ours but not in canary. Mem-watch on 0x40d09a40
shows zero guest stores in ours' 50M parallel run — setter is either a
kernel-side store, computed alias, or probe-quantum-elided JIT store.
Phase B classification: Class 3a (state-divergence on controller object).
The vtable is the same; the controller's bit 28 evolves differently during
sub_822F1AA8 setup. Class 4 (synthesis) is now less attractive since we
correctly reach the dispatcher with the right inputs — we just exit too
soon.
Phase C will need either JIT instrumentation to identify the bit-28 setter,
or a kernel-side hook to clear bit 28 on entry to the loop check site.
Findings notes:
- round-A4b-ours-spawn-gate/FINDINGS.md (spawn topology + tid mapping)
- round-A8-ours-822F1AA8-trace/FINDINGS.md (full loop structure + bit-28 gate)
New reading-error class #18: probe-output anchor misframing (singleton[VA]=X
vtable=Y was misread as "Y is canary-only vtable" when Y is the same
.rdata vtable in both engines).
Branch: iterate-2C/silph-ui-spawn-trace off master @ 229b46c.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
xenia-rs
Rust reimplementation of the Xbox 360 emulator xenia, focused on reverse-engineering and preservation rather than full-speed play. The initial target is Project Sylpheed — Arc of Deception; getting the title disassembled, traced, and far enough into its init path to understand its engine.
Heavy cross-reference to xenia-canary for CPU context setup, kernel export behavior, and XEX loading semantics.
Status
- XEX loader — XEX2 header parsing, LZX decompression, AES decryption, PE section parsing.
- VFS / XISO — XGD2 dual-layer disc images (with the 0x0FD90000 partition offset).
- PPC interpreter — 200+ opcodes, PowerPC 32/64-bit GPR/FPR, VMX128 decoding.
- Static analyzer — function discovery (prolog/epilog heuristics), cross-references, labels, save/restore helper detection, assembly text + SQLite database output.
- Kernel HLE — minimal subset driving Project Sylpheed: ~170 xboxkrnl + xam exports (critical sections, events, TLS, virtual memory, Vd stubs, XAM input/user/content).
- Debugger — in-memory step/break, SQLite execution + import-call + branch tracing.
Not yet: GPU (xenos/xe-shader), APU audio, HID, kernel scheduler, full threading, exception delivery.
Workspace
crates/
xenia-types # shared primitive types, bitflags
xenia-memory # guest memory, paged allocator, page table
xenia-cpu # PPC decoder, interpreter, context
xenia-xex # XEX2 loader, PE parser, LZX, AES
xenia-vfs # XISO / disc-image reader
xenia-kernel # HLE kernel state, exports, XAM
xenia-gpu # (stub) Xenos command processor
xenia-apu # (stub) XAudio
xenia-hid # (stub) XInput
xenia-debugger # in-memory trace, breakpoints, step modes
xenia-analysis # function/xref analysis, assembly formatter, SQLite DbWriter
xenia-app # `xenia-rs` CLI binary
CLI
Build:
cargo build --release
The binary xenia-rs accepts XEX2 files or ISO / XISO disc images as input
(the loader auto-detects discs and extracts default.xex).
info / browse / disasm
Quick header / disc / first-N-instructions inspection. See --help.
extract — unpack PE + metadata
xenia-rs extract <xex-or-iso> [-o <out-dir>] [--db <sqlite-path>]
Writes <name>.pe (decompressed/decrypted PE image) and <name>.xex.json
(header metadata). With --db, also emits a SQLite database containing the
base tables: metadata, sections, imports.
dis — full disassembly
xenia-rs dis <xex-or-iso> [-o <asm-file>] [--db <sqlite-path>] [--quiet]
Runs function + cross-reference analysis and produces:
- assembly text to stdout or
-o <file>(unless--quiet) - optional SQLite DB with the base tables + disasm tables:
functions,labels,instructions,xrefs
exec — interpret with tracing
xenia-rs exec <xex-or-iso> [-n <max-instrs>] [--db <sqlite-path>]
[--trace-instructions] [--trace-imports] [--trace-branches]
Loads the title, initializes CPU state per xenia-canary, intercepts import
thunks with HLE kernel calls, and interprets from the entry point. Without
-n, runs until halt/fault. With --db, produces a DB that is a superset
of dis --db plus opt-in trace tables:
| flag | table | rows |
|---|---|---|
--trace-instructions |
exec_trace |
one row per interpreted instruction (PC, r3/r4, LR, SP) |
--trace-imports |
import_calls |
one row per kernel/XAM call (module, ordinal, args) |
--trace-branches |
branch_trace |
taken branches classified as call/return/jump/branch |
Cumulative DB layering
Each command's DB is a superset of the previous. A single
xenia-rs exec <iso> --db full.db --trace-instructions --trace-imports --trace-branches
produces the full picture in one pass — base tables, complete static
disassembly, and runtime traces correlatable by address/cycle.
Performance knobs
XENIA_DB_BATCH_SIZE— rows per streaming commit / trace-buffer flush (default100_000). Lower values reduce memory use; higher values reduce fsync overhead on slow disks.
The DB writer uses journal_mode=OFF, synchronous=OFF, locking_mode=EXCLUSIVE
and commits in batches; no ANALYZE is run at finalize. Indices are created
after bulk insertion with progress messages.
Example queries
-- Top 20 kernel functions called during early init
SELECT name, COUNT(*) FROM import_calls GROUP BY name ORDER BY 2 DESC LIMIT 20;
-- All basic-block leaders (targets of taken branches) not already labelled
SELECT DISTINCT bt.target
FROM branch_trace bt LEFT JOIN labels l ON l.address = bt.target
WHERE l.address IS NULL;
-- Correlate a traced call site with its static disassembly
SELECT et.cycle, i.disasm, i.ext_disasm
FROM exec_trace et JOIN instructions i ON i.address = et.address
WHERE et.address = 0x824AB748 ORDER BY et.cycle;
License
BSD-3-Clause, matching upstream xenia.