# GPU Bakeoff — Gemma 4 Throughput: 3090 Ti vs Strix Halo **Date:** 2026-04-20 **Host matrix:** steel141 (RTX 3090 Ti) · strix-halo (AMD Strix Halo iGPU) **Models:** `gemma4:26b` (MoE Q4_K_M) · `gemma4:31b-it-q4_K_M` (dense Q4_K_M) **Harness:** `scripts/gpu-bakeoff/harness.py` **Raw data:** `scripts/gpu-bakeoff/runs/` --- ## TL;DR | GPU | 26B (MoE) decode | 31B (dense) decode | Long-prompt prefill (26B) | |-----|------------------|--------------------|-----------------------| | **RTX 3090 Ti** (steel141) | **128 tok/s** | **27 tok/s** | **23,849 tok/s** | | **AMD Strix Halo iGPU** (strix-halo) | 54 tok/s (42%) | 11 tok/s (39%) | 14,326 tok/s (60%) | ### Headline findings 1. **MoE changes everything.** `gemma4:26b` decodes **~4.7× faster** than `gemma4:31b` on every GPU tested, because only ~4 B of its 25.8 B parameters activate per token. Total parameter counts (26 B vs 31 B) don't predict latency; *active* parameters do. 2. **3090 Ti wins decisively on decode.** For inference workloads the memory-bandwidth-flop ratio of consumer Ampere GDDR6X is hard to beat at this price point. 3. **Strix Halo punches above its bandwidth.** Gets 42 % of 3090 Ti decode speed on only ~25 % of the memory bandwidth (~256 GB/s vs ~1008 GB/s) — good SIMD utilization, especially on the MoE model. --- ## Hardware inventory | Host | GPU | VRAM | Bandwidth | Compute cap | Notes | |------|-----|------|-----------|-------------|-------| | steel141 | RTX 3090 Ti | 24 GB GDDR6X | ~1008 GB/s | 8.6 (Ampere) | Workstation. Also has a GTX 1660 SUPER as aux display card — not used for inference. Ollama on localhost. | | strix-halo | AMD Strix Halo (Radeon 890M iGPU + XDNA 2 NPU) | Shared LPDDR5X | ~256 GB/s | — | Unified memory lets it fit models a 24 GB card can't. Ollama accessed via Tailscale. | --- ## Methodology - Each (host × model × prompt-length) cell: - 1 warm-up call (discarded, absorbs model load time and JIT warm-up) - 3 measurement calls - `temperature: 0.0`, `top_k: 1` (greedy), `num_predict: 256`, `num_ctx: 4096` - `keep_alive: 10m` so the model stays resident between runs - Two prompt lengths: - **short** (~15 tokens) — isolates decode performance, prefill time is negligible - **long** (~500 tokens) — stresses prefill (prompt evaluation) - All timings come from Ollama's own `/api/generate` response fields (`prompt_eval_duration`, `eval_duration`, etc.), so HTTP and wall-clock jitter are excluded from the rates. - Median of the 3 measurement runs is reported in tables; min/max are in the raw JSON. --- ## Full results ### Decode rate (tok/s, median of 3 runs) Decode is the metric that matters most for interactive LLM use — it's the speed of token generation after the prompt has been processed. | Model | 3090 Ti | Strix Halo | |-------|---------|------------| | gemma4:26b (MoE, ~4 B active) | **128.20** | 53.86 | | gemma4:31b (dense, 31.3 B active) | **27.15** | 10.64 | ### Prefill rate (tok/s, long ~500-token prompt, median) Prefill is the cost of ingesting the prompt and populating the KV cache before decode begins. Batched per-token, so short-prompt prefill numbers are noisy (dominated by fixed overhead — see raw JSON for those); the long-prompt numbers below are the ones to reason from. | Model | 3090 Ti | Strix Halo | |-------|---------|------------| | gemma4:26b (long) | **23,849** | 14,326 | | gemma4:31b (long) | **7,716** | 3,278 | ### Short-prompt prefill (for reference) On a 15-token prompt, prefill tokens/sec is meaningless — prompt is too small to amortize overhead. Included only to confirm no regression. | Model | 3090 Ti | Strix Halo | |-------|---------|------------| | gemma4:26b (short) | 2,063 | 1,276 | | gemma4:31b (short) | 661 | 292 | --- ## Why 26B decodes 4.7× faster than 31B `gemma4:26b` is the MoE variant ("A4B" in Google's naming = *activated 4B*). Per-token inference routes through only ~4 B of its 25.8 B total parameters. `gemma4:31b` is dense: every one of its 31.3 B parameters participates in every token's forward pass. Memory bandwidth is the binding constraint for decode, so the ratio of *active* params is what you actually pay for. Rough math (3090 Ti, 1008 GB/s, Q4_K_M ≈ 0.5 bytes/param): - 26B MoE: 4 B × 0.5 B = 2 GB per token. Theoretical max ≈ 504 tok/s. Observed 128 tok/s = **25 % utilization**. - 31B dense: 31.3 B × 0.5 B = 15.65 GB per token. Theoretical max ≈ 64 tok/s. Observed 27 tok/s = **42 % utilization**. So dense workloads actually extract *higher* bandwidth utilization — they're less overhead-dominated per token. But in absolute terms, MoE wins by a large factor because the active-parameter bill is much smaller. For interactive chat this is decisive: Seth's `mort-bot` running `gemma4:26b` gets ~4.7× the responsiveness it would on `gemma4:31b`, even though the models are near-equal in total params. Why the ratio holds on both GPUs: **memory bandwidth is the bottleneck** on both cards. Strix gets 42 % of 3090 Ti on 26B and 39 % of 3090 Ti on 31B — nearly identical ratios — because it has ~25 % of the bandwidth and matches or slightly exceeds proportionally. --- ## When to use which GPU **Interactive chat / agent workloads (decode-heavy).** - Primary: **3090 Ti** — by a wide margin. 128 tok/s on 26B is comfortable for real-time responses. - Fallback: **Strix Halo** — 54 tok/s is usable. Benefit is unified memory can host larger models the 24 GB 3090 Ti can't. **Long-context / prompt-heavy workloads (prefill-heavy).** - Primary: **3090 Ti** again — 23,849 tok/s prefill means a 500-token prompt ingests in ~21 ms. - Strix at 14,326 tok/s is ~35 ms — still interactive. **Running models that don't fit on discrete cards.** - Strix Halo. Unified LPDDR5X can hold 80 GB+ models that a 24 GB 3090 Ti can't — at the cost of lower bandwidth. - The largest model tested here (`gemma4:31b` Q4 at 19.9 GB) fits both. Q8 variants (28 GB+) only fit Strix in this matrix. **Fine-tuning / training.** - Not measured here. 3090 Ti's 24 GB limits batch size on 20 B+ models. --- ## Open questions / follow-ups 1. **Strix max-model fit.** Strix can host models that wouldn't fit the 3090 Ti. A follow-up would pull a larger model (70 B+ quantized) on strix-halo and measure the Strix-only performance ceiling. 2. **Q8 vs Q4 on Strix.** Same model, two quantizations — quality/speed tradeoff characterization. --- ## Raw data All per-run JSON traces are under `scripts/gpu-bakeoff/runs/`: ``` runs/ ├── steel141/ │ ├── gemma4-26b/{short,long}.json │ └── gemma4-31b/{short,long}.json └── strix-halo/ ├── gemma4-26b/{short,long}.json └── gemma4-31b/{short,long}.json ``` Each JSON contains the warmup call and all 3 measurement calls with every field Ollama's `/api/generate` returns (token counts, durations, loaded-at, context length), plus a `summary` with min/median/max for prefill and decode rates.