skill-memory
- Repo stars 435
- Author updated Live
- Author repo nvim
- Domain
- Other
- Compatible agents
-
- Claude Code
- Cursor
- Cline
- Codex
- Windsurf
- Gemini CLI
- +20
- Trust score
- 88 / 100 · community maintained
- Author / version / license
- @benbrastmckie · no license declared
- Token usage
- Heavy
- Setup complexity
- Guided setup
- External API key
- Not required
- Operating systems
- macOS
- Runtime requirements
- No special requirements
- Permissions
-
- Read-only
- Write / modify
- Shell exec
- Network behavior
- Local-only
- Install commands
- 26 variants
Profile is derived at build time from SKILL.md and install vectors. Subject to drift from author intent.
Heads up: 未限定 allowed-tools,默认拥有全部工具权限。
---
name: skill-memory
description: Memory vault management - create, search, classify, and index memories. Invoke for /learn comman…
category: other
runtime: no special runtime
---
# skill-memory output preview
## PART A: Task fit
- Use case: Memory vault management - create, search, classify, and index memories. Invoke for /learn command memory operations. Direct execution skill for memory vault management. Handles memory creation, similarity search, classification, and index maintenance through content mapping, MCP-based deduplication, and three memory operations (UPDATE, EXTEND, CREATE). ru….
- Inputs: target material, constraints, expected output, and acceptance criteria.
- Evidence boundary: follow “Context References / Execution Modes / Content Mapping” and do not present inference as author intent.
## PART B: Execution result
- **01** The card summarizes the use case; runtime output centers on “Memory vault management - create, search, classify, and index memories. Invoke for /learn command memory operations. Direct execution skill for memory vault management. Handles memory creation, similarity search, classification, and index maintenance through content mapping, MCP-based deduplication, and three memory operations (UPDATE, EXTEND, CREATE). ru…”.
- **02** When the source has headings, the agent prioritizes “Context References / Execution Modes / Content Mapping” so the result follows the author’s structure.
- **03** Typical output includes task judgment, concrete steps, required commands or file edits, validation, and follow-up options.
- **04** Risk context follows the fingerprint: read files, write/modify files, run shell commands; mostly runs locally; usually needs no extra API key.
## Running Rules
- read files, write/modify files, run shell commands; mostly runs locally; usually needs no extra API key.
- Validate with a small sample before expanding scope.
- Return the result, validation criteria, and next iteration options. The source mentions slash commands such as `/project`, `/home`, `/learn`; use them first when your agent supports command triggers.
Name target files or source material, expected output, forbidden changes, and whether network or shell access is allowed. Permission fingerprint: read files, write/modify files, run shell commands.
Start with a small task and check whether the result follows “Context References / Execution Modes / Content Mapping”. Inspect diffs, logs, previews, or tests before expanding scope.
Confirm the final output includes a concrete result, evidence, and next action. If it stays generic, tighten inputs, boundaries, and acceptance criteria.
---
name: skill-memory
description: Memory vault management - create, search, classify, and index memories. Invoke for /learn comman…
category: other
source: benbrastmckie/nvim
---
# skill-memory
## When to use
- Memory vault management - create, search, classify, and index memories. Invoke for /learn command memory operations. D…
- Use it when the task has clear inputs, repeatable steps, and validation criteria.
## What to provide
- Target material, scope, expected result, and forbidden changes.
- Whether network, commands, file writes, or external services are allowed.
## Execution rules
- Organize steps around “Context References / Execution Modes / Content Mapping” and keep inference separate from source facts.
- read files, write/modify files, run shell commands; mostly runs locally; usually needs no extra API key.
- Validate with a small sample before expanding the task.
## Output requirements
- Return the deliverable, key evidence, validation method, and next action.
- Mark missing information as unknown; do not invent commands, platforms, or dependencies. The author source anchors workflow facts; repository files anchor sources and commands; Fluxly only adds fit, limitations, and quality judgment.
skill "skill-memory" {
input -> user goal + target files + boundaries + acceptance criteria
context -> Context References / Execution Modes / Content Mapping
rules -> SKILL.md triggers / order / output contract
runtime -> no special runtime | read files, write/modify files, run shell commands | mostly runs locally
guardrails -> usually needs no extra API key + small-sample validation + diff/log review
output -> copyable result + checklist + next iteration
} Memory Skill (Direct Execution)
Direct execution skill for memory vault management. Handles memory creation, similarity search, classification, and index maintenance through content mapping, MCP-based deduplication, and three memory operations (UPDATE, EXTEND, CREATE).
MANDATORY INTERACTIVE REQUIREMENT — DO NOT SKIP:
- STOP at Step 4 and call AskUserQuestion to show files. Write NOTHING to disk until user responds.
- STOP at Memory Search and call AskUserQuestion for each segment. Write NOTHING to disk until user responds.
- These are not optional. Running autonomously without user input is a critical failure.
Context References
Reference (do not load eagerly):
- Path:
@.memory/30-Templates/memory-template.md- Memory template - Path:
@.memory/20-Indices/index.md- Memory index - Path:
@.opencode/context/project/memory/learn-usage.md- Usage guide
Execution Modes
| Mode | Input | Description |
|---|---|---|
text |
Text content | Add quoted text as memory |
file |
File path | Add single file content as memory |
directory |
Directory path | Scan directory for learnable content |
task |
Task number | Review task artifacts and create memories |
All non-task modes flow through: Content Mapping -> Memory Search -> Memory Operations
Content Mapping
Content mapping is the intermediate representation between input acquisition and memory operations. It segments input into topic-aligned chunks that can be matched against existing memories.
Content Map Data Structure
{
"source": {
"type": "text|file|directory",
"path": "/path/to/input",
"total_tokens": 2500
},
"segments": [
{
"id": "seg-001",
"topic": "neovim/plugins/telescope",
"source_file": "/path/to/file.md",
"source_lines": "15-42",
"summary": "Telescope custom picker creation pattern",
"estimated_tokens": 350,
"key_terms": ["telescope", "picker", "finders", "sorters", "attach_mappings"]
}
]
}
Field Descriptions
| Field | Type | Description |
|---|---|---|
id |
string | Unique segment identifier (seg-NNN) |
topic |
string | Inferred topic path (slash-separated hierarchy) |
source_file |
string | Original file path (for file/directory modes) |
source_lines |
string | Line range in source file (e.g., "15-42") |
summary |
string | 1-2 sentence summary of segment content |
estimated_tokens |
number | Approximate token count for this segment |
key_terms |
array | 3-5 significant terms for matching |
Segmentation Algorithms
Structured Files (Markdown)
Split at heading boundaries:
1. Identify all headings (# ## ### ####)
2. Each heading starts a new segment
3. Segment includes all content until next same-or-higher level heading
4. Top-level content before first heading becomes its own segment
Structured Files (Code)
Split at blank-line-separated blocks:
1. Identify function/class definitions
2. Group related comments with their definitions
3. Separate standalone comment blocks as documentation segments
4. Keep import/require blocks together
Unstructured Text
Split at paragraph boundaries with topic grouping:
1. Split at double-newline (paragraph boundaries)
2. Group adjacent paragraphs with keyword overlap >40%
3. Single-sentence paragraphs merge with adjacent
Directory Input
Each file becomes an initial segment, then large files are split:
1. Each file is an initial segment
2. Files >800 tokens are split at section boundaries
3. Files <100 tokens are candidates for merging with related files
Small-Input Bypass
Inputs under 500 tokens skip segmentation and become a single segment:
if total_tokens < 500:
segments = [{
"id": "seg-001",
"topic": inferred_topic,
"summary": first_line_or_60_chars,
"estimated_tokens": total_tokens,
"key_terms": extract_keywords(content, 5)
}]
Segment Size Guidelines
| Condition | Action |
|---|---|
| Segment <100 tokens | Merge with adjacent same-topic segment |
| Segment 200-500 tokens | Ideal size, no action |
| Segment >800 tokens | Split at next heading/paragraph boundary |
Key Term Extraction
Extract 3-5 significant terms per segment:
1. Remove stop words (the, a, is, are, etc.)
2. Extract nouns and technical terms (>4 characters)
3. Prioritize: proper nouns > technical terms > common nouns
4. Deduplicate (case-insensitive)
5. Return top 5 by frequency within segment
Memory Search
After content mapping, each segment is matched against existing memories to determine the appropriate operation (UPDATE, EXTEND, or CREATE).
MCP Search Path
When MCP server is available, use the execute pattern:
For each segment in content_map.segments:
query = segment.key_terms.join(" ")
results = execute("search", {
"query": query,
"vault": ".memory",
"limit": 5
})
Grep Fallback Path
When MCP is unavailable, use keyword-based file search:
# For each segment
for keyword in $key_terms; do
grep -l -i "$keyword" .memory/10-Memories/*.md 2>/dev/null
done | sort | uniq -c | sort -rn | head -5
Overlap Scoring
Score keyword overlap between segment and each matching memory:
overlap_score = |segment_terms intersect memory_terms| / |segment_terms|
Where:
- segment_terms = segment.key_terms
- memory_terms = keywords extracted from memory content (same algorithm)
Classification Thresholds
| Overlap Score | Classification | Action |
|---|---|---|
| >60% | HIGH | UPDATE - Replace memory content |
| 30-60% | MEDIUM | EXTEND - Append new section |
| <30% | LOW | CREATE - New memory |
Search Result Presentation — MANDATORY STOP
YOU MUST call AskUserQuestion for EACH segment before writing anything. Do NOT infer what the user wants. Do NOT skip segments. Do NOT write memory files without explicit user confirmation per segment.
Present each segment with related memories via AskUserQuestion:
Segment: {segment.summary}
Topic: {segment.topic}
Key terms: {segment.key_terms.join(", ")}
Related Memories:
1. MEM-telescope-custom-pickers (72% overlap) -> Recommended: UPDATE
2. MEM-neovim-plugin-patterns (45% overlap) -> Recommended: EXTEND
3. MEM-lua-module-structure (18% overlap) -> Recommended: CREATE (no strong match)
What would you like to do with this segment?
[ ] UPDATE MEM-telescope-custom-pickers (replace content)
[ ] EXTEND MEM-neovim-plugin-patterns (append section)
[ ] CREATE new memory
[ ] SKIP - don't save this segment
Interactive Override
Users can override any recommendation:
- Change UPDATE to CREATE (preserve existing, create duplicate)
- Change EXTEND to UPDATE (replace instead of append)
- Skip any segment
- Merge segments before processing (combine into single memory)
Memory Operations
Three distinct operations for memory management:
UPDATE Operation
Replace memory content while preserving structure:
1. Read existing memory file
2. Preserve frontmatter: created (original), tags, topic
3. Update frontmatter: modified = today
4. Move current content to ## History section with date marker
5. Replace main content with new segment content
6. Preserve ## Connections section
7. Write updated memory
Template for UPDATE:
---
title: "{new_title_from_segment}"
created: {original_created}
tags: {merged_tags}
topic: "{existing_or_updated_topic}"
source: "{new_source}"
modified: {today}
---
# {new_title}
{new_content_from_segment}
## History
### Previous Version ({original_created})
{previous_content}
## Connections
{preserved_connections}
EXTEND Operation
Append new dated section without modifying existing content:
1. Read existing memory file
2. Find insertion point (before ## Connections, or end of file)
3. Add dated extension section
4. Update frontmatter: modified = today
5. Optionally update tags if new topics introduced
6. Write updated memory
Template for EXTEND:
## Extension ({today})
**Source**: {segment.source_file}
{segment_content}
CREATE Operation
Generate new memory from segment:
1. Generate semantic slug from topic and title:
generate_slug() {
local topic="$1"
local title="$2"
local base=""
# Priority 1: Topic path (most specific segment)
if [ -n "$topic" ]; then
base=$(echo "$topic" | rev | cut -d'/' -f1 | rev)
fi
# Priority 2: First 2-3 words of title
local title_slug=$(echo "$title" | tr '[:upper:]' '[:lower:]' | \
sed 's/[^a-z0-9 ]/-/g' | tr ' ' '-' | \
cut -d'-' -f1-3 | sed 's/-$//')
# Combine
if [ -n "$base" ]; then
slug="${base}-${title_slug}"
else
slug="$title_slug"
fi
# Sanitize and truncate to 50 chars
slug=$(echo "$slug" | sed 's/--*/-/g' | sed 's/^-//' | sed 's/-$//' | cut -c1-50)
# Handle collision - NOTE: MEM- prefix preserved for grep discoverability
local final_slug="$slug"
local counter=2
while [ -f ".memory/10-Memories/MEM-${final_slug}.md" ]; do
final_slug="${slug}-${counter}"
counter=$((counter + 1))
done
echo "$final_slug"
}
slug=$(generate_slug "$topic" "$title")
filename="MEM-${slug}.md"
2. Apply memory template with all fields
3. Infer and apply topic
4. Add to index (both category and topic sections)
5. Write new memory file
Template for CREATE:
---
title: "{segment.summary}"
created: {today}
tags: {inferred_tags}
topic: "{segment.topic}"
source: "{segment.source_file or 'user input'}"
modified: {today}
---
# {segment.summary}
{segment_content}
## Connections
<!-- Add links to related memories using [[filename]] syntax -->
Note: The MEM- prefix is preserved for grep discoverability (grep -r "MEM-" .memory/). Filenames follow the pattern MEM-{semantic-slug}.md (e.g., MEM-telescope-custom-pickers.md).
Topic Inference
Infer topic using four-source priority:
1. Source directory path (highest priority)
- /project/src/utils/ -> "project/utils"
- /home/user/notes/neovim/ -> "neovim"
2. Keyword analysis
- Extract domain indicators: neovim, lua, telescope, lazy
- Map to topic: "neovim/plugins" or "neovim/config"
3. Related memory topics
- If UPDATE/EXTEND: inherit topic from target memory
- If CREATE with high-overlap match: suggest that topic
4. User confirmation/override
- Always present inferred topic for confirmation
- User can modify or create new topic path
Index Maintenance
After each operation, update both index.md and .memory/10-Memories/README.md:
index.md:
1. Add/update entry in "## By Category" under appropriate tag
2. Add/update entry in "## By Topic" under topic path
3. Update "## Recent Memories" (prepend, keep last 10)
4. Update "## Statistics" counts
.memory/10-Memories/README.md -- regenerate the full file listing:
1. List all MEM-*.md files in the directory (ls .memory/10-Memories/MEM-*.md)
2. For each file, extract: title, topic, tags, created from frontmatter
3. Rewrite README.md with updated count and one entry per memory:
### [MEM-{slug}](MEM-{slug}.md)
**Title**: {title}
**Topic**: {topic}
**Tags**: {tags}
**Created**: {created}
4. Keep "## Navigation" section at the bottom
Index Regeneration Pattern
To avoid concurrent write conflicts, regenerate index.md from filesystem state rather than append:
# 1. List all memory files
memories=$(ls .memory/10-Memories/MEM-*.md 2>/dev/null)
# 2. Extract metadata from each file
for mem in $memories; do
title=$(grep -m1 "^title:" "$mem" | cut -d'"' -f2)
topic=$(grep -m1 "^topic:" "$mem" | cut -d'"' -f2)
created=$(grep -m1 "^created:" "$mem" | cut -d: -f2 | tr -d ' ')
# Store for index generation
done
# 3. Regenerate index.md from extracted data
# Sort by date descending, write complete file
Benefits:
- No append conflicts (complete overwrite)
- Self-healing (missing entries recovered)
- Idempotent (multiple regenerations produce same result)
Task Mode Execution
Task mode has special handling for reviewing existing task artifacts.
Step 1: Locate Task Directory
task_num=$task_number
padded_num=$(printf "%03d" $task_num)
task_dir=$(ls -d specs/${padded_num}_* 2>/dev/null | head -1)
if [ -z "$task_dir" ]; then
task_dir=$(ls -d specs/${task_num}_* 2>/dev/null | head -1)
fi
if [ -z "$task_dir" ]; then
echo "Task directory not found: specs/${padded_num}_*"
exit 1
fi
Step 2: Scan Artifacts
artifacts=$(find "$task_dir" -type f -name "*.md" | sort)
if [ -z "$artifacts" ]; then
echo "No artifacts found for task ${task_number}"
exit 1
fi
Step 3: Present Artifact List
Display via AskUserQuestion:
{
"question": "Select artifacts to review for memory extraction:",
"header": "Task Artifacts",
"multiSelect": true,
"options": [
{
"label": "{artifact_1_name}",
"description": "{artifact_1_path}"
}
]
}
Step 4: Process Through Content Mapping
For each selected artifact:
- Read content
- If >500 tokens: run through content mapping (segmentation)
- If <=500 tokens: treat as single segment
- Proceed to Memory Search (Phase 4)
- Proceed to Memory Operations (Phase 5)
Step 5: Classification Taxonomy
For task artifacts, also present classification options:
{
"question": "Classify this segment:",
"header": "Classification: {segment.summary}",
"multiSelect": false,
"options": [
{"label": "[TECHNIQUE]", "description": "Reusable method or approach"},
{"label": "[PATTERN]", "description": "Design or implementation pattern"},
{"label": "[CONFIG]", "description": "Configuration or setup knowledge"},
{"label": "[WORKFLOW]", "description": "Process or procedure"},
{"label": "[INSIGHT]", "description": "Key learning or understanding"},
{"label": "[SKIP]", "description": "Not valuable for memory"}
]
}
Step 6: Return Result
{
"status": "completed",
"mode": "task",
"artifacts_reviewed": [...],
"content_map": { ... },
"operations": [
{"type": "CREATE", "memory_id": "MEM-...", "category": "[PATTERN]"}
],
"memories_affected": 3
}
Directory Mode Execution
Directory mode scans a directory tree for learnable content.
Step 1: Recursive Scanning
# Exclusion patterns
EXCLUDES="-path '*/.git' -prune -o -path '*/node_modules' -prune -o -path '*/__pycache__' -prune -o -path '*/.obsidian' -prune"
# Find all files
files=$(find "$directory_path" $EXCLUDES -type f -print | head -250)
Step 2: Two-Tier Text Detection
Tier 1: Extension Whitelist
Recognized text extensions (alphabetized by category):
| Category | Extensions |
|---|---|
| Code | .c, .cpp, .cs, .go, .h, .hpp, .java, .js, .jsx, .kt, .lua, .php, .pl, .py, .r, .rb, .rs, .scala, .sh, .swift, .ts, .tsx, .vim |
| Config | .cfg, .conf, .ini, .json, .toml, .xml, .yaml, .yml |
| Data | .csv, .sql |
| Documentation | .adoc, .asciidoc, .md, .org, .rdoc, .rst, .tex, .txt |
| Web | .css, .htm, .html, .less, .sass, .scss, .svg |
| Neovim | .fnl, .janet, .nix |
Tier 2: MIME-Type Fallback
For files without recognized extensions:
mime=$(file --mime-type -b "$file")
if [[ "$mime" == text/* ]]; then
# Include file
fi
Step 3: Size Limits
# Per-file limit
if [ $(stat -c%s "$file") -gt 102400 ]; then
echo "Skipping large file: $file (>100KB)"
continue
fi
# Warning at 50 files
if [ ${#files[@]} -gt 50 ]; then
echo "Warning: ${#files[@]} files found. Consider narrowing scope."
fi
# Hard limit at 200 files
if [ ${#files[@]} -gt 200 ]; then
echo "Error: Too many files (${#files[@]}). Maximum is 200."
echo "Narrow your path or use file mode for specific files."
exit 1
fi
Step 4: File Selection (Paginated) — MANDATORY STOP
YOU MUST call AskUserQuestion here. Do NOT skip to Step 5. Do NOT process any files until the user has made their selection.
Present files in pages of 10 to avoid overwhelming the display. Accumulate selections across all pages before processing.
selected_files = []
page_size = 10
total_files = len(files)
page = 0
while page * page_size < total_files:
start = page * page_size
end = min(start + page_size, total_files)
page_files = files[start:end]
remaining = total_files - end
page_num = page + 1
total_pages = ceil(total_files / page_size)
# Build options for this page
options = [{"label": relative_path, "description": file_size} for each file in page_files]
# Add navigation options at the bottom
if remaining > 0:
options.append({"label": "--- Continue to next page ---", "description": f"{remaining} more files remaining"})
AskUserQuestion({
"question": f"Select files to include (page {page_num}/{total_pages}, showing {start+1}-{end} of {total_files}):",
"header": f"Directory Scan: {directory_path}",
"multiSelect": true,
"options": options
})
# Add any selected files (excluding the navigation option) to accumulated list
selected_files.extend(user_selections excluding navigation option)
# If user selected "Continue to next page" OR there are more pages, advance
# If user did NOT select "Continue to next page" on the last page, stop
if "--- Continue to next page ---" not in user_selections and remaining > 0:
# User is done selecting (didn't ask for more)
break
page += 1
# After all pages processed, confirm total selection
if len(selected_files) == 0:
print("No files selected. Exiting.")
exit
Example page 1 of 3:
{
"question": "Select files to include (page 1/3, showing 1-10 of 28):",
"header": "Directory Scan: /home/user/project/",
"multiSelect": true,
"options": [
{"label": "README.md", "description": "4.1KB"},
{"label": "src/main.lua", "description": "2.3KB"},
{"label": "--- Continue to next page ---", "description": "18 more files remaining"}
]
}
Step 5: Route Through Pipeline
For each selected file:
- Read file content
- Run through content mapping (directory-type segmentation)
- Route segments through memory search
- Route through memory operations
- Update index
Step 6: Return Result
{
"status": "completed",
"mode": "directory",
"files_scanned": 45,
"files_selected": 12,
"content_map": { ... },
"operations": [...],
"memories_affected": 8
}
Text Mode Execution
Step 1: Parse Input
content="$text_content"
source="user input"
Step 2: Content Mapping
For text >500 tokens, segment at paragraph boundaries:
1. Split at double-newline
2. Group related paragraphs
3. Generate single content map
For text <500 tokens, create single segment.
Step 3: Memory Search & Operations
Route through standard memory search and operations pipeline.
Step 4: Return Result
{
"status": "completed",
"mode": "text",
"content_map": { ... },
"operations": [...],
"memories_affected": 1
}
File Mode Execution
Step 1: Read File
if [ ! -f "$file_path" ]; then
echo "File not found: $file_path"
exit 1
fi
content=$(cat "$file_path")
source="file: $file_path"
Step 2: Content Mapping
Apply structured or unstructured segmentation based on file type.
Step 3: Memory Search & Operations
Route through standard pipeline.
Step 4: Return Result
{
"status": "completed",
"mode": "file",
"file_path": "...",
"content_map": { ... },
"operations": [...],
"memories_affected": 2
}
Error Handling
No Content Provided
Usage: /learn <text or file path or directory> OR /learn --task N
File Not Found
File not found: {path}
Directory Not Found
Directory not found: {path}
Empty Directory
No text files found in: {path}
Too Many Files
Too many files ({N}). Maximum is 200.
Narrow your path or use file mode for specific files.
Task Directory Not Found
Task directory not found: specs/{NNN}_*
User Cancels
Memory operation cancelled. No files created.
All Content Skipped
No memories created (all content skipped)
MCP Unavailable
MCP search unavailable. Using grep-based fallback.
Git Commit (Postflight)
After successful memory operations:
git add .memory/
git commit -m "memory: add/update ${memories_affected} memories
Session: ${session_id}
Decide Fit First
Design Intent
How To Use It
Boundaries And Review