OmniRoute Auto-Combo Engine
For Users: Looking for a quick start? See the Auto-Combo User Guide for simple explanations and examples.
Self-managing model chains with adaptive scoring + zero-config auto-routing
Zero-Config Auto-Routing (auto/ prefix)
NEW: No combo creation required. Use
auto/prefix directly in any client.
Quick Examples
| Model ID | Variant | Behavior |
|---|---|---|
auto | default | All connected providers, LKGP strategy, balanced weights |
auto/coding | coding | Quality-first weights, suitable for code generation |
auto/fast | fast | Low-latency weighted selection |
auto/cheap | cheap | Cost-optimized routing (lowest cost first) |
auto/offline | offline | Favors providers with highest quota availability |
auto/smart | smart | Quality-first + higher exploration rate (10%) for better model discovery |
auto/lkgp | lkgp | Explicit LKGP (same as default auto) |
Category × Tier Composition (auto/<category>:<tier>)
OpenRouter-style suffixes separate what kind of route (category) from how to optimize it (tier), so you can compose them freely (#4235 Phase B, open-sse/services/autoCombo/suffixComposition.ts):
- Categories (filter the candidate pool by capability):
coding·reasoning·vision·chat·multimodal.vision/multimodalkeep vision-capable models;reasoningkeeps reasoning/thinking models. - Tiers (pick the scoring weights / pool filter):
fast(ship-fast) ·cheap(aliasfloor, cost-saver) ·reliable(circuit-breaker health + latency stability) ·free/pro(filter the pool by model tier viaclassifyTier— free-tier vs. premium).
| Example | Resolves to |
|---|---|
auto/coding:fast | coding pool, low-latency weights |
auto/coding:cheap | coding pool, cost-optimized (alias auto/coding:floor) |
auto/reasoning:pro | reasoning/thinking models only, premium tier |
auto/vision | vision-capable models (no tier → balanced weights) |
auto/multimodal:free | multimodal-capable models, free tier only |
Any valid auto/<category>[:<tier>] resolves on demand; a curated subset is advertised in /v1/models and the dashboard (AUTO_SUFFIX_VARIANTS in open-sse/services/autoCombo/builtinCatalog.ts). Filtering is fail-open — if a constraint matches no connected models, the full pool is used so routing never breaks. The core scorer (combo.ts) is unchanged; the category/tier filter is applied in buildAutoCandidates.
Live model intelligence: auto-routing fitness is informed by live Arena ELO rankings + models.dev tier data when the
ARENA_ELO_SYNC_ENABLEDflag is on (falls back to the static fitness map otherwise).
How to use:
# Any IDE or CLI tool that supports OpenAI format
Base URL: http://localhost:20128/v1
API Key: <your-endpoint-key>
# In your code/config, set model to:
model: "auto" # balanced default
model: "auto/coding" # best for coding tasks
model: "auto/fast" # fastest available
model: "auto/cheap" # cheapest per tokenWhat happens:
- OmniRoute detects
auto/prefix insrc/sse/handlers/chat.ts - Queries all active provider connections from the database
- Filters to those with valid credentials (API key or OAuth token)
- Determines the model per connection (
connection.defaultModelor provider's first model) - Builds a virtual combo in-memory (not stored in DB)
- Routes using the selected variant's weight profile + LKGP strategy
Key properties:
- ✅ Always-on: No toggle, no combo creation, no configuration needed
- ✅ Dynamic: Reflects current connected providers automatically
- ✅ Session stickiness: LKGP ensures last successful provider is prioritized
- ✅ Multi-account aware: Each provider connection becomes a separate candidate
- ✅ No DB writes: Virtual combo exists only for the request, zero persistence overhead
Behind the scenes:
Request: { model: "auto/coding" }
↓
src/sse/handlers/chat.ts detects prefix
↓
createVirtualAutoCombo('coding') → candidatePool from active connections
↓
handleComboChat (same engine as persisted combos)
↓
Auto-scoring selects best provider/model per requestImplementation files:
| File | Purpose |
|---|---|
open-sse/services/autoCombo/autoPrefix.ts | Prefix parser (parseAutoPrefix) |
open-sse/services/autoCombo/virtualFactory.ts | Creates virtual AutoComboConfig objects |
open-sse/services/autoCombo/providerRegistryAccessor.ts | Test hook for mocking provider registry |
src/sse/handlers/chat.ts | Integration: auto prefix short-circuit |
src/shared/constants/providers.ts | SYSTEM_PROVIDERS.auto system entry |
How It Works (Persisted Auto-Combos)
The Auto-Combo Engine dynamically selects the best provider/model for each request using a 12-factor scoring function (defined in open-sse/services/autoCombo/scoring.ts → DEFAULT_WEIGHTS). All weights sum to 1.0.
Source: diagrams/auto-combo-12factor.mmd (regenerate via
npm run docs:render-diagrams).
| Factor | Default Weight | Description |
|---|---|---|
health | 0.20 | Health score from circuit breaker (CLOSED=1.0, HALF_OPEN=0.5, OPEN=0.0) |
quota | 0.15 | Remaining quota / rate-limit headroom [0..1] |
costInv | 0.15 | Inverse blended cost (60% input + 40% output token price, normalized) — cheaper = higher score |
latencyInv | 0.12 | Inverse p95 latency normalized to pool — faster = higher score |
taskFit | 0.08 | Task-type fitness (coding, review, planning, analysis, debugging, docs) |
stability | 0.05 | Variance-based stability (low latency stdDev / error rate) |
tierPriority | 0.05 | Account-tier priority — Ultra=1.0, Pro=0.67, Standard=0.33, Free=0.0 |
tierAffinity | 0.05 | Affinity between the candidate's tier and the manifest-recommended tier |
specificityMatch | 0.05 | Match between request specificity (manifest hint) and model tier |
contextAffinity | 0.05 | Affinity between the request's context-window need and the model's context window |
connectionDensity | 0.05 | Spreads load across connections of the same provider (anti-concentration) |
resetWindowAffinity | 0.00 | Bias toward connections whose quota reset window is favorable (disabled by default) |
Sum: 0.20 + 0.15 + 0.15 + 0.12 + 0.08 + 0.05 + 0.05 + 0.05 + 0.05 + 0.05 + 0.05 + 0.00 = 1.0 (validated by validateWeights()).
Mode Packs
Four pre-defined weight profiles in open-sse/services/autoCombo/modePacks.ts. Each pack overrides the default weights to bias selection toward a specific goal. Below are the full weight tables per pack (each row sums to 1.0).
| Factor | ship-fast | cost-saver | quality-first | offline-friendly |
|---|---|---|---|---|
| quota | 0.14 | 0.14 | 0.10 | 0.37 |
| health | 0.28 | 0.19 | 0.18 | 0.28 |
| costInv | 0.05 | 0.37 | 0.05 | 0.10 |
| latencyInv | 0.32 | 0.05 | 0.05 | 0.05 |
| taskFit | 0.10 | 0.10 | 0.37 | 0.00 |
| stability | 0.00 | 0.05 | 0.15 | 0.10 |
| tierPriority | 0.05 | 0.05 | 0.05 | 0.05 |
Notes:
tierAffinityandspecificityMatchare not set in mode packs —calculateScore()treats them as?? 0when absent.- Each pack's emphasis at a glance:
- ship-fast → latencyInv 0.32 + health 0.28 (low-latency, healthy connections)
- cost-saver → costInv 0.37 (cheapest tokens win)
- quality-first → taskFit 0.37 + stability 0.15 (best model for the task, consistent)
- offline-friendly → quota 0.37 + health 0.28 (max headroom regardless of speed/cost)
Per-Request Controls (headers) — #6023 / #6024 / #6025
An auto combo can be steered per request via two headers, without mutating the
combo's stored config. These apply only to the auto strategy and only for the request
that carries them; the combo's saved modePack/budgetCap are used when the header is
absent.
| Header | Accepts | Effect |
|---|---|---|
X-OmniRoute-Mode | a preset alias (fast, balanced, quality, cheap, reliable, offline) or a raw pack name (ship-fast, cost-saver, quality-first, offline-friendly, reliability-first) | Overrides the scoring weights for this request. balanced/default force the default weights (no pack). Unknown values are ignored (config preserved). |
X-OmniRoute-Budget | a positive number (max USD per request) | Hard cost ceiling: candidates whose estimated cost exceeds it are filtered before selection, falling back to the cheapest healthy candidate if all exceed. Non-positive/garbage values are ignored. |
# Force the fastest profile and cap this request at $0.05
curl -sS http://localhost:20128/v1/chat/completions \
-H "Content-Type: application/json" \
-H "X-OmniRoute-Mode: fast" \
-H "X-OmniRoute-Budget: 0.05" \
-d '{"model":"auto","messages":[{"role":"user","content":"hi"}]}'Resolution is a pure function (open-sse/services/autoCombo/requestControls.ts); the
resolved values feed the engine's existing config.modePack / config.budgetCap inputs.
All Routing Strategies
OmniRoute's combo engine supports 17 routing strategies (declared in src/shared/constants/routingStrategies.ts → ROUTING_STRATEGY_VALUES). The Auto Combo engine itself is exposed under the auto strategy; the others are available for persisted combos.
| Strategy | Description |
|---|---|
priority | First-target ordered list with explicit priority |
weighted | Weighted random by per-target weight |
round-robin | Cycle through targets in order |
context-relay | Hand off context across targets (long conversations) |
fill-first | Fill each target's quota before moving to next |
p2c | Power-of-2-choices random load balancing |
random | Uniform random selection |
least-used | Pick target with lowest current load |
cost-optimized | Minimize $ per request given catalog pricing |
reset-aware ⭐ | Prioritize by quota reset time — short reset windows ranked higher |
reset-window | Prefer targets whose quota window resets soonest |
headroom | Pick the target with the most remaining quota headroom |
strict-random | Random without deduplication of repeats |
auto | Use Auto Combo scoring (9-factor) — recommended |
lkgp | Last-Known-Good Path (sticky route to last successful target) |
context-optimized | Pick target with best fit for current context size |
fusion 🧬 | Fan out to a panel of models in parallel, then synthesize one answer via a judge (see below) |
⭐ = New in v3.8.0 · 🧬 = New in v3.8.36
Fusion Strategy
fusion is the one strategy that does not pick a single target. It fans the prompt
out to every panel model in parallel, then a configurable judge model synthesizes
a single final answer from all panel responses. Ported from upstream decolua/9router
(OpenRouter's Fusion design); implementation in open-sse/services/fusion.ts.
How it works:
- Fan-out — the prompt is sent to every panel model at once, forced non-streaming with tools stripped (the judge needs complete prose to synthesize).
- Quorum-grace collection — as soon as
minPanelanswers arrive, a short grace timer starts for the stragglers, then fusion proceeds with whatever was collected. This caps the slowest model's penalty on wall time, bounded by a hard timeout. - Judge synthesis — panel answers are anonymized (
Source 1,Source 2, … — so the judge weighs substance, not model brand) and handed to the judge, which analyzes consensus / contradictions / partial coverage / unique insights / blind spots, then writes one authoritative answer. The judge call keeps the client's originalstreamflag + tools, so streaming and downstream tool use still work. - Graceful degradation — 0 panel answers →
503; exactly 1 survivor → that answer is returned directly (nothing to fuse); a single-model panel answers directly.
Configuration
Configured on the combo's config blob (no schema migration — it reuses the existing
combos table):
| Field | Type | Default | Purpose |
|---|---|---|---|
config.judgeModel | string | first panel model | Model that synthesizes the final answer |
config.fusionTuning.minPanel | number | 2 | Successful answers required before the grace timer starts (clamped to [2, panelSize]) |
config.fusionTuning.stragglerGraceMs | number | 8000 | How long to wait for laggards once quorum is reached |
config.fusionTuning.panelHardTimeoutMs | number | 90000 | Absolute cap so one hung model can't stall the request |
Defaults live in FUSION_DEFAULTS (open-sse/services/fusion.ts).
Example
curl -X POST http://localhost:20128/api/combos \
-H "Authorization: Bearer <key>" \
-H "Content-Type: application/json" \
-d '{
"name": "fusion-panel",
"strategy": "fusion",
"targets": [
{ "model": "cc/claude-opus-4-7" },
{ "model": "cx/gpt-5.5" },
{ "model": "glm/glm-5.1" }
],
"config": {
"judgeModel": "cc/claude-opus-4-7",
"fusionTuning": { "minPanel": 2, "stragglerGraceMs": 8000, "panelHardTimeoutMs": 90000 }
}
}'Then call it like any combo: {"model":"fusion-panel","messages":[...]}.
Virtual Auto-Combo Factory
The Auto Combo engine doesn't require pre-defined combos. Instead, open-sse/services/autoCombo/virtualFactory.ts builds candidates on-the-fly:
- Pulls
getProviderConnections({ isActive: true })(all enabled connections) - Filters to those with valid credentials (API key or non-expired OAuth token via
hasUsableOAuthToken()) - Cross-references with
getProviderRegistry()for model availability + pricing - For each tuple
(provider, model, connection), builds aVirtualAutoComboCandidate - Picks
connection.defaultModel(or the registry's first model) as the dispatch target - Scores each candidate using the 9-factor
scorePool()and the variant's weight pack - Returns the resulting in-memory
AutoComboConfigforhandleComboChat()— never persisted to DB
This means adding a new provider with auto/* enabled automatically expands the candidate pool — no manual combo editing needed. The virtual combo is rebuilt per request, so newly-added or newly-healthy connections are picked up immediately.
Self-Healing
- Temporary exclusion: Score < 0.2 → excluded for 5 min (progressive backoff, max 30 min)
- Circuit breaker awareness: OPEN → auto-excluded; HALF_OPEN → probe requests
- Incident mode: >50% OPEN → disable exploration, maximize stability
- Cooldown recovery: After exclusion, first request is a "probe" with reduced timeout
Bandit Exploration
5% of requests (configurable) are routed to random providers for exploration. Disabled in incident mode.
API
There is no dedicated POST /api/combos/auto endpoint — Auto-Combo is consumed in two ways:
-
Zero-config (recommended): Send any chat completion request with
model: "auto"ormodel: "auto/<variant>". The virtual factory builds the combo per request — no persistence, no API calls needed. -
Persisted combo with
strategy: "auto": Create a regular combo viaPOST /api/combosand setstrategy: "auto"plusconfig.auto.weights/config.auto.candidatePool. The same scoring engine is used; the combo is stored incombosand reusable by ID.
For discovery, GET /api/combos/auto lists every variant with its resolved candidate pool plus context_length / max_output_tokens — the MAX across the candidate pool's windows. Clients (e.g. the opencode plugin) must advertise these values instead of 0: a zero context disables opencode's auto-compaction entirely, letting sessions grow until the gateway's history purge destroys context. MAX is safe to advertise because the auto-combo context pre-filter routes oversized requests to large-window candidates.
# Zero-config usage (no combo creation)
curl -X POST http://localhost:20128/v1/chat/completions \
-H "Authorization: Bearer <key>" \
-H "Content-Type: application/json" \
-d '{"model":"auto/coding","messages":[{"role":"user","content":"Hello"}]}'
# Persisted auto combo via the regular combos endpoint
curl -X POST http://localhost:20128/api/combos \
-H "Content-Type: application/json" \
-d '{"id":"my-auto","name":"Auto Coder","strategy":"auto","config":{"auto":{"candidatePool":["anthropic","google","openai"],"weights":{"quota":0.15,"health":0.3,"costInv":0.05,"latencyInv":0.35,"taskFit":0.1,"stability":0,"tierPriority":0.05}}}}'Auto router strategies
Persisted strategy: "auto" combos can set config.routerStrategy (or legacy
config.auto.routerStrategy) to one of:
rules— default weighted scoringcost/eco— cheapest healthy providerlatency/fast— lowest p95 latency with reliability penaltysla-aware/sla— prefer candidates that satisfy p95 latency, error-rate, and optional cost SLOslkgp— last known good provider first
Router strategies in detail
The auto-combo engine exposes 5 pluggable RouterStrategy implementations that
you can swap via config.routerStrategy (or the legacy config.auto.routerStrategy).
Each strategy picks one provider from the candidate pool, given a RoutingContext
(task type, tool/vision hints, token estimate, optional SLA policy, optional
last-known-good provider).
1. rules (default) — 6-factor weighted scoring
Wraps the existing scoring engine. Filters out OPEN circuit-breaker
candidates, then runs scorePool() with the current task type and getTaskFitness(),
picking the top-scoring provider.
class RulesStrategyImpl implements RouterStrategy {
readonly name = "rules";
readonly description =
"6-factor weighted scoring: quota, health, cost, latency, taskFit, stability";
select(pool, context) {
const eligible = pool.filter((c) => c.circuitBreakerState !== "OPEN");
const ranked = scorePool(
eligible.length > 0 ? eligible : pool,
context.taskType,
undefined,
getTaskFitness
);
return { provider: ranked[0].provider /* ... */ };
}
}When to use: Default. Use when you want a balanced trade-off across all signals.
Alias: rules (no alias)
2. cost / eco — cheapest healthy provider
Sorts the candidate pool by costPer1MTokens (ascending) and picks the cheapest.
Filters out OPEN candidates first.
class CostStrategyImpl implements RouterStrategy {
readonly name = "cost";
readonly description = "Always selects cheapest available provider";
select(pool, context) {
const healthy = pool.filter((c) => c.circuitBreakerState !== "OPEN");
const sorted = [...healthy].sort((a, b) => a.costPer1MTokens - b.costPer1MTokens);
return { provider: sorted[0].provider /* ... */ };
}
}When to use: Cost-sensitive workloads, batch processing, or background jobs.
Aliases: cost, eco
3. latency / fast — lowest p95 latency with reliability penalty
Sorts by p95LatencyMs + (errorRate * 1000). The error-rate penalty ensures
unreliable providers are ranked lower even if their nominal latency is low.
class LatencyStrategyImpl implements RouterStrategy {
readonly name = "latency";
readonly description = "Prioritizes lowest p95 latency with reliability weighting";
select(pool, context) {
const healthy = pool.filter((c) => c.circuitBreakerState !== "OPEN");
const sorted = [...healthy].sort(
(a, b) => a.p95LatencyMs + a.errorRate * 1000 - (b.p95LatencyMs + b.errorRate * 1000)
);
return { provider: sorted[0].provider /* ... */ };
}
}When to use: Latency-sensitive workloads like real-time chat, autocomplete, or interactive coding assistants.
Aliases: latency, fast
4. sla-aware / sla — latency/error/cost SLO compliance
Scores each candidate by how well it satisfies the configured SLO policy:
| Factor | Weight | Formula |
|---|---|---|
| Latency score | 35% | threshold / max(value, ε) |
| Error score | 35% | threshold / max(value, ε) |
| Health score | 15% | 1.0 (CLOSED) / 0.5 (HALF_OPEN) / 0.0 (OPEN) |
| Cost score | 10% | threshold / max(value, ε) or inverse normalized |
| Stability score | 5% | inverse normalized latency stddev |
When hardConstraints: true, candidates are sorted primarily by violation score
(how far they exceed any SLO), then by composite score. Otherwise it's just
the composite score.
class SLAStrategyImpl implements RouterStrategy {
readonly name = "sla-aware";
readonly description =
"Selects the provider most likely to satisfy latency, error-rate, and cost SLOs";
select(pool, context) {
// ... scores each candidate against policy: { targetP95Ms, maxErrorRate, maxCostPer1MTokens, hardConstraints }
}
}SLA fields (set on the combo config):
{
"strategy": "auto",
"config": {
"routerStrategy": "sla-aware",
"slaTargetP95Ms": 1500,
"slaMaxErrorRate": 0.05,
"slaMaxCostPer1MTokens": 5,
"slaHardConstraints": true
}
}When to use: Production workloads with strict latency, error-rate, or cost budgets.
Aliases: sla-aware, sla
5. lkgp — last known good provider first
Tries the last known good provider (if set) first, then falls back to the
rules strategy. Useful for session stickiness — the same provider handles
follow-up requests in a conversation.
class LKGPStrategyImpl implements RouterStrategy {
readonly name = "lkgp";
readonly description = "Tries last known good provider first, then falls back to rules";
select(pool, context) {
if (context.lkgpEnabled === false) {
return getStrategy("rules").select(pool, context);
}
if (context.lastKnownGoodProvider) {
const candidates = pool.filter(
(c) => c.provider === context.lastKnownGoodProvider && c.circuitBreakerState !== "OPEN"
);
if (candidates.length > 0) {
return { provider: candidates[0].provider /* ... */ };
}
}
// Fallback to rules strategy
return getStrategy("rules").select(pool, context);
}
}When to use: Multi-turn conversations where you want the same provider to handle follow-up requests (e.g., for caching, context continuity, or pricing consistency).
Alias: lkgp (no alias)
Custom router strategies
You can register your own RouterStrategy implementation via the public API:
import {
registerStrategy,
type RouterStrategy,
} from "@omniroute/open-sse/services/autoCombo/routerStrategy";
class MyCustomStrategy implements RouterStrategy {
readonly name = "my-custom";
readonly description = "My custom routing strategy";
select(pool, context) {
// Your routing logic here
return {
provider: pool[0].provider,
model: pool[0].model,
strategy: this.name,
reason: "MyCustomStrategy: ...",
candidatesConsidered: pool.length,
finalScore: 1.0,
};
}
}
registerStrategy("my-custom", new MyCustomStrategy());Then use it:
{
"strategy": "auto",
"config": {
"routerStrategy": "my-custom"
}
}Router strategy selection guide
| Use case | Strategy | Reason |
|---|---|---|
| Balanced workload | rules | Default — considers all factors |
| Minimize cost | cost | Always picks cheapest |
| Minimize latency | latency | Picks fastest reliable provider |
| Strict SLOs | sla-aware | Filters by p95/error/cost thresholds |
| Multi-turn chat | lkgp | Session stickiness |
SLA-aware fields:
{
"strategy": "auto",
"config": {
"routerStrategy": "sla-aware",
"slaTargetP95Ms": 1500,
"slaMaxErrorRate": 0.05,
"slaMaxCostPer1MTokens": 5,
"slaHardConstraints": true
}
}Task Fitness
30+ models scored across 6 task types (coding, review, planning, analysis, debugging, documentation). Supports wildcard patterns (e.g., *-coder → high coding score).
Auto Variants Recap
Including the bare auto (default) plus the 6 AutoVariant values declared in autoPrefix.ts, there are 7 invokable model IDs:
auto, auto/coding, auto/fast, auto/cheap, auto/offline, auto/smart, auto/lkgp
(AutoVariant itself enumerates 6 values; the 7th option is "no variant" — bare auto — handled by parseAutoPrefix() as variant: undefined.)
How tiers fit Auto-Combo
The 12-factor scoring function (open-sse/services/autoCombo/scoring.ts) treats tier
membership as two signals: tierPriority (0.05) and tierAffinity (0.05). See the
canonical scoring factor table above for the full
DEFAULT_WEIGHTS set — the per-pack overrides (ship-fast/cost-saver/quality-first/
offline-friendly) are listed in the "Weight profiles per pack" table.
Tier alone does not force Tier 1 first — if Tier 1 latency is bad or
cost-vs-quality is suboptimal, Tier 2 wins. To force tier ordering, use combo
strategy priority and arrange providers by tier.
To strongly favor Tier 1 (subscription), increase tierPriority weight:
{
"strategy": "auto",
"config": { "auto": { "weights": { "tierPriority": 0.3, "costInv": 0.05 } } }
}See docs/marketing/TIERS.md for tier definitions and provider classification.
Testing & Coverage
Deterministic routing-decision matrix (npm run test:combo:matrix)
tests/integration/combo-matrix/*.test.ts proves the routing decision of all 17
public strategies end-to-end through the real combo pipeline with a mocked upstream.
Coverage includes:
- All 17
ROUTING_STRATEGY_VALUESstrategies (ordered, weighted, cost, context, fusion, …). quota-share(internal) end-to-end: DRR fairness + saturation deprioritization via the realselectQuotaShareTargetseam (registerQuotaFetcher/setLKGP/__setHeadroomSaturationFetcherForTests).context-relayuniversal-handoff coverage across every target count.
This suite runs in CI (test:integration job) with --test-concurrency=1 and
--test-force-exit so it is deterministic and does not require live credentials.
Gated live smoke (NOT in CI — real providers)
| Command | What it does |
|---|---|
npm run test:combo:live | In-process real routing with RUN_COMBO_LIVE=1; snapshots a live OmniRoute DB |
npm run test:combo:live:vps | HTTP calls against a live OmniRoute server (set COMBO_LIVE_BASE_URL) |
npm run test:combo:live:vps:failover | Same, with deliberate failover scenarios |
These smoke tests exercise the real wire path (combo → provider → completion). They are intentionally excluded from CI because they require live credentials and VPS access.
Files
| File | Purpose |
|---|---|
open-sse/services/autoCombo/scoring.ts | 9-factor scoring function, DEFAULT_WEIGHTS, pool norm |
open-sse/services/autoCombo/taskFitness.ts | Model × task fitness lookup |
open-sse/services/autoCombo/engine.ts | Selection logic, bandit, budget cap |
open-sse/services/autoCombo/selfHealing.ts | Exclusion, probes, incident mode |
open-sse/services/autoCombo/modePacks.ts | 4 weight profiles (ship-fast, cost-saver, quality-first, offline-friendly) |
open-sse/services/autoCombo/autoPrefix.ts | auto/ prefix parser + 6 variants |
open-sse/services/autoCombo/virtualFactory.ts | Builds in-memory AutoComboConfig from live connections |
open-sse/services/autoCombo/providerRegistryAccessor.ts | Test hook for mocking provider registry |
src/shared/constants/routingStrategies.ts | ROUTING_STRATEGY_VALUES (17 strategies) |
src/sse/handlers/chat.ts | Integration: auto-prefix short-circuit |