Files
esphome/tests/benchmarks/components/api/bench_proto_encode.cpp
T
J. Nick Koston 38ff332fec [core] Add CodSpeed C++ benchmarks for protobuf and main loop
Add automated benchmarks using Google Benchmark to prevent performance
regressions in the API protobuf encoding/decoding and core loop paths.

Benchmarks cover:
- Protobuf encode: SensorState, BinarySensorState, HelloResponse,
  LightState, DeviceInfoResponse (20 nested devices + 20 areas)
- Protobuf decode: HelloRequest, SwitchCommand, LightCommand
- Protobuf calculate_size and full calc+encode send path
- Varint parse/encode/size for various value ranges
- Scheduler call/next_schedule_in with idle and active timers
- Application loop component dispatch and blocking guard overhead

Infrastructure:
- Extract shared build logic from cpp_unit_test.py into test_helpers.py
- Add cpp_benchmark.py mirroring the unit test build pattern
- Support benchmark.yaml per component dir for declaring dependencies
- Add CodSpeed CI workflow triggered on api/core changes
- Fix ProtoMessage protected destructor on host platform
2026-03-16 19:25:46 -10:00

211 lines
5.8 KiB
C++

#include <benchmark/benchmark.h>
#include "esphome/components/api/api_pb2.h"
#include "esphome/components/api/api_buffer.h"
namespace esphome::api::benchmarks {
// --- SensorStateResponse (highest frequency message) ---
static void BM_Encode_SensorStateResponse(benchmark::State &state) {
APIBuffer buffer;
SensorStateResponse msg;
msg.key = 0x12345678;
msg.state = 23.5f;
msg.missing_state = false;
uint32_t size = msg.calculate_size();
buffer.resize(size);
for (auto _ : state) {
ProtoWriteBuffer writer(&buffer, 0);
msg.encode(writer);
benchmark::DoNotOptimize(buffer.data());
}
}
BENCHMARK(BM_Encode_SensorStateResponse);
static void BM_CalculateSize_SensorStateResponse(benchmark::State &state) {
SensorStateResponse msg;
msg.key = 0x12345678;
msg.state = 23.5f;
msg.missing_state = false;
for (auto _ : state) {
benchmark::DoNotOptimize(msg.calculate_size());
}
}
BENCHMARK(BM_CalculateSize_SensorStateResponse);
static void BM_CalcAndEncode_SensorStateResponse(benchmark::State &state) {
APIBuffer buffer;
SensorStateResponse msg;
msg.key = 0x12345678;
msg.state = 23.5f;
msg.missing_state = false;
for (auto _ : state) {
uint32_t size = msg.calculate_size();
buffer.resize(size);
ProtoWriteBuffer writer(&buffer, 0);
msg.encode(writer);
benchmark::DoNotOptimize(buffer.data());
}
}
BENCHMARK(BM_CalcAndEncode_SensorStateResponse);
// --- BinarySensorStateResponse ---
static void BM_Encode_BinarySensorStateResponse(benchmark::State &state) {
APIBuffer buffer;
BinarySensorStateResponse msg;
msg.key = 0xAABBCCDD;
msg.state = true;
msg.missing_state = false;
uint32_t size = msg.calculate_size();
buffer.resize(size);
for (auto _ : state) {
ProtoWriteBuffer writer(&buffer, 0);
msg.encode(writer);
benchmark::DoNotOptimize(buffer.data());
}
}
BENCHMARK(BM_Encode_BinarySensorStateResponse);
// --- HelloResponse (string fields) ---
static void BM_Encode_HelloResponse(benchmark::State &state) {
APIBuffer buffer;
HelloResponse msg;
msg.api_version_major = 1;
msg.api_version_minor = 10;
msg.server_info = StringRef::from_lit("esphome v2026.3.0");
msg.name = StringRef::from_lit("living-room-sensor");
uint32_t size = msg.calculate_size();
buffer.resize(size);
for (auto _ : state) {
ProtoWriteBuffer writer(&buffer, 0);
msg.encode(writer);
benchmark::DoNotOptimize(buffer.data());
}
}
BENCHMARK(BM_Encode_HelloResponse);
// --- LightStateResponse (complex multi-field message) ---
static void BM_Encode_LightStateResponse(benchmark::State &state) {
APIBuffer buffer;
LightStateResponse msg;
msg.key = 0x11223344;
msg.state = true;
msg.brightness = 0.8f;
msg.color_mode = enums::COLOR_MODE_RGB_WHITE;
msg.color_brightness = 1.0f;
msg.red = 1.0f;
msg.green = 0.5f;
msg.blue = 0.2f;
msg.white = 0.0f;
msg.color_temperature = 4000.0f;
msg.cold_white = 0.0f;
msg.warm_white = 0.0f;
msg.effect = StringRef::from_lit("rainbow");
uint32_t size = msg.calculate_size();
buffer.resize(size);
for (auto _ : state) {
ProtoWriteBuffer writer(&buffer, 0);
msg.encode(writer);
benchmark::DoNotOptimize(buffer.data());
}
}
BENCHMARK(BM_Encode_LightStateResponse);
static void BM_CalculateSize_LightStateResponse(benchmark::State &state) {
LightStateResponse msg;
msg.key = 0x11223344;
msg.state = true;
msg.brightness = 0.8f;
msg.color_mode = enums::COLOR_MODE_RGB_WHITE;
msg.color_brightness = 1.0f;
msg.red = 1.0f;
msg.green = 0.5f;
msg.blue = 0.2f;
msg.white = 0.0f;
msg.color_temperature = 4000.0f;
msg.cold_white = 0.0f;
msg.warm_white = 0.0f;
msg.effect = StringRef::from_lit("rainbow");
for (auto _ : state) {
benchmark::DoNotOptimize(msg.calculate_size());
}
}
BENCHMARK(BM_CalculateSize_LightStateResponse);
// --- DeviceInfoResponse (nested submessages: 20 devices + 20 areas) ---
static DeviceInfoResponse make_device_info_response() {
DeviceInfoResponse msg;
msg.name = StringRef::from_lit("living-room-sensor");
msg.mac_address = StringRef::from_lit("AA:BB:CC:DD:EE:FF");
msg.esphome_version = StringRef::from_lit("2026.3.0");
msg.compilation_time = StringRef::from_lit("Mar 16 2026, 12:00:00");
msg.model = StringRef::from_lit("esp32-poe-iso");
msg.manufacturer = StringRef::from_lit("Olimex");
msg.friendly_name = StringRef::from_lit("Living Room Sensor");
#ifdef USE_DEVICES
for (uint32_t i = 0; i < ESPHOME_DEVICE_COUNT && i < 20; i++) {
msg.devices[i].device_id = i + 1;
msg.devices[i].name = StringRef::from_lit("device");
msg.devices[i].area_id = (i % 20) + 1;
}
#endif
#ifdef USE_AREAS
for (uint32_t i = 0; i < ESPHOME_AREA_COUNT && i < 20; i++) {
msg.areas[i].area_id = i + 1;
msg.areas[i].name = StringRef::from_lit("area");
}
#endif
return msg;
}
static void BM_CalculateSize_DeviceInfoResponse(benchmark::State &state) {
auto msg = make_device_info_response();
for (auto _ : state) {
benchmark::DoNotOptimize(msg.calculate_size());
}
}
BENCHMARK(BM_CalculateSize_DeviceInfoResponse);
static void BM_Encode_DeviceInfoResponse(benchmark::State &state) {
auto msg = make_device_info_response();
APIBuffer buffer;
uint32_t total_size = msg.calculate_size();
buffer.resize(total_size);
for (auto _ : state) {
ProtoWriteBuffer writer(&buffer, 0);
msg.encode(writer);
benchmark::DoNotOptimize(buffer.data());
}
}
BENCHMARK(BM_Encode_DeviceInfoResponse);
static void BM_CalcAndEncode_DeviceInfoResponse(benchmark::State &state) {
auto msg = make_device_info_response();
APIBuffer buffer;
for (auto _ : state) {
uint32_t size = msg.calculate_size();
buffer.resize(size);
ProtoWriteBuffer writer(&buffer, 0);
msg.encode(writer);
benchmark::DoNotOptimize(buffer.data());
}
}
BENCHMARK(BM_CalcAndEncode_DeviceInfoResponse);
} // namespace esphome::api::benchmarks