rob thijssen
05e15f3597
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Adds the bf16/fp16 safetensors path alongside the existing GGUF quantized one. The harness now dispatches by ModelSpec.quant: - Some(_) → GGUF (pre-quantized, single-GPU only path, unchanged). - None → safetensors dense (new). The dense path uses candle-transformers::models::qwen3::ModelForCausalLM verbatim, fed via VarBuilder::from_mmaped_safetensors over the files listed in `model.safetensors.index.json` (sharded layout) or the single `model.safetensors` fallback. dtype is bf16 to match the canonical Qwen3 HF distribution dtype. tokenizer.json is fetched from the same repo (no -GGUF suffix to strip). ModelArch gains a Qwen3Dense variant; the forward signature mirrors QuantizedQwen3Weights (same `forward(&Tensor, offset)` → last-position logits), so run_inference / run_inference_streaming just add a parallel match arm — no shape changes downstream. This is the foundation 7b-ii (ColumnParallel/RowParallel) builds on: because the source is dense safetensors that can be byte-sliced per rank, the TP work avoids the GGUF super-block alignment problem entirely. Vanilla GGUF inference keeps working unchanged. validate-neuron.sh learns the dense path: pass an empty third arg (quant) and the script omits the `quant` field from the load payload, triggering the dense dispatch. Example: script/validate-neuron.sh beast.hanzalova.internal Qwen/Qwen3-0.6B '' Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
161 lines
5.7 KiB
Bash
Executable File
161 lines
5.7 KiB
Bash
Executable File
#!/bin/env bash
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#
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# End-to-end smoke test for a deployed neuron.
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#
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# Confirms the daemon is reachable, loads a small public Qwen3 GGUF,
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# fires a reasoning probe at /v1/chat/completions, and prints the
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# answer. Used to validate the candle harness on a real GPU host
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# before trusting it for production traffic, and as a regression test
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# after pushing new neuron builds.
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#
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# Usage:
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# script/validate-neuron.sh [host] [model_id] [quant]
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#
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# Defaults:
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# host = beast.hanzalova.internal
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# model_id = unsloth/Qwen3-0.6B-GGUF (official Qwen3-*-GGUF repos
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# ship Q8_0 only; unsloth's mirror ships the full Q-spectrum
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# including Q4_K_M)
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# quant = Q4_K_M
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set -euo pipefail
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HOST="${1:-beast.hanzalova.internal}"
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MODEL_ID="${2:-unsloth/Qwen3-0.6B-GGUF}"
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QUANT="${3:-Q4_K_M}"
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PORT="${NEURON_PORT:-13131}"
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BASE="http://${HOST}:${PORT}"
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# Reasoning probe — concrete, low-temperature answer that small models
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# can still get right. "Paris" is a strong signal of basic competence
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# beyond gibberish.
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PROBE_PROMPT='What is the capital of Georgia (Caucasus)? Respond with the city name only, no punctuation.'
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EXPECT_SUBSTR='Tbilisi'
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# Qwen3 prepends <think>...</think> reasoning before the answer when the
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# chat template enables thinking mode, which eats most of a small token
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# budget. 256 leaves enough room for thinking + final answer.
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MAX_TOKENS=256
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# /models/load is synchronous — neuron blocks the response until the
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# hf-hub download + GGUF parse + tensor materialisation is done. A
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# fresh 0.6B-Q4_K_M is ~400 MB; on a slow link or cold cache that's
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# easily a minute. Pick a generous ceiling.
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LOAD_TIMEOUT=600
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INFER_TIMEOUT=120
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# Status messages go to stderr so command substitutions like
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# `raw=$(run_probe)` capture only the function's intended return value
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# (an HTTP body), not the progress chatter.
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say() { printf '[%s] %s\n' "${HOST}" "$*" >&2; }
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die() { say "FAIL: $*"; exit 1; }
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probe_health() {
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curl --silent --fail --max-time 5 "${BASE}/health" >/dev/null \
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|| die "neuron not reachable at ${BASE}/health"
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}
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list_loaded_ids() {
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# The manifest is YAML and uses yq; HTTP responses are JSON and use
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# jq directly. pip-yq parses input as YAML by default, which trips
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# on JSON content that happens to look like YAML aliases (chatcmpl
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# ids, escaped quotes inside `<think>...</think>` blocks, etc.).
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curl --silent --fail "${BASE}/models" | jq -r '.[].id'
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}
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is_loaded() {
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list_loaded_ids 2>/dev/null | grep -Fxq "${MODEL_ID}"
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}
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trigger_load() {
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say "POST /models/load ${MODEL_ID} (quant=${QUANT:-<dense>}, device=[0])"
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say " (synchronous; may take a minute on first run while HF downloads)"
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# Build the payload via jq so the optional `quant` field is
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# omitted entirely when empty — that's the signal to the harness
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# to take the dense safetensors load path rather than GGUF.
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local payload
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if [[ -z "${QUANT}" ]]; then
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payload=$(jq -n -c \
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--arg id "${MODEL_ID}" \
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'{model_id: $id, harness: "candle", devices: [0]}')
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else
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payload=$(jq -n -c \
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--arg id "${MODEL_ID}" \
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--arg q "${QUANT}" \
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'{model_id: $id, harness: "candle", quant: $q, devices: [0]}')
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fi
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# --write-out captures the response code on a separate line so we
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# can surface a real diagnostic instead of relying on --fail.
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local resp http_code body
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resp=$(curl --silent --show-error --max-time "${LOAD_TIMEOUT}" \
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--write-out '\n__HTTP__%{http_code}' \
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-X POST "${BASE}/models/load" \
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-H 'content-type: application/json' \
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--data "${payload}") || die "curl /models/load failed: $?"
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http_code=$(echo "${resp}" | grep -oP '(?<=__HTTP__)\d+$' | tail -1)
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body=$(echo "${resp}" | sed '$ s/__HTTP__.*$//')
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if [[ "${http_code}" != "200" ]]; then
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die "load returned HTTP ${http_code}: ${body}"
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fi
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say "load returned ${http_code}: ${body}"
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}
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run_probe() {
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say "POST /v1/chat/completions (probe: ${PROBE_PROMPT})"
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local payload
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payload=$(jq -n -c \
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--arg model "${MODEL_ID}" \
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--arg content "${PROBE_PROMPT}" \
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--argjson tokens "${MAX_TOKENS}" \
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'{
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model: $model,
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messages: [{role: "user", content: $content}],
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temperature: 0.1,
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max_tokens: $tokens
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}')
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local resp http_code body
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resp=$(curl --silent --show-error --max-time "${INFER_TIMEOUT}" \
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--write-out '\n__HTTP__%{http_code}' \
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-X POST "${BASE}/v1/chat/completions" \
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-H 'content-type: application/json' \
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--data "${payload}") || die "curl /v1/chat/completions failed: $?"
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http_code=$(echo "${resp}" | grep -oP '(?<=__HTTP__)\d+$' | tail -1)
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body=$(echo "${resp}" | sed '$ s/__HTTP__.*$//')
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if [[ "${http_code}" != "200" ]]; then
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die "inference returned HTTP ${http_code}: ${body}"
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fi
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echo "${body}"
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}
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say "validating neuron at ${BASE}"
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probe_health
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say "/health OK"
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if is_loaded; then
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say "${MODEL_ID} already loaded"
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else
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trigger_load
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fi
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raw=$(run_probe)
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echo "---"
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# Dump the raw JSON. Don't pipe through `yq -r '.'` — yq's default
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# YAML output mode chokes on JSON strings that contain `<` (and the
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# `<think>` markers Qwen3 emits during reasoning are a perfect
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# example). The targeted `yq -r '.path'` calls below work fine
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# because jq's path filter mode bypasses the YAML re-emit.
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echo "${raw}"
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echo "---"
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content=$(echo "${raw}" | jq -r '.choices[0].message.content // empty')
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if [[ -z "${content}" ]]; then
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die "no content in chat completion response"
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fi
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say "assistant said: ${content}"
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if echo "${content}" | grep -qiF "${EXPECT_SUBSTR}"; then
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say "PASS — response contains expected substring '${EXPECT_SUBSTR}'"
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exit 0
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else
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die "response did not contain '${EXPECT_SUBSTR}'"
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fi
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