| name | build-parallelism |
| description | Guide for optimizing MSBuild build parallelism and multi-project scheduling. USE FOR: builds not utilizing all CPU cores, speeding up multi-project solutions, evaluating graph build mode (/graph), build time not improving with -m flag, understanding project dependency topology. Note: /maxcpucount default is 1 (sequential) — always use -m for parallel builds. Covers /maxcpucount, graph build for better scheduling and isolation, BuildInParallel on MSBuild task, reducing unnecessary ProjectReferences, solution filters (.slnf) for building subsets. DO NOT USE FOR: single-project builds, incremental build issues (use incremental-build), compilation slowness within a project (use build-perf-diagnostics), non-MSBuild build systems. |
| license | MIT |
MSBuild Parallelism Model
/maxcpucount (or -m): number of worker nodes (processes)
- Default: 1 node (sequential!). Always use
-m for parallel builds
- Recommended:
-m without a number = use all logical processors
- Each node builds one project at a time
- Projects are scheduled based on dependency graph
Project Dependency Graph
- MSBuild builds projects in dependency order (topological sort)
- Critical path: longest chain of dependent projects determines minimum build time
- Bottleneck: if project A depends on B, C, D and B takes 60s while C and D take 5s, B is the bottleneck
- Diagnosis: replay binlog to diagnostic log with
performancesummary and check Project Performance Summary — shows per-project time; grep for node.*assigned to check scheduling
- Wide graphs (many independent projects) parallelize well; deep graphs (long chains) don't
Graph Build Mode (/graph)
dotnet build /graph or msbuild /graph
- What it changes: MSBuild constructs the full project dependency graph BEFORE building
- Benefits: better scheduling, avoids redundant evaluations, enables isolated builds
- Limitations: all projects must use
<ProjectReference> (no programmatic MSBuild task references)
- When to use: large solutions with many projects, CI builds
- When NOT to use: projects that dynamically discover references at build time
Optimizing Project References
- Reduce unnecessary
<ProjectReference> — each adds to the dependency chain
- Use
<ProjectReference ... SkipGetTargetFrameworkProperties="true"> to avoid extra evaluations
<ProjectReference ... ReferenceOutputAssembly="false"> for build-order-only dependencies
- Consider if a ProjectReference should be a PackageReference instead (pre-built NuGet)
- Use
solution filters (.slnf) to build subsets of the solution
BuildInParallel
<MSBuild Projects="@(ProjectsToBuild)" BuildInParallel="true" /> in custom targets
- Without
BuildInParallel="true", MSBuild task batches projects sequentially
- Ensure
/maxcpucount > 1 for this to have effect
Multi-threaded MSBuild Tasks
- Individual tasks can run multi-threaded within a single project build
- Tasks implementing
IMultiThreadableTask can run on multiple threads
- Tasks must declare thread-safety via
[MSBuildMultiThreadableTask]
Analyzing Parallelism with Binlog
Primary: binlog MCP (preferred)
Use the binlog MCP server (Microsoft.AITools.BinlogMcp, exposed under the binlog MCP namespace):
- Use expensive_projects tool → find the slowest projects and compare individual vs total build time
- Use expensive_targets tool → find bottleneck targets
- Use project_target_times tool → drill into a specific project's target-level timing
- Ideal: build time should be much less than sum of project times (parallelism)
- If build time ≈ sum of project times: too many serial dependencies, or one slow project blocking others
Fallback: text-log replay (when MCP is unavailable)
Step-by-step:
- Replay the binlog:
dotnet msbuild build.binlog -noconlog -fl -flp:v=diag;logfile=full.log;performancesummary
- Check Project Performance Summary at the end of
full.log
- Ideal: build time should be much less than sum of project times (parallelism)
- If build time ≈ sum of project times: too many serial dependencies, or one slow project blocking others
grep 'Target Performance Summary' -A 30 full.log → find the bottleneck targets
- Consider splitting large projects or optimizing the critical path
CI/CD Parallelism Tips
- Use
-m in CI (many CI runners have multiple cores)
- Consider splitting solution into build stages for extreme parallelism
- Use build caching (NuGet lock files, deterministic builds) to avoid rebuilding unchanged projects
dotnet build /graph works well with structured CI pipelines