SMF (Semantic Memory Filesystem) vs tldr MCP Gateway

SMF (Semantic Memory Filesystem) is an open-source Python library that treats the POSIX filesystem as the native memory infrastructure for AI agents. The core bet: instead of standing up a vector database, embedding service, and retrieval pipeline, you model your agent's memory as ordinary directories, files, and symlinks — then use the OS's own tools for retrieval. Entities are directories, relationships are symlinks, metadata is file attributes, and search is built on grep and find. The appeal is radical simplicity. Every developer already understands the filesystem. Memory built on top of it is inspectable with any editor, versionable with git, and portable across machines with rsync. There's no new query language to learn, no vector index to maintain, and no external service to keep running. Dynamis-Labs argues that for many agent memory use cases, semantic similarity search is overkill — you need entity graphs and efficient lookup, which the filesystem already provides. With only 7 stars and created yesterday (April 14), SMF is in very early stages. But the approach has attracted immediate discussion from developers frustrated with the operational overhead of vector databases for relatively structured memory tasks. It's a contrarian bet that's worth watching.

tldr is a local proxy that sits between your AI coding harness and upstream MCP servers, solving one of the most underappreciated problems in agentic workflows: context bloat from tool schema proliferation. When you connect GitHub MCP, filesystem MCP, and a few others, you can easily be sending 24,000+ tokens of tool schemas to the model before any work begins. Instead of passing all those schemas directly, tldr exposes exactly five wrapper tools to the model: search_tools, execute_plan, call_raw, inspect_tool, and get_result. The model learns which underlying tools exist on-demand through search_tools, then calls them through the proxy. GitHub MCP's 24,473-token schema surface compresses to 3,482 tokens — an 86% reduction. Output responses are further compressed through field stripping, a 4,096-token cap, and a 64KB byte limit. This is a genuinely practical solution for power users running multi-MCP setups who've noticed degraded performance as their tool count grows. The tradeoff is one extra hop of indirection, but the token savings pay for themselves in improved model attention and lower API costs.