blob: bcfbb09b79463f1c3899e4c7fed49e881a37525b [file] [log] [blame]
// Copyright 2021 The Pigweed Authors
//
// Licensed under the Apache License, Version 2.0 (the "License"); you may not
// use this file except in compliance with the License. You may obtain a copy of
// the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
// License for the specific language governing permissions and limitations under
// the License.
syntax = "proto3";
package pw.thread;
import "pw_tokenizer/proto/options.proto";
option java_package = "pw.thread.proto";
option java_outer_classname = "Thread";
message ThreadState {
enum Enum {
// Thread state is invalid or cannot be expressed by this enum.
UNKNOWN = 0;
// Interrupt handling is often done on a stack that isn't associated with a
// true RTOS thread. This state indicates the provided thread info is for an
// interrupt handler.
INTERRUPT_HANDLER = 1;
// This is the currently active thread as marked by the RTOS. In crashes in
// interrupt contexts, this isn’t necessarily the thread that crashed.
RUNNING = 2;
// Thread is ready to run, but isn’t currently running.
READY = 3;
// The thread is not ready to run, and will not be ready to run until it is
// explicitly resumed.
SUSPENDED = 4;
// The thread is waiting on something before it can run again.
BLOCKED = 5;
// The thread is either not yet initialized, or has terminated. In other
// words, this thread is a suspended thread that cannot be unsuspended.
INACTIVE = 6;
}
}
message Thread {
// Thread names must be unique; this allows extensions of Snapshot to augment
// threads with additional data. This should either be human readable text, or
// tokenized data (e.g. base-64 encoded or binary data).
bytes name = 1 [(tokenizer.format) = TOKENIZATION_OPTIONAL];
// This field has been deprecatdin favor of using the state enum to report
// RUNNING or INTERRUPT_CONTEXT to mark them as active.
//
// Whether or not this thread is the thread is the currently active context
// at the time of capture. For multi-thread dumps, this field should only be
// set on ONE thread.
bool active = 2 [deprecated = true];
// A summarized thread state. RTOS-specific extensions of the Thread message
// may provide more specific thread state information.
ThreadState.Enum state = 3;
// Contents of a stack trace. It is expected that this stack is pre-walked,
// and contains addresses. Most recent stack events are at the beginning of
// the captured stack trace.
repeated uint64 raw_backtrace = 4;
// Results of symbolizing stack_entries. This is usually not provided by the
// device, but instead by server/host side processing.
repeated string symbolized_backtrace = 5;
// This should contain the raw contents of the thread's stack. This might not
// match stack_size. It can be larger due to a stack overflow, or smaller due
// to the implementation deciding to only capture a portion of the stack.
// Partial stack captures are typically a result of storage/memory
// limitations.
bytes raw_stack = 6;
// The address this thread's stack pointer began at. For descending stacks,
// this is the highest address of the stack bounds. For ascending stacks, this
// is the lowest address of the stack bounds.
optional uint64 stack_start_pointer = 7;
// The furthest permitted address from where this thread's stack pointer
// began. For descending stacks, this is the lowest address of the stack
// bounds. For ascending stacks, this is the highest address of the stack
// bounds.
optional uint64 stack_end_pointer = 8;
// The current stack pointer of this thread.
optional uint64 stack_pointer = 9;
// CPU usage info. This is the percentage of CPU time the thread has been
// active in hundredths of a percent. (e.g. 5.00% = 500u)
optional uint32 cpu_usage_hundredths = 10;
// The address of highest estimated currently used in the thread stack.
// Percentage of bytes used can be calculated by:
// (stack_estimate_max_addr-stack_start_pointer) /
// (stack_end_pointer-stack_start_pointer) * 100%
optional uint64 stack_pointer_est_peak = 11;
}
// This message overlays the pw.snapshot.Snapshot proto. It's valid to encode
// this message to the same sink that a Snapshot proto is being written to.
message SnapshotThreadInfo {
repeated pw.thread.Thread threads = 18;
}