Five parallel agents + dat probes ruled out:
- byte-level decode primitive (matches ACViewer)
- polygon emission (no ST_DOUBLE / Surface.Type & 6 issues)
- per-PART texture-override scoping (correctly per-MeshRef'd)
- SubPalette indexing convention (full-size 2048 palettes, *8 wire un-pack
is single-applied)
Smoking gun: for +Acdream the server sends 10 SubPaletteSwap ranges that
overlay palette indices [0..320), [576..1024), [1392..1488), [1728..1920).
The complement — [320..576), [1024..1392), [1488..1728), [1920..2048) —
is NOT overlaid. Base palette 0x0400007E at those indices has
red/skin tones. Coat texture UVs sampling those non-overlaid indices
render as visible "skin stub at top of coat".
Either ACE sends incomplete SubPaletteSwap data, or retail does extra
client-side ClothingTable computation we (and ACE) don't.
Diagnostic harness now lives at tools/InspectCoatTex/Program.cs;
GameWindow's DUMP_CLOTHING also probes runtime SubPalette dat sizes.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Adds five diagnostics, no behavior changes. All gated on existing
ACDREAM_REMOTE_VEL_DIAG=1 env var. Plan at
~/.claude/plans/yes-make-a-plan-parsed-axolotl.md.
Five hypotheses surviving from the four-agent investigation
(docs/research/2026-05-03-remote-anim-cycle/investigation-prompt.md):
H1 SEQSTATE silently swallowed by OMEGA_DIAG sharing throttle clock
H2 ApplyServerControlledVelocityCycle races UM-driven SetCycle per UP
H3 SetCycle fast-path returns without updating _currNode
H4 GetLink/GetCycle null → defensive fallback lands on stale head
H5 PartTemplate.Count diverges from anim PartFrames.Count → silent
identity-quat freeze
Diagnostics added (all log lines are grep-prefixed):
D1 Split LastSeqStateLogTime field for SEQSTATE — own throttle.
Foundational: every other diag depends on SEQSTATE telling truth.
D2 [UPCYCLE] inside ApplyServerControlledVelocityCycle, +
[UPCYCLE_SRC] at the call site (wire vs synth velocity).
D3 [SCFAST] in fast-path return, [SCFULL] at full-rebuild end.
D4 [SCNULLFALLBACK] in the null-data defensive fallback.
D5 [PARTSDIAG] with pt.Count / seqFrames.Count / setup.Parts.Count /
anim.PartFrames[0].Frames.Count + sum-of-components hash.
Repro recipe:
$env:ACDREAM_INTERP_MANAGER = "1"
$env:ACDREAM_REMOTE_VEL_DIAG = "1"
dotnet run … 2>&1 | Tee-Object tools/diag-logs/walkrun-<ts>.log
Then watch a retail-driven character through acdream and exercise:
idle → W run → release → shift+W walk → release → demote → promote →
run+turn (this last one is the H1 trap).
Decision matrix in the plan file maps each [TAG] signature to a
specific Commit B fix.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
When AnimationSequencer.SetCycle transitions between forward-locomotion
cycles (Walk↔Run, Walk↔WalkBackward, etc.) — i.e. when both old and new
motion's low byte is in {0x05 WalkForward, 0x06 WalkBackward, 0x07
RunForward} — do a full queue drain + _currNode/_firstCyclic reset
(matching the existing skipTransitionLink branch) instead of just
ClearCyclicTail. Without this, _currNode is left pointing into the
previous cycle's non-cyclic head (link frames from the prior Ready→walk
transition), and the visible legs continue playing those head frames
before reaching the new run cycle.
Investigation findings (cdb live trace of retail at
tools/cdb-scripts/walk_run_motion_trace.log):
Retail's actual approach is "additive add_to_queue with no truncate" —
MotionTableManager handles the natural progression via per-tick
CheckForCompletedMotions / remove_redundant_links cleanup. Acdream
doesn't have that machinery, so this fix is the closest viable
emulation: force the queue back to a clean state and rebuild from
scratch on the locomotion-cycle transition.
User-reported symptom this addresses (walk→run direct transition,
release shift while W held): visible animation cycle did not switch
until next motion event. Verified via FWD_WIRE + SETCYCLE diags that
both ACE and our SetCycle are firing correctly on the transition.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Live cdb trace of retail acclient.exe (v11.4186, PDB-matched) capturing
the exact function call sequence for a direct walk-to-run motion
transition where the user holds shift+W (walk) then releases SHIFT
while still holding W (transition to run).
Trace bps on:
- CPhysicsObj::DoInterpretedMotion (0x0050EA70)
- CPartArray::DoInterpretedMotion (0x00518750)
- MotionTableManager::PerformMovement (0x0051C0B0)
- MotionTableManager::add_to_queue (0x0051BFE0)
- MotionTableManager::truncate_animation_list (0x0051BCA0)
- CMotionTable::DoObjectMotion (0x00523E90)
- CMotionTable::StopObjectMotion (0x00523EC0)
Captured trace at tools/cdb-scripts/walk_run_motion_trace.log shows
the precise walk-to-run sequence:
[79] CPhysicsObj::DoInterpretedMotion: motion=45000005 walk start
[82] CMotionTable::DoObjectMotion: motion=45000005
[83] MotionTableManager::add_to_queue: arg1=45000005 arg2=00000001
[89] CPhysicsObj::DoInterpretedMotion: motion=44000007 run start
[92] CMotionTable::DoObjectMotion: motion=44000007
[93] MotionTableManager::add_to_queue: arg1=44000007 arg2=00000001
[104] CMotionTable::StopObjectMotion: motion=44000007 run end
Critical structural finding for #L.4-walk-run:
Retail does NOT call truncate_animation_list during the walk→run
transition. truncate_animation_list never fires in the entire 200-hit
trace. Retail also does NOT call StopObjectMotion(WalkForward) before
add_to_queue(RunForward). Retail just appends the new motion to the
queue and lets MotionTableManager (and its CheckForCompletedMotions /
remove_redundant_links per-tick cleanup, not yet traced) handle the
natural progression.
acdream's AnimationSequencer.SetCycle aggressively calls
ClearCyclicTail() at line 430 BEFORE enqueuing the new cycle, which
destroys the in-flight walk cycle's frames. The new run cycle is
enqueued but _currNode is left in a state that doesn't smoothly
continue — visible to the user as "it just blips forward walking,
AS SOON as press another key like turning, its starts running"
(the next motion event re-fires SetCycle which finally aligns state).
Fix is a structural refactor of SetCycle to mirror retail's
"additive queue with auto-cleanup" semantics. Out of scope for this
research commit; filed as #L.4 in the next ISSUES.md entry.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Three intertwined changes from a single investigation session driven by
attaching cdb to a live retail acclient.exe (v11.4186, Sept 2013 EoR
build) and tracing what retail actually DOES on the steep-roof wedge
scenario the user reported in acdream.
═══════════════════════════════════════════════════════════
1. L.5 — physics-tick MinQuantum gate (PlayerMovementController)
═══════════════════════════════════════════════════════════
Retail's CPhysicsObj::update_object subdivides per-frame dt into 1/30 s
sized integration steps and SKIPS entirely when accumulated dt is below
MinQuantum. Live trace evidence:
update_object = 40,960 calls
UpdatePhysicsInternal = 25,087 calls (61%)
i.e., 39% of update_object calls return early via the MinQuantum gate.
Retail's effective physics tick rate is 30Hz even at 60+ Hz render.
acdream's PlayerMovementController bypassed the existing PhysicsBody.
update_object and called UpdatePhysicsInternal(dt) directly each render
frame, which compressed bounce-energy / gravity-tangent accumulation
into half the time and amplified our steep-roof wedge dynamics.
Fix: add `_physicsAccum` accumulator. Integrate only when accumulated
dt ≥ MinQuantum (clamped to MaxQuantum to bound stale-frame jumps).
HugeQuantum drops accumulated time to discard truly stale frames
(debugger break, GC pause). Render still runs at full rate; only the
physics step is gated.
═══════════════════════════════════════════════════════════
2. Phase 3 reset retail-faithful kill_velocity (TransitionTypes)
═══════════════════════════════════════════════════════════
Retail's reset path (acclient_2013_pseudo_c.txt:273231-273239) gates
kill_velocity on `last_known_contact_plane_valid`:
if (last_known_valid == 0) {
set_collision_normal(step_up_normal); return COLLIDED;
}
kill_velocity(this);
last_known_valid = 0;
return COLLIDED;
Earlier in this session I deviated to "unconditional kill_velocity" as
a hypothesis-driven wedge fix. The live trace then showed the
deviation CAUSED a different wedge by zeroing V every frame, leaving
the body with no tangent momentum to escape (V = (0,0,0) for 169
consecutive frames while position pre/resolved frozen). The retail-
faithful gate is restored.
Note: the gate rarely fires in normal airborne play because our L.2.4
proximity guard clears last_known_valid soon after the body separates
from its remembered floor. Live retail trace also showed
kill_velocity = 0 hits over an entire play session — same behavior. So
acdream's kill_velocity is correct as ported now.
The supporting ObjectInfo.VelocityKilled flag + StopVelocity wiring +
PhysicsEngine.ResolveWithTransition consumer that actually zeros
body.Velocity when the flag is set — these were a no-op stub before
this session and are now correctly wired. Retail anchor:
OBJECTINFO::kill_velocity → CPhysicsObj::set_velocity({0,0,0}, 0) at
acclient_2013_pseudo_c.txt:274467-274475.
═══════════════════════════════════════════════════════════
3. Retail debugger toolchain (#35)
═══════════════════════════════════════════════════════════
When the question is "what does retail actually DO at runtime?" — not
"what does retail's code SAY" — the decomp at docs/research/named-retail/
is invaluable but doesn't capture state interactions across frames.
This commit ships infrastructure to attach Windows' cdb.exe to a live
retail acclient.exe with full PDB symbols and capture state at any
breakpoint.
- tools/pdb-extract/check_exe_pdb.py — reads any PE's CodeView entry
and reports MATCH / MISMATCH against refs/acclient.pdb's GUID.
Always run before attaching cdb. The matching v11.4186 build's
GUID is 9e847e2f-777c-4bd9-886c-22256bb87f32.
- tools/pdb-extract/dump_pdb_info.py — dumps a PDB's expected
build timestamp + GUID + age. Used to figure out which acclient.exe
build pairs with our PDB.
CLAUDE.md gets a Step -1 in the development workflow ("ATTACH cdb
TO RETAIL when behavior is the question, not code") and a full
"Retail debugger toolchain" section with the workflow, sample .cdb
script structure, and watchouts (PDB names use snake_case for some
classes / PascalCase for CPhysicsObj; ; is cdb's command separator;
killing cdb kills the debuggee; high-hit-rate breakpoints lag the game).
memory/project_retail_debugger.md captures the workflow + key findings
so future sessions inherit the toolchain by reading project memory.
═══════════════════════════════════════════════════════════
4. BSPQuery Path 6 slide-tangent restored (b1af56e behavior)
═══════════════════════════════════════════════════════════
After this session's retail-strict experiments showed that retail-
faithful Path 6 (SetCollide + Phase 3 reset chain) produces a
"lands on roof in falling animation, can't slide off" half-state in
acdream — because our acdream port of step_up_slide / cliff_slide is
incomplete for grounded-on-steep movement — the L.4 slide-tangent
deviation from commit b1af56e is restored as the pragmatic ship state.
The deviation: when an airborne sphere hits a polygon whose normal Z
is below FloorZ (≈ 0.6642, slope > ~49°), project the move along the
steep face to remove the into-wall displacement, set CollisionNormal +
SlidingNormal, return Slid. Body never gets ContactPlane on the steep
poly, never gets the half-state, slides off the slope under gravity's
tangent contribution.
Retail-strict requires the deeper step_up_slide / cliff_slide audit
(filed under #32). Until that lands, slide-tangent is the right
deviation — produces user-acceptable "slide off the roof" behavior.
═══════════════════════════════════════════════════════════
Test status: 833/833 green.
Refs:
acclient_2013_pseudo_c.txt:283950 (CPhysicsObj::update_object)
acclient_2013_pseudo_c.txt:273231-273239 (Phase 3 reset path)
acclient_2013_pseudo_c.txt:274467-274475 (OBJECTINFO::kill_velocity)
acclient_2013_pseudo_c.txt:323783-323821 (BSPTREE::find_collisions Path 6)
Closes#35. Updates #32 with L.4/L.5 status.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Independent code review by an external agent (2026-04-27) flagged
that SkyRenderer.EnsureMeshUploaded only ever called
_dats.Get<GfxObj>(...) — every 0x020xxx Setup ID returned null and
got cached as an empty submesh list, silently dropping every
Setup-backed sky object across the Dereth Region. In Rainy DG3
alone that's 6 dropped SkyObjects (0x02000714, 0x02000BA6 ×2,
0x02000588 ×4, 0x02000589 ×3 across various time-of-day windows).
Verbatim from retail's CelestialPosition struct at acclient.h:35451:
struct CelestialPosition {
IDClass<...> gfx_id;
IDClass<...> pes_id; // particle scheduler
float heading; float rotation;
Vector3 tex_velocity;
float transparent; float luminosity; float max_bright;
unsigned int properties;
};
Per the named retail decomp, CPhysicsObj::InitPartArrayObject (decomp
~280484) dispatches gfx_id by type prefix: type 6 → direct GfxObj,
type 7 → Setup via CPartArray::CreateSetup (decomp ~287490) which
walks Setup.Parts. Mirror that here: detect 0x020xxxxx in
EnsureMeshUploaded, route to a new EnsureSetupUploaded helper that
flattens via SetupMesh.Flatten (existing Phase-2 utility) and bakes
each part's transform into the vertex positions before upload.
Sky setups don't animate in any way that affects the static-mesh
visual we render here.
Probe extension: also added the Diffuse column to RainMeshProbe's
sky-surface audit so the (Type, Translucency, Luminosity, Diffuse)
quadruple is visible on every flag-bit row.
Visual impact at verification launch: not observable. The Setup
objects in Rainy DGs appear to be tiny placeholder meshes existing
mainly to anchor PES emitters. The dynamic "aurora-like" sheen the
user observes in retail comes from the PES particle layer, which
remains unimplemented (issue #28). Keeping this fix because the
geometry path is now decomp-correct and provides foundation for
the eventual PES wiring.
Issue #29 filed for the residual cloud-density gap. 1227 tests pass.
Added per-Surface dump that decodes Type bits and prints whether the
LUMINOUS (0x40) flag is set on each. Targets all 27 sky surface IDs
referenced by Holtburg's Region — every dome variant (0x010015EE/F0/F1/F2),
the inner sky/star sheet (0x010015EF), sun (0x01001F67/0x01001348), moon
(0x01001F6A), every cloud variant (0x01004C35..0x01004C3A, 0x010015B6),
and rain (0x01004C42/0x01004C44 — control row).
Result: zero of the 27 surfaces have the LUMINOUS bit set. The previous
SkyRenderer comment that claimed dome+clouds carried the bit was wrong;
the differentiator between "self-lit texture passthrough" and
"ambient+diffuse-tinted" sky meshes is purely the Surface.Luminosity
FLOAT (1.0 dome/sun/moon, 0.0 stars/clouds, 0.1484 rain). This fed
directly into the emissive-default fix in the next commit.
Bonus finding: cloud surface 0x08000023 has Translucency=0.25 (not 0)
which the Translucency plumbing fix in the next commit will also pick
up — clouds will render at 75% opacity, matching retail's curr_alpha
derivation (D3DPolyRender::SetSurface at 0x59c767).
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Sibling of StarsProbe/WeatherEnumerator. Targets GfxObjs 0x01004C42 and
0x01004C44 (the two rain cylinders). For each: dumps the Surface raw
record (Type bits, Translucency, Luminosity, Diffuse, ColorValue,
OrigTextureId), every polygon's SidesType + Stippling + hasPos/hasNeg
emission flags (mirroring GfxObjMesh.Build's neg-side rule), and the
final GfxObjMesh.Build() submesh+index counts.
Built per independent code-review §5: "Run one targeted probe... if one
cylinder has more than 48 indices per side-equivalent, fix the
duplicate-side/cull behavior together with the surface-opacity uniform."
Probe results (rain_mesh_probe.log, not committed):
Surface 0x080000C5: Type=0x10112 (Base1Image|Translucent|Alpha|Additive),
Translucency=0.5000, Luminosity=0.1484, OrigTextureId=0x050016A6.
Polygons: all 8 are Stippling=Positive, SidesType=None, hasNeg=False.
Build output: 1 submesh, 24 verts, 48 indices = 8 walls × 2 tris × 3.
→ SINGLE-SIDED (the duplicate-side hypothesis is disconfirmed).
Confirmed: the rim brightness excess is purely from Translucency not
being plumbed (acdream draws rain at full alpha=1.0 instead of retail's
0.5). Bonus finding: surface.Luminosity=0.1484 is also ignored by the
renderer's `effEmissive = (luminosity > 0) ? luminosity : sub.SurfLuminosity`
fallback (the local `luminosity` defaults to 1.0 so the fallback never
fires) — but that's keyed on the LUMINOUS flag bit (0x40), which the rain
surface does NOT have. Filed as follow-up.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Sibling of WeatherEnumerator/PesChainAudit. Walks every DayGroup in the
Dereth Region (0x13000000), prints each SkyObject (Properties bits,
TexVelocity, BeginTime/EndTime, gfx/pes ids), then dumps the underlying
GfxObj's vertices, UV ranges, and surfaces. The crucial diagnostic is
the per-GfxObj "UV range outside [0,1]" flag.
Built for Bug B (sky-investigation-handoff §"Bug B"): stars rendering as
a square in one corner of the sky. Smoking gun on first run: GfxObj
0x010015EF (OI-1 in every DayGroup, TexVelocity = 0) has UVs in
[0.398, 4.602] — meaning the texture tiles ~4× across each face, but
SkyRenderer's "CLAMP_TO_EDGE unless TexVelocity != 0" heuristic forces
clamp on it, so the whole inner dome samples edge texels except the
tiny region where UVs happen to fall in [0,1]. That tiny region is the
"square in one corner" the user observed.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Captures everything learned from a long worktree iteration on the
foreground-rain bug (ISSUES.md #1 / #26) plus a new star-rendering
bug observed in the same area. The code work from that worktree
(WeatherDispatcher, EmitterDescLoader.LoadFromDat, WeatherCellRenderer,
GameWindow integration) was reverted because it didn't visibly fix
the rain bug — but the research findings + diagnostic tools are
durable and should not have to be rediscovered.
What's added:
- docs/research/2026-04-26-sky-investigation-handoff.md
Comprehensive seed prompt for the next session. Covers:
* Bug A: foreground rain (#26) — what's open, what's confirmed,
what's been tried
* Bug B: stars rendering as square in corner (NEW, user-observed)
* 40-agent decomp scan findings — retail rain is NOT camera-
particles, NOT server-driven, NOT screen-space; the mesh IS
a hollow octagonal tube; only 5 weather GfxObjs in Dereth
* Things ruled out by trial (envelope, scaling, unlit, depth-
always alone, Setup loading)
* Things to try next (depth+zfar combined, full render-state
audit, frame ordering, star UV bug as easier first target)
* Acceptance criteria for "done"
- docs/research/2026-04-26-chorizite-pr-draft.md
Upstream PR draft for Chorizite/DatReaderWriter. Five generated
DBObj source files reference nonexistent enum values and are
silently excluded from the NuGet build:
ParticleEmitterInfo, Clothing, PaletteSet, DataIdMapper,
DualDataIdMapper. Fix: delete the duplicates. Independent of
the rain work — benefits the AC modding ecosystem broadly.
- docs/research/2026-04-26-datreaderwriter-reference.md
Developer reference for our DatReaderWriter usage. Version,
types we consume, known broken types, thread-safety caveats,
upgrade procedure, NuGet-vs-vendored decision matrix.
- tools/PesChainAudit/
Recursive PES walker — given a 0x33xxxxxx script id, walks all
CallPES references and dumps every hook + every referenced
ParticleEmitter's parameters. Used to prove no weather PES
emits rain particles.
- tools/TextureDump/
Dumps texture pixel statistics (alpha histogram, brightness,
max) and saves as PNG for visual inspection.
- tools/WeatherEnumerator/
Enumerates every DayGroup in a Region, lists weather SkyObjects
(Properties & 0x04), dumps GfxObj bounding boxes.
- tools/WeatherSetupProbe/
Loads a Setup id, dumps each part's GfxObj + frame + scale +
surface. Used to prove weather Setups are 5cm dummy carriers.
Worktree feature/sky-fixes is being deleted in a follow-up step.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Pre-Phase K research artifact. Captures the AC retail default keymap
in two complementary forms so the upcoming InputAction enum + retail
preset (Phase K.1c) can be built byte-precise.
- docs/research/named-retail/retail-default.keymap.txt — verbatim
copy of the user's test.keymap from
~/Documents/Asheron's Call/. Human-readable text format with
every binding categorized: MovementCommands (W/X/A/D/Z/C/Q/Space/
LShift/S + Y/G/H/B postures), ItemSelectionCommands (F/T/P + 18
punctuation keys for compass/item/monster/player/fellow targeting),
UICommands (F1-F12 panel toggles, R=USE, E=Examine, Esc=close,
Shift+Esc=Logout), QuickslotCommands (1-9 + Ctrl/Alt variants for
hotbar pages), Combat / MeleeCombat / MissileCombat / MagicCombat
(mode-dependent Insert/PgUp/Delete/End/PgDn), Emotes
(U=Cry, I=Laugh, J=Wave, O=Cheer, K=Point), CameraControls (numpad
cluster), MouseCommands, ScrollableControls, EditControls,
CopyAndPasteControls, DialogBoxes. 346 lines.
- docs/research/named-retail/keymap-default.txt — binary dump of
the gmDefaultMap MasterInputMap from client_portal.dat at file id
0x14000000. Decoded via the new tools/dump-keymap utility:
scancodes + modifier flags + action IDs + activation phase per
context. Confirms the text file's bindings against the dat-shipped
default. Cross-referenced against
acclient_2013_pseudo_c.txt:405510 (ACCmdInterp::OnAction) for the
movement dispatch logic and :365889 (CPlayerSystem::OnAction) for
the targeting dispatch.
- tools/dump-keymap/ — dotnet console tool referencing
references/DatReaderWriter. Reads MasterInputMap entries from a
dat directory + emits human-readable per-context binding tables.
Reusable for future custom keymap analysis. Run with:
dotnet run --project tools/dump-keymap/dump-keymap.csproj -c Release
Default dat dir is %USERPROFILE%/Documents/Asheron's Call.
Foundation for Phase K — control system overhaul. Plan documented at
~/.claude/plans/ticklish-conjuring-cake.md.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Pure-docs sweep. Cross-checked 63 hand-curated entries in
acclient_function_map.md against docs/research/named-retail/symbols.json
(the PDB-derived authoritative name table) using the new helper at
tools/pdb-extract/check_function_map.py.
Findings:
- Zero entries matched address-and-name exactly. Confirms the
PDB build is from a different revision than the binary that
produced our Ghidra chunks (~0x800-0xC10 byte delta varies by
function cluster). Match by NAME, not by raw address.
- 38 entries corrected by PDB name lookup. The "Was" column
preserves the old address for traceability against existing
code comments. Old entries pointed mid-body of the actual
function; new column heads point to function starts.
- 25 entries have no PDB match. Either inlined / non-public
(no S_PUB32 record) or our hand-derived names were synthesized
from call-site analysis and don't match the MSVC mangled form
in the PDB. Several had wrong class assignments (e.g. 0x5387C0
claimed as CTransition::find_collisions, actually
CPolygon::polygon_hits_sphere). Flagged for re-derivation in
acclient_2013_pseudo_c.txt.
Pattern: kept the table format with two address columns (PDB +
legacy) so existing code references using the old addresses can
still be looked up. Added a sweep-summary section at the bottom of
the file documenting the methodology + findings.
Helper script at tools/pdb-extract/check_function_map.py is reusable
for future re-runs (re-run after every PDB regeneration / function
map edit).
Closes#9.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Pure-Python MSF 7.00 PDB extractor (no deps, stdlib only). Reads
refs/acclient.pdb directly:
- DBI stream (3) -> symbol record stream index + section header
stream index
- Section headers stream (9) -> per-segment image VA bases
- Symbol record stream (8) -> S_PUB32 records with image VAs
- TPI stream (2) -> LF_CLASS / LF_STRUCTURE named records (not
forward-declared), with size leaf + name
Includes a best-effort MSVC C++ demangler so symbols.json is
grep-friendly:
?EnchantAttribute@CEnchantmentRegistry@@QBEHKAAK@Z
-> CEnchantmentRegistry::EnchantAttribute
Both demangled `name` + raw `mangled` emitted per entry so callers
can choose. Operator overloads, vtables, and other special forms
where a partial demangle would be misleading are kept mangled.
Outputs committed to docs/research/named-retail/:
- symbols.json (2.9 MB) — 18,366 named public function symbols
- types.json (506 KB) — 5,371 unique named class/struct records
Spot check (matches discovery agent's earlier finding):
CEnchantmentRegistry::EnchantAttribute -> 0x00594570 ✓
Updated docs/research/acclient_function_map.md header preamble to
direct readers at the new symbols.json as the authoritative name
source; the hand-curated table stays as the cross-port (ACE/ACME)
index. Several addresses there are wrong vs the PDB and will be
swept in the issue #9 close (Phase E).
Closes#8 (filed in Phase D's commit). Foundation for the address
sweep + name-driven workflows from here on.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Iteration on the sky rendering pipeline to restore stars/moon visibility
at night and fix washed-out grey daytime clouds. Key fixes:
* sky.frag: disable fog-mix on sky meshes. Retail's keyframe FogEnd
(0..400m at midnight, up to 2400m during day) is calibrated for
terrain; sky meshes are authored at radii 1050-14271m which sits
past FogEnd universally, causing every sky pixel to saturate to
fogColor (dark navy). Stars, moon, dome texture all got
obliterated. The horizon-glow trade-off is noted in the shader
comment; research item to find retail's sky-specific fog range
later.
* SkyRenderer + sky.frag: promote rep.Luminosity into uEmissive so the
vertex lighting saturates properly for bright keyframes. Retail's
FUN_0059da60 non-luminous path writes rep.Luminosity into
material.Emissive via the cache +0x3c slot; we were instead using
it as a post-fragment multiply which could only dim, never brighten.
Net effect: daytime clouds now render saturated white, dome dims
correctly at night (rep.Luminosity=0.11 → Emissive=0.11), stars
and moon unchanged.
* terrain.vert: MIN_FACTOR 0.08 -> 0.0 per retail FUN_00532440 decompile
(DAT_00796344 ambient-floor = 0.0). Back-lit terrain now falls to
pure ambient rather than getting an 8% sun floor.
New research / tooling (no runtime impact):
* docs/research/2026-04-24-lambert-brightness-split.md — retail's
ambient-brightness formula pinned from PE .rdata read + live
RetailTimeProbe capture: effAmbBright = AmbBright + |sunDir| * 0.2
where scale constant 0x0079a1e8 = 0.2f exactly.
* docs/research/2026-04-23-lightning-real.md — research note on the
dat-baked PhysicsScript-driven lightning path (Rainy DayGroup has
explicit PES-triggered flash SkyObjects with 5ms time windows).
* Corrections stapled to sky-decompile-hunt-{B,C}.md: DAT_00842778 is
DirColor, DAT_0084277c is AmbColor (the hunt docs had the swap
backwards).
* tools/RetailTimeProbe/Program.cs: extended with pid=NNNN selector,
sky global probe (DirColor/AmbColor/AmbBright/sunDir/cache.amb),
and the 0x0079a1e8 scale-factor readout.
* tools/SkyObjectInspect/: throwaway dat-inspector built by the Opus
deep-dive agent. Identified GfxObj 0x010015EF as the stars layer
(A8R8G8B8 128x128 texture, 4% bright-pixel ratio).
* src/AcDream.App/Rendering/TextureCache.cs: per-texture alpha
histogram dump under ACDREAM_DUMP_SKY=1 for diagnosing "are the
clouds decoded with proper alpha" type questions.
README: rewrite to reflect current state (playable pre-alpha rendering
Dereth with animated characters, day-night cycle, weather, etc.)
instead of the stale "Phase 0 dat inventory only" description.
All 742 tests green.
Ran a live memory probe against retail acclient.exe (new tool:
tools/RetailTimeProbe/) to read the TimeOfDay struct at
DAT_008ee9c8 and compare against our computed values. The decompile
agent's identification of TimeOfDay+0x10 as "SecondsPerDay (int
copy)" turned out to be WRONG — the live value is **360**, which is
GameTime.DaysPerYear.
The retail FUN_00501990 LCG seed is:
seed = Year × (*+0x10) + DayOfYear
= Year × DaysPerYear + DayOfYear
= flat "total days since epoch" day-index
Our previous Phase 3c port passed 7620 (DayLength in ticks) as the
multiplier, producing seed=883,967 against retail's seed=41,807 —
completely different LCG outputs, completely different DayGroup
picks. That's why the user's retail kept showing stormy/rainy while
acdream showed sunny/clear (or vice versa) even after Phases 3c.1
and 3f aligned Year and DayOfYear.
Also confirmed by the probe:
- EpochBase / ZeroTimeOfYear = 3600 ✓ Phase 3f already correct
- BaseYear / ZeroYear = 10 ✓ DerethDateTime.ZeroYear
- Year=116, DayOfYear=47 ✓ our AbsoluteYear / DayOfYear
- SecondsPerDay float (+0x0C) = 7620 ✓ DayTicks
- SecondsPerYear = 2,743,200 ✓ YearTicks
One "finding that's not a fix": retail's +0x48 DayFraction is a
sub-period fraction (fraction through current day/night window)
NOT a full-day fraction. CurDayEnd - CurDayStart = 2857.5 = 0.375
of a day = 6 Dereth hours = night duration. Not relevant for our
keyframe bracket interpolation, which correctly uses a full-day
0..1 scale matching the SkyTime.Begin values. Documented in the
probe research doc so future work doesn't trip on it.
Changes:
- tools/RetailTimeProbe/ — new P/Invoke tool. Forced x86 target to
match retail's bitness so hardcoded DAT_xxxxxxxx addresses are
pointer-width-correct. Handles ASLR relocation via
Process.MainModule.BaseAddress.
- src/AcDream.App/Rendering/GameWindow.cs: RefreshSkyForCurrentDay
passes 360 (DaysInAMonth × MonthsInAYear) not 7620.
- src/AcDream.Core/World/SkyDescLoader.cs: ActiveDayGroup(ticks)
and DefaultDayGroup same.
- docs/research/2026-04-23-retail-memory-probe.md — full probe
results + decompile-agent correction.
- AcDream.slnx — add tools/ folder.
Build + 733 tests green.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
Complete decompilation of the retail Asheron's Call client using
Ghidra 12.0.4 + pyghidra headless. 22,225 of 22,226 functions
successfully decompiled in 75 seconds.
Output: docs/research/decompiled/ (54 files, 688,567 lines of C)
Key findings already identified:
- CLandBlockStruct::ConstructPolygons at chunk_00530000.c:2270
(split direction formula with 0x0CCAC033 constants)
- Motion command handlers at chunk_00510000.c (0x45000005 etc)
- Motion interpreter at chunk_00520000.c
- Portal space UI at chunk_004D0000.c and chunk_00560000.c
Next: identify CPhysicsObj, CMotionInterp, collision, and movement
functions by cross-referencing against ACE's C# port.
Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
