mamba-architecture

Included with Lifetime

$97 forever

State-space model with O(n) complexity vs Transformers' O(n²). 5× faster inference, million-token sequences, no KV cache. Selective SSM with hardware-aware design. Mamba-1 (d_state=16) and Mamba-2 (d_state=128, multi-head). Models 130M-2.8B on HuggingFace.

DesignModel ArchitectureMambaState Space ModelsSSMLinear ComplexityLong ContextEfficient InferenceHardware-Aware

What this skill does


# Mamba - Selective State Space Models

## Quick start

Mamba is a state-space model architecture achieving O(n) linear complexity for sequence modeling.

**Installation**:
```bash
# Install causal-conv1d (optional, for efficiency)
pip install causal-conv1d>=1.4.0

# Install Mamba
pip install mamba-ssm
# Or both together
pip install mamba-ssm[causal-conv1d]
```

**Prerequisites**: Linux, NVIDIA GPU, PyTorch 1.12+, CUDA 11.6+

**Basic usage** (Mamba block):
```python
import torch
from mamba_ssm import Mamba

batch, length, dim = 2, 64, 16
x = torch.randn(batch, length, dim).to("cuda")

model = Mamba(
    d_model=dim,      # Model dimension
    d_state=16,       # SSM state dimension
    d_conv=4,         # Conv1d kernel size
    expand=2          # Expansion factor
).to("cuda")

y = model(x)  # O(n) complexity!
assert y.shape == x.shape
```

## Common workflows

### Workflow 1: Language model with Mamba-2

**Complete LM with generation**:
```python
from mamba_ssm.models.mixer_seq_simple import MambaLMHeadModel
from mamba_ssm.models.config_mamba import MambaConfig
import torch

# Configure Mamba-2 LM
config = MambaConfig(
    d_model=1024,           # Hidden dimension
    n_layer=24,             # Number of layers
    vocab_size=50277,       # Vocabulary size
    ssm_cfg=dict(
        layer="Mamba2",     # Use Mamba-2
        d_state=128,        # Larger state for Mamba-2
        headdim=64,         # Head dimension
        ngroups=1           # Number of groups
    )
)

model = MambaLMHeadModel(config, device="cuda", dtype=torch.float16)

# Generate text
input_ids = torch.randint(0, 1000, (1, 20), device="cuda", dtype=torch.long)
output = model.generate(
    input_ids=input_ids,
    max_length=100,
    temperature=0.7,
    top_p=0.9
)
```

### Workflow 2: Use pretrained Mamba models

**Load from HuggingFace**:
```python
from transformers import AutoTokenizer
from mamba_ssm.models.mixer_seq_simple import MambaLMHeadModel

# Load pretrained model
model_name = "state-spaces/mamba-2.8b"
tokenizer = AutoTokenizer.from_pretrained("EleutherAI/gpt-neox-20b")  # Use compatible tokenizer
model = MambaLMHeadModel.from_pretrained(model_name, device="cuda", dtype=torch.float16)

# Generate
prompt = "The future of AI is"
input_ids = tokenizer(prompt, return_tensors="pt").input_ids.to("cuda")
output_ids = model.generate(
    input_ids=input_ids,
    max_length=200,
    temperature=0.7,
    top_p=0.9,
    repetition_penalty=1.2
)
generated_text = tokenizer.decode(output_ids[0])
print(generated_text)
```

**Available models**:
- `state-spaces/mamba-130m`
- `state-spaces/mamba-370m`
- `state-spaces/mamba-790m`
- `state-spaces/mamba-1.4b`
- `state-spaces/mamba-2.8b`

### Workflow 3: Mamba-1 vs Mamba-2

**Mamba-1** (smaller state):
```python
from mamba_ssm import Mamba

model = Mamba(
    d_model=256,
    d_state=16,      # Smaller state dimension
    d_conv=4,
    expand=2
).to("cuda")
```

**Mamba-2** (multi-head, larger state):
```python
from mamba_ssm import Mamba2

model = Mamba2(
    d_model=256,
    d_state=128,     # Larger state dimension
    d_conv=4,
    expand=2,
    headdim=64,      # Head dimension for multi-head
    ngroups=1        # Parallel groups
).to("cuda")
```

**Key differences**:
- **State size**: Mamba-1 (d_state=16) vs Mamba-2 (d_state=128)
- **Architecture**: Mamba-2 has multi-head structure
- **Normalization**: Mamba-2 uses RMSNorm
- **Distributed**: Mamba-2 supports tensor parallelism

### Workflow 4: Benchmark vs Transformers

**Generation speed comparison**:
```bash
# Benchmark Mamba
python benchmarks/benchmark_generation_mamba_simple.py \
  --model-name "state-spaces/mamba-2.8b" \
  --prompt "The future of machine learning is" \
  --topp 0.9 --temperature 0.7 --repetition-penalty 1.2

# Benchmark Transformer
python benchmarks/benchmark_generation_mamba_simple.py \
  --model-name "EleutherAI/pythia-2.8b" \
  --prompt "The future of machine learning is" \
  --topp 0.9 --temperature 0.7 --repetition-penalty 1.2
```

**Expected results**:
- **Mamba**: 5× faster inference
- **Memory**: No KV cache needed
- **Scaling**: Linear with sequence length

## When to use vs alternatives

**Use Mamba when**:
- Need long sequences (100K+ tokens)
- Want faster inference than Transformers
- Memory-constrained (no KV cache)
- Building streaming applications
- Linear scaling important

**Advantages**:
- **O(n) complexity**: Linear vs quadratic
- **5× faster inference**: No attention overhead
- **No KV cache**: Lower memory usage
- **Million-token sequences**: Hardware-efficient
- **Streaming**: Constant memory per token

**Use alternatives instead**:
- **Transformers**: Need best-in-class performance, have compute
- **RWKV**: Want RNN+Transformer hybrid
- **RetNet**: Need retention-based architecture
- **Hyena**: Want convolution-based approach

## Common issues

**Issue: CUDA out of memory**

Reduce batch size or use gradient checkpointing:
```python
model = MambaLMHeadModel(config, device="cuda", dtype=torch.float16)
model.gradient_checkpointing_enable()  # Enable checkpointing
```

**Issue: Slow installation**

Install binary wheels (not source):
```bash
pip install mamba-ssm --no-build-isolation
```

**Issue: Missing causal-conv1d**

Install separately:
```bash
pip install causal-conv1d>=1.4.0
```

**Issue: Model not loading from HuggingFace**

Use `MambaLMHeadModel.from_pretrained` (not `AutoModel`):
```python
from mamba_ssm.models.mixer_seq_simple import MambaLMHeadModel
model = MambaLMHeadModel.from_pretrained("state-spaces/mamba-2.8b")
```

## Advanced topics

**Selective SSM**: See [references/selective-ssm.md](references/selective-ssm.md) for mathematical formulation, state-space equations, and how selectivity enables O(n) complexity.

**Mamba-2 architecture**: See [references/mamba2-details.md](references/mamba2-details.md) for multi-head structure, tensor parallelism, and distributed training setup.

**Performance optimization**: See [references/performance.md](references/performance.md) for hardware-aware design, CUDA kernels, and memory efficiency techniques.

## Hardware requirements

- **GPU**: NVIDIA with CUDA 11.6+
- **VRAM**:
  - 130M model: 2GB
  - 370M model: 4GB
  - 790M model: 8GB
  - 1.4B model: 14GB
  - 2.8B model: 28GB (FP16)
- **Inference**: 5× faster than Transformers
- **Memory**: No KV cache (lower than Transformers)

**Performance** (vs Transformers):
- **Speed**: 5× faster inference
- **Memory**: 50% less (no KV cache)
- **Scaling**: Linear vs quadratic

## Resources

- Paper (Mamba-1): https://arxiv.org/abs/2312.00752 (Dec 2023)
- Paper (Mamba-2): https://arxiv.org/abs/2405.21060 (May 2024)
- GitHub: https://github.com/state-spaces/mamba ⭐ 13,000+
- Models: https://huggingface.co/state-spaces
- Docs: Repository README and wiki

Files: 4

Size: 29.3 KB

Complexity: 50/100

Category: Design

Source: https://github.com/davila7/claude-code-templates/tree/main/cli-tool/components/skills/ai-research/model-architecture-mamba

Related in Design

contribute

Included

Local-only OSS contribution command center. Auto-refreshes the user's in-flight PR and issue state on invoke so conversations start with full context — no need to brief Claude on what's in flight. Helps the user find issues to contribute to on GitHub, builds per-repo dossiers of what each upstream expects (CLA, DCO, branch convention, AI policy, draft-first, review bots, issue templates), runs deterministic gates before any external action so AI-assisted contributions don't reach maintainers as slop. State is markdown-only: candidate files at ~/.contribute-system/candidates/, repo dossiers at ~/.contribute-system/research/, append-only event log at ~/.contribute-system/log.jsonl. No database, no cloud calls. Use when the user asks about their PRs / issues / contributions, wants to find new work to take on, claim an issue, build/refresh a repo's dossier, or draft a Design Issue or PR. Trigger with "/contribute", "what's my PR status", "find a contribution", "claim issue X", "draft a Design Issue for Y", "refresh dossier for Z".

Designscripts

architectural-analysis

Included

User-triggered deep architectural analysis of a codebase or scoped subtree across eight modes — information architecture, data flow, integration points, UI surfaces, interaction patterns, data model, control flow, and failure modes. This skill should be used when the user asks to "diagram this codebase," "map the architecture," "show the data flow," "give me an ERD," "trace control flow," "find the integration points," "verify the layout pattern," "audit the UX architecture," or any similar request whose primary deliverable is mermaid diagrams plus cited reports under docs/architecture/. Dispatches haiku/sonnet sub-agents in parallel for per-mode exploration, then verifies every citation mechanically before any node lands in a diagram. Not for one-off prose explanations of code (use code-explanation) or for high-level system design from scratch (use system-design).

Designscripts

mcp

Included

Model Context Protocol (MCP) server development and tool management. Languages: Python, TypeScript. Capabilities: build MCP servers, integrate external APIs, discover/execute MCP tools, manage multi-server configs, design agent-centric tools. Actions: create, build, integrate, discover, execute, configure MCP servers/tools. Keywords: MCP, Model Context Protocol, MCP server, MCP tool, stdio transport, SSE transport, tool discovery, resource provider, prompt template, external API integration, Gemini CLI MCP, Claude MCP, agent tools, tool execution, server config. Use when: building MCP servers, integrating external APIs as MCP tools, discovering available MCP tools, executing MCP capabilities, configuring multi-server setups, designing tools for AI agents.

Designscripts

react-native-skia

Included

Design, build, debug, and optimise high-polish animated graphics in React Native or Expo using @shopify/react-native-skia, Reanimated, and Gesture Handler. Use when the user wants canvas-driven UI, shaders, paths, rich text, image filters, sprite fields, Skottie, video frames, snapshots, web CanvasKit setup, or performance tuning for custom motion-heavy elements such as loaders, hero art, cards, charts, progress indicators, particle systems, or gesture-driven surfaces. Also use when the user asks for fluid, glow, glass, blob, parallax, 60fps/120fps, or GPU-friendly animated effects in React Native, even if they do not explicitly say "Skia". Do not use for ordinary form/layout work with standard views.

Designscripts

plaid

Included

Product Led AI Development — guides founders from idea to launched product. Six capabilities: Idea (discover a product idea), Validate (pressure-test the idea against fatal flaws, problem reality, competition, and 2-week MVP feasibility), Plan (vision intake + document generation), Design (translate image references into a design.md spec), Launch (go-to-market strategy), and Build (roadmap execution). Use when someone says "PLAID", "plaid idea", "help me find an idea", "product idea", "idea from my business", "idea from my expertise", "plaid validate", "validate my idea", "pressure-test", "is this idea good", "find fatal flaws", "validate the problem", "plan a product", "define my vision", "generate a PRD", "product strategy", "plaid design", "design from image", "translate image to design", "create design.md", "extract design tokens", "plaid launch", "go-to-market", "launch plan", "GTM strategy", "launch playbook", "plaid build", "build the app", "start building", or "execute the roadmap".

Designscripts

nextjs-framer-motion-animations

Included

Adds production-safe Motion for React or Framer Motion animations to Next.js apps, including reveal, hover and tap micro-interactions, whileInView, stagger, AnimatePresence, layout and layoutId transitions, reorder, scroll-linked UI, and lightweight route-content transitions. Use when the user asks to add, refactor, or debug Motion or Framer Motion in App Router or Pages Router codebases, especially around server/client boundaries, reduced motion, LazyMotion, bundle size, hydration, or route transitions. Avoid for GSAP-style timelines, WebGL or 3D scenes, heavy scroll storytelling, or CSS-only effects unless Motion is explicitly requested.

Designscripts