# Service-based model  ## Service The tracing service is a long-lived entity (a system daemon on Linux/Android, a service in Chrome) that has the following responsibilities: * Maintains a registry of active producers and their data sources. * Owns the trace buffers. * Handles multiplexing of several tracing sessions. * Routes the trace config from the consumers to the corresponding producers. * Tells the Producers when and what to trace. * Moves data from the Producer's shared memory buffer to the central non-shared trace buffers. ## Producer A producer is an untrusted entity that offers the ability to contribute to the trace. In a multiprocess model, a producer almost always corresponds to a client process of the tracing service. It advertises its ability to contribute to the trace with one or more data sources. Each producer has exactly: * One shared memory buffer, shared exclusively with the tracing service. * One IPC channel with the tracing service. A producer is completely decoupled (both technically and conceptually) from consumer(s). A producer knows nothing about: * How many consumer(s) are connected to the service. * How many tracing sessions are active. * How many other producer(s) are registered or active. * Trace data written by other producer(s). NOTE: In rare circumstances a process can host more than one producer and hence more than one shared memory buffer. This can be the case for a process bundling third-party libraries that in turn include the Perfetto client library. Concrete example: at some point in the future Chrome might expose one Producer for tracing within the main project, one for V8 and one for Skia (for each child process). ## Consumer A consumer is a trusted entity (a cmdline client on Linux/Android, an interface of the Browser process in Chrome) that controls (non-exclusively) the tracing service and reads back (destructively) the trace buffers. A consumer has the ability to: * Send a [trace config](#) to the service, determining: * How many trace buffers to create. * How big the trace buffers should be. * The policy for each buffer (*ring-buffer* or *stop-when-full*). * Which data sources to enable. * The configuration for each data source. * The target buffer for the data produced by each data source configured. * Enable and disable tracing. * Read back the trace buffers: * Streaming data over the IPC channel. * Passing a file descriptor to the service and instructing it to periodically save the trace buffers into the file. ## Data source A data source is a capability, exposed by a Producer, of providing some tracing data. A data source almost always defines its own schema (a protobuf) consisting of: * At most one `DataSourceConfig` sub-message: ([example](/protos/perfetto/config/ftrace/ftrace_config.proto)) * One or more `TracePacket` sub-messages ([example](/protos/perfetto/trace/ps/process_tree.proto)) Different producers may expose the same data source. Concrete example: *** aside At some point in the near future we might offer, as part of Perfetto, a library for in-process heap profiling. In such case more than one producer, linking against the updated Perfetto library, will expose the heap profiler data source, for its own process. ** ## IPC channel In a multiprocess scenario, each producer and each consumer interact with the service using an IPC channel. IPC is used only in non-fast-path interactions, mostly handshakes such as enabling/disabling trace (consumer), (un)registering and starting/stopping data sources (producer). The IPC is typically NOT employed to transport the protobufs for the trace. Perfetto provides a POSIX-friendly IPC implementation, based on protobufs over a UNIX socket (see [Socket protocol](/docs/design-docs/api-and-abi#socket-protocol)). That IPC implementation is not mandated. Perfetto allows the embedder: * Wrap its own IPC subsystem (e.g., Perfetto in Chromium uses Mojo) * Not use an IPC mechanism at all and just short circuit the Producer <> Service <> Consumer interaction via `PostTask(s)`. ## Shared memory buffer Producer(s) write tracing data, in the form of protobuf-encoded binary blobs, directly into its shared memory buffer, using a special library called [ProtoZero](/docs/design-docs/protozero.md). The shared memory buffer: * Has a fixed and typically small size (configurable, default: 128 KB). * Is an ABI and must maintain backwards compatibility. * Is shared by all data sources of the producer. * Is independent of the number and the size of the trace buffers. * Is independent of the number of Consumer(s). * Is partitioned in *chunks* of variable size. Each chunk: * Is owned exclusively by one Producer thread (or shared through a mutex). * Contains a linear sequence of `TracePacket(s)`, or fragments of that. A `TracePacket` can span across several chunks, the fragmentation is not exposed to the consumers (consumers always see whole packets as if they were never fragmented). * Can be owned and written by exactly one `TraceWriter`. * Is part of a reliable and ordered sequence, identified by the `WriterID`: packets in a sequence are guaranteed to be read back in order, without gaps and without repetitions. See the comments in [shared_memory_abi.h](/include/perfetto/ext/tracing/core/shared_memory_abi.h) for more details about the binary format of this buffer.