ChTheo/RFG_stm32_ADC_receiver_GUI
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base: ChTheo:complex-adc-format
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ChTheo:master ChTheo:complex-adc-format ChTheo:log-detector-refactor ChTheo:log-detector ChTheo:simplified_refactor ChTheo:head-fixer ChTheo:stupid ChTheo:normaliser ChTheo:refactor
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compare: ChTheo:1e05b1f3fda3a9060bbf25f086d7a9e760985c4a
Branches Tags
ChTheo:complex-adc-format ChTheo:log-detector-refactor ChTheo:log-detector ChTheo:simplified_refactor ChTheo:head-fixer ChTheo:stupid ChTheo:normaliser ChTheo:master ChTheo:refactor

22 Commits
complex-ad ... 1e05b1f3fd

Author SHA1 Message Date
awe
1e05b1f3fd 3 freq diversion 2026-03-02 15:43:41 +03:00
awe
8cc21316e7 try normalization after grad 2026-03-02 13:25:12 +03:00
awe
c199ab7f28 last implement diff 2026-02-27 17:43:32 +03:00
awe
33e1976233 remove half junk from spectre 2026-02-26 16:57:07 +03:00
awe
00323af0f0 arccos to apply 2026-02-26 14:00:56 +03:00
awe
f1652d072e done 2026-02-25 20:20:40 +03:00
awe
267ddedb19 fix binary format 2026-02-25 18:33:50 +03:00
Theodor Chikin
d56e439bf2 WIP on normaliser: 2e6ad24 ad to gitignore 2026-02-20 20:32:02 +03:00
Theodor Chikin
33bde7be5a index on normaliser: 2e6ad24 ad to gitignore 2026-02-20 20:32:02 +03:00
awe
2e6ad24aaa ad to gitignore 2026-02-19 18:34:59 +03:00
Theodor Chikin
02fa3645d7 Now software can be run by: run_dataplotter /dev/ttyACM0 2026-02-18 23:07:17 +03:00
Theodor Chikin
ece30f1cd5 impoved tty parser binary mode: now it supports 32-bit values of intensity 2026-02-18 23:01:34 +03:00
Theodor Chikin
8b1d424cbe New tty parser: accepts binary format. Enable arg: --bin 2026-02-17 18:51:12 +03:00
awe
34d151aef1 fix bug 2026-02-13 17:49:43 +03:00
awe
0ecb83751f add background remove 2026-02-13 17:45:14 +03:00
awe
66a318fff8 add calibration file 2026-02-13 17:32:04 +03:00
awe
d2d504f5b8 fix axis 2026-02-11 19:26:00 +03:00
awe
66b9eee230 right ifft implementation 2026-02-11 18:43:43 +03:00
awe
ea57f87920 new graph style 2026-02-11 18:27:12 +03:00
awe
c3acd0c193 new project structure 2026-02-11 16:32:21 +03:00
awe
0eaa07c03a gitignore upd 2026-02-11 16:32:04 +03:00
Theodor Chikin
64c813bf02 implemented new normalisator mode: projector. It takes upper and lower evenlopes of ref signal and projects raw data from evenlopes scope to +-1000 2026-02-10 21:55:12 +03:00
46 changed files with 3830 additions and 8340 deletions
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.gitignore vendored
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.venv/
env/
__pycache__/
*.py[cod]
.pytest_cache/
.Python
my_picocom_logfile.txt
sample_data/
*pyc
__pycache__/
*.log
*.tmp
*.bak
*.swp
*.swo
acm_9
build
.venv
sample_data

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README.md
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# RFG STM32 ADC Receiver GUI
PyQtGraph-приложение для чтения свипов из последовательного порта и отображения:
- текущего свипа
- водопада по свипам
- FFT текущего свипа
- B-scan по FFT
После рефакторинга проект разделен на пакет `rfg_adc_plotter`. Старый запуск через `RFG_ADC_dataplotter.py` сохранен как совместимый wrapper.
## Структура
- `RFG_ADC_dataplotter.py` — совместимый entrypoint
- `rfg_adc_plotter/cli.py` — CLI-аргументы
- `rfg_adc_plotter/io/` — чтение порта и парсеры протоколов
- `rfg_adc_plotter/processing/` — FFT, нормировка, калибровка, поиск пиков
- `rfg_adc_plotter/state/` — runtime state и кольцевые буферы
- `rfg_adc_plotter/gui/pyqtgraph_backend.py` — GUI на PyQtGraph
- `replay_pty.py` — воспроизведение захвата через виртуальный PTY
## Зависимости
Минимально нужны:
```bash
python3 -m venv .venv
. .venv/bin/activate
pip install numpy pyqtgraph PyQt5
```
Если `pyserial` не установлен, приложение попробует открыть порт через raw TTY.
## Быстрый старт
Запуск через старый entrypoint:
```bash
.venv/bin/python RFG_ADC_dataplotter.py /dev/ttyACM0
```
Запуск напрямую через пакет:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0
```
Показать справку:
```bash
.venv/bin/python RFG_ADC_dataplotter.py --help
```
## Примеры запуска
Обычный запуск с живого порта:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --baud 115200
```
Больше истории в водопаде и ограничение FPS:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --max-sweeps 400 --max-fps 20
```
Фиксированный диапазон по оси Y:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --ylim -1000,1000
```
С включенной нормировкой `simple`:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --norm-type simple
```
Режим измерения ширины главного пика FFT:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --calibrate
```
Поиск топ-3 пиков относительно rolling median reference:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --peak_search --peak_ref_window 1.5
```
Вычитание среднего спектра по последним секундам:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --spec-mean-sec 3
```
## Протоколы ввода
ASCII-протокол по умолчанию:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0
```
Legacy binary:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --bin
```
`--bin` понимает mixed 8-байтный поток:
- `0x000A,step,ch1_i16,ch2_i16` для CH1/CH2 из `kamil_adc` (`tty:/tmp/ttyADC_data`)
- `0x00A3,step,ch1_i16,ch2_i16` и `0x00A4,step,ch1_i16,ch2_i16` для DO1 LOW/HIGH tagged fast-tty
- `0x001A,step,data_i16,0x0000` для логарифмического детектора
Для `0x000A` сырая кривая строится как `ch1^2 + ch2^2`, а FFT рассчитывается от комплексного сигнала `ch1 + i*ch2`.
Для `0x00A3/0x00A4` tagged-режим определяется автоматически: LOW/HIGH отображаются раздельно в raw/aux/phase, а waterfall/FFT/B-scan скрываются.
Для `0x001A` signed `data_i16` сначала переводится в В, затем raw отображается как `V`, а FFT рассчитывается от `exp(V)`.
Параметр `--tty-range-v` применяется к обоим типам `--bin`-данных.
Logscale binary с парой `int32`:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --logscale
```
Complex binary `16-bit x2`:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --parser_16_bit_x2
```
Тестовый парсер для экспериментального `16-bit x2` потока:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --parser_test
```
Комплексный ASCII-поток `step real imag`:
```bash
.venv/bin/python -m rfg_adc_plotter.main /dev/ttyACM0 --parser_complex_ascii
```
## Локальная проверка через replay_pty
Если есть лог-файл захвата, его можно воспроизвести как виртуальный последовательный порт.
В первом терминале:
```bash
.venv/bin/python replay_pty.py my_picocom_logfile.txt --pty /tmp/ttyVIRT0 --speed 1.0
```
Во втором терминале:
```bash
.venv/bin/python -m rfg_adc_plotter.main /tmp/ttyVIRT0
```
Максимально быстрый replay:
```bash
.venv/bin/python replay_pty.py my_picocom_logfile.txt --pty /tmp/ttyVIRT0 --speed 0
```
## Удаленный захват по SSH
В приложении SSH-источник не встроен. Для удаленной проверки нужно сначала получить поток или лог на локальную машину, а затем либо:
- запускать GUI напрямую на локальном PTY
- сохранять поток в файл и воспроизводить его через `replay_pty.py`
Пример команды для ручной диагностики удаленного устройства:
```bash
ssh 192.148.0.148 'ls -l /dev/ttyACM0'
```
Если на удаленной машине есть доступ к потоку, удобнее сохранять его в файл и уже этот файл гонять локально через `replay_pty.py`.
Для локального `tty`-потока из `kamil_adc` используйте:
```bash
.venv/bin/python -m rfg_adc_plotter.main /tmp/ttyADC_data --bin
```
## Проверка и тесты
Синтаксическая проверка:
```bash
python3 -m compileall RFG_ADC_dataplotter.py replay_pty.py rfg_adc_plotter tests
```
Запуск тестов:
```bash
.venv/bin/python -m unittest discover -s tests -v
```
## Замечания
- Поддерживается только PyQtGraph backend.
- `--backend mpl` оставлен только для совместимости CLI и завершится ошибкой.
- Каталоги `sample_data/` и локальные логи добавлены в `.gitignore` и не считаются частью обязательного tracked-состояния репозитория.

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RFG_ADC_dataplotter.py
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#!/usr/bin/env python3
"""Compatibility wrapper for the modularized ADC plotter."""
from rfg_adc_plotter.main import main
if __name__ == "__main__":
main()

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replay_pty.py
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#!/usr/bin/env python3
"""Replay a capture file through a pseudo-TTY for local GUI verification."""
"""
Эмулятор серийного порта: воспроизводит лог-файл в цикле через PTY.
from __future__ import annotations
Использование:
python3 replay_pty.py my_picocom_logfile.txt
python3 replay_pty.py my_picocom_logfile.txt --pty /tmp/ttyVIRT0
python3 replay_pty.py my_picocom_logfile.txt --speed 2.0 # в 2 раза быстрее реального
python3 replay_pty.py my_picocom_logfile.txt --speed 0 # максимально быстро
Затем в другом терминале:
python -m rfg_adc_plotter.main /tmp/ttyVIRT0
"""
import argparse
import os
@ -9,7 +18,7 @@ import sys
import time
def main() -> None:
def main():
parser = argparse.ArgumentParser(
description="Воспроизводит лог-файл через PTY как виртуальный серийный порт."
)
@ -34,18 +43,20 @@ def main() -> None:
"--baud",
type=int,
default=115200,
help="Скорость (бод) для расчета задержек (по умолчанию 115200)",
help="Скорость (бод) для расчёта задержек (по умолчанию 115200)",
)
args = parser.parse_args()
if not os.path.isfile(args.file):
sys.stderr.write(f"[error] Файл не найден: {args.file}\n")
raise SystemExit(1)
sys.exit(1)
# Открываем PTY-пару: master (мы пишем) / slave (GUI читает)
master_fd, slave_fd = os.openpty()
slave_path = os.ttyname(slave_fd)
os.close(slave_fd)
os.close(slave_fd) # GUI откроет slave сам по симлинку
# Симлинк с удобным именем
try:
os.unlink(args.pty)
except FileNotFoundError:
@ -53,25 +64,26 @@ def main() -> None:
os.symlink(slave_path, args.pty)
print(f"PTY slave : {slave_path}")
print(f"Симлинк : {args.pty} -> {slave_path}")
print(f"Запустите : python3 -m rfg_adc_plotter.main {args.pty}")
print(f"Симлинк : {args.pty} {slave_path}")
print(f"Запустите : python -m rfg_adc_plotter.main {args.pty}")
print("Ctrl+C для остановки.\n")
# Задержка на байт: 10 бит (8N1) / скорость / множитель
if args.speed > 0:
bytes_per_sec = args.baud / 10.0 * args.speed
delay_per_byte = 1.0 / bytes_per_sec
else:
delay_per_byte = 0.0
chunk_size = 4096
_CHUNK = 4096
loop = 0
try:
while True:
loop += 1
print(f"[loop {loop}] {args.file}")
with open(args.file, "rb") as handle:
with open(args.file, "rb") as f:
while True:
chunk = handle.read(chunk_size)
chunk = f.read(_CHUNK)
if not chunk:
break
os.write(master_fd, chunk)

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rfg_adc_plotter/__init__.py
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"""RFG ADC plotter package."""
__all__ = []

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rfg_adc_plotter/cli.py
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"""Command-line parser for the ADC plotter."""
from __future__ import annotations
import argparse
def build_parser() -> argparse.ArgumentParser:
parser = argparse.ArgumentParser(
description=(
"Читает свипы из виртуального COM-порта и рисует: "
"последний свип и водопад (реалтайм)."
)
)
parser.add_argument(
"port",
help="Путь к порту, например /dev/ttyACM1 или COM3 (COM10+: \\\\.\\COM10)",
)
parser.add_argument("--baud", type=int, default=115200, help="Скорость (по умолчанию 115200)")
parser.add_argument("--max-sweeps", type=int, default=200, help="Количество видимых свипов в водопаде")
parser.add_argument("--max-fps", type=float, default=30.0, help="Лимит частоты отрисовки, кадров/с")
parser.add_argument("--cmap", default="viridis", help="Цветовая карта водопада")
parser.add_argument(
"--spec-clip",
default="2,98",
help=(
"Процентильная обрезка уровней водопада спектров, %% (min,max). "
"Напр. 2,98. 'off' — отключить"
),
)
parser.add_argument(
"--spec-mean-sec",
type=float,
default=0.0,
help=(
"Вычитание среднего по каждой частоте за последние N секунд "
"в водопаде спектров (0 — отключить)"
),
)
parser.add_argument("--title", default="ADC Sweeps", help="Заголовок окна")
parser.add_argument(
"--fancy",
action="store_true",
help="Заполнять выпавшие точки средними значениями между соседними",
)
parser.add_argument(
"--ylim",
type=str,
default=None,
help="Фиксированные Y-пределы для кривой формата min,max (например -1000,1000). По умолчанию авто",
)
parser.add_argument(
"--backend",
choices=["auto", "pg", "mpl"],
default="pg",
help="Совместимый флаг. Поддерживаются только auto и pg; mpl удален.",
)
parser.add_argument(
"--opengl",
action="store_true",
help="Включить OpenGL-ускорение для PyQtGraph. По умолчанию используется CPU-отрисовка.",
)
parser.add_argument(
"--norm-type",
choices=["projector", "simple"],
default="projector",
help="Тип нормировки: projector (по огибающим в [-1,+1]) или simple (raw/calib)",
)
parser.add_argument(
"--bin",
dest="bin_mode",
action="store_true",
help=(
"8-байтный бинарный протокол: либо legacy старт "
"0xFFFF,0xFFFF,0xFFFF,(CH<<8)|0x0A и точки step,uint32(hi16,lo16),0x000A, "
"либо mixed поток 0x000A,step,ch1_i16,ch2_i16; "
"0x00A3/0x00A4,step,ch1_i16,ch2_i16 (DO1 LOW/HIGH tagged); "
"и 0x001A,step,data_i16,0x0000. "
"Для 0x000A: после парсинга int16 переводятся в В, "
"сырая кривая = ch1^2+ch2^2 (В^2), FFT вход = ch1+i*ch2 (В). "
"Для 0x00A3/0x00A4: auto-detect tagged режим с раздельным отображением LOW/HIGH в raw. "
"Для 0x001A: code_i16 переводится в В, raw = V, FFT вход = exp(V)"
),
)
parser.add_argument(
"--tty-range-v",
type=float,
default=5.0,
help=(
"Полный диапазон для пересчета tty int16 в напряжение ±V "
"(для --bin 0x000A CH1/CH2 и 0x001A log-detector, по умолчанию 5.0)"
),
)
parser.add_argument(
"--logscale",
action="store_true",
help=(
"Новый бинарный протокол: точка несет пару int32 (avg_1, avg_2), "
"а свип считается как |10**(avg_1*0.001) - 10**(avg_2*0.001)|"
),
)
parser.add_argument(
"--parser_16_bit_x2",
action="store_true",
help=(
"Бинарный complex-протокол c парой int16 (Re, Im): "
"старт 0xFFFF,0xFFFF,0xFFFF,(CH<<8)|0x0A; точка step,re_lo16,im_lo16,0xFFFF"
),
)
parser.add_argument(
"--parser_test",
action="store_true",
help=(
"Тестовый парсер для complex-формата 16-bit x2: "
"одиночный 0xFFFF завершает точку, серия 0xFFFF начинает новый свип"
),
)
parser.add_argument(
"--parser_complex_ascii",
action="store_true",
help=(
"ASCII-поток из трех чисел на строку: step real imag. "
"Новый свип определяется по сбросу/повтору step, FFT строится по комплексным данным"
),
)
parser.add_argument(
"--calibrate",
action="store_true",
help=(
"Режим измерения ширины главного пика FFT: рисует красные маркеры "
"границ и фона и выводит ширину пика в статус"
),
)
parser.add_argument(
"--peak_search",
action="store_true",
help=(
"Поиск топ-3 пиков на FFT относительно референса (скользящая медиана) "
"с отрисовкой bounding box и параметров пиков"
),
)
parser.add_argument(
"--peak_ref_window",
type=float,
default=1.0,
help="Ширина окна скользящей медианы для --peak_search, ГГц/м по оси FFT (по умолчанию 1.0)",
)
return parser

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rfg_adc_plotter/constants.py
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@ -1,17 +1,21 @@
"""Shared constants for sweep parsing and visualization."""
WF_WIDTH = 1000
FFT_LEN = 2048
BACKGROUND_MEDIAN_SWEEPS = 64
SWEEP_FREQ_MIN_GHZ = 3.3
SWEEP_FREQ_MAX_GHZ = 6.3
LOG_BASE = 10.0
LOG_SCALER = 0.001
LOG_POSTSCALER = 10.0
LOG_EXP_LIMIT = 300.0
C_M_S = 299_792_458.0
WF_WIDTH = 1000 # максимальное число точек в ряду водопада
FFT_LEN = 4096 # длина БПФ для спектра/водопада спектров
LOG_EXP = 2.0 # основание экспоненты для опции --logscale
# Порог для инверсии сырых данных: если среднее значение свипа ниже порога —
# считаем, что сигнал «меньше нуля» и домножаем свип на -1
DATA_INVERSION_THRESHOLD = 10.0
# Частотная сетка рабочего свипа (положительная часть), ГГц
FREQ_MIN_GHZ = 3.323
FREQ_MAX_GHZ = 14.323
# Скорость света для перевода времени пролёта в one-way depth
SPEED_OF_LIGHT_M_S = 299_792_458.0
# Параметры IFFT-спектра (временной профиль из спектра 3.2..14.3 ГГц)
# Двусторонний спектр формируется как: [нули -14.3..-3.2 | нули -3.2..+3.2 | данные +3.2..+14.3]
ZEROS_LOW = 758 # нули от -14.3 до -3.2 ГГц
ZEROS_MID = 437 # нули от -3.2 до +3.2 ГГц
SWEEP_LEN = 758 # ожидаемая длина свипа (3.2 → 14.3 ГГц)
FREQ_SPAN_GHZ = 28.6 # полная двусторонняя полоса (-14.3 .. +14.3 ГГц)
IFFT_LEN = ZEROS_LOW + ZEROS_MID + SWEEP_LEN # = 1953

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rfg_adc_plotter/gui/__init__.py
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"""GUI backends."""
from rfg_adc_plotter.gui.pyqtgraph_backend import run_pyqtgraph
__all__ = ["run_pyqtgraph"]

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rfg_adc_plotter/gui/matplotlib_backend.py Normal file
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@ -0,0 +1,680 @@
"""Matplotlib-бэкенд реалтайм-плоттера свипов."""
import sys
import threading
from queue import Queue
from typing import Optional, Tuple
import numpy as np
from rfg_adc_plotter.constants import FFT_LEN, FREQ_MAX_GHZ, FREQ_MIN_GHZ, IFFT_LEN
from rfg_adc_plotter.io.sweep_reader import SweepReader
from rfg_adc_plotter.processing.normalizer import build_calib_envelopes
from rfg_adc_plotter.state.app_state import AppState, format_status
from rfg_adc_plotter.state.ring_buffer import RingBuffer
from rfg_adc_plotter.types import SweepPacket
def _parse_ylim(ylim_str: Optional[str]) -> Optional[Tuple[float, float]]:
if not ylim_str:
return None
try:
y0, y1 = ylim_str.split(",")
return (float(y0), float(y1))
except Exception:
sys.stderr.write("[warn] Некорректный формат --ylim, игнорирую. Ожидалось min,max\n")
return None
def _parse_spec_clip(spec: Optional[str]) -> Optional[Tuple[float, float]]:
if not spec:
return None
s = str(spec).strip().lower()
if s in ("off", "none", "no"):
return None
try:
p0, p1 = s.replace(";", ",").split(",")
low, high = float(p0), float(p1)
if not (0.0 <= low < high <= 100.0):
return None
return (low, high)
except Exception:
return None
def _visible_levels(data: np.ndarray, axis) -> Optional[Tuple[float, float]]:
"""(vmin, vmax) по текущей видимой области imshow."""
if data.size == 0:
return None
ny, nx = data.shape[0], data.shape[1]
try:
x0, x1 = axis.get_xlim()
y0, y1 = axis.get_ylim()
except Exception:
x0, x1 = 0.0, float(nx - 1)
y0, y1 = 0.0, float(ny - 1)
xmin, xmax = sorted((float(x0), float(x1)))
ymin, ymax = sorted((float(y0), float(y1)))
ix0 = max(0, min(nx - 1, int(np.floor(xmin))))
ix1 = max(0, min(nx - 1, int(np.ceil(xmax))))
iy0 = max(0, min(ny - 1, int(np.floor(ymin))))
iy1 = max(0, min(ny - 1, int(np.ceil(ymax))))
if ix1 < ix0:
ix1 = ix0
if iy1 < iy0:
iy1 = iy0
sub = data[iy0 : iy1 + 1, ix0 : ix1 + 1]
finite = np.isfinite(sub)
if not finite.any():
return None
vals = sub[finite]
vmin = float(np.min(vals))
vmax = float(np.max(vals))
if not (np.isfinite(vmin) and np.isfinite(vmax)) or vmin == vmax:
return None
return (vmin, vmax)
def run_matplotlib(args):
try:
import matplotlib
import matplotlib.pyplot as plt
from matplotlib.animation import FuncAnimation
from matplotlib.widgets import Button as MplButton
from matplotlib.widgets import CheckButtons, RadioButtons, Slider, TextBox
except Exception as e:
sys.stderr.write(f"[error] Нужны matplotlib и её зависимости: {e}\n")
sys.exit(1)
q: Queue[SweepPacket] = Queue(maxsize=1000)
stop_event = threading.Event()
reader = SweepReader(
args.port,
args.baud,
q,
stop_event,
fancy=bool(args.fancy),
bin_mode=bool(getattr(args, "bin_mode", False)),
logscale=bool(getattr(args, "logscale", False)),
debug=bool(getattr(args, "debug", False)),
)
reader.start()
max_sweeps = int(max(10, args.max_sweeps))
max_fps = max(1.0, float(args.max_fps))
interval_ms = int(1000.0 / max_fps)
spec_clip = _parse_spec_clip(getattr(args, "spec_clip", None))
spec_mean_sec = float(getattr(args, "spec_mean_sec", 0.0))
fixed_ylim = _parse_ylim(getattr(args, "ylim", None))
norm_type = str(getattr(args, "norm_type", "projector")).strip().lower()
logscale_enabled = bool(getattr(args, "logscale", False))
state = AppState(norm_type=norm_type)
state.configure_capture_import(fancy=bool(args.fancy), logscale=bool(getattr(args, "logscale", False)))
ring = RingBuffer(max_sweeps)
try:
ring.set_fft_complex_mode(str(getattr(args, "ifft_complex_mode", "arccos")))
except Exception:
pass
# --- Создание фигуры ---
fig, axs = plt.subplots(2, 2, figsize=(12, 8))
(ax_line, ax_img), (ax_fft, ax_spec) = axs
if hasattr(fig.canvas.manager, "set_window_title"):
fig.canvas.manager.set_window_title(args.title)
fig.subplots_adjust(wspace=0.25, hspace=0.35, left=0.07, right=0.90, top=0.92, bottom=0.22)
# Статусная строка
status_text = fig.text(0.01, 0.01, "", ha="left", va="bottom", fontsize=8, family="monospace")
pipeline_text = fig.text(0.01, 0.03, "", ha="left", va="bottom", fontsize=8, family="monospace")
ref_text = fig.text(0.01, 0.05, "", ha="left", va="bottom", fontsize=8, family="monospace")
# График последнего свипа
line_obj, = ax_line.plot([], [], lw=1, color="tab:blue")
line_norm_obj, = ax_line.plot([], [], lw=1, color="tab:green")
line_pre_exp_obj, = ax_line.plot([], [], lw=1, color="tab:red")
line_post_exp_obj, = ax_line.plot([], [], lw=1, color="tab:green")
line_env_lo, = ax_line.plot([], [], lw=1, color="tab:orange", linestyle="--", alpha=0.7)
line_env_hi, = ax_line.plot([], [], lw=1, color="tab:orange", linestyle="--", alpha=0.7)
ax_line.set_title("Сырые данные", pad=1)
ax_line.set_xlabel("Частота, ГГц")
channel_text = ax_line.text(
0.98, 0.98, "", transform=ax_line.transAxes,
ha="right", va="top", fontsize=9, family="monospace",
)
if fixed_ylim is not None:
ax_line.set_ylim(fixed_ylim)
# График спектра
fft_line_t1, = ax_fft.plot([], [], lw=1, color="tab:blue", label="1/3 (low f)")
fft_line_t2, = ax_fft.plot([], [], lw=1, color="tab:orange", label="2/3 (mid f)")
fft_line_t3, = ax_fft.plot([], [], lw=1, color="tab:green", label="3/3 (high f)")
ax_fft.set_title("FFT", pad=1)
ax_fft.set_xlabel("Глубина, м")
ax_fft.set_ylabel("Амплитуда")
ax_fft.legend(loc="upper right", fontsize=8)
# Водопад сырых данных
img_obj = ax_img.imshow(
np.zeros((1, 1), dtype=np.float32),
aspect="auto", interpolation="nearest", origin="lower", cmap=args.cmap,
)
ax_img.set_title("Сырые данные", pad=12)
ax_img.set_ylabel("частота")
try:
ax_img.tick_params(axis="x", labelbottom=False)
except Exception:
pass
# Водопад спектров
img_fft_obj = ax_spec.imshow(
np.zeros((1, 1), dtype=np.float32),
aspect="auto", interpolation="nearest", origin="lower", cmap=args.cmap,
)
ax_spec.set_title("B-scan", pad=12)
ax_spec.set_ylabel("Глубина, м")
try:
ax_spec.tick_params(axis="x", labelbottom=False)
except Exception:
pass
# Слайдеры и чекбокс
contrast_slider = None
try:
fft_bins = ring.fft_bins if ring.fft_bins > 0 else IFFT_LEN
ax_smin = fig.add_axes([0.92, 0.55, 0.02, 0.35])
ax_smax = fig.add_axes([0.95, 0.55, 0.02, 0.35])
ax_sctr = fig.add_axes([0.98, 0.55, 0.02, 0.35])
ax_cb = fig.add_axes([0.92, 0.45, 0.08, 0.08])
ax_cb_file = fig.add_axes([0.92, 0.36, 0.08, 0.08])
ax_line_mode = fig.add_axes([0.92, 0.10, 0.08, 0.08])
ax_ifft_mode = fig.add_axes([0.92, 0.01, 0.08, 0.08])
ymin_slider = Slider(ax_smin, "Y min", 0, max(1, fft_bins - 1), valinit=0, valstep=1, orientation="vertical")
ymax_slider = Slider(ax_smax, "Y max", 0, max(1, fft_bins - 1), valinit=max(1, fft_bins - 1), valstep=1, orientation="vertical")
contrast_slider = Slider(ax_sctr, "Int max", 0, 100, valinit=100, valstep=1, orientation="vertical")
calib_cb = CheckButtons(ax_cb, ["калибровка"], [False])
calib_file_cb = CheckButtons(ax_cb_file, ["из файла"], [False])
line_mode_rb = RadioButtons(ax_line_mode, ("raw", "processed"), active=0)
ifft_mode_rb = RadioButtons(
ax_ifft_mode,
("arccos", "diff"),
active=(1 if ring.fft_complex_mode == "diff" else 0),
)
try:
ax_line_mode.set_title("Линия", fontsize=8, pad=2)
except Exception:
pass
try:
ax_ifft_mode.set_title("IFFT", fontsize=8, pad=2)
except Exception:
pass
line_mode_state = {"value": "raw"}
ifft_mode_state = {"value": str(ring.fft_complex_mode)}
import os as _os
try:
import tkinter as _tk
from tkinter import filedialog as _tk_filedialog
_tk_available = True
except Exception:
_tk = None
_tk_filedialog = None
_tk_available = False
# Нижняя панель путей и кнопок (работает без Qt; выбор файла через tkinter опционален).
ax_calib_path = fig.add_axes([0.07, 0.14, 0.40, 0.04])
ax_calib_load = fig.add_axes([0.48, 0.14, 0.07, 0.04])
ax_calib_pick = fig.add_axes([0.56, 0.14, 0.06, 0.04])
ax_calib_sample = fig.add_axes([0.63, 0.14, 0.09, 0.04])
ax_calib_save = fig.add_axes([0.73, 0.14, 0.10, 0.04])
ax_bg_path = fig.add_axes([0.07, 0.09, 0.40, 0.04])
ax_bg_load = fig.add_axes([0.48, 0.09, 0.07, 0.04])
ax_bg_pick = fig.add_axes([0.56, 0.09, 0.06, 0.04])
ax_bg_sample = fig.add_axes([0.63, 0.09, 0.09, 0.04])
ax_bg_save2 = fig.add_axes([0.73, 0.09, 0.10, 0.04])
calib_path_box = TextBox(ax_calib_path, "Калибр", initial=state.calib_envelope_path)
bg_path_box = TextBox(ax_bg_path, "Фон", initial=state.background_path)
calib_load_btn2 = MplButton(ax_calib_load, "Загруз.")
calib_pick_btn2 = MplButton(ax_calib_pick, "Файл")
calib_sample_btn2 = MplButton(ax_calib_sample, "sample")
calib_save_btn2 = MplButton(ax_calib_save, "Сохр env")
bg_load_btn2 = MplButton(ax_bg_load, "Загруз.")
bg_pick_btn2 = MplButton(ax_bg_pick, "Файл")
bg_sample_btn2 = MplButton(ax_bg_sample, "sample")
bg_save_btn2 = MplButton(ax_bg_save2, "Сохр фон")
if not _tk_available:
try:
calib_pick_btn2.label.set_text("Файл-")
bg_pick_btn2.label.set_text("Файл-")
except Exception:
pass
def _tb_text(tb):
try:
return str(tb.text).strip()
except Exception:
return ""
def _pick_file_dialog(initial_path: str) -> str:
if not _tk_available or _tk is None or _tk_filedialog is None:
return ""
root = None
try:
root = _tk.Tk()
root.withdraw()
root.attributes("-topmost", True)
except Exception:
root = None
try:
return str(
_tk_filedialog.askopenfilename(
initialdir=_os.path.dirname(initial_path) or ".",
initialfile=_os.path.basename(initial_path) or "",
title="Выбрать файл эталона (.npy или capture)",
)
)
finally:
try:
if root is not None:
root.destroy()
except Exception:
pass
def _sync_path_boxes():
try:
if _tb_text(calib_path_box) != state.calib_envelope_path:
calib_path_box.set_val(state.calib_envelope_path)
except Exception:
pass
try:
if _tb_text(bg_path_box) != state.background_path:
bg_path_box.set_val(state.background_path)
except Exception:
pass
def _refresh_status_texts():
pipeline_text.set_text(f"{state.format_pipeline_status()} | cplx:{ring.fft_complex_mode}")
ref_text.set_text(state.format_reference_status())
try:
fig.canvas.draw_idle()
except Exception:
pass
def _line_mode() -> str:
return str(line_mode_state.get("value", "raw"))
def _refresh_checkboxes():
try:
# file-mode чекбокс показываем всегда; он активен при наличии пути/данных.
ax_cb_file.set_visible(True)
except Exception:
pass
def _load_calib_from_ui():
p = _tb_text(calib_path_box)
if p:
state.set_calib_envelope_path(p)
ok = state.load_calib_reference()
if ok and bool(calib_file_cb.get_status()[0]):
state.set_calib_mode("file")
state.set_calib_enabled(bool(calib_cb.get_status()[0]))
_sync_path_boxes()
_refresh_checkboxes()
_refresh_status_texts()
return ok
def _load_bg_from_ui():
p = _tb_text(bg_path_box)
if p:
state.set_background_path(p)
ok = state.load_background_reference()
_sync_path_boxes()
_refresh_status_texts()
return ok
def _on_ylim_change(_val):
try:
y0 = int(min(ymin_slider.val, ymax_slider.val))
y1 = int(max(ymin_slider.val, ymax_slider.val))
ax_spec.set_ylim(y0, y1)
fig.canvas.draw_idle()
except Exception:
pass
def _on_calib_file_clicked(_v):
use_file = bool(calib_file_cb.get_status()[0])
if use_file:
ok = _load_calib_from_ui()
if ok:
state.set_calib_mode("file")
else:
calib_file_cb.set_active(0) # снять галочку
else:
state.set_calib_mode("live")
state.set_calib_enabled(bool(calib_cb.get_status()[0]))
_refresh_status_texts()
def _on_calib_clicked(_v):
state.set_calib_enabled(bool(calib_cb.get_status()[0]))
_refresh_checkboxes()
_refresh_status_texts()
ax_btn_bg = fig.add_axes([0.92, 0.27, 0.08, 0.05])
ax_cb_bg = fig.add_axes([0.92, 0.20, 0.08, 0.06])
save_bg_btn = MplButton(ax_btn_bg, "Сохр. фон")
bg_cb = CheckButtons(ax_cb_bg, ["вычет фона"], [False])
def _on_save_bg(_event):
ok = state.save_background()
if ok:
state.load_background()
_sync_path_boxes()
_refresh_status_texts()
def _on_bg_clicked(_v):
state.set_background_enabled(bool(bg_cb.get_status()[0]))
_refresh_status_texts()
def _on_calib_load_btn(_event):
_load_calib_from_ui()
def _on_calib_pick_btn(_event):
path = _pick_file_dialog(_tb_text(calib_path_box) or state.calib_envelope_path)
if not path:
return
state.set_calib_envelope_path(path)
_sync_path_boxes()
_refresh_status_texts()
def _on_calib_sample_btn(_event):
state.set_calib_envelope_path(_os.path.join("sample_data", "no_antennas_35dB_attenuators"))
_sync_path_boxes()
if _load_calib_from_ui() and not bool(calib_file_cb.get_status()[0]):
calib_file_cb.set_active(0)
def _on_calib_save_btn(_event):
state.save_calib_envelope()
_sync_path_boxes()
_refresh_status_texts()
def _on_bg_load_btn(_event):
_load_bg_from_ui()
def _on_bg_pick_btn(_event):
path = _pick_file_dialog(_tb_text(bg_path_box) or state.background_path)
if not path:
return
state.set_background_path(path)
_sync_path_boxes()
_refresh_status_texts()
def _on_bg_sample_btn(_event):
state.set_background_path(_os.path.join("sample_data", "empty"))
_sync_path_boxes()
_load_bg_from_ui()
def _on_bg_save_btn2(_event):
ok = state.save_background()
if ok:
state.load_background()
_sync_path_boxes()
_refresh_status_texts()
def _on_line_mode_clicked(label):
line_mode_state["value"] = str(label)
try:
fig.canvas.draw_idle()
except Exception:
pass
def _on_ifft_mode_clicked(label):
ifft_mode_state["value"] = str(label)
try:
ring.set_fft_complex_mode(str(label))
except Exception:
pass
fft_line_t1.set_data([], [])
fft_line_t2.set_data([], [])
fft_line_t3.set_data([], [])
_refresh_status_texts()
try:
fig.canvas.draw_idle()
except Exception:
pass
save_bg_btn.on_clicked(_on_save_bg)
bg_cb.on_clicked(_on_bg_clicked)
calib_load_btn2.on_clicked(_on_calib_load_btn)
calib_pick_btn2.on_clicked(_on_calib_pick_btn)
calib_sample_btn2.on_clicked(_on_calib_sample_btn)
calib_save_btn2.on_clicked(_on_calib_save_btn)
bg_load_btn2.on_clicked(_on_bg_load_btn)
bg_pick_btn2.on_clicked(_on_bg_pick_btn)
bg_sample_btn2.on_clicked(_on_bg_sample_btn)
bg_save_btn2.on_clicked(_on_bg_save_btn2)
line_mode_rb.on_clicked(_on_line_mode_clicked)
ifft_mode_rb.on_clicked(_on_ifft_mode_clicked)
ymin_slider.on_changed(_on_ylim_change)
ymax_slider.on_changed(_on_ylim_change)
contrast_slider.on_changed(lambda _v: fig.canvas.draw_idle())
calib_cb.on_clicked(_on_calib_clicked)
calib_file_cb.on_clicked(_on_calib_file_clicked)
_sync_path_boxes()
_refresh_checkboxes()
_refresh_status_texts()
except Exception:
calib_cb = None
line_mode_state = {"value": "raw"}
ifft_mode_state = {"value": str(getattr(ring, "fft_complex_mode", "arccos"))}
FREQ_MIN = float(FREQ_MIN_GHZ)
FREQ_MAX = float(FREQ_MAX_GHZ)
def _fft_depth_max() -> float:
axis = ring.fft_depth_axis_m
if axis is None or axis.size == 0:
return 1.0
try:
vmax = float(axis[-1])
except Exception:
vmax = float(np.nanmax(axis))
if not np.isfinite(vmax) or vmax <= 0.0:
return 1.0
return vmax
# --- Инициализация imshow при первом свипе ---
def _init_imshow_extents():
w = ring.width
ms = ring.max_sweeps
fb = max(1, int(ring.fft_bins))
depth_max = _fft_depth_max()
img_obj.set_data(np.zeros((w, ms), dtype=np.float32))
img_obj.set_extent((0, ms - 1, FREQ_MIN, FREQ_MAX))
ax_img.set_xlim(0, ms - 1)
ax_img.set_ylim(FREQ_MIN, FREQ_MAX)
img_fft_obj.set_data(np.zeros((fb, ms), dtype=np.float32))
img_fft_obj.set_extent((0, ms - 1, 0.0, depth_max))
ax_spec.set_xlim(0, ms - 1)
ax_spec.set_ylim(0.0, depth_max)
ax_fft.set_xlim(0.0, depth_max)
_imshow_initialized = [False]
def update(_frame):
changed = state.drain_queue(q, ring) > 0
if changed and not _imshow_initialized[0] and ring.is_ready:
_init_imshow_extents()
_imshow_initialized[0] = True
# Линейный график свипа
if state.current_sweep_raw is not None:
raw = state.current_sweep_raw
if ring.x_shared is not None and raw.size <= ring.x_shared.size:
xs = ring.x_shared[: raw.size]
else:
xs = np.arange(raw.size, dtype=np.int32)
line_mode = str(line_mode_state.get("value", "raw"))
main = state.current_sweep_processed if line_mode == "processed" else raw
if main is not None:
line_obj.set_data(xs[: main.size], main)
else:
line_obj.set_data([], [])
if line_mode == "raw":
if state.calib_mode == "file" and state.calib_file_envelope is not None:
upper = np.asarray(state.calib_file_envelope, dtype=np.float32)
n_env = min(xs.size, upper.size)
if n_env > 0:
x_env = xs[:n_env]
y_env = upper[:n_env]
line_env_lo.set_data(x_env, -y_env)
line_env_hi.set_data(x_env, y_env)
else:
line_env_lo.set_data([], [])
line_env_hi.set_data([], [])
elif state.last_calib_sweep is not None:
calib = np.asarray(state.last_calib_sweep, dtype=np.float32)
lower, upper = build_calib_envelopes(calib)
n_env = min(xs.size, lower.size, upper.size)
if n_env > 0:
line_env_lo.set_data(xs[:n_env], lower[:n_env])
line_env_hi.set_data(xs[:n_env], upper[:n_env])
else:
line_env_lo.set_data([], [])
line_env_hi.set_data([], [])
else:
line_env_lo.set_data([], [])
line_env_hi.set_data([], [])
else:
line_env_lo.set_data([], [])
line_env_hi.set_data([], [])
if logscale_enabled:
if state.current_sweep_pre_exp is not None:
pre = state.current_sweep_pre_exp
line_pre_exp_obj.set_data(xs[: pre.size], pre)
else:
line_pre_exp_obj.set_data([], [])
post = state.current_sweep_post_exp if state.current_sweep_post_exp is not None else raw
line_post_exp_obj.set_data(xs[: post.size], post)
if line_mode == "processed":
if state.current_sweep_processed is not None:
proc = state.current_sweep_processed
line_obj.set_data(xs[: proc.size], proc)
else:
line_obj.set_data([], [])
else:
line_obj.set_data(xs[: raw.size], raw)
line_norm_obj.set_data([], [])
else:
line_pre_exp_obj.set_data([], [])
line_post_exp_obj.set_data([], [])
if line_mode == "raw" and state.current_sweep_norm is not None:
line_norm_obj.set_data(
xs[: state.current_sweep_norm.size], state.current_sweep_norm
)
else:
line_norm_obj.set_data([], [])
ax_line.set_xlim(FREQ_MIN, FREQ_MAX)
if fixed_ylim is not None:
ax_line.set_ylim(fixed_ylim)
else:
ax_line.relim()
ax_line.autoscale_view(scalex=False, scaley=True)
ax_line.set_ylabel("Y")
# Профиль по глубине: три линии для 1/3, 2/3, 3/3 частотного диапазона.
third_axes = ring.last_fft_third_axes_m
third_vals = ring.last_fft_third_vals
lines = (fft_line_t1, fft_line_t2, fft_line_t3)
xs_max = []
ys_min = []
ys_max = []
for line_fft, xs_fft, fft_vals in zip(lines, third_axes, third_vals):
if xs_fft is None or fft_vals is None:
line_fft.set_data([], [])
continue
n = min(int(xs_fft.size), int(fft_vals.size))
if n <= 0:
line_fft.set_data([], [])
continue
x_seg = xs_fft[:n]
y_seg = fft_vals[:n]
line_fft.set_data(x_seg, y_seg)
xs_max.append(float(x_seg[n - 1]))
ys_min.append(float(np.nanmin(y_seg)))
ys_max.append(float(np.nanmax(y_seg)))
if xs_max and ys_min and ys_max:
ax_fft.set_xlim(0, float(max(xs_max)))
ax_fft.set_ylim(float(min(ys_min)), float(max(ys_max)))
# Водопад сырых данных
if changed and ring.is_ready:
disp = ring.get_display_ring()
if ring.x_shared is not None:
n = ring.x_shared.size
disp = disp[:n, :]
img_obj.set_data(disp)
img_obj.set_extent((0, ring.max_sweeps - 1, FREQ_MIN, FREQ_MAX))
ax_img.set_ylim(FREQ_MIN, FREQ_MAX)
levels = _visible_levels(disp, ax_img)
if levels is not None:
img_obj.set_clim(vmin=levels[0], vmax=levels[1])
# Водопад спектров
if changed and ring.is_ready:
disp_fft = ring.get_display_ring_fft()
disp_fft = ring.subtract_recent_mean_fft(disp_fft, spec_mean_sec)
img_fft_obj.set_data(disp_fft)
depth_max = _fft_depth_max()
img_fft_obj.set_extent((0, ring.max_sweeps - 1, 0.0, depth_max))
ax_spec.set_ylim(0.0, depth_max)
levels = ring.compute_fft_levels(disp_fft, spec_clip)
if levels is not None:
try:
c = float(contrast_slider.val) / 100.0 if contrast_slider is not None else 1.0
except Exception:
c = 1.0
vmax_eff = levels[0] + c * (levels[1] - levels[0])
img_fft_obj.set_clim(vmin=levels[0], vmax=vmax_eff)
# Статус и подпись канала
if changed and state.current_info:
status_text.set_text(format_status(state.current_info))
channel_text.set_text(state.format_channel_label())
pipeline_text.set_text(f"{state.format_pipeline_status()} | cplx:{ring.fft_complex_mode}")
ref_text.set_text(state.format_reference_status())
elif changed:
pipeline_text.set_text(f"{state.format_pipeline_status()} | cplx:{ring.fft_complex_mode}")
ref_text.set_text(state.format_reference_status())
return (
line_obj,
line_norm_obj,
line_pre_exp_obj,
line_post_exp_obj,
line_env_lo,
line_env_hi,
img_obj,
fft_line_t1,
fft_line_t2,
fft_line_t3,
img_fft_obj,
status_text,
pipeline_text,
ref_text,
channel_text,
)
ani = FuncAnimation(fig, update, interval=interval_ms, blit=False)
plt.show()
stop_event.set()
reader.join(timeout=1.0)

3702
rfg_adc_plotter/gui/pyqtgraph_backend.py
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File diff suppressed because it is too large Load Diff

6
rfg_adc_plotter/io/__init__.py
View File

@ -1,6 +0,0 @@
"""I/O helpers for serial sources and sweep parsing."""
from rfg_adc_plotter.io.serial_source import SerialChunkReader, SerialLineSource
from rfg_adc_plotter.io.sweep_reader import SweepReader
__all__ = ["SerialChunkReader", "SerialLineSource", "SweepReader"]

227
rfg_adc_plotter/io/capture_reference_loader.py Normal file
View File

@ -0,0 +1,227 @@
"""Загрузка эталонов (калибровка/фон) из .npy или бинарных capture-файлов."""
from __future__ import annotations
from collections import Counter
from dataclasses import dataclass
import os
from typing import Iterable, List, Optional, Tuple
import numpy as np
from rfg_adc_plotter.io.sweep_parser_core import BinaryRecordStreamParser, SweepAssembler
from rfg_adc_plotter.types import SweepPacket
@dataclass(frozen=True)
class CaptureParseSummary:
path: str
format: str # "npy" | "bin_capture"
sweeps_total: int
sweeps_valid: int
channels_seen: Tuple[int, ...]
dominant_width: Optional[int]
dominant_n_valid: Optional[int]
aggregation: str
warnings: Tuple[str, ...]
@dataclass(frozen=True)
class ReferenceLoadResult:
vector: np.ndarray
summary: CaptureParseSummary
kind: str # "calibration_envelope" | "background_raw" | "background_processed"
source_type: str # "npy" | "capture"
def detect_reference_file_format(path: str) -> Optional[str]:
"""Определить формат файла эталона: .npy или бинарный capture."""
p = str(path).strip()
if not p or not os.path.isfile(p):
return None
if p.lower().endswith(".npy"):
return "npy"
try:
size = os.path.getsize(p)
except Exception:
return None
if size <= 0 or (size % 8) != 0:
return None
try:
with open(p, "rb") as f:
sample = f.read(min(size, 8 * 2048))
except Exception:
return None
if len(sample) < 8:
return None
# Быстрый sniff aligned-записей: в валидных записях байт 6 == 0x0A.
recs = len(sample) // 8
if recs <= 0:
return None
marker_hits = 0
start_hits = 0
for i in range(0, recs * 8, 8):
b = sample[i : i + 8]
if b[6] == 0x0A:
marker_hits += 1
if b[:6] == b"\xff\xff\xff\xff\xff\xff":
start_hits += 1
if marker_hits >= max(4, int(recs * 0.8)) and start_hits >= 1:
return "bin_capture"
return None
def load_capture_sweeps(path: str, *, fancy: bool = False, logscale: bool = False) -> List[SweepPacket]:
"""Загрузить свипы из бинарного capture-файла в формате --bin."""
parser = BinaryRecordStreamParser()
assembler = SweepAssembler(fancy=fancy, logscale=logscale, debug=False)
sweeps: List[SweepPacket] = []
with open(path, "rb") as f:
while True:
chunk = f.read(65536)
if not chunk:
break
events = parser.feed(chunk)
for ev in events:
packets = assembler.consume_binary_event(ev)
if packets:
sweeps.extend(packets)
tail = assembler.finalize_current()
if tail is not None:
sweeps.append(tail)
return sweeps
def _mode_int(values: Iterable[int]) -> Optional[int]:
vals = [int(v) for v in values]
if not vals:
return None
ctr = Counter(vals)
return int(max(ctr.items(), key=lambda kv: (kv[1], kv[0]))[0])
def aggregate_capture_reference(
sweeps: List[SweepPacket],
*,
channel: int = 0,
method: str = "median",
path: str = "",
) -> Tuple[np.ndarray, CaptureParseSummary]:
"""Отфильтровать и агрегировать свипы из capture в один эталонный вектор."""
ch_target = int(channel)
meth = str(method).strip().lower() or "median"
warnings: list[str] = []
if meth != "median":
warnings.append(f"aggregation '{meth}' не поддерживается, использую median")
meth = "median"
channels_seen: set[int] = set()
candidate_rows: list[np.ndarray] = []
widths: list[int] = []
n_valids: list[int] = []
for sweep, info in sweeps:
chs = info.get("chs") if isinstance(info, dict) else None
ch_set: set[int] = set()
if isinstance(chs, (list, tuple, set)):
for v in chs:
try:
ch_set.add(int(v))
except Exception:
pass
else:
try:
ch_set.add(int(info.get("ch", 0))) # type: ignore[union-attr]
except Exception:
pass
channels_seen.update(ch_set)
if ch_target not in ch_set:
continue
row = np.asarray(sweep, dtype=np.float32).reshape(-1)
candidate_rows.append(row)
widths.append(int(row.size))
n_valids.append(int(np.count_nonzero(np.isfinite(row))))
sweeps_total = len(sweeps)
if not candidate_rows:
summary = CaptureParseSummary(
path=path,
format="bin_capture",
sweeps_total=sweeps_total,
sweeps_valid=0,
channels_seen=tuple(sorted(channels_seen)),
dominant_width=None,
dominant_n_valid=None,
aggregation=meth,
warnings=tuple(warnings + [f"канал ch{ch_target} не найден"]),
)
raise ValueError(summary.warnings[-1])
dominant_width = _mode_int(widths)
dominant_n_valid = _mode_int(n_valids)
if dominant_width is None or dominant_n_valid is None:
summary = CaptureParseSummary(
path=path,
format="bin_capture",
sweeps_total=sweeps_total,
sweeps_valid=0,
channels_seen=tuple(sorted(channels_seen)),
dominant_width=dominant_width,
dominant_n_valid=dominant_n_valid,
aggregation=meth,
warnings=tuple(warnings + ["не удалось определить доминирующие параметры свипа"]),
)
raise ValueError(summary.warnings[-1])
valid_rows: list[np.ndarray] = []
n_valid_threshold = max(1, int(np.floor(0.95 * dominant_n_valid)))
for row in candidate_rows:
if row.size != dominant_width:
continue
n_valid = int(np.count_nonzero(np.isfinite(row)))
if n_valid < n_valid_threshold:
continue
valid_rows.append(row)
if not valid_rows:
warnings.append("после фильтрации не осталось валидных свипов")
summary = CaptureParseSummary(
path=path,
format="bin_capture",
sweeps_total=sweeps_total,
sweeps_valid=0,
channels_seen=tuple(sorted(channels_seen)),
dominant_width=dominant_width,
dominant_n_valid=dominant_n_valid,
aggregation=meth,
warnings=tuple(warnings),
)
raise ValueError(summary.warnings[-1])
# Детерминированная агрегация: медиана по валидным свипам.
stack = np.stack(valid_rows, axis=0).astype(np.float32, copy=False)
vector = np.nanmedian(stack, axis=0).astype(np.float32, copy=False)
if len(valid_rows) < len(candidate_rows):
warnings.append(f"отфильтровано {len(candidate_rows) - len(valid_rows)} неполных/нестандартных свипов")
summary = CaptureParseSummary(
path=path,
format="bin_capture",
sweeps_total=sweeps_total,
sweeps_valid=len(valid_rows),
channels_seen=tuple(sorted(channels_seen)),
dominant_width=dominant_width,
dominant_n_valid=dominant_n_valid,
aggregation=meth,
warnings=tuple(warnings),
)
return vector, summary

54
rfg_adc_plotter/io/serial_source.py
View File

@ -1,6 +1,4 @@
"""Serial input helpers with pyserial and raw TTY fallbacks."""
from __future__ import annotations
"""Источники последовательного ввода: обёртки над pyserial и raw TTY."""
import io
import os
@ -14,13 +12,14 @@ def try_open_pyserial(path: str, baud: int, timeout: float):
except Exception:
return None
try:
return serial.Serial(path, baudrate=baud, timeout=timeout)
ser = serial.Serial(path, baudrate=baud, timeout=timeout)
return ser
except Exception:
return None
class FDReader:
"""Buffered wrapper around a raw TTY file descriptor."""
"""Простой враппер чтения строк из файлового дескриптора TTY."""
def __init__(self, fd: int):
self._fd = fd
@ -34,7 +33,7 @@ class FDReader:
def readline(self) -> bytes:
return self._buf.readline()
def close(self) -> None:
def close(self):
try:
self._buf.close()
except Exception:
@ -42,7 +41,10 @@ class FDReader:
def open_raw_tty(path: str, baud: int) -> Optional[FDReader]:
"""Open a TTY without pyserial and configure it via termios."""
"""Открыть TTY без pyserial и настроить порт через termios.
Возвращает FDReader или None при ошибке.
"""
try:
import termios
import tty
@ -67,14 +69,17 @@ def open_raw_tty(path: str, baud: int) -> Optional[FDReader]:
230400: getattr(termios, "B230400", None),
460800: getattr(termios, "B460800", None),
}
speed = baud_map.get(baud) or termios.B115200
b = baud_map.get(baud) or termios.B115200
attrs[4] = speed
attrs[5] = speed
attrs[4] = b # ispeed
attrs[5] = b # ospeed
# VMIN=1, VTIME=0 — блокирующее чтение по байту
cc = attrs[6]
cc[termios.VMIN] = 1
cc[termios.VTIME] = 0
attrs[6] = cc
termios.tcsetattr(fd, termios.TCSANOW, attrs)
except Exception:
try:
@ -87,11 +92,11 @@ def open_raw_tty(path: str, baud: int) -> Optional[FDReader]:
class SerialLineSource:
"""Unified line-oriented wrapper for pyserial and raw TTY readers."""
"""Единый интерфейс для чтения строк из порта (pyserial или raw TTY)."""
def __init__(self, path: str, baud: int, timeout: float = 1.0):
self._pyserial = try_open_pyserial(path, baud, timeout)
self._fdreader: Optional[FDReader] = None
self._fdreader = None
self._using = "pyserial" if self._pyserial is not None else "raw"
if self._pyserial is None:
self._fdreader = open_raw_tty(path, baud)
@ -107,12 +112,13 @@ class SerialLineSource:
return self._pyserial.readline()
except Exception:
return b""
try:
return self._fdreader.readline() # type: ignore[union-attr]
except Exception:
return b""
else:
try:
return self._fdreader.readline() # type: ignore[union-attr]
except Exception:
return b""
def close(self) -> None:
def close(self):
try:
if self._pyserial is not None:
self._pyserial.close()
@ -123,7 +129,7 @@ class SerialLineSource:
class SerialChunkReader:
"""Fast non-blocking chunk reader for serial sources."""
"""Быстрое неблокирующее чтение чанков из serial/raw TTY для максимального дренажа буфера."""
def __init__(self, src: SerialLineSource):
self._src = src
@ -145,22 +151,20 @@ class SerialChunkReader:
self._fd = None
def read_available(self) -> bytes:
"""Return currently available bytes or b"" when nothing is ready."""
"""Вернёт доступные байты (b"" если данных нет)."""
if self._ser is not None:
try:
available = int(getattr(self._ser, "in_waiting", 0))
n = int(getattr(self._ser, "in_waiting", 0))
except Exception:
available = 0
if available > 0:
n = 0
if n > 0:
try:
return self._ser.read(available)
return self._ser.read(n)
except Exception:
return b""
return b""
if self._fd is None:
return b""
out = bytearray()
while True:
try:

948
rfg_adc_plotter/io/sweep_parser_core.py
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524
rfg_adc_plotter/io/sweep_reader.py
View File

@ -1,109 +1,18 @@
"""Background sweep reader thread."""
from __future__ import annotations
"""Фоновый поток чтения и парсинга свипов из последовательного порта."""
import sys
import threading
import time
from queue import Full, Queue
from typing import Optional
from rfg_adc_plotter.io.sweep_parser_core import BinaryRecordStreamParser, SweepAssembler
from rfg_adc_plotter.io.serial_source import SerialChunkReader, SerialLineSource
from rfg_adc_plotter.io.sweep_parser_core import (
AsciiSweepParser,
ComplexAsciiSweepParser,
LegacyBinaryParser,
LogScale16BitX2BinaryParser,
LogScaleBinaryParser32,
ParserTestStreamParser,
SweepAssembler,
)
from rfg_adc_plotter.types import ParserEvent, PointEvent, StartEvent, SweepPacket
_PARSER_16_BIT_X2_PROBE_BYTES = 64 * 1024
_LEGACY_STREAM_MIN_RECORDS = 32
_LEGACY_STREAM_MIN_MATCH_RATIO = 0.95
_TTY_STREAM_MIN_MATCH_RATIO = 0.60
_DEBUG_FRAME_LOG_EVERY = 10
_NO_INPUT_WARN_INTERVAL_S = 5.0
_NO_PACKET_WARN_INTERVAL_S = 5.0
_NO_PACKET_HINT_AFTER_S = 10.0
def _u16le_at(data: bytes, offset: int) -> int:
return int(data[offset]) | (int(data[offset + 1]) << 8)
def _looks_like_legacy_8byte_stream(data: bytes) -> bool:
"""Heuristically detect supported 8-byte binary streams on an arbitrary byte offset."""
buf = bytes(data)
for offset in range(8):
blocks = (len(buf) - offset) // 8
if blocks < _LEGACY_STREAM_MIN_RECORDS:
continue
min_matches = max(_LEGACY_STREAM_MIN_RECORDS, int(blocks * _LEGACY_STREAM_MIN_MATCH_RATIO))
matched_steps_legacy: list[int] = []
matched_steps_tty: list[int] = []
matched_steps_logdet: list[int] = []
for block_idx in range(blocks):
base = offset + (block_idx * 8)
if (_u16le_at(buf, base + 6) & 0x00FF) != 0x000A:
w0 = _u16le_at(buf, base)
w1 = _u16le_at(buf, base + 2)
w3 = _u16le_at(buf, base + 6)
if w0 in {0x000A, 0x00A3, 0x00A4} and w1 != 0xFFFF:
matched_steps_tty.append(w1)
elif w0 == 0x001A and w3 == 0x0000:
matched_steps_logdet.append(w1)
continue
matched_steps_legacy.append(_u16le_at(buf, base))
if len(matched_steps_legacy) >= min_matches:
monotonic_or_reset = 0
for prev_step, next_step in zip(matched_steps_legacy, matched_steps_legacy[1:]):
if next_step == (prev_step + 1) or next_step <= prev_step:
monotonic_or_reset += 1
if monotonic_or_reset >= max(4, len(matched_steps_legacy) - 4):
return True
tty_min_matches = max(_LEGACY_STREAM_MIN_RECORDS, int(blocks * _TTY_STREAM_MIN_MATCH_RATIO))
if len(matched_steps_tty) >= tty_min_matches:
monotonic_or_reset = 0
for prev_step, next_step in zip(matched_steps_tty, matched_steps_tty[1:]):
if next_step == (prev_step + 1) or next_step <= 2:
monotonic_or_reset += 1
if monotonic_or_reset >= max(4, len(matched_steps_tty) - 4):
return True
if len(matched_steps_logdet) >= tty_min_matches:
monotonic_or_reset = 0
for prev_step, next_step in zip(matched_steps_logdet, matched_steps_logdet[1:]):
if next_step == (prev_step + 1) or next_step <= 2:
monotonic_or_reset += 1
if monotonic_or_reset >= max(4, len(matched_steps_logdet) - 4):
return True
return False
def _is_valid_parser_16_bit_x2_probe(events: list[ParserEvent]) -> bool:
"""Accept only plausible complex streams and ignore resync noise."""
point_steps: list[int] = []
for event in events:
if isinstance(event, PointEvent):
point_steps.append(int(event.x))
if len(point_steps) < 3:
return False
monotonic_or_small_reset = 0
for prev_step, next_step in zip(point_steps, point_steps[1:]):
if next_step == (prev_step + 1) or next_step <= 2:
monotonic_or_small_reset += 1
return monotonic_or_small_reset >= max(2, len(point_steps) - 3)
from rfg_adc_plotter.types import SweepPacket
class SweepReader(threading.Thread):
"""Read a serial source in the background and emit completed sweep packets."""
"""Фоновый поток: читает строки, формирует завершённые свипы и кладёт в очередь."""
def __init__(
self,
@ -114,267 +23,220 @@ class SweepReader(threading.Thread):
fancy: bool = False,
bin_mode: bool = False,
logscale: bool = False,
parser_16_bit_x2: bool = False,
parser_test: bool = False,
parser_complex_ascii: bool = False,
debug: bool = False,
):
super().__init__(daemon=True)
self._port_path = port_path
self._baud = int(baud)
self._queue = out_queue
self._stop_event = stop_event
self._baud = baud
self._q = out_queue
self._stop = stop_event
self._src: Optional[SerialLineSource] = None
self._fancy = bool(fancy)
self._bin_mode = bool(bin_mode)
self._logscale = bool(logscale)
self._parser_16_bit_x2 = bool(parser_16_bit_x2)
self._parser_test = bool(parser_test)
self._parser_complex_ascii = bool(parser_complex_ascii)
self._src: SerialLineSource | None = None
self._frames_read = 0
self._frames_dropped = 0
self._started_at = time.perf_counter()
self._debug = bool(debug)
self._assembler = SweepAssembler(fancy=self._fancy, logscale=self._logscale, debug=self._debug)
def _resolve_parser_mode_label(self) -> str:
if self._parser_complex_ascii:
return "complex_ascii"
if self._parser_test:
return "parser_test_16x2"
if self._parser_16_bit_x2:
return "parser_16_bit_x2"
if self._logscale:
return "logscale_32"
if self._bin_mode:
return "legacy_8byte"
return "ascii"
def _build_parser(self):
if self._parser_complex_ascii:
return ComplexAsciiSweepParser(), SweepAssembler(fancy=self._fancy, apply_inversion=False)
if self._parser_test:
return ParserTestStreamParser(), SweepAssembler(fancy=self._fancy, apply_inversion=False)
if self._parser_16_bit_x2:
return LogScale16BitX2BinaryParser(), SweepAssembler(fancy=self._fancy, apply_inversion=False)
if self._logscale:
return LogScaleBinaryParser32(), SweepAssembler(fancy=self._fancy, apply_inversion=False)
if self._bin_mode:
return LegacyBinaryParser(), SweepAssembler(fancy=self._fancy, apply_inversion=True)
return AsciiSweepParser(), SweepAssembler(fancy=self._fancy, apply_inversion=True)
@staticmethod
def _consume_events(assembler: SweepAssembler, events) -> list[SweepPacket]:
packets: list[SweepPacket] = []
for event in events:
packet = assembler.consume(event)
if packet is not None:
packets.append(packet)
return packets
def _probe_parser_16_bit_x2(self, chunk_reader: SerialChunkReader):
parser = LogScale16BitX2BinaryParser()
probe_buf = bytearray()
probe_events: list[ParserEvent] = []
probe_started_at = time.perf_counter()
while not self._stop_event.is_set() and len(probe_buf) < _PARSER_16_BIT_X2_PROBE_BYTES:
data = chunk_reader.read_available()
if not data:
time.sleep(0.0005)
continue
probe_buf += data
probe_events.extend(parser.feed(data))
if _is_valid_parser_16_bit_x2_probe(probe_events):
assembler = SweepAssembler(fancy=self._fancy, apply_inversion=False)
probe_packets = self._consume_events(assembler, probe_events)
n_points = int(sum(1 for event in probe_events if isinstance(event, PointEvent)))
n_starts = int(sum(1 for event in probe_events if isinstance(event, StartEvent)))
probe_ms = (time.perf_counter() - probe_started_at) * 1000.0
sys.stderr.write(
"[info] parser_16_bit_x2 probe: bytes:%d events:%d points:%d starts:%d parser:16x2 elapsed_ms:%.1f\n"
% (
len(probe_buf),
len(probe_events),
n_points,
n_starts,
probe_ms,
)
)
return parser, assembler, probe_packets
probe_looks_legacy = bool(probe_buf) and _looks_like_legacy_8byte_stream(bytes(probe_buf))
n_points = int(sum(1 for event in probe_events if isinstance(event, PointEvent)))
n_starts = int(sum(1 for event in probe_events if isinstance(event, StartEvent)))
probe_ms = (time.perf_counter() - probe_started_at) * 1000.0
if probe_looks_legacy:
sys.stderr.write(
"[info] parser_16_bit_x2 probe: bytes:%d events:%d points:%d starts:%d parser:legacy(fallback) elapsed_ms:%.1f\n"
% (
len(probe_buf),
len(probe_events),
n_points,
n_starts,
probe_ms,
)
)
sys.stderr.write("[info] parser_16_bit_x2: fallback -> legacy\n")
parser = LegacyBinaryParser()
assembler = SweepAssembler(fancy=self._fancy, apply_inversion=True)
probe_packets = self._consume_events(assembler, parser.feed(bytes(probe_buf)))
return parser, assembler, probe_packets
sys.stderr.write(
"[warn] parser_16_bit_x2 probe inconclusive: bytes:%d events:%d points:%d starts:%d parser:16x2 elapsed_ms:%.1f\n"
% (
len(probe_buf),
len(probe_events),
n_points,
n_starts,
probe_ms,
)
)
sys.stderr.write(
"[hint] parser_16_bit_x2: if source is 8-byte tty CH1/CH2 stream "
"(0x000A/0x00A3/0x00A4,step,ch1,ch2), try --bin\n"
)
assembler = SweepAssembler(fancy=self._fancy, apply_inversion=False)
return parser, assembler, []
def _enqueue(self, packet: SweepPacket) -> None:
dropped = False
def _finalize_current(self, xs, ys, channels: Optional[set]):
packet = self._assembler.finalize_arrays(xs, ys, channels)
if packet is None:
return
sweep, info = packet
try:
self._queue.put_nowait(packet)
self._q.put_nowait((sweep, info))
except Full:
try:
_ = self._queue.get_nowait()
dropped = True
_ = self._q.get_nowait()
except Exception:
pass
try:
self._queue.put_nowait(packet)
self._q.put_nowait((sweep, info))
except Exception:
pass
if dropped:
self._frames_dropped += 1
self._frames_read += 1
if self._frames_read % _DEBUG_FRAME_LOG_EVERY == 0:
sweep, info, _aux = packet
try:
queue_size = self._queue.qsize()
except Exception:
queue_size = -1
elapsed_s = max(time.perf_counter() - self._started_at, 1e-9)
frames_per_sec = float(self._frames_read) / elapsed_s
sweep_idx = info.get("sweep") if isinstance(info, dict) else None
channel = info.get("ch") if isinstance(info, dict) else None
sys.stderr.write(
"[debug] reader frames:%d rate:%.2f/s last_sweep:%s ch:%s width:%d queue:%d dropped:%d\n"
% (
self._frames_read,
frames_per_sec,
str(sweep_idx),
str(channel),
int(getattr(sweep, "size", 0)),
int(queue_size),
self._frames_dropped,
def _run_ascii_stream(self, chunk_reader: SerialChunkReader):
xs: list[int] = []
ys: list[int] = []
cur_channel: Optional[int] = None
cur_channels: set[int] = set()
buf = bytearray()
_dbg_line_count = 0
_dbg_match_count = 0
_dbg_sweep_count = 0
while not self._stop.is_set():
data = chunk_reader.read_available()
if data:
buf += data
else:
time.sleep(0.0005)
continue
while True:
nl = buf.find(b"\n")
if nl == -1:
break
line = bytes(buf[:nl])
del buf[: nl + 1]
if line.endswith(b"\r"):
line = line[:-1]
if not line:
continue
_dbg_line_count += 1
if line.startswith(b"Sweep_start"):
if self._debug:
sys.stderr.write(f"[debug] ASCII строка #{_dbg_line_count}: Sweep_start → финализация свипа\n")
_dbg_sweep_count += 1
self._finalize_current(xs, ys, cur_channels)
xs.clear()
ys.clear()
cur_channel = None
cur_channels.clear()
continue
if len(line) >= 3:
parts = line.split()
if len(parts) >= 3 and (parts[0].lower() == b"s" or parts[0].lower().startswith(b"s")):
try:
if parts[0].lower() == b"s":
if len(parts) >= 4:
ch = int(parts[1], 10)
x = int(parts[2], 10)
y = int(parts[3], 10)
else:
ch = 0
x = int(parts[1], 10)
y = int(parts[2], 10)
else:
ch = int(parts[0][1:], 10)
x = int(parts[1], 10)
y = int(parts[2], 10)
except Exception:
if self._debug and _dbg_line_count <= 5:
hex_repr = " ".join(f"{b:02x}" for b in line[:16])
sys.stderr.write(
f"[debug] ASCII строка #{_dbg_line_count} ({len(line)} байт): {hex_repr}"
f"{'...' if len(line) > 16 else ''} → похожа на 's', но не парсится\n"
)
continue
_dbg_match_count += 1
if self._debug and _dbg_match_count <= 3:
sys.stderr.write(f"[debug] ASCII точка: ch={ch} x={x} y={y}\n")
if cur_channel is None:
cur_channel = ch
cur_channels.add(ch)
xs.append(x)
ys.append(y)
continue
if self._debug and _dbg_line_count <= 5:
hex_repr = " ".join(f"{b:02x}" for b in line[:16])
sys.stderr.write(
f"[debug] ASCII строка #{_dbg_line_count} ({len(line)} байт): {hex_repr}"
f"{'...' if len(line) > 16 else ''} → нет совпадения\n"
)
if self._debug and _dbg_line_count % 100 == 0:
sys.stderr.write(
f"[debug] ASCII статистика: строк={_dbg_line_count}, "
f"совпадений={_dbg_match_count}, свипов={_dbg_sweep_count}\n"
)
if len(buf) > 1_000_000:
del buf[:-262144]
self._finalize_current(xs, ys, cur_channels)
def _run_binary_stream(self, chunk_reader: SerialChunkReader):
xs: list[int] = []
ys: list[int] = []
cur_channel: Optional[int] = None
cur_channels: set[int] = set()
parser = BinaryRecordStreamParser()
# Бинарный протокол (4 слова LE u16 = 8 байт на запись):
# старт свипа: 0xFFFF, 0xFFFF, 0xFFFF, (ch<<8)|0x0A
# Байты на проводе: ff ff ff ff ff ff 0a [ch]
# ch=0 → последнее слово=0x000A; ch=1 → 0x010A; и т.д.
# точка данных: step_u16, value_hi_u16, value_lo_u16, (ch<<8)|0x0A
# Байты на проводе: [step_lo step_hi] [hi_lo hi_hi] [lo_lo lo_hi] 0a [ch]
# value_i32 = sign_extend((value_hi<<16)|value_lo)
# Признак записи: байт 6 == 0x0A, байт 7 — номер канала.
# При десинхронизации сдвигаемся на 1 БАЙТ (не слово) для самосинхронизации.
_dbg_byte_count = 0
_dbg_desync_count = 0
_dbg_sweep_count = 0
_dbg_point_count = 0
while not self._stop.is_set():
data = chunk_reader.read_available()
if data:
events = parser.feed(data)
else:
time.sleep(0.0005)
continue
for ev in events:
tag = ev[0]
if tag == "start":
ch_new = int(ev[1])
if self._debug:
sys.stderr.write(f"[debug] BIN: старт свипа, ch={ch_new}\n")
_dbg_sweep_count += 1
self._finalize_current(xs, ys, cur_channels)
xs.clear()
ys.clear()
cur_channels.clear()
cur_channel = ch_new
cur_channels.add(cur_channel)
continue
_tag, ch_from_term, step, value_i32 = ev # type: ignore[misc]
if cur_channel is None:
cur_channel = int(ch_from_term)
cur_channels.add(int(cur_channel))
xs.append(int(step))
ys.append(int(value_i32))
_dbg_point_count += 1
if self._debug and _dbg_point_count <= 3:
sys.stderr.write(
f"[debug] BIN точка: step={int(step)} ch={int(ch_from_term)} → value={int(value_i32)}\n"
)
_dbg_byte_count = parser.bytes_consumed
_dbg_desync_count = parser.desync_count
if self._debug and _dbg_byte_count > 0 and _dbg_byte_count % 4000 < 8:
sys.stderr.write(
f"[debug] BIN статистика: байт={_dbg_byte_count}, "
f"десинхронизаций={_dbg_desync_count}, точек={_dbg_point_count}, свипов={_dbg_sweep_count}\n"
)
)
def run(self) -> None:
if parser.buffered_size() > 1_000_000:
parser.clear_buffer_keep_tail(262_144)
self._finalize_current(xs, ys, cur_channels)
def run(self):
try:
self._src = SerialLineSource(self._port_path, self._baud, timeout=1.0)
queue_cap = int(getattr(self._queue, "maxsize", -1))
sys.stderr.write(f"[info] Открыл порт {self._port_path} ({self._src._using})\n")
sys.stderr.write(
"[info] reader start: parser:%s fancy:%d queue_max:%d source:%s\n"
% (
self._resolve_parser_mode_label(),
int(self._fancy),
queue_cap,
getattr(self._src, "_using", "unknown"),
)
)
except Exception as exc:
sys.stderr.write(f"[error] {exc}\n")
except Exception as e:
sys.stderr.write(f"[error] {e}\n")
return
try:
chunk_reader = SerialChunkReader(self._src)
if self._parser_16_bit_x2:
parser, assembler, pending_packets = self._probe_parser_16_bit_x2(chunk_reader)
if self._debug:
mode_str = "бинарный (--bin)" if self._bin_mode else "ASCII (по умолчанию)"
sys.stderr.write(f"[debug] Режим парсера: {mode_str}\n")
if self._bin_mode:
self._run_binary_stream(chunk_reader)
else:
parser, assembler = self._build_parser()
pending_packets = []
for packet in pending_packets:
self._enqueue(packet)
loop_started_at = time.perf_counter()
last_input_at = loop_started_at
last_packet_at = loop_started_at if self._frames_read > 0 else loop_started_at
last_no_input_warn_at = loop_started_at
last_no_packet_warn_at = loop_started_at
parser_hint_emitted = False
while not self._stop_event.is_set():
data = chunk_reader.read_available()
now_s = time.perf_counter()
if not data:
input_idle_s = now_s - last_input_at
if (
input_idle_s >= _NO_INPUT_WARN_INTERVAL_S
and (now_s - last_no_input_warn_at) >= _NO_INPUT_WARN_INTERVAL_S
):
sys.stderr.write(
"[warn] reader no input bytes for %.1fs on %s (parser:%s)\n"
% (
input_idle_s,
self._port_path,
self._resolve_parser_mode_label(),
)
)
last_no_input_warn_at = now_s
packets_idle_s = now_s - last_packet_at
if (
packets_idle_s >= _NO_PACKET_WARN_INTERVAL_S
and (now_s - last_no_packet_warn_at) >= _NO_PACKET_WARN_INTERVAL_S
):
try:
queue_size = self._queue.qsize()
except Exception:
queue_size = -1
sys.stderr.write(
"[warn] reader no sweep packets for %.1fs (input_idle:%.1fs queue:%d parser:%s)\n"
% (
packets_idle_s,
input_idle_s,
int(queue_size),
self._resolve_parser_mode_label(),
)
)
last_no_packet_warn_at = now_s
if (
self._parser_16_bit_x2
and (not parser_hint_emitted)
and (now_s - self._started_at) >= _NO_PACKET_HINT_AFTER_S
):
sys.stderr.write(
"[hint] parser_16_bit_x2 still has no sweeps; "
"if source is tty CH1/CH2 (0x000A/0x00A3/0x00A4), rerun with --bin\n"
)
parser_hint_emitted = True
time.sleep(0.0005)
continue
last_input_at = now_s
packets = self._consume_events(assembler, parser.feed(data))
if packets:
last_packet_at = now_s
for packet in packets:
self._enqueue(packet)
packet = assembler.finalize_current()
if packet is not None:
self._enqueue(packet)
self._run_ascii_stream(chunk_reader)
finally:
try:
if self._src is not None:

138
rfg_adc_plotter/main.py Normal file → Executable file
View File

@ -1,25 +1,137 @@
"""Main entrypoint for the modularized ADC plotter."""
#!/usr/bin/env python3
"""
Реалтайм-плоттер для свипов из виртуального COM-порта.
from __future__ import annotations
Формат строк:
- "Sweep_start" — начало нового свипа (предыдущий считается завершённым)
- "s CH X Y" — точка (номер канала, индекс X, значение Y), все целые со знаком
Отрисовываются четыре графика:
- Сырые данные: последний полученный свип (Y vs X)
- Водопад сырых данных: последние N свипов
- FFT текущего свипа
- B-scan: водопад FFT-строк
Зависимости: numpy. PySerial опционален — при его отсутствии
используется сырой доступ к TTY через termios.
GUI: matplotlib (совместимый) или pyqtgraph (быстрый).
"""
import argparse
import sys
from rfg_adc_plotter.cli import build_parser
def build_parser() -> argparse.ArgumentParser:
parser = argparse.ArgumentParser(
description=(
"Читает свипы из виртуального COM-порта и рисует: "
"последний свип и водопад (реалтайм)."
)
)
parser.add_argument(
"port",
help="Путь к порту, например /dev/ttyACM1 или COM3 (COM10+: \\\\.\\COM10)",
)
parser.add_argument("--baud", type=int, default=115200, help="Скорость (по умолчанию 115200)")
parser.add_argument("--max-sweeps", type=int, default=200, help="Количество видимых свипов в водопаде")
parser.add_argument("--max-fps", type=float, default=30.0, help="Лимит частоты отрисовки, кадров/с")
parser.add_argument("--cmap", default="viridis", help="Цветовая карта водопада")
parser.add_argument(
"--spec-clip",
default="2,98",
help=(
"Процентильная обрезка уровней водопада спектров, %% (min,max). "
"Напр. 2,98. 'off' — отключить"
),
)
parser.add_argument(
"--spec-mean-sec",
type=float,
default=0.0,
help=(
"Вычитание среднего по каждой частоте за последние N секунд "
"в водопаде спектров (0 — отключить)"
),
)
parser.add_argument("--title", default="ADC Sweeps", help="Заголовок окна")
parser.add_argument(
"--fancy",
action="store_true",
help="Заполнять выпавшие точки средними значениями между соседними",
)
parser.add_argument(
"--ylim",
type=str,
default=None,
help="Фиксированные Y-пределы для кривой формата min,max (например -1000,1000). По умолчанию авто",
)
parser.add_argument(
"--backend",
choices=["auto", "pg", "mpl"],
default="auto",
help="Графический бэкенд: pyqtgraph (pg) — быстрее; matplotlib (mpl) — совместимый. По умолчанию auto",
)
parser.add_argument(
"--norm-type",
choices=["projector", "simple"],
default="projector",
help="Тип нормировки: projector (по огибающим в [-1000,+1000]) или simple (raw/calib)",
)
parser.add_argument(
"--ifft-complex-mode",
choices=["arccos", "diff"],
default="arccos",
help=(
"Режим реконструкции комплексного спектра перед IFFT: "
"arccos (phi=arccos(x), unwrap) или diff (sin(phi) через численную производную)"
),
)
parser.add_argument(
"--bin",
dest="bin_mode",
action="store_true",
help=(
"Бинарный протокол (8 байт на запись, LE u16 слова): "
"старт свипа ff ff ff ff ff ff 0a [ch]; "
"точка step_u16 hi_u16 lo_u16 0a [ch]; "
"value=sign_ext((hi<<16)|lo); ch=0..N в старшем байте маркера"
),
)
parser.add_argument(
"--logscale",
action="store_true",
help="После поправки знака применять экспоненту LOG_EXP**x (LOG_EXP=2)",
)
parser.add_argument(
"--debug",
action="store_true",
help="Отладочный вывод парсера: показывает принятые строки/слова и причины отсутствия свипов",
)
return parser
def main() -> None:
def main():
args = build_parser().parse_args()
if args.backend == "mpl":
sys.stderr.write("[error] Matplotlib backend removed. Use --backend pg or --backend auto.\n")
raise SystemExit(2)
from rfg_adc_plotter.gui.pyqtgraph_backend import run_pyqtgraph
if args.backend == "pg":
from rfg_adc_plotter.gui.pyqtgraph_backend import run_pyqtgraph
try:
run_pyqtgraph(args)
except Exception as e:
sys.stderr.write(f"[error] PyQtGraph бэкенд недоступен: {e}\n")
sys.exit(1)
return
try:
run_pyqtgraph(args)
except Exception as exc:
sys.stderr.write(f"[error] PyQtGraph бэкенд недоступен: {exc}\n")
raise SystemExit(1) from exc
if args.backend == "auto":
try:
from rfg_adc_plotter.gui.pyqtgraph_backend import run_pyqtgraph
run_pyqtgraph(args)
return
except Exception:
pass # Откатываемся на matplotlib
from rfg_adc_plotter.gui.matplotlib_backend import run_matplotlib
run_matplotlib(args)
if __name__ == "__main__":

79
rfg_adc_plotter/processing/__init__.py
View File

@ -1,79 +0,0 @@
"""Pure sweep-processing helpers."""
from rfg_adc_plotter.processing.background import (
load_fft_background,
save_fft_background,
subtract_fft_background,
validate_fft_background,
)
from rfg_adc_plotter.processing.calibration import (
build_calib_envelope,
build_complex_calibration_curve,
calibrate_freqs,
get_calibration_base,
get_calibration_coeffs,
load_calib_envelope,
load_complex_calibration,
recalculate_calibration_c,
save_calib_envelope,
save_complex_calibration,
set_calibration_base_value,
)
from rfg_adc_plotter.processing.fft import (
compute_distance_axis,
compute_fft_complex_row,
compute_fft_mag_row,
compute_fft_row,
fft_mag_to_db,
)
from rfg_adc_plotter.processing.formatting import (
compute_auto_ylim,
format_status_kv,
parse_spec_clip,
)
from rfg_adc_plotter.processing.normalization import (
build_calib_envelopes,
fit_complex_calibration_to_width,
normalize_by_complex_calibration,
normalize_by_envelope,
normalize_by_calib,
)
from rfg_adc_plotter.processing.peaks import (
find_peak_width_markers,
find_top_peaks_over_ref,
rolling_median_ref,
)
__all__ = [
"build_calib_envelopes",
"build_calib_envelope",
"build_complex_calibration_curve",
"calibrate_freqs",
"compute_auto_ylim",
"compute_distance_axis",
"compute_fft_complex_row",
"compute_fft_mag_row",
"compute_fft_row",
"fft_mag_to_db",
"find_peak_width_markers",
"find_top_peaks_over_ref",
"format_status_kv",
"get_calibration_base",
"get_calibration_coeffs",
"load_calib_envelope",
"load_complex_calibration",
"load_fft_background",
"fit_complex_calibration_to_width",
"normalize_by_complex_calibration",
"normalize_by_envelope",
"normalize_by_calib",
"parse_spec_clip",
"recalculate_calibration_c",
"rolling_median_ref",
"save_calib_envelope",
"save_complex_calibration",
"save_fft_background",
"set_calibration_base_value",
"subtract_fft_background",
"validate_fft_background",
]

66
rfg_adc_plotter/processing/background.py
View File

@ -1,66 +0,0 @@
"""Helpers for persisted FFT background profiles."""
from __future__ import annotations
from pathlib import Path
import numpy as np
def validate_fft_background(background: np.ndarray) -> np.ndarray:
"""Validate a saved FFT background payload."""
values = np.asarray(background)
if values.ndim != 1:
raise ValueError("FFT background must be a 1D array")
if not np.issubdtype(values.dtype, np.number):
raise ValueError("FFT background must be numeric")
values = np.asarray(values, dtype=np.float32).reshape(-1)
if values.size == 0:
raise ValueError("FFT background is empty")
return values
def _normalize_background_path(path: str | Path) -> Path:
out = Path(path).expanduser()
if out.suffix.lower() != ".npy":
out = out.with_suffix(".npy")
return out
def save_fft_background(path: str | Path, background: np.ndarray) -> str:
"""Persist an FFT background profile as a .npy file."""
normalized_path = _normalize_background_path(path)
values = validate_fft_background(background)
np.save(normalized_path, values.astype(np.float32, copy=False))
return str(normalized_path)
def load_fft_background(path: str | Path) -> np.ndarray:
"""Load and validate an FFT background profile from a .npy file."""
normalized_path = _normalize_background_path(path)
loaded = np.load(normalized_path, allow_pickle=False)
return validate_fft_background(loaded)
def subtract_fft_background(signal_mag: np.ndarray, background_mag: np.ndarray) -> np.ndarray:
"""Subtract a background profile from FFT magnitudes in linear amplitude."""
signal = np.asarray(signal_mag, dtype=np.float32)
background = validate_fft_background(background_mag)
if signal.ndim == 1:
if signal.size != background.size:
raise ValueError("FFT background size does not match signal size")
valid = np.isfinite(signal) & np.isfinite(background)
out = np.full_like(signal, np.nan, dtype=np.float32)
if np.any(valid):
out[valid] = np.maximum(signal[valid] - background[valid], 0.0)
return out
if signal.ndim == 2:
if signal.shape[0] != background.size:
raise ValueError("FFT background size does not match signal rows")
background_2d = background[:, None]
valid = np.isfinite(signal) & np.isfinite(background_2d)
diff = signal - background_2d
return np.where(valid, np.maximum(diff, 0.0), np.nan).astype(np.float32, copy=False)
raise ValueError("FFT background subtraction supports only 1D or 2D signals")

169
rfg_adc_plotter/processing/calibration.py
View File

@ -1,169 +0,0 @@
"""Frequency-axis calibration helpers."""
from __future__ import annotations
from pathlib import Path
from typing import Any, Mapping
import numpy as np
from rfg_adc_plotter.constants import SWEEP_FREQ_MAX_GHZ, SWEEP_FREQ_MIN_GHZ
from rfg_adc_plotter.processing.normalization import build_calib_envelopes
from rfg_adc_plotter.types import SweepData
def recalculate_calibration_c(
base_coeffs: np.ndarray,
f_min: float = SWEEP_FREQ_MIN_GHZ,
f_max: float = SWEEP_FREQ_MAX_GHZ,
) -> np.ndarray:
"""Recalculate coefficients while preserving sweep edges."""
coeffs = np.asarray(base_coeffs, dtype=np.float64).reshape(-1)
if coeffs.size < 3:
out = np.zeros((3,), dtype=np.float64)
out[: coeffs.size] = coeffs
coeffs = out
c0, c1, c2 = float(coeffs[0]), float(coeffs[1]), float(coeffs[2])
x0 = float(f_min)
x1 = float(f_max)
y0 = c0 + c1 * x0 + c2 * (x0 ** 2)
y1 = c0 + c1 * x1 + c2 * (x1 ** 2)
if not (np.isfinite(y0) and np.isfinite(y1)) or y1 == y0:
return np.asarray([c0, c1, c2], dtype=np.float64)
scale = (x1 - x0) / (y1 - y0)
shift = x0 - scale * y0
return np.asarray(
[
shift + scale * c0,
scale * c1,
scale * c2,
],
dtype=np.float64,
)
CALIBRATION_C_BASE = np.asarray([0.0, 1.0, 0.025], dtype=np.float64)
CALIBRATION_C = recalculate_calibration_c(CALIBRATION_C_BASE)
def get_calibration_base() -> np.ndarray:
return np.asarray(CALIBRATION_C_BASE, dtype=np.float64).copy()
def get_calibration_coeffs() -> np.ndarray:
return np.asarray(CALIBRATION_C, dtype=np.float64).copy()
def set_calibration_base_value(index: int, value: float) -> np.ndarray:
"""Update one base coefficient and recalculate the working coefficients."""
global CALIBRATION_C
CALIBRATION_C_BASE[int(index)] = float(value)
CALIBRATION_C = recalculate_calibration_c(CALIBRATION_C_BASE)
return get_calibration_coeffs()
def calibrate_freqs(sweep: Mapping[str, Any]) -> SweepData:
"""Return a sweep copy with calibrated and resampled frequency axis."""
freqs = np.asarray(sweep["F"], dtype=np.float64).copy()
values_in = np.asarray(sweep["I"]).reshape(-1)
values = np.asarray(
values_in,
dtype=np.complex128 if np.iscomplexobj(values_in) else np.float64,
).copy()
coeffs = np.asarray(CALIBRATION_C, dtype=np.float64)
if freqs.size > 0:
freqs = coeffs[0] + coeffs[1] * freqs + coeffs[2] * (freqs * freqs)
if freqs.size >= 2:
freqs_cal = np.linspace(float(freqs[0]), float(freqs[-1]), freqs.size, dtype=np.float64)
if np.iscomplexobj(values):
values_real = np.interp(freqs_cal, freqs, values.real.astype(np.float64, copy=False))
values_imag = np.interp(freqs_cal, freqs, values.imag.astype(np.float64, copy=False))
values_cal = (values_real + (1j * values_imag)).astype(np.complex64)
else:
values_cal = np.interp(freqs_cal, freqs, values).astype(np.float64)
else:
freqs_cal = freqs.copy()
values_cal = values.copy()
return {
"F": freqs_cal,
"I": values_cal,
}
def build_calib_envelope(sweep: np.ndarray) -> np.ndarray:
"""Build the active calibration envelope from a raw sweep."""
values = np.asarray(sweep, dtype=np.float32).reshape(-1)
if values.size == 0:
raise ValueError("Calibration sweep is empty")
_, upper = build_calib_envelopes(values)
return np.asarray(upper, dtype=np.float32)
def build_complex_calibration_curve(ch1: np.ndarray, ch2: np.ndarray) -> np.ndarray:
"""Build a complex calibration curve as ``ch1 + 1j*ch2``."""
ch1_arr = np.asarray(ch1, dtype=np.float32).reshape(-1)
ch2_arr = np.asarray(ch2, dtype=np.float32).reshape(-1)
width = min(ch1_arr.size, ch2_arr.size)
if width <= 0:
raise ValueError("Complex calibration source is empty")
curve = ch1_arr[:width].astype(np.complex64) + (1j * ch2_arr[:width].astype(np.complex64))
return validate_complex_calibration_curve(curve)
def validate_calib_envelope(envelope: np.ndarray) -> np.ndarray:
"""Validate a saved calibration envelope payload."""
values = np.asarray(envelope, dtype=np.float32).reshape(-1)
if values.size == 0:
raise ValueError("Calibration envelope is empty")
if not np.issubdtype(values.dtype, np.number):
raise ValueError("Calibration envelope must be numeric")
return values
def validate_complex_calibration_curve(curve: np.ndarray) -> np.ndarray:
"""Validate a saved complex calibration payload."""
values = np.asarray(curve).reshape(-1)
if values.size == 0:
raise ValueError("Complex calibration curve is empty")
if not np.issubdtype(values.dtype, np.number):
raise ValueError("Complex calibration curve must be numeric")
return np.asarray(values, dtype=np.complex64)
def _normalize_calib_path(path: str | Path) -> Path:
out = Path(path).expanduser()
if out.suffix.lower() != ".npy":
out = out.with_suffix(".npy")
return out
def save_calib_envelope(path: str | Path, envelope: np.ndarray) -> str:
"""Persist a calibration envelope as a .npy file and return the final path."""
normalized_path = _normalize_calib_path(path)
values = validate_calib_envelope(envelope)
np.save(normalized_path, values.astype(np.float32, copy=False))
return str(normalized_path)
def load_calib_envelope(path: str | Path) -> np.ndarray:
"""Load and validate a calibration envelope from a .npy file."""
normalized_path = _normalize_calib_path(path)
loaded = np.load(normalized_path, allow_pickle=False)
return validate_calib_envelope(loaded)
def save_complex_calibration(path: str | Path, curve: np.ndarray) -> str:
"""Persist a complex calibration curve as a .npy file and return the final path."""
normalized_path = _normalize_calib_path(path)
values = validate_complex_calibration_curve(curve)
np.save(normalized_path, values.astype(np.complex64, copy=False))
return str(normalized_path)
def load_complex_calibration(path: str | Path) -> np.ndarray:
"""Load and validate a complex calibration curve from a .npy file."""
normalized_path = _normalize_calib_path(path)
loaded = np.load(normalized_path, allow_pickle=False)
return validate_complex_calibration_curve(loaded)

511
rfg_adc_plotter/processing/fft.py
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@ -1,511 +0,0 @@
"""FFT helpers for line and waterfall views."""
from __future__ import annotations
from typing import Optional, Tuple
import numpy as np
from rfg_adc_plotter.constants import C_M_S, FFT_LEN, SWEEP_FREQ_MAX_GHZ, SWEEP_FREQ_MIN_GHZ
def _finite_freq_bounds(freqs: Optional[np.ndarray]) -> Optional[Tuple[float, float]]:
"""Return finite frequency bounds for the current working segment."""
if freqs is None:
return None
freq_arr = np.asarray(freqs, dtype=np.float64).reshape(-1)
finite = freq_arr[np.isfinite(freq_arr)]
if finite.size < 2:
return None
f_min = float(np.min(finite))
f_max = float(np.max(finite))
if not np.isfinite(f_min) or not np.isfinite(f_max) or f_max <= f_min:
return None
return f_min, f_max
def _coerce_sweep_array(sweep: np.ndarray) -> np.ndarray:
values = np.asarray(sweep).reshape(-1)
if np.iscomplexobj(values):
return np.asarray(values, dtype=np.complex64)
return np.asarray(values, dtype=np.float32)
def _interp_signal(x_uniform: np.ndarray, x_known: np.ndarray, y_known: np.ndarray) -> np.ndarray:
if np.iscomplexobj(y_known):
real = np.interp(x_uniform, x_known, np.asarray(y_known.real, dtype=np.float64))
imag = np.interp(x_uniform, x_known, np.asarray(y_known.imag, dtype=np.float64))
return (real + (1j * imag)).astype(np.complex64)
return np.interp(x_uniform, x_known, np.asarray(y_known, dtype=np.float64)).astype(np.float32)
def _fit_complex_bins(values: np.ndarray, bins: int) -> np.ndarray:
arr = np.asarray(values, dtype=np.complex64).reshape(-1)
if bins <= 0:
return np.zeros((0,), dtype=np.complex64)
if arr.size == bins:
return arr
out = np.full((bins,), np.nan + 0j, dtype=np.complex64)
take = min(arr.size, bins)
out[:take] = arr[:take]
return out
def _extract_positive_exact_band(
sweep: np.ndarray,
freqs: Optional[np.ndarray],
) -> Optional[Tuple[np.ndarray, np.ndarray, float, float]]:
"""Return sorted positive band data and exact-grid parameters."""
if freqs is None:
return None
sweep_arr = _coerce_sweep_array(sweep)
freq_arr = np.asarray(freqs, dtype=np.float64).reshape(-1)
take = min(int(sweep_arr.size), int(freq_arr.size))
if take <= 1:
return None
sweep_seg = sweep_arr[:take]
freq_seg = freq_arr[:take]
valid = np.isfinite(freq_seg) & np.isfinite(sweep_seg) & (freq_seg > 0.0)
if int(np.count_nonzero(valid)) < 2:
return None
freq_band = np.asarray(freq_seg[valid], dtype=np.float64)
sweep_band = np.asarray(sweep_seg[valid])
order = np.argsort(freq_band, kind="mergesort")
freq_band = freq_band[order]
sweep_band = sweep_band[order]
n_band = int(freq_band.size)
if n_band <= 1:
return None
f_min = float(freq_band[0])
f_max = float(freq_band[-1])
if (not np.isfinite(f_min)) or (not np.isfinite(f_max)) or f_max <= f_min:
return None
df_ghz = float((f_max - f_min) / max(1, n_band - 1))
if (not np.isfinite(df_ghz)) or df_ghz <= 0.0:
return None
return freq_band, sweep_band, f_max, df_ghz
def _positive_exact_shift_size(f_max: float, df_ghz: float) -> int:
if (not np.isfinite(f_max)) or (not np.isfinite(df_ghz)) or f_max <= 0.0 or df_ghz <= 0.0:
return 0
return int(np.arange(-f_max, f_max + (0.5 * df_ghz), df_ghz, dtype=np.float64).size)
def _resolve_positive_exact_band_size(
f_min: float,
f_max: float,
n_band: int,
max_shift_len: Optional[int],
) -> int:
if n_band <= 2:
return max(2, int(n_band))
if max_shift_len is None:
return int(n_band)
limit = int(max_shift_len)
if limit <= 1:
return max(2, int(n_band))
span = float(f_max - f_min)
if (not np.isfinite(span)) or span <= 0.0:
return int(n_band)
df_current = float(span / max(1, int(n_band) - 1))
if _positive_exact_shift_size(f_max, df_current) <= limit:
return int(n_band)
denom = max(2.0 * f_max, 1e-12)
approx = int(np.floor(1.0 + ((float(limit - 1) * span) / denom)))
target = min(int(n_band), max(2, approx))
while target > 2:
df_try = float(span / max(1, target - 1))
if _positive_exact_shift_size(f_max, df_try) <= limit:
break
target -= 1
return max(2, target)
def _normalize_positive_exact_band(
freq_band: np.ndarray,
sweep_band: np.ndarray,
*,
max_shift_len: Optional[int] = None,
) -> Optional[Tuple[np.ndarray, np.ndarray, float, float]]:
freq_arr = np.asarray(freq_band, dtype=np.float64).reshape(-1)
sweep_arr = np.asarray(sweep_band).reshape(-1)
width = min(int(freq_arr.size), int(sweep_arr.size))
if width <= 1:
return None
freq_arr = freq_arr[:width]
sweep_arr = sweep_arr[:width]
f_min = float(freq_arr[0])
f_max = float(freq_arr[-1])
if (not np.isfinite(f_min)) or (not np.isfinite(f_max)) or f_max <= f_min:
return None
target_band = _resolve_positive_exact_band_size(f_min, f_max, int(freq_arr.size), max_shift_len)
if target_band < int(freq_arr.size):
target_freqs = np.linspace(f_min, f_max, target_band, dtype=np.float64)
target_sweep = _interp_signal(target_freqs, freq_arr, sweep_arr)
freq_arr = target_freqs
sweep_arr = np.asarray(target_sweep).reshape(-1)
n_band = int(freq_arr.size)
if n_band <= 1:
return None
df_ghz = float((f_max - f_min) / max(1, n_band - 1))
if (not np.isfinite(df_ghz)) or df_ghz <= 0.0:
return None
return freq_arr, sweep_arr, f_max, df_ghz
def _resolve_positive_only_exact_geometry(
freqs: Optional[np.ndarray],
*,
max_shift_len: Optional[int] = None,
) -> Optional[Tuple[int, float]]:
"""Return (N_shift, df_hz) for the exact centered positive-only mode."""
if freqs is None:
return None
freq_arr = np.asarray(freqs, dtype=np.float64).reshape(-1)
finite = np.asarray(freq_arr[np.isfinite(freq_arr) & (freq_arr > 0.0)], dtype=np.float64)
if finite.size < 2:
return None
finite.sort(kind="mergesort")
f_min = float(finite[0])
f_max = float(finite[-1])
if (not np.isfinite(f_min)) or (not np.isfinite(f_max)) or f_max <= f_min:
return None
n_band = int(finite.size)
target_band = _resolve_positive_exact_band_size(f_min, f_max, n_band, max_shift_len)
n_band = max(2, min(n_band, target_band))
df_ghz = float((f_max - f_min) / max(1, n_band - 1))
if (not np.isfinite(df_ghz)) or df_ghz <= 0.0:
return None
n_shift = _positive_exact_shift_size(f_max, df_ghz)
if n_shift <= 1:
return None
return int(n_shift), float(df_ghz * 1e9)
def prepare_fft_segment(
sweep: np.ndarray,
freqs: Optional[np.ndarray],
fft_len: int = FFT_LEN,
) -> Optional[Tuple[np.ndarray, int]]:
"""Prepare a sweep segment for FFT on a uniform frequency grid."""
take_fft = min(int(sweep.size), int(fft_len))
if take_fft <= 0:
return None
sweep_arr = _coerce_sweep_array(sweep)
sweep_seg = sweep_arr[:take_fft]
fallback_dtype = np.complex64 if np.iscomplexobj(sweep_seg) else np.float32
fallback = np.nan_to_num(sweep_seg, nan=0.0).astype(fallback_dtype, copy=False)
if freqs is None:
return fallback, take_fft
freq_arr = np.asarray(freqs)
if freq_arr.size < take_fft:
return fallback, take_fft
freq_seg = np.asarray(freq_arr[:take_fft], dtype=np.float64)
valid = np.isfinite(sweep_seg) & np.isfinite(freq_seg)
if int(np.count_nonzero(valid)) < 2:
return fallback, take_fft
x_valid = freq_seg[valid]
y_valid = sweep_seg[valid]
order = np.argsort(x_valid, kind="mergesort")
x_valid = x_valid[order]
y_valid = y_valid[order]
x_unique, unique_idx = np.unique(x_valid, return_index=True)
y_unique = y_valid[unique_idx]
if x_unique.size < 2 or x_unique[-1] <= x_unique[0]:
return fallback, take_fft
x_uniform = np.linspace(float(x_unique[0]), float(x_unique[-1]), take_fft, dtype=np.float64)
resampled = _interp_signal(x_uniform, x_unique, y_unique)
return resampled, take_fft
def build_symmetric_ifft_spectrum(
sweep: np.ndarray,
freqs: Optional[np.ndarray],
fft_len: int = FFT_LEN,
) -> Optional[np.ndarray]:
"""Build a centered symmetric spectrum over [-f_max, f_max] for IFFT."""
if fft_len <= 0:
return None
bounds = _finite_freq_bounds(freqs)
if bounds is None:
f_min = float(SWEEP_FREQ_MIN_GHZ)
f_max = float(SWEEP_FREQ_MAX_GHZ)
else:
f_min, f_max = bounds
freq_axis = np.linspace(-f_max, f_max, int(fft_len), dtype=np.float64)
neg_idx_all = np.flatnonzero(freq_axis <= (-f_min))
pos_idx_all = np.flatnonzero(freq_axis >= f_min)
band_len = int(min(neg_idx_all.size, pos_idx_all.size))
if band_len <= 1:
return None
neg_idx = neg_idx_all[:band_len]
pos_idx = pos_idx_all[-band_len:]
prepared = prepare_fft_segment(sweep, freqs, fft_len=band_len)
if prepared is None:
return None
fft_seg, take_fft = prepared
if take_fft != band_len:
fft_dtype = np.complex64 if np.iscomplexobj(fft_seg) else np.float32
fft_seg = np.asarray(fft_seg[:band_len], dtype=fft_dtype)
if fft_seg.size < band_len:
padded = np.zeros((band_len,), dtype=fft_dtype)
padded[: fft_seg.size] = fft_seg
fft_seg = padded
window = np.hanning(band_len).astype(np.float32)
band_dtype = np.complex64 if np.iscomplexobj(fft_seg) else np.float32
band = np.nan_to_num(fft_seg, nan=0.0).astype(band_dtype, copy=False) * window
spectrum = np.zeros((int(fft_len),), dtype=band_dtype)
spectrum[pos_idx] = band
spectrum[neg_idx] = np.conj(band[::-1]) if np.iscomplexobj(band) else band[::-1]
return spectrum
def build_positive_only_centered_ifft_spectrum(
sweep: np.ndarray,
freqs: Optional[np.ndarray],
fft_len: int = FFT_LEN,
) -> Optional[np.ndarray]:
"""Build a centered spectrum with zeros from -f_max to +f_min."""
if fft_len <= 0:
return None
bounds = _finite_freq_bounds(freqs)
if bounds is None:
f_min = float(SWEEP_FREQ_MIN_GHZ)
f_max = float(SWEEP_FREQ_MAX_GHZ)
else:
f_min, f_max = bounds
freq_axis = np.linspace(-f_max, f_max, int(fft_len), dtype=np.float64)
pos_idx = np.flatnonzero(freq_axis >= f_min)
band_len = int(pos_idx.size)
if band_len <= 1:
return None
prepared = prepare_fft_segment(sweep, freqs, fft_len=band_len)
if prepared is None:
return None
fft_seg, take_fft = prepared
if take_fft != band_len:
fft_dtype = np.complex64 if np.iscomplexobj(fft_seg) else np.float32
fft_seg = np.asarray(fft_seg[:band_len], dtype=fft_dtype)
if fft_seg.size < band_len:
padded = np.zeros((band_len,), dtype=fft_dtype)
padded[: fft_seg.size] = fft_seg
fft_seg = padded
window = np.hanning(band_len).astype(np.float32)
band_dtype = np.complex64 if np.iscomplexobj(fft_seg) else np.float32
band = np.nan_to_num(fft_seg, nan=0.0).astype(band_dtype, copy=False) * window
spectrum = np.zeros((int(fft_len),), dtype=band_dtype)
spectrum[pos_idx] = band
return spectrum
def build_positive_only_exact_centered_ifft_spectrum(
sweep: np.ndarray,
freqs: Optional[np.ndarray],
*,
max_shift_len: Optional[int] = None,
) -> Optional[np.ndarray]:
"""Build centered spectrum exactly as zeros[-f_max..+f_min) + measured positive band."""
prepared = _extract_positive_exact_band(sweep, freqs)
if prepared is None:
return None
freq_band, sweep_band, _f_max, _df_ghz = prepared
normalized = _normalize_positive_exact_band(
freq_band,
sweep_band,
max_shift_len=max_shift_len,
)
if normalized is None:
return None
freq_band, sweep_band, f_max, df_ghz = normalized
f_shift = np.arange(-f_max, f_max + (0.5 * df_ghz), df_ghz, dtype=np.float64)
if f_shift.size <= 1:
return None
band_dtype = np.complex64 if np.iscomplexobj(sweep_band) else np.float32
band = np.nan_to_num(np.asarray(sweep_band, dtype=band_dtype), nan=0.0)
spectrum = np.zeros((int(f_shift.size),), dtype=band_dtype)
idx = np.round((freq_band - f_shift[0]) / df_ghz).astype(np.int64)
idx = np.clip(idx, 0, spectrum.size - 1)
spectrum[idx] = band
return spectrum
def fft_mag_to_db(mag: np.ndarray) -> np.ndarray:
"""Convert magnitude to dB with safe zero handling."""
mag_arr = np.asarray(mag, dtype=np.float32)
safe_mag = np.maximum(mag_arr, 0.0)
return (20.0 * np.log10(safe_mag + 1e-9)).astype(np.float32, copy=False)
def _compute_fft_complex_row_direct(
sweep: np.ndarray,
freqs: Optional[np.ndarray],
bins: int,
) -> np.ndarray:
prepared = prepare_fft_segment(sweep, freqs, fft_len=FFT_LEN)
if prepared is None:
return np.full((bins,), np.nan + 0j, dtype=np.complex64)
fft_seg, take_fft = prepared
fft_in = np.zeros((FFT_LEN,), dtype=np.complex64)
window = np.hanning(take_fft).astype(np.float32)
fft_in[:take_fft] = np.asarray(fft_seg, dtype=np.complex64) * window
spec = np.fft.ifft(fft_in)
return _fit_complex_bins(spec, bins)
def _normalize_fft_mode(mode: str | None, symmetric: Optional[bool]) -> str:
if symmetric is not None:
return "symmetric" if symmetric else "direct"
normalized = str(mode or "symmetric").strip().lower()
if normalized in {"direct", "ordinary", "normal"}:
return "direct"
if normalized in {"symmetric", "sym", "mirror"}:
return "symmetric"
if normalized in {"positive_only", "positive-centered", "positive_centered", "zero_left"}:
return "positive_only"
if normalized in {"positive_only_exact", "positive-centered-exact", "positive_centered_exact", "zero_left_exact"}:
return "positive_only_exact"
raise ValueError(f"Unsupported FFT mode: {mode!r}")
def compute_fft_complex_row(
sweep: np.ndarray,
freqs: Optional[np.ndarray],
bins: int,
*,
mode: str = "symmetric",
symmetric: Optional[bool] = None,
) -> np.ndarray:
"""Compute a complex FFT/IFFT row on the distance axis."""
if bins <= 0:
return np.zeros((0,), dtype=np.complex64)
fft_mode = _normalize_fft_mode(mode, symmetric)
if fft_mode == "direct":
return _compute_fft_complex_row_direct(sweep, freqs, bins)
if fft_mode == "positive_only":
spectrum_centered = build_positive_only_centered_ifft_spectrum(sweep, freqs, fft_len=FFT_LEN)
elif fft_mode == "positive_only_exact":
spectrum_centered = build_positive_only_exact_centered_ifft_spectrum(
sweep,
freqs,
max_shift_len=bins,
)
else:
spectrum_centered = build_symmetric_ifft_spectrum(sweep, freqs, fft_len=FFT_LEN)
if spectrum_centered is None:
return np.full((bins,), np.nan + 0j, dtype=np.complex64)
spec = np.fft.ifft(np.fft.ifftshift(np.asarray(spectrum_centered, dtype=np.complex64)))
return _fit_complex_bins(spec, bins)
def compute_fft_mag_row(
sweep: np.ndarray,
freqs: Optional[np.ndarray],
bins: int,
*,
mode: str = "symmetric",
symmetric: Optional[bool] = None,
) -> np.ndarray:
"""Compute a linear FFT magnitude row."""
complex_row = compute_fft_complex_row(sweep, freqs, bins, mode=mode, symmetric=symmetric)
return np.abs(complex_row).astype(np.float32, copy=False)
def compute_fft_row(
sweep: np.ndarray,
freqs: Optional[np.ndarray],
bins: int,
*,
mode: str = "symmetric",
symmetric: Optional[bool] = None,
) -> np.ndarray:
"""Compute a dB FFT row."""
return fft_mag_to_db(compute_fft_mag_row(sweep, freqs, bins, mode=mode, symmetric=symmetric))
def compute_distance_axis(
freqs: Optional[np.ndarray],
bins: int,
*,
mode: str = "symmetric",
symmetric: Optional[bool] = None,
) -> np.ndarray:
"""Compute the one-way distance axis for IFFT output."""
if bins <= 0:
return np.zeros((0,), dtype=np.float64)
fft_mode = _normalize_fft_mode(mode, symmetric)
if fft_mode == "positive_only_exact":
geometry = _resolve_positive_only_exact_geometry(freqs, max_shift_len=bins)
if geometry is None:
return np.arange(bins, dtype=np.float64)
n_shift, df_hz = geometry
if (not np.isfinite(df_hz)) or df_hz <= 0.0 or n_shift <= 0:
return np.arange(bins, dtype=np.float64)
step_m = C_M_S / (2.0 * float(n_shift) * df_hz)
return np.arange(bins, dtype=np.float64) * step_m
if fft_mode in {"symmetric", "positive_only"}:
bounds = _finite_freq_bounds(freqs)
if bounds is None:
f_max = float(SWEEP_FREQ_MAX_GHZ)
else:
_, f_max = bounds
df_ghz = (2.0 * f_max) / max(1, FFT_LEN - 1)
else:
if freqs is None:
return np.arange(bins, dtype=np.float64)
freq_arr = np.asarray(freqs, dtype=np.float64)
finite = freq_arr[np.isfinite(freq_arr)]
if finite.size < 2:
return np.arange(bins, dtype=np.float64)
df_ghz = float((finite[-1] - finite[0]) / max(1, finite.size - 1))
df_hz = abs(df_ghz) * 1e9
if not np.isfinite(df_hz) or df_hz <= 0.0:
return np.arange(bins, dtype=np.float64)
step_m = C_M_S / (2.0 * FFT_LEN * df_hz)
return np.arange(bins, dtype=np.float64) * step_m

71
rfg_adc_plotter/processing/formatting.py
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@ -1,71 +0,0 @@
"""Formatting and display-range helpers."""
from __future__ import annotations
from typing import Any, Mapping, Optional, Tuple
import numpy as np
def format_status_kv(data: Mapping[str, Any]) -> str:
"""Convert status metrics into a compact single-line representation."""
def _fmt(value: Any) -> str:
if value is None:
return "NA"
try:
f_value = float(value)
except Exception:
return str(value)
if not np.isfinite(f_value):
return "nan"
if abs(f_value) >= 1000 or (0 < abs(f_value) < 0.01):
return f"{f_value:.3g}"
return f"{f_value:.3f}".rstrip("0").rstrip(".")
return " ".join(f"{key}:{_fmt(value)}" for key, value in data.items())
def parse_spec_clip(spec: Optional[str]) -> Optional[Tuple[float, float]]:
"""Parse a waterfall percentile clip specification."""
if not spec:
return None
value = str(spec).strip().lower()
if value in ("off", "none", "no"):
return None
try:
p0, p1 = value.replace(";", ",").split(",")
low = float(p0)
high = float(p1)
if not (0.0 <= low < high <= 100.0):
return None
return (low, high)
except Exception:
return None
def compute_auto_ylim(*series_list: Optional[np.ndarray]) -> Optional[Tuple[float, float]]:
"""Compute a common Y-range with a small padding."""
y_min: Optional[float] = None
y_max: Optional[float] = None
for series in series_list:
if series is None:
continue
arr = np.asarray(series)
if arr.size == 0:
continue
finite = arr[np.isfinite(arr)]
if finite.size == 0:
continue
cur_min = float(np.min(finite))
cur_max = float(np.max(finite))
y_min = cur_min if y_min is None else min(y_min, cur_min)
y_max = cur_max if y_max is None else max(y_max, cur_max)
if y_min is None or y_max is None:
return None
if y_min == y_max:
pad = max(1.0, abs(y_min) * 0.05)
else:
pad = 0.05 * (y_max - y_min)
return (y_min - pad, y_max + pad)

300
rfg_adc_plotter/processing/fourier.py Normal file
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"""Преобразование свипа в IFFT-профиль по глубине (м).
Поддерживает несколько режимов восстановления комплексного спектра перед IFFT:
- ``arccos``: phi = arccos(x), continuous unwrap, z = exp(1j*phi)
- ``diff``: x ~= cos(phi), diff(x) -> sin(phi), z = cos + 1j*sin (с проекцией на единичную окружность)
"""
from __future__ import annotations
import logging
from typing import Optional
import numpy as np
from rfg_adc_plotter.constants import (
FREQ_MAX_GHZ,
FREQ_MIN_GHZ,
FREQ_SPAN_GHZ,
IFFT_LEN,
SPEED_OF_LIGHT_M_S,
)
logger = logging.getLogger(__name__)
_EPS = 1e-12
_TWO_PI = float(2.0 * np.pi)
_VALID_COMPLEX_MODES = {"arccos", "diff"}
def _fallback_depth_response(
size: int,
values: Optional[np.ndarray] = None,
) -> tuple[np.ndarray, np.ndarray]:
"""Безопасный fallback для GUI/ring: всегда возвращает ненулевую длину."""
n = max(1, int(size))
depth = np.linspace(0.0, 1.0, n, dtype=np.float32)
if values is None:
return depth, np.zeros((n,), dtype=np.float32)
arr = np.asarray(values)
if arr.size == 0:
return depth, np.zeros((n,), dtype=np.float32)
if np.iscomplexobj(arr):
src = np.abs(arr)
else:
src = np.abs(np.nan_to_num(arr, nan=0.0, posinf=0.0, neginf=0.0))
src = np.asarray(src, dtype=np.float32).ravel()
out = np.zeros((n,), dtype=np.float32)
take = min(n, src.size)
if take > 0:
out[:take] = src[:take]
return depth, out
def _normalize_complex_mode(mode: str) -> str:
m = str(mode).strip().lower()
if m not in _VALID_COMPLEX_MODES:
raise ValueError(f"Invalid complex reconstruction mode: {mode!r}")
return m
def build_ifft_time_axis_ns() -> np.ndarray:
"""Legacy helper: старая временная ось IFFT в наносекундах (фиксированная длина)."""
return (
np.arange(IFFT_LEN, dtype=np.float64) / (FREQ_SPAN_GHZ * 1e9) * 1e9
).astype(np.float32)
def build_frequency_axis_hz(sweep_width: int) -> np.ndarray:
"""Построить частотную сетку (Гц) для текущей длины свипа."""
n = int(sweep_width)
if n <= 0:
return np.zeros((0,), dtype=np.float64)
if n == 1:
return np.array([FREQ_MIN_GHZ * 1e9], dtype=np.float64)
return np.linspace(FREQ_MIN_GHZ * 1e9, FREQ_MAX_GHZ * 1e9, n, dtype=np.float64)
def normalize_trace_unit_range(x: np.ndarray) -> np.ndarray:
"""Signed-нормировка массива по max(abs(.)) в диапазон около [-1, 1]."""
arr = np.asarray(x, dtype=np.float64).ravel()
if arr.size == 0:
return arr
arr = np.nan_to_num(arr, nan=0.0, posinf=0.0, neginf=0.0)
amax = float(np.max(np.abs(arr)))
if (not np.isfinite(amax)) or amax <= _EPS:
return np.zeros_like(arr, dtype=np.float64)
return arr / amax
def normalize_sweep_for_phase(sweep: np.ndarray) -> np.ndarray:
"""Совместимый alias: нормировка свипа перед восстановлением фазы."""
return normalize_trace_unit_range(sweep)
def unwrap_arccos_phase_continuous(x_norm: np.ndarray) -> np.ndarray:
"""Непрерывно развернуть фазу, восстановленную через arccos.
Для каждой точки рассматриваются ветви ±phi + 2πk и выбирается кандидат,
ближайший к предыдущей фазе (nearest continuous).
"""
x = np.asarray(x_norm, dtype=np.float64).ravel()
if x.size == 0:
return np.zeros((0,), dtype=np.float64)
x = np.nan_to_num(x, nan=0.0, posinf=1.0, neginf=-1.0)
x = np.clip(x, -1.0, 1.0)
phi0 = np.arccos(x)
out = np.empty_like(phi0, dtype=np.float64)
out[0] = float(phi0[0])
for i in range(1, phi0.size):
base_phi = float(phi0[i])
prev = float(out[i - 1])
best_cand: Optional[float] = None
best_key: Optional[tuple[float, float]] = None
for sign in (1.0, -1.0):
base = sign * base_phi
k_center = int(np.round((prev - base) / _TWO_PI))
for k in (k_center - 1, k_center, k_center + 1):
cand = base + _TWO_PI * float(k)
step = abs(cand - prev)
# Tie-break: при равенстве шага предпочесть больший кандидат.
key = (step, -cand)
if best_key is None or key < best_key:
best_key = key
best_cand = cand
out[i] = prev if best_cand is None else float(best_cand)
return out
def reconstruct_complex_spectrum_arccos(sweep: np.ndarray) -> np.ndarray:
"""Режим arccos: cos(phi) -> phi -> exp(i*phi)."""
x_norm = normalize_trace_unit_range(sweep)
if x_norm.size == 0:
return np.zeros((0,), dtype=np.complex128)
phi = unwrap_arccos_phase_continuous(np.clip(x_norm, -1.0, 1.0))
return np.exp(1j * phi).astype(np.complex128, copy=False)
def reconstruct_complex_spectrum_diff(sweep: np.ndarray) -> np.ndarray:
"""Режим diff: x~=cos(phi), diff(x)->sin(phi), z=cos+i*sin с проекцией на единичную окружность."""
cos_phi = normalize_trace_unit_range(sweep)
if cos_phi.size == 0:
return np.zeros((0,), dtype=np.complex128)
cos_phi = np.clip(cos_phi, -1.0, 1.0)
if cos_phi.size < 2:
sin_est = np.zeros_like(cos_phi, dtype=np.float64)
else:
d = np.gradient(cos_phi)
sin_est = normalize_trace_unit_range(d)
sin_est = np.clip(sin_est, -1.0, 1.0)
sin_est = normalize_trace_unit_range(d)
# mag = np.abs(sin_est)
# mask = mag > _EPS
# if np.any(mask):
# sin_est[mask] = sin_est[mask] / mag[mask]
z = cos_phi.astype(np.complex128, copy=False) + 1j * sin_est.astype(np.complex128, copy=False)
mag = np.abs(z)
z_unit = np.ones_like(z, dtype=np.complex128)
mask = mag > _EPS
if np.any(mask):
z_unit[mask] = z[mask] / mag[mask]
return z_unit
def reconstruct_complex_spectrum_from_real_trace(
sweep: np.ndarray,
*,
complex_mode: str = "arccos",
) -> np.ndarray:
"""Восстановить комплексный спектр из вещественного свипа в выбранном режиме."""
mode = _normalize_complex_mode(complex_mode)
if mode == "arccos":
return reconstruct_complex_spectrum_arccos(sweep)
if mode == "diff":
return reconstruct_complex_spectrum_diff(sweep)
raise ValueError(f"Unsupported complex reconstruction mode: {complex_mode!r}")
def perform_ifft_depth_response(
s_array: np.ndarray,
frequencies_hz: np.ndarray,
*,
axis: str = "abs",
start_hz: float | None = None,
stop_hz: float | None = None,
) -> tuple[np.ndarray, np.ndarray]:
"""Frequency-to-depth conversion with zero-padding and frequency offset handling."""
try:
s_in = np.asarray(s_array, dtype=np.complex128).ravel()
f_in = np.asarray(frequencies_hz, dtype=np.float64).ravel()
m = min(s_in.size, f_in.size)
if m < 2:
raise ValueError("Not enough points")
s = s_in[:m]
f = f_in[:m]
lo = float(FREQ_MIN_GHZ * 1e9 if start_hz is None else start_hz)
hi = float(FREQ_MAX_GHZ * 1e9 if stop_hz is None else stop_hz)
if hi < lo:
lo, hi = hi, lo
mask = (
np.isfinite(f)
& np.isfinite(np.real(s))
& np.isfinite(np.imag(s))
& (f >= lo)
& (f <= hi)
)
f = f[mask]
s = s[mask]
n = int(f.size)
if n < 2:
raise ValueError("Not enough frequency points after filtering")
if np.any(np.diff(f) <= 0.0):
raise ValueError("Non-increasing frequency grid")
df = float((f[-1] - f[0]) / (n - 1))
if not np.isfinite(df) or df <= 0.0:
raise ValueError("Invalid frequency step")
k0 = int(np.round(float(f[0]) / df))
if k0 < 0:
raise ValueError("Negative frequency offset index")
min_len = int(2 * (k0 + n - 1))
if min_len <= 0:
raise ValueError("Invalid FFT length")
n_fft = 1 << int(np.ceil(np.log2(float(min_len))))
dt = 1.0 / (n_fft * df)
t_sec = np.arange(n_fft, dtype=np.float64) * dt
h = np.zeros((n_fft,), dtype=np.complex128)
end = k0 + n
if end > n_fft:
raise ValueError("Spectrum placement exceeds FFT buffer")
h[k0:end] = s
y = np.fft.ifft(h)
depth_m = t_sec * SPEED_OF_LIGHT_M_S
axis_name = str(axis).strip().lower()
if axis_name == "abs":
y_fin = np.abs(y)
elif axis_name == "real":
y_fin = np.real(y)
elif axis_name == "imag":
y_fin = np.imag(y)
elif axis_name == "phase":
y_fin = np.angle(y)
else:
raise ValueError(f"Invalid axis parameter: {axis!r}")
return depth_m.astype(np.float32, copy=False), np.asarray(y_fin, dtype=np.float32)
except Exception as exc: # noqa: BLE001
logger.error("IFFT depth response failed: %r", exc)
return _fallback_depth_response(np.asarray(s_array).size, np.asarray(s_array))
def compute_ifft_profile_from_sweep(
sweep: Optional[np.ndarray],
*,
complex_mode: str = "arccos",
) -> tuple[np.ndarray, np.ndarray]:
"""Высокоуровневый pipeline: sweep -> complex spectrum -> IFFT(abs) depth profile."""
if sweep is None:
return _fallback_depth_response(1, None)
try:
s = np.asarray(sweep, dtype=np.float64).ravel()
if s.size == 0:
return _fallback_depth_response(1, None)
freqs_hz = build_frequency_axis_hz(s.size)
s_complex = reconstruct_complex_spectrum_from_real_trace(s, complex_mode=complex_mode)
depth_m, y = perform_ifft_depth_response(s_complex, freqs_hz, axis="abs")
n = min(depth_m.size, y.size)
if n <= 0:
return _fallback_depth_response(s.size, s)
return depth_m[:n].astype(np.float32, copy=False), np.maximum(y[:n], 1e-12).astype(np.float32, copy=False) # log10 для лучшей визуализации в водопаде
except Exception as exc: # noqa: BLE001
logger.error("compute_ifft_profile_from_sweep failed: %r", exc)
return _fallback_depth_response(np.asarray(sweep).size if sweep is not None else 1, sweep)
def compute_ifft_db_profile(sweep: Optional[np.ndarray]) -> np.ndarray:
"""Legacy wrapper (deprecated name): возвращает линейный |IFFT| профиль."""
_depth_m, y = compute_ifft_profile_from_sweep(sweep, complex_mode="arccos")
return y

230
rfg_adc_plotter/processing/normalization.py
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"""Sweep normalization helpers."""
from __future__ import annotations
from typing import Tuple
import numpy as np
def normalize_sweep_simple(raw: np.ndarray, calib: np.ndarray) -> np.ndarray:
"""Simple element-wise raw/calib normalization."""
width = min(raw.size, calib.size)
if width <= 0:
return raw
out = np.full_like(raw, np.nan, dtype=np.float32)
with np.errstate(divide="ignore", invalid="ignore"):
out[:width] = raw[:width] / calib[:width]
out = np.nan_to_num(out, nan=np.nan, posinf=np.nan, neginf=np.nan)
return out
def build_calib_envelopes(calib: np.ndarray) -> Tuple[np.ndarray, np.ndarray]:
"""Estimate smooth lower/upper envelopes from local extrema."""
n = int(calib.size)
if n <= 0:
empty = np.zeros((0,), dtype=np.float32)
return empty, empty
values = np.asarray(calib, dtype=np.float32)
finite = np.isfinite(values)
if not np.any(finite):
zeros = np.zeros_like(values, dtype=np.float32)
return zeros, zeros
if not np.all(finite):
x = np.arange(n, dtype=np.float32)
values = values.copy()
values[~finite] = np.interp(x[~finite], x[finite], values[finite]).astype(np.float32)
if n < 3:
return values.copy(), values.copy()
x = np.arange(n, dtype=np.float32)
def _moving_average(series: np.ndarray, window: int) -> np.ndarray:
width = max(1, int(window))
if width <= 1 or series.size <= 2:
return np.asarray(series, dtype=np.float32).copy()
if width % 2 == 0:
width += 1
pad = width // 2
padded = np.pad(np.asarray(series, dtype=np.float32), (pad, pad), mode="edge")
kernel = np.full((width,), 1.0 / float(width), dtype=np.float32)
return np.convolve(padded, kernel, mode="valid").astype(np.float32)
def _smooth_extrema_envelope(use_max: bool) -> np.ndarray:
step = max(3, n // 32)
node_idx_list = []
for start in range(0, n, step):
stop = min(n, start + step)
segment = values[start:stop]
idx_rel = int(np.argmax(segment) if use_max else np.argmin(segment))
node_idx_list.append(start + idx_rel)
extrema_idx = np.unique(np.asarray(node_idx_list, dtype=np.int64))
if extrema_idx.size == 0:
extrema_idx = np.asarray([int(np.argmax(values) if use_max else np.argmin(values))], dtype=np.int64)
node_idx = np.unique(np.concatenate(([0], extrema_idx, [n - 1]))).astype(np.int64)
node_vals = values[node_idx].astype(np.float32, copy=True)
node_vals[0] = float(values[extrema_idx[0]])
node_vals[-1] = float(values[extrema_idx[-1]])
node_vals = _moving_average(node_vals, 3)
node_vals[0] = float(values[extrema_idx[0]])
node_vals[-1] = float(values[extrema_idx[-1]])
envelope = np.interp(x, node_idx.astype(np.float32), node_vals).astype(np.float32)
smooth_window = max(1, n // 64)
if smooth_window > 1:
envelope = _moving_average(envelope, smooth_window)
return envelope
upper = _smooth_extrema_envelope(use_max=True)
lower = _smooth_extrema_envelope(use_max=False)
swap = lower > upper
if np.any(swap):
tmp = upper[swap].copy()
upper[swap] = lower[swap]
lower[swap] = tmp
return lower, upper
def normalize_sweep_projector(raw: np.ndarray, calib: np.ndarray) -> np.ndarray:
"""Project raw values between calibration envelopes into [-1000, 1000]."""
width = min(raw.size, calib.size)
if width <= 0:
return raw
out = np.full_like(raw, np.nan, dtype=np.float32)
raw_seg = np.asarray(raw[:width], dtype=np.float32)
lower, upper = build_calib_envelopes(np.asarray(calib[:width], dtype=np.float32))
span = upper - lower
finite_span = span[np.isfinite(span) & (span > 0)]
if finite_span.size > 0:
eps = max(float(np.median(finite_span)) * 1e-6, 1e-9)
else:
eps = 1e-9
valid = (
np.isfinite(raw_seg)
& np.isfinite(lower)
& np.isfinite(upper)
& (span > eps)
)
if np.any(valid):
proj = np.empty_like(raw_seg, dtype=np.float32)
proj[valid] = ((2.0 * (raw_seg[valid] - lower[valid]) / span[valid]) - 1.0) * 1000.0
proj[valid] = np.clip(proj[valid], -1000.0, 1000.0)
proj[~valid] = np.nan
out[:width] = proj
return out
def resample_envelope(envelope: np.ndarray, width: int) -> np.ndarray:
"""Resample an envelope to the target sweep width on the index axis."""
target_width = int(width)
if target_width <= 0:
return np.zeros((0,), dtype=np.float32)
values = np.asarray(envelope, dtype=np.float32).reshape(-1)
if values.size == 0:
return np.full((target_width,), np.nan, dtype=np.float32)
if values.size == target_width:
return values.astype(np.float32, copy=True)
x_src = np.arange(values.size, dtype=np.float32)
finite = np.isfinite(values)
if not np.any(finite):
return np.full((target_width,), np.nan, dtype=np.float32)
if int(np.count_nonzero(finite)) == 1:
fill = float(values[finite][0])
return np.full((target_width,), fill, dtype=np.float32)
x_dst = np.linspace(0.0, float(values.size - 1), target_width, dtype=np.float32)
return np.interp(x_dst, x_src[finite], values[finite]).astype(np.float32)
def fit_complex_calibration_to_width(calib: np.ndarray, width: int) -> np.ndarray:
"""Fit a complex calibration curve to the signal width via trim/pad with ones."""
target_width = int(width)
if target_width <= 0:
return np.zeros((0,), dtype=np.complex64)
values = np.asarray(calib, dtype=np.complex64).reshape(-1)
if values.size <= 0:
return np.ones((target_width,), dtype=np.complex64)
if values.size == target_width:
return values.astype(np.complex64, copy=True)
if values.size > target_width:
return np.asarray(values[:target_width], dtype=np.complex64)
out = np.ones((target_width,), dtype=np.complex64)
out[: values.size] = values
return out
def normalize_by_complex_calibration(
signal: np.ndarray,
calib: np.ndarray,
eps: float = 1e-9,
) -> np.ndarray:
"""Normalize complex signal by a complex calibration curve with zero protection."""
sig_arr = np.asarray(signal, dtype=np.complex64).reshape(-1)
if sig_arr.size <= 0:
return sig_arr.copy()
calib_fit = fit_complex_calibration_to_width(calib, sig_arr.size)
eps_abs = max(abs(float(eps)), 1e-12)
denom = np.asarray(calib_fit, dtype=np.complex64).copy()
safe_denom = (
np.isfinite(denom.real)
& np.isfinite(denom.imag)
& (np.abs(denom) >= eps_abs)
)
if np.any(~safe_denom):
denom[~safe_denom] = np.complex64(1.0 + 0.0j)
out = np.full(sig_arr.shape, np.nan + 0j, dtype=np.complex64)
valid_sig = np.isfinite(sig_arr.real) & np.isfinite(sig_arr.imag)
if np.any(valid_sig):
with np.errstate(divide="ignore", invalid="ignore"):
out[valid_sig] = sig_arr[valid_sig] / denom[valid_sig]
out_real = np.nan_to_num(out.real, nan=np.nan, posinf=np.nan, neginf=np.nan)
out_imag = np.nan_to_num(out.imag, nan=np.nan, posinf=np.nan, neginf=np.nan)
return (out_real + (1j * out_imag)).astype(np.complex64, copy=False)
def normalize_by_envelope(raw: np.ndarray, envelope: np.ndarray) -> np.ndarray:
"""Normalize a sweep by an envelope with safe resampling and zero protection."""
raw_in = np.asarray(raw).reshape(-1)
raw_dtype = np.complex64 if np.iscomplexobj(raw_in) else np.float32
raw_arr = np.asarray(raw_in, dtype=raw_dtype).reshape(-1)
if raw_arr.size == 0:
return raw_arr.copy()
env = resample_envelope(envelope, raw_arr.size)
out = np.full(raw_arr.shape, np.nan + 0j if np.iscomplexobj(raw_arr) else np.nan, dtype=raw_dtype)
den_eps = np.float32(1e-9)
valid = np.isfinite(raw_arr) & np.isfinite(env)
if np.any(valid):
with np.errstate(divide="ignore", invalid="ignore"):
denom = env[valid] + np.where(env[valid] >= 0.0, den_eps, -den_eps)
out[valid] = raw_arr[valid] / denom
if np.iscomplexobj(out):
out_real = np.nan_to_num(out.real, nan=np.nan, posinf=np.nan, neginf=np.nan)
out_imag = np.nan_to_num(out.imag, nan=np.nan, posinf=np.nan, neginf=np.nan)
return (out_real + (1j * out_imag)).astype(np.complex64, copy=False)
return np.nan_to_num(out, nan=np.nan, posinf=np.nan, neginf=np.nan)
def normalize_by_calib(raw: np.ndarray, calib: np.ndarray, norm_type: str) -> np.ndarray:
"""Apply the selected normalization method."""
norm = str(norm_type).strip().lower()
if norm == "simple":
return normalize_sweep_simple(raw, calib)
return normalize_sweep_projector(raw, calib)

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rfg_adc_plotter/processing/normalizer.py Normal file
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"""Алгоритмы нормировки свипов по калибровочной кривой."""
from typing import Tuple
import numpy as np
def normalize_simple(raw: np.ndarray, calib: np.ndarray) -> np.ndarray:
"""Простая нормировка: поэлементное деление raw/calib."""
w = min(raw.size, calib.size)
if w <= 0:
return raw
out = np.full_like(raw, np.nan, dtype=np.float32)
with np.errstate(divide="ignore", invalid="ignore"):
out[:w] = raw[:w] / calib[:w]
out = np.nan_to_num(out, nan=np.nan, posinf=np.nan, neginf=np.nan)
return out
def build_calib_envelopes(calib: np.ndarray) -> Tuple[np.ndarray, np.ndarray]:
"""Оценить огибающую по модулю сигнала.
Возвращает (lower, upper) = (-envelope, +envelope), где envelope —
интерполяция через локальные максимумы |calib|.
"""
n = int(calib.size)
if n <= 0:
empty = np.zeros((0,), dtype=np.float32)
return empty, empty
y = np.asarray(calib, dtype=np.float32)
finite = np.isfinite(y)
if not np.any(finite):
zeros = np.zeros_like(y, dtype=np.float32)
return zeros, zeros
if not np.all(finite):
x = np.arange(n, dtype=np.float32)
y = y.copy()
y[~finite] = np.interp(x[~finite], x[finite], y[finite]).astype(np.float32)
a = np.abs(y)
if n < 3:
env = a.copy()
return -env, env
da = np.diff(a)
s = np.sign(da).astype(np.int8, copy=False)
if np.any(s == 0):
for i in range(1, s.size):
if s[i] == 0:
s[i] = s[i - 1]
for i in range(s.size - 2, -1, -1):
if s[i] == 0:
s[i] = s[i + 1]
s[s == 0] = 1
max_idx = np.where((s[:-1] > 0) & (s[1:] < 0))[0] + 1
x = np.arange(n, dtype=np.float32)
if max_idx.size == 0:
idx = np.array([0, n - 1], dtype=np.int64)
else:
idx = np.unique(np.concatenate(([0], max_idx, [n - 1]))).astype(np.int64)
env = np.interp(x, idx.astype(np.float32), a[idx]).astype(np.float32)
return -env, env
def normalize_projector(raw: np.ndarray, calib: np.ndarray) -> np.ndarray:
"""Нормировка через проекцию между огибающими калибровки в диапазон [-1000, +1000]."""
w = min(raw.size, calib.size)
if w <= 0:
return raw
out = np.full_like(raw, np.nan, dtype=np.float32)
raw_seg = np.asarray(raw[:w], dtype=np.float32)
lower, upper = build_calib_envelopes(np.asarray(calib[:w], dtype=np.float32))
span = upper - lower
finite_span = span[np.isfinite(span) & (span > 0)]
if finite_span.size > 0:
eps = max(float(np.median(finite_span)) * 1e-6, 1e-9)
else:
eps = 1e-9
valid = (
np.isfinite(raw_seg)
& np.isfinite(lower)
& np.isfinite(upper)
& (span > eps)
)
if np.any(valid):
proj = np.empty_like(raw_seg, dtype=np.float32)
proj[valid] = ((2.0 * (raw_seg[valid] - lower[valid]) / span[valid]) - 1.0) * 1000.0
proj[valid] = np.clip(proj[valid], -1000.0, 1000.0)
proj[~valid] = np.nan
out[:w] = proj
return out
def normalize_by_calib(raw: np.ndarray, calib: np.ndarray, norm_type: str) -> np.ndarray:
"""Нормировка свипа по выбранному алгоритму."""
nt = str(norm_type).strip().lower()
if nt == "simple":
return normalize_simple(raw, calib)
return normalize_projector(raw, calib)
def normalize_by_envelope(raw: np.ndarray, envelope: np.ndarray) -> np.ndarray:
"""Нормировка свипа через проекцию на огибающую из файла.
Воспроизводит логику normalize_projector: проецирует raw в [-1000, +1000]
используя готовую верхнюю огибающую (upper = envelope, lower = -envelope).
"""
w = min(raw.size, envelope.size)
if w <= 0:
return raw
out = np.full_like(raw, np.nan, dtype=np.float32)
raw_seg = np.asarray(raw[:w], dtype=np.float32)
upper = np.asarray(envelope[:w], dtype=np.float32)
lower = -upper
span = upper - lower # = 2 * upper
finite_span = span[np.isfinite(span) & (span > 0)]
if finite_span.size > 0:
eps = max(float(np.median(finite_span)) * 1e-6, 1e-9)
else:
eps = 1e-9
valid = (
np.isfinite(raw_seg)
& np.isfinite(lower)
& np.isfinite(upper)
& (span > eps)
)
if np.any(valid):
proj = np.empty_like(raw_seg, dtype=np.float32)
proj[valid] = ((2.0 * (raw_seg[valid] - lower[valid]) / span[valid]) - 1.0) * 1000.0
proj[valid] = np.clip(proj[valid], -1000.0, 1000.0)
proj[~valid] = np.nan
out[:w] = proj
return out

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rfg_adc_plotter/processing/peaks.py
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"""Peak-search helpers for FFT visualizations."""
from __future__ import annotations
from typing import Dict, List, Optional
import numpy as np
def find_peak_width_markers(xs: np.ndarray, ys: np.ndarray) -> Optional[Dict[str, float]]:
"""Find the dominant non-zero peak and its half-height width."""
x_arr = np.asarray(xs, dtype=np.float64)
y_arr = np.asarray(ys, dtype=np.float64)
valid = np.isfinite(x_arr) & np.isfinite(y_arr) & (x_arr > 0.0)
if int(np.count_nonzero(valid)) < 3:
return None
x = x_arr[valid]
y = y_arr[valid]
x_min = float(x[0])
x_max = float(x[-1])
x_span = x_max - x_min
central_mask = (x >= (x_min + 0.25 * x_span)) & (x <= (x_min + 0.75 * x_span))
if int(np.count_nonzero(central_mask)) > 0:
central_idx = np.flatnonzero(central_mask)
peak_idx = int(central_idx[int(np.argmax(y[central_mask]))])
else:
peak_idx = int(np.argmax(y))
peak_y = float(y[peak_idx])
shoulder_gap = max(1, min(8, y.size // 64 if y.size > 0 else 1))
shoulder_width = max(4, min(32, y.size // 16 if y.size > 0 else 4))
left_lo = max(0, peak_idx - shoulder_gap - shoulder_width)
left_hi = max(0, peak_idx - shoulder_gap)
right_lo = min(y.size, peak_idx + shoulder_gap + 1)
right_hi = min(y.size, right_lo + shoulder_width)
background_parts = []
if left_hi > left_lo:
background_parts.append(float(np.nanmedian(y[left_lo:left_hi])))
if right_hi > right_lo:
background_parts.append(float(np.nanmedian(y[right_lo:right_hi])))
if background_parts:
background = float(np.mean(background_parts))
else:
background = float(np.nanpercentile(y, 10))
if not np.isfinite(peak_y) or not np.isfinite(background) or peak_y <= background:
return None
half_level = background + 0.5 * (peak_y - background)
def _interp_cross(x0: float, y0: float, x1: float, y1: float) -> float:
if not (np.isfinite(x0) and np.isfinite(y0) and np.isfinite(x1) and np.isfinite(y1)):
return x1
dy = y1 - y0
if dy == 0.0:
return x1
t = (half_level - y0) / dy
t = min(1.0, max(0.0, t))
return x0 + t * (x1 - x0)
left_x = float(x[0])
for i in range(peak_idx, 0, -1):
if y[i - 1] <= half_level <= y[i]:
left_x = _interp_cross(float(x[i - 1]), float(y[i - 1]), float(x[i]), float(y[i]))
break
right_x = float(x[-1])
for i in range(peak_idx, x.size - 1):
if y[i] >= half_level >= y[i + 1]:
right_x = _interp_cross(float(x[i]), float(y[i]), float(x[i + 1]), float(y[i + 1]))
break
width = right_x - left_x
if not np.isfinite(width) or width <= 0.0:
return None
return {
"background": background,
"left": left_x,
"right": right_x,
"width": width,
"amplitude": peak_y,
}
def rolling_median_ref(xs: np.ndarray, ys: np.ndarray, window_ghz: float) -> np.ndarray:
"""Compute a rolling median reference on a fixed-width X window."""
x = np.asarray(xs, dtype=np.float64)
y = np.asarray(ys, dtype=np.float64)
out = np.full(y.shape, np.nan, dtype=np.float64)
if x.size == 0 or y.size == 0 or x.size != y.size:
return out
width = float(window_ghz)
if not np.isfinite(width) or width <= 0.0:
return out
half = 0.5 * width
for i in range(x.size):
xi = x[i]
if not np.isfinite(xi):
continue
left = np.searchsorted(x, xi - half, side="left")
right = np.searchsorted(x, xi + half, side="right")
if right <= left:
continue
segment = y[left:right]
finite = np.isfinite(segment)
if not np.any(finite):
continue
out[i] = float(np.nanmedian(segment))
return out
def find_top_peaks_over_ref(
xs: np.ndarray,
ys: np.ndarray,
ref: np.ndarray,
top_n: int = 3,
) -> List[Dict[str, float]]:
"""Find the top-N non-overlapping peaks above a reference curve."""
x = np.asarray(xs, dtype=np.float64)
y = np.asarray(ys, dtype=np.float64)
r = np.asarray(ref, dtype=np.float64)
if x.size < 3 or y.size != x.size or r.size != x.size:
return []
valid = np.isfinite(x) & np.isfinite(y) & np.isfinite(r)
if not np.any(valid):
return []
delta = np.full_like(y, np.nan, dtype=np.float64)
delta[valid] = y[valid] - r[valid]
candidates: List[int] = []
for i in range(1, x.size - 1):
if not (np.isfinite(delta[i - 1]) and np.isfinite(delta[i]) and np.isfinite(delta[i + 1])):
continue
if delta[i] <= 0.0:
continue
left_ok = delta[i] > delta[i - 1]
right_ok = delta[i] >= delta[i + 1]
alt_left_ok = delta[i] >= delta[i - 1]
alt_right_ok = delta[i] > delta[i + 1]
if (left_ok and right_ok) or (alt_left_ok and alt_right_ok):
candidates.append(i)
if not candidates:
return []
candidates.sort(key=lambda i: float(delta[i]), reverse=True)
def _interp_cross(x0: float, y0: float, x1: float, y1: float, y_cross: float) -> float:
dy = y1 - y0
if not np.isfinite(dy) or dy == 0.0:
return x1
t = (y_cross - y0) / dy
t = min(1.0, max(0.0, t))
return x0 + t * (x1 - x0)
picked: List[Dict[str, float]] = []
for idx in candidates:
peak_y = float(y[idx])
peak_ref = float(r[idx])
peak_h = float(delta[idx])
if not (np.isfinite(peak_y) and np.isfinite(peak_ref) and np.isfinite(peak_h)) or peak_h <= 0.0:
continue
half_level = peak_ref + 0.5 * peak_h
left_x = float(x[0])
for i in range(idx, 0, -1):
y0 = float(y[i - 1])
y1 = float(y[i])
if np.isfinite(y0) and np.isfinite(y1) and (y0 <= half_level <= y1):
left_x = _interp_cross(float(x[i - 1]), y0, float(x[i]), y1, half_level)
break
right_x = float(x[-1])
for i in range(idx, x.size - 1):
y0 = float(y[i])
y1 = float(y[i + 1])
if np.isfinite(y0) and np.isfinite(y1) and (y0 >= half_level >= y1):
right_x = _interp_cross(float(x[i]), y0, float(x[i + 1]), y1, half_level)
break
width = float(right_x - left_x)
if not np.isfinite(width) or width <= 0.0:
continue
overlap = False
for peak in picked:
if not (right_x <= peak["left"] or left_x >= peak["right"]):
overlap = True
break
if overlap:
continue
picked.append(
{
"x": float(x[idx]),
"peak_y": peak_y,
"ref": peak_ref,
"height": peak_h,
"left": left_x,
"right": right_x,
"width": width,
}
)
if len(picked) >= int(max(1, top_n)):
break
picked.sort(key=lambda peak: peak["x"])
return picked

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"""Явный pipeline предобработки свипов перед помещением в RingBuffer."""
from __future__ import annotations
from dataclasses import dataclass
import os
from typing import Optional, Tuple
import numpy as np
from rfg_adc_plotter.io.capture_reference_loader import (
CaptureParseSummary,
aggregate_capture_reference,
detect_reference_file_format,
load_capture_sweeps,
)
from rfg_adc_plotter.processing.normalizer import (
build_calib_envelopes,
normalize_by_calib,
normalize_by_envelope,
)
DEFAULT_CALIB_ENVELOPE_PATH = "calib_envelope.npy"
DEFAULT_BACKGROUND_PATH = "background.npy"
def _normalize_path(path: str) -> str:
return str(path).strip()
def _normalize_save_npy_path(path: str) -> str:
p = _normalize_path(path)
if not p:
return p
_root, ext = os.path.splitext(p)
if ext:
return p
return f"{p}.npy"
def _summary_for_npy(path: str) -> CaptureParseSummary:
return CaptureParseSummary(
path=path,
format="npy",
sweeps_total=0,
sweeps_valid=0,
channels_seen=tuple(),
dominant_width=None,
dominant_n_valid=None,
aggregation="median",
warnings=tuple(),
)
@dataclass(frozen=True)
class SweepProcessingResult:
"""Результат предобработки одного свипа."""
processed_sweep: np.ndarray
normalized_sweep: Optional[np.ndarray]
calibration_applied: bool
background_applied: bool
calibration_source: str # off|live|npy|capture
background_source: str # off|npy|capture(raw)|capture(raw->calib)
is_calibration_reference: bool
stage_trace: Tuple[str, ...]
class SweepPreprocessor:
"""Управляет калибровкой/фоном и применяет их к входному свипу."""
def __init__(
self,
norm_type: str = "projector",
calib_envelope_path: str = DEFAULT_CALIB_ENVELOPE_PATH,
background_path: str = DEFAULT_BACKGROUND_PATH,
auto_save_live_calib_envelope: bool = True,
):
self.norm_type = str(norm_type).strip().lower() or "projector"
self.calib_enabled = False
self.calib_mode = "live" # live | file
self.background_enabled = False
self.auto_save_live_calib_envelope = bool(auto_save_live_calib_envelope)
self.calib_envelope_path = _normalize_path(calib_envelope_path)
self.background_path = _normalize_path(background_path)
self.last_calib_sweep: Optional[np.ndarray] = None
self.calib_file_envelope: Optional[np.ndarray] = None
# background — в текущем домене вычитания (raw или normalized), UI использует для preview/state
self.background: Optional[np.ndarray] = None
# raw background loaded from capture file; преобразуется на лету при активной калибровке
self.background_raw_capture: Optional[np.ndarray] = None
# Источники и метаданные загрузки
self.calib_external_source_type: str = "none" # none|npy|capture
self.background_source_type: str = "none" # none|npy_processed|capture_raw
self.calib_reference_summary: Optional[CaptureParseSummary] = None
self.background_reference_summary: Optional[CaptureParseSummary] = None
self.last_reference_error: str = ""
# Параметры офлайн-парсинга capture (должны совпадать с live parser по настройке UI)
self.capture_fancy: bool = False
self.capture_logscale: bool = False
self.reference_aggregation_method: str = "median"
# ---- Конфигурация ----
def set_calib_mode(self, mode: str):
m = str(mode).strip().lower()
self.calib_mode = "file" if m == "file" else "live"
def set_calib_enabled(self, enabled: bool):
self.calib_enabled = bool(enabled)
def set_background_enabled(self, enabled: bool):
self.background_enabled = bool(enabled)
def set_capture_parse_options(self, *, fancy: Optional[bool] = None, logscale: Optional[bool] = None):
if fancy is not None:
self.capture_fancy = bool(fancy)
if logscale is not None:
self.capture_logscale = bool(logscale)
def set_calib_envelope_path(self, path: str):
p = _normalize_path(path)
if p:
if p != self.calib_envelope_path:
self.calib_file_envelope = None
if self.calib_external_source_type in ("npy", "capture"):
self.calib_external_source_type = "none"
self.calib_reference_summary = None
self.calib_envelope_path = p
def set_background_path(self, path: str):
p = _normalize_path(path)
if p:
if p != self.background_path:
self.background = None
self.background_raw_capture = None
self.background_source_type = "none"
self.background_reference_summary = None
self.background_path = p
def has_calib_envelope_file(self) -> bool:
return bool(self.calib_envelope_path) and os.path.isfile(self.calib_envelope_path)
def has_background_file(self) -> bool:
return bool(self.background_path) and os.path.isfile(self.background_path)
# ---- Загрузка/сохранение .npy ----
def _save_array(self, arr: np.ndarray, current_path: str, path: Optional[str]) -> str:
target = _normalize_save_npy_path(path if path is not None else current_path)
if not target:
raise ValueError("Пустой путь сохранения")
np.save(target, arr)
return target
def save_calib_envelope(self, path: Optional[str] = None) -> bool:
"""Сохранить огибающую из последнего live-калибровочного свипа (экспорт .npy)."""
if self.last_calib_sweep is None:
return False
try:
_lower, upper = build_calib_envelopes(self.last_calib_sweep)
self.calib_envelope_path = self._save_array(upper, self.calib_envelope_path, path)
self.last_reference_error = ""
return True
except Exception as exc:
self.last_reference_error = f"save calib envelope failed: {exc}"
return False
def save_background(self, sweep_for_ring: Optional[np.ndarray], path: Optional[str] = None) -> bool:
"""Сохранить текущий свип (в текущем домене обработки) как .npy-фон."""
if sweep_for_ring is None:
return False
try:
bg = np.asarray(sweep_for_ring, dtype=np.float32).copy()
self.background_path = self._save_array(bg, self.background_path, path)
self.background = bg
self.background_raw_capture = None
self.background_source_type = "npy_processed"
self.background_reference_summary = _summary_for_npy(self.background_path)
self.last_reference_error = ""
return True
except Exception as exc:
self.last_reference_error = f"save background failed: {exc}"
return False
# ---- Загрузка эталонов (.npy или capture) ----
def _detect_source_kind(self, path: str, source_kind: str) -> Optional[str]:
sk = str(source_kind).strip().lower() or "auto"
if sk == "auto":
return detect_reference_file_format(path)
if sk in ("npy", "bin_capture", "capture"):
return "bin_capture" if sk == "capture" else sk
return None
def _load_npy_vector(self, path: str) -> np.ndarray:
arr = np.load(path)
return np.asarray(arr, dtype=np.float32).reshape(-1)
def load_calib_reference(
self,
path: Optional[str] = None,
*,
source_kind: str = "auto",
method: str = "median",
) -> bool:
"""Загрузить калибровку из .npy (огибающая) или raw capture файла."""
if path is not None:
self.set_calib_envelope_path(path)
p = self.calib_envelope_path
if not p or not os.path.isfile(p):
self.last_reference_error = f"Файл калибровки не найден: {p}"
return False
fmt = self._detect_source_kind(p, source_kind)
if fmt is None:
self.last_reference_error = f"Неизвестный формат файла калибровки: {p}"
return False
try:
if fmt == "npy":
env = self._load_npy_vector(p)
self.calib_file_envelope = env
self.calib_external_source_type = "npy"
self.calib_reference_summary = _summary_for_npy(p)
self.last_reference_error = ""
return True
sweeps = load_capture_sweeps(p, fancy=self.capture_fancy, logscale=self.capture_logscale)
vec, summary = aggregate_capture_reference(
sweeps,
channel=0,
method=method or self.reference_aggregation_method,
path=p,
)
_lower, upper = build_calib_envelopes(vec)
self.calib_file_envelope = np.asarray(upper, dtype=np.float32)
self.calib_external_source_type = "capture"
self.calib_reference_summary = summary
self.last_reference_error = ""
return True
except Exception as exc:
self.last_reference_error = f"Ошибка загрузки калибровки: {exc}"
return False
def load_background_reference(
self,
path: Optional[str] = None,
*,
source_kind: str = "auto",
method: str = "median",
) -> bool:
"""Загрузить фон из .npy (готовый домен) или raw capture файла."""
if path is not None:
self.set_background_path(path)
p = self.background_path
if not p or not os.path.isfile(p):
self.last_reference_error = f"Файл фона не найден: {p}"
return False
fmt = self._detect_source_kind(p, source_kind)
if fmt is None:
self.last_reference_error = f"Неизвестный формат файла фона: {p}"
return False
try:
if fmt == "npy":
bg = self._load_npy_vector(p)
self.background = bg
self.background_raw_capture = None
self.background_source_type = "npy_processed"
self.background_reference_summary = _summary_for_npy(p)
self.last_reference_error = ""
return True
sweeps = load_capture_sweeps(p, fancy=self.capture_fancy, logscale=self.capture_logscale)
vec, summary = aggregate_capture_reference(
sweeps,
channel=0,
method=method or self.reference_aggregation_method,
path=p,
)
self.background_raw_capture = np.asarray(vec, dtype=np.float32)
# Для UI/preview текущий background отражает текущий домен (пока raw по умолчанию).
self.background = self.background_raw_capture
self.background_source_type = "capture_raw"
self.background_reference_summary = summary
self.last_reference_error = ""
return True
except Exception as exc:
self.last_reference_error = f"Ошибка загрузки фона: {exc}"
return False
# Совместимые обертки для старого API (строго .npy)
def load_calib_envelope(self, path: Optional[str] = None) -> bool:
target = path if path is not None else self.calib_envelope_path
return self.load_calib_reference(target, source_kind="npy")
def load_background(self, path: Optional[str] = None) -> bool:
target = path if path is not None else self.background_path
return self.load_background_reference(target, source_kind="npy")
# ---- Нормировка / фон ----
def _normalize_against_active_reference(self, raw: np.ndarray) -> Tuple[Optional[np.ndarray], bool, str]:
if not self.calib_enabled:
return None, False, "off"
if self.calib_mode == "file":
if self.calib_file_envelope is None:
return None, False, "off"
src = "capture" if self.calib_external_source_type == "capture" else "npy"
return normalize_by_envelope(raw, self.calib_file_envelope), True, src
if self.last_calib_sweep is None:
return None, False, "off"
return normalize_by_calib(raw, self.last_calib_sweep, self.norm_type), True, "live"
def _transform_raw_background_for_current_domain(self, calib_applied: bool) -> Optional[np.ndarray]:
if self.background_raw_capture is None:
return None
if not calib_applied:
return self.background_raw_capture
# Порядок pipeline фиксирован: raw -> calibration -> background -> IFFT.
# Поэтому raw-фон из capture нужно привести в тот же домен, что и текущий sweep_for_ring.
if self.calib_mode == "file" and self.calib_file_envelope is not None:
return normalize_by_envelope(self.background_raw_capture, self.calib_file_envelope)
if self.calib_mode == "live" and self.last_calib_sweep is not None:
return normalize_by_calib(self.background_raw_capture, self.last_calib_sweep, self.norm_type)
return None
def _effective_background(self, calib_applied: bool) -> Tuple[Optional[np.ndarray], str]:
if self.background_source_type == "capture_raw":
bg = self._transform_raw_background_for_current_domain(calib_applied)
if bg is None:
return None, "capture(raw->calib:missing-calib)"
self.background = np.asarray(bg, dtype=np.float32)
return self.background, ("capture(raw->calib)" if calib_applied else "capture(raw)")
if self.background_source_type == "npy_processed" and self.background is not None:
return self.background, "npy"
if self.background is not None:
return self.background, "unknown"
return None, "off"
def _subtract_background(self, sweep: np.ndarray, calib_applied: bool) -> Tuple[np.ndarray, bool, str]:
if not self.background_enabled:
return sweep, False, "off"
bg, bg_src = self._effective_background(calib_applied)
if bg is None:
return sweep, False, f"{bg_src}:missing"
out = np.asarray(sweep, dtype=np.float32).copy()
w = min(out.size, bg.size)
if w > 0:
out[:w] -= bg[:w]
return out, True, bg_src
def process(self, sweep: np.ndarray, channel: int, update_references: bool = True) -> SweepProcessingResult:
"""Применить к свипу калибровку/фон и вернуть явные этапы обработки."""
raw = np.asarray(sweep, dtype=np.float32)
ch = int(channel)
if ch == 0:
if update_references:
self.last_calib_sweep = raw
if self.auto_save_live_calib_envelope:
self.save_calib_envelope()
# ch0 всегда остаётся live-калибровочной ссылкой (raw), но при file-калибровке
# можем применять её и к ch0 для отображения/обработки независимо от канала.
calib_applied = False
calib_source = "off"
normalized: Optional[np.ndarray] = None
if self.calib_enabled and self.calib_mode == "file":
normalized, calib_applied, calib_source = self._normalize_against_active_reference(raw)
base = normalized if normalized is not None else raw
processed, bg_applied, bg_source = self._subtract_background(base, calib_applied=calib_applied)
stages = ["parsed_sweep", "raw_sweep", "ch0_live_calibration_reference"]
stages.append(f"calibration_{calib_source}" if calib_applied else "calibration_off")
stages.append(f"background_{bg_source}" if bg_applied else "background_off")
stages.extend(["ring_buffer", "ifft_db"])
return SweepProcessingResult(
processed_sweep=processed,
normalized_sweep=normalized,
calibration_applied=calib_applied,
background_applied=bg_applied,
calibration_source=calib_source if calib_applied else "off",
background_source=bg_source if bg_applied else "off",
is_calibration_reference=True,
stage_trace=tuple(stages),
)
normalized, calib_applied, calib_source = self._normalize_against_active_reference(raw)
base = normalized if normalized is not None else raw
processed, bg_applied, bg_source = self._subtract_background(base, calib_applied)
stages = ["parsed_sweep", "raw_sweep"]
stages.append(f"calibration_{calib_source}" if calib_applied else "calibration_off")
stages.append(f"background_{bg_source}" if bg_applied else "background_off")
stages.extend(["ring_buffer", "ifft_db"])
return SweepProcessingResult(
processed_sweep=processed,
normalized_sweep=normalized,
calibration_applied=calib_applied,
background_applied=bg_applied,
calibration_source=calib_source if calib_applied else "off",
background_source=bg_source if bg_applied else "off",
is_calibration_reference=False,
stage_trace=tuple(stages),
)

7
rfg_adc_plotter/state/__init__.py
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@ -1,7 +0,0 @@
"""Runtime state helpers."""
from rfg_adc_plotter.state.background_buffer import BackgroundMedianBuffer
from rfg_adc_plotter.state.ring_buffer import RingBuffer
from rfg_adc_plotter.state.runtime_state import RuntimeState
__all__ = ["BackgroundMedianBuffer", "RingBuffer", "RuntimeState"]

355
rfg_adc_plotter/state/app_state.py Normal file
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@ -0,0 +1,355 @@
"""Состояние приложения: текущие свипы и настройки калибровки/нормировки."""
from queue import Empty, Queue
from typing import Any, Mapping, Optional
import numpy as np
from rfg_adc_plotter.processing.pipeline import (
DEFAULT_BACKGROUND_PATH,
DEFAULT_CALIB_ENVELOPE_PATH,
SweepPreprocessor,
)
from rfg_adc_plotter.state.ring_buffer import RingBuffer
from rfg_adc_plotter.types import SweepInfo, SweepPacket
CALIB_ENVELOPE_PATH = DEFAULT_CALIB_ENVELOPE_PATH
BACKGROUND_PATH = DEFAULT_BACKGROUND_PATH
def format_status(data: Mapping[str, Any]) -> str:
"""Преобразовать словарь метрик в одну строку 'k:v'."""
def _fmt(v: Any) -> str:
if v is None:
return "NA"
try:
fv = float(v)
except Exception:
return str(v)
if not np.isfinite(fv):
return "nan"
if abs(fv) >= 1000 or (0 < abs(fv) < 0.01):
return f"{fv:.3g}"
return f"{fv:.3f}".rstrip("0").rstrip(".")
parts = [f"{k}:{_fmt(v)}" for k, v in data.items() if k != "pre_exp_sweep"]
return " ".join(parts)
class AppState:
"""Весь изменяемый GUI-state: текущие данные + pipeline предобработки."""
def __init__(self, norm_type: str = "projector"):
self.current_sweep_pre_exp: Optional[np.ndarray] = None
self.current_sweep_post_exp: Optional[np.ndarray] = None
self.current_sweep_processed: Optional[np.ndarray] = None
self.current_sweep_raw: Optional[np.ndarray] = None
self.current_sweep_norm: Optional[np.ndarray] = None
self.current_info: Optional[SweepInfo] = None
self.norm_type: str = str(norm_type).strip().lower()
self.preprocessor = SweepPreprocessor(norm_type=self.norm_type)
self._last_sweep_for_ring: Optional[np.ndarray] = None
self._last_stage_trace: tuple[str, ...] = tuple()
def configure_capture_import(self, *, fancy: Optional[bool] = None, logscale: Optional[bool] = None):
self.preprocessor.set_capture_parse_options(fancy=fancy, logscale=logscale)
# ---- Свойства pipeline (для совместимости с GUI) ----
@property
def calib_enabled(self) -> bool:
return self.preprocessor.calib_enabled
@property
def calib_mode(self) -> str:
return self.preprocessor.calib_mode
@property
def calib_file_envelope(self) -> Optional[np.ndarray]:
return self.preprocessor.calib_file_envelope
@property
def last_calib_sweep(self) -> Optional[np.ndarray]:
return self.preprocessor.last_calib_sweep
@property
def background(self) -> Optional[np.ndarray]:
return self.preprocessor.background
@property
def background_enabled(self) -> bool:
return self.preprocessor.background_enabled
@property
def calib_source_type(self) -> str:
return self.preprocessor.calib_external_source_type
@property
def background_source_type(self) -> str:
return self.preprocessor.background_source_type
@property
def calib_reference_summary(self):
return self.preprocessor.calib_reference_summary
@property
def background_reference_summary(self):
return self.preprocessor.background_reference_summary
@property
def last_reference_error(self) -> str:
return self.preprocessor.last_reference_error
@property
def calib_envelope_path(self) -> str:
return self.preprocessor.calib_envelope_path
@property
def background_path(self) -> str:
return self.preprocessor.background_path
# ---- Управление файлами калибровки/фона ----
def set_calib_envelope_path(self, path: str):
self.preprocessor.set_calib_envelope_path(path)
self._refresh_current_processed()
def set_background_path(self, path: str):
self.preprocessor.set_background_path(path)
self._refresh_current_processed()
def has_calib_envelope_file(self) -> bool:
return self.preprocessor.has_calib_envelope_file()
def has_background_file(self) -> bool:
return self.preprocessor.has_background_file()
def save_calib_envelope(self, path: Optional[str] = None) -> bool:
return self.preprocessor.save_calib_envelope(path)
def load_calib_reference(self, path: Optional[str] = None) -> bool:
ok = self.preprocessor.load_calib_reference(path)
if ok:
self._refresh_current_processed()
return ok
def load_calib_envelope(self, path: Optional[str] = None) -> bool:
return self.load_calib_reference(path)
def set_calib_mode(self, mode: str):
self.preprocessor.set_calib_mode(mode)
self._refresh_current_processed()
def save_background(self, path: Optional[str] = None) -> bool:
return self.preprocessor.save_background(self._last_sweep_for_ring, path)
def load_background_reference(self, path: Optional[str] = None) -> bool:
ok = self.preprocessor.load_background_reference(path)
if ok:
self._refresh_current_processed()
return ok
def load_background(self, path: Optional[str] = None) -> bool:
return self.load_background_reference(path)
def set_background_enabled(self, enabled: bool):
self.preprocessor.set_background_enabled(enabled)
self._refresh_current_processed()
def set_calib_enabled(self, enabled: bool):
self.preprocessor.set_calib_enabled(enabled)
self._refresh_current_processed()
# ---- Вспомогательные методы для UI ----
def _current_channel(self) -> Optional[int]:
if not isinstance(self.current_info, dict):
return None
try:
return int(self.current_info.get("ch", 0))
except Exception:
return 0
def _apply_result_to_current(self, result) -> None:
self._last_stage_trace = tuple(result.stage_trace)
if result.is_calibration_reference:
self.current_sweep_norm = None
elif result.calibration_applied or result.background_applied:
self.current_sweep_norm = result.processed_sweep
else:
self.current_sweep_norm = None
self.current_sweep_processed = result.processed_sweep
self._last_sweep_for_ring = result.processed_sweep
def _refresh_current_processed(self):
if self.current_sweep_raw is None:
self.current_sweep_norm = None
self.current_sweep_processed = None
self._last_stage_trace = tuple()
return
ch = self._current_channel() or 0
result = self.preprocessor.process(self.current_sweep_raw, ch, update_references=False)
self._apply_result_to_current(result)
def format_pipeline_status(self) -> str:
"""Краткое описание pipeline для UI: от распарсенного свипа до IFFT."""
ch = self._current_channel()
if ch is None:
ch_txt = "?"
else:
ch_txt = str(ch)
reader_stage = "log-exp" if self.current_sweep_pre_exp is not None else "linear"
if ch == 0:
file_calib_applies = (
self.calib_enabled
and self.calib_mode == "file"
and self.calib_file_envelope is not None
)
if self.calib_enabled and self.calib_mode == "file":
calib_stage = self.format_calib_source_status()
else:
calib_stage = "calib[off]"
if not self.background_enabled:
bg_stage = "bg[off]"
elif self.background_source_type == "capture_raw":
if self.background is None:
bg_stage = (
"bg[capture(raw->calib):missing]"
if file_calib_applies
else "bg[capture(raw):missing]"
)
else:
bg_stage = "bg[capture(raw->calib)]" if file_calib_applies else "bg[capture(raw)]"
elif self.background_source_type == "npy_processed":
bg_stage = "bg[npy]" if self.background is not None else "bg[npy:missing]"
else:
bg_stage = "bg[sub]" if self.background is not None else "bg[missing]"
return (
f"pipeline ch{ch_txt}: parsed -> {reader_stage} -> raw -> "
f"live-calib-ref -> {calib_stage} -> {bg_stage} -> ring -> IFFT(abs, depth_m)"
)
calib_stage = self.format_calib_source_status()
bg_stage = self.format_background_source_status()
return (
f"pipeline ch{ch_txt}: parsed -> {reader_stage} -> raw -> "
f"{calib_stage} -> {bg_stage} -> ring -> IFFT(abs, depth_m)"
)
def _format_summary(self, summary) -> str:
if summary is None:
return ""
parts: list[str] = []
if getattr(summary, "sweeps_valid", 0) or getattr(summary, "sweeps_total", 0):
parts.append(f"valid:{summary.sweeps_valid}/{summary.sweeps_total}")
if getattr(summary, "dominant_width", None) is not None:
parts.append(f"w:{summary.dominant_width}")
chs = getattr(summary, "channels_seen", tuple())
if chs:
parts.append("chs:" + ",".join(str(v) for v in chs))
warns = getattr(summary, "warnings", tuple())
if warns:
parts.append(f"warn:{warns[0]}")
return " ".join(parts)
def format_calib_source_status(self) -> str:
if not self.calib_enabled:
return "calib[off]"
if self.calib_mode == "live":
return "calib[live]" if self.last_calib_sweep is not None else "calib[live:no-ref]"
if self.calib_file_envelope is None:
return "calib[file:missing]"
if self.calib_source_type == "capture":
return "calib[capture]"
if self.calib_source_type == "npy":
return "calib[npy]"
return "calib[file]"
def format_background_source_status(self) -> str:
if not self.background_enabled:
return "bg[off]"
src = self.background_source_type
if src == "capture_raw":
if self.calib_enabled:
can_map = (
(self.calib_mode == "file" and self.calib_file_envelope is not None)
or (self.calib_mode == "live" and self.last_calib_sweep is not None)
)
if not can_map:
return "bg[capture(raw->calib):missing]"
if self.background is None:
return "bg[capture(raw->calib):missing]"
return "bg[capture(raw->calib)]" if self.calib_enabled else "bg[capture(raw)]"
if src == "npy_processed":
return "bg[npy]" if self.background is not None else "bg[npy:missing]"
if self.background is not None:
return "bg[sub]"
return "bg[missing]"
def format_reference_status(self) -> str:
parts: list[str] = []
calib_s = self._format_summary(self.calib_reference_summary)
if calib_s:
parts.append(f"calib[{calib_s}]")
bg_s = self._format_summary(self.background_reference_summary)
if bg_s:
parts.append(f"bg[{bg_s}]")
if self.last_reference_error:
parts.append(f"err:{self.last_reference_error}")
return " | ".join(parts)
def format_stage_trace(self) -> str:
if not self._last_stage_trace:
return ""
return " -> ".join(self._last_stage_trace)
def drain_queue(self, q: "Queue[SweepPacket]", ring: RingBuffer) -> int:
"""Вытащить все ожидающие свипы из очереди, обновить state и ring.
Возвращает количество обработанных свипов.
"""
drained = 0
while True:
try:
s, info = q.get_nowait()
except Empty:
break
drained += 1
self.current_sweep_raw = s
self.current_sweep_post_exp = s
self.current_info = info
pre_exp = info.get("pre_exp_sweep") if isinstance(info, dict) else None
self.current_sweep_pre_exp = pre_exp if isinstance(pre_exp, np.ndarray) else None
try:
ch = int(info.get("ch", 0)) if isinstance(info, dict) else 0
except Exception:
ch = 0
result = self.preprocessor.process(s, ch, update_references=True)
self._apply_result_to_current(result)
ring.ensure_init(s.size)
ring.push(result.processed_sweep)
return drained
def format_channel_label(self) -> str:
"""Строка с номерами каналов для подписи на графике."""
if self.current_info is None:
return ""
info = self.current_info
chs = info.get("chs") if isinstance(info, dict) else None
if chs is None:
chs = info.get("ch") if isinstance(info, dict) else None
if chs is None:
return ""
try:
if isinstance(chs, (list, tuple, set)):
ch_list = sorted(int(v) for v in chs)
return "chs " + ", ".join(str(v) for v in ch_list)
return f"chs {int(chs)}"
except Exception:
return f"chs {chs}"

49
rfg_adc_plotter/state/background_buffer.py
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@ -1,49 +0,0 @@
"""Rolling median buffer for persisted FFT background capture."""
from __future__ import annotations
from typing import Optional
import numpy as np
class BackgroundMedianBuffer:
"""Store recent FFT rows and expose their median profile."""
def __init__(self, max_rows: int):
self.max_rows = max(1, int(max_rows))
self.width = 0
self.head = 0
self.count = 0
self.rows: Optional[np.ndarray] = None
def reset(self) -> None:
self.width = 0
self.head = 0
self.count = 0
self.rows = None
def push(self, fft_mag: np.ndarray) -> None:
values = np.asarray(fft_mag, dtype=np.float32).reshape(-1)
if values.size == 0:
return
if self.rows is None or self.width != values.size:
self.width = values.size
self.rows = np.full((self.max_rows, self.width), np.nan, dtype=np.float32)
self.head = 0
self.count = 0
self.rows[self.head, :] = values
self.head = (self.head + 1) % self.max_rows
self.count = min(self.count + 1, self.max_rows)
def median(self) -> Optional[np.ndarray]:
if self.rows is None or self.count <= 0:
return None
rows = self.rows[: self.count] if self.count < self.max_rows else self.rows
valid_rows = np.any(np.isfinite(rows), axis=1)
if not np.any(valid_rows):
return None
median = np.nanmedian(rows[valid_rows], axis=0).astype(np.float32, copy=False)
if not np.any(np.isfinite(median)):
return None
return np.nan_to_num(median, nan=0.0).astype(np.float32, copy=False)

488
rfg_adc_plotter/state/ring_buffer.py
View File

@ -1,266 +1,314 @@
"""Ring buffers for raw sweeps and FFT waterfall rows."""
from __future__ import annotations
"""Кольцевой буфер свипов и FFT-строк для водопадного отображения."""
import time
from typing import Optional
from typing import Optional, Tuple
import numpy as np
from rfg_adc_plotter.constants import FFT_LEN, SWEEP_FREQ_MAX_GHZ, SWEEP_FREQ_MIN_GHZ
from rfg_adc_plotter.processing.fft import compute_distance_axis, compute_fft_mag_row, fft_mag_to_db
from rfg_adc_plotter.constants import (
FREQ_MAX_GHZ,
FREQ_MIN_GHZ,
WF_WIDTH,
)
from rfg_adc_plotter.processing.fourier import (
build_frequency_axis_hz,
compute_ifft_profile_from_sweep,
perform_ifft_depth_response,
reconstruct_complex_spectrum_from_real_trace,
)
class RingBuffer:
"""Store raw sweeps, FFT rows, and matching time markers."""
"""Хранит последние N свипов и соответствующие FFT-строки.
Все мутабельные поля водопада инкапсулированы здесь,
что устраняет необходимость nonlocal в GUI-коде.
"""
def __init__(self, max_sweeps: int):
self.max_sweeps = int(max_sweeps)
self.fft_bins = FFT_LEN // 2 + 1
self.fft_mode = "symmetric"
self.width = 0
self.head = 0
self.ring: Optional[np.ndarray] = None
self.ring_time: Optional[np.ndarray] = None
self.ring_fft: Optional[np.ndarray] = None
self.ring_fft_input: Optional[np.ndarray] = None
self.max_sweeps = max_sweeps
# Размер IFFT-профиля теперь динамический и определяется по первому успешному свипу.
self.fft_bins = 0
self.fft_complex_mode: str = "arccos"
# Инициализируются при первом свипе (ensure_init)
self.ring: Optional[np.ndarray] = None # (max_sweeps, WF_WIDTH)
self.ring_fft: Optional[np.ndarray] = None # (max_sweeps, fft_bins)
self.ring_time: Optional[np.ndarray] = None # (max_sweeps,)
self.head: int = 0
self.width: Optional[int] = None
self.x_shared: Optional[np.ndarray] = None
self.distance_axis: Optional[np.ndarray] = None
self.last_fft_mag: Optional[np.ndarray] = None
self.last_fft_db: Optional[np.ndarray] = None
self.last_freqs: Optional[np.ndarray] = None
self.fft_depth_axis_m: Optional[np.ndarray] = None # ось глубины IFFT в метрах
self.y_min_fft: Optional[float] = None
self.y_max_fft: Optional[float] = None
self.last_push_valid_points = 0
self.last_push_fft_valid = False
self.last_push_axis_valid = False
# FFT последнего свипа (для отображения без повторного вычисления)
self.last_fft_vals: Optional[np.ndarray] = None
# FFT-профили по третям входного частотного диапазона (для line-plot).
self.last_fft_third_axes_m: tuple[Optional[np.ndarray], Optional[np.ndarray], Optional[np.ndarray]] = (
None,
None,
None,
)
self.last_fft_third_vals: tuple[Optional[np.ndarray], Optional[np.ndarray], Optional[np.ndarray]] = (
None,
None,
None,
)
@property
def is_ready(self) -> bool:
return self.ring is not None and self.ring_fft is not None
return self.ring is not None
@property
def fft_symmetric(self) -> bool:
return self.fft_mode == "symmetric"
def fft_time_axis(self) -> Optional[np.ndarray]:
"""Legacy alias: старое имя поля (раньше было время в нс, теперь глубина в м)."""
return self.fft_depth_axis_m
def reset(self) -> None:
"""Drop all buffered sweeps and derived FFT state."""
self.width = 0
self.head = 0
self.ring = None
self.ring_time = None
def set_fft_complex_mode(self, mode: str) -> bool:
"""Выбрать режим реконструкции комплексного спектра для IFFT.
Возвращает True, если режим изменился (и FFT-буфер был сброшен).
"""
m = str(mode).strip().lower()
if m not in ("arccos", "diff"):
raise ValueError(f"Unsupported IFFT complex mode: {mode!r}")
if m == self.fft_complex_mode:
return False
self.fft_complex_mode = m
# Сбрасываем только FFT-зависимые структуры. Сырые ряды сохраняем.
self.ring_fft = None
self.ring_fft_input = None
self.x_shared = None
self.distance_axis = None
self.last_fft_mag = None
self.last_fft_db = None
self.last_freqs = None
self.fft_depth_axis_m = None
self.fft_bins = 0
self.last_fft_vals = None
self.last_fft_third_axes_m = (None, None, None)
self.last_fft_third_vals = (None, None, None)
self.y_min_fft = None
self.y_max_fft = None
self.last_push_valid_points = 0
self.last_push_fft_valid = False
self.last_push_axis_valid = False
def _promote_fft_cache(self, fft_mag: np.ndarray) -> bool:
fft_mag_arr = np.asarray(fft_mag, dtype=np.float32).reshape(-1)
if fft_mag_arr.size <= 0:
self.last_push_fft_valid = False
return False
fft_db = fft_mag_to_db(fft_mag_arr)
finite_db = fft_db[np.isfinite(fft_db)]
if finite_db.size <= 0:
self.last_push_fft_valid = False
return False
self.last_fft_mag = fft_mag_arr.copy()
self.last_fft_db = fft_db
fr_min = float(np.min(finite_db))
fr_max = float(np.max(finite_db))
self.y_min_fft = fr_min if self.y_min_fft is None else min(self.y_min_fft, fr_min)
self.y_max_fft = fr_max if self.y_max_fft is None else max(self.y_max_fft, fr_max)
self.last_push_fft_valid = True
return True
def _promote_distance_axis(self, axis: np.ndarray) -> bool:
axis_arr = np.asarray(axis, dtype=np.float64).reshape(-1)
if axis_arr.size <= 0 or not np.all(np.isfinite(axis_arr)):
self.last_push_axis_valid = False
return False
self.distance_axis = axis_arr.copy()
self.last_push_axis_valid = True
return True
def ensure_init(self, sweep_width: int) -> bool:
"""Allocate or resize buffers. Returns True when geometry changed."""
target_width = max(1, int(sweep_width))
changed = False
if self.ring is None or self.ring_time is None or self.ring_fft is None:
self.width = target_width
def ensure_init(self, sweep_width: int):
"""Инициализировать буферы при первом свипе. Повторные вызовы — no-op (кроме x_shared)."""
if self.ring is None:
self.width = WF_WIDTH
self.ring = np.full((self.max_sweeps, self.width), np.nan, dtype=np.float32)
self.ring_time = np.full((self.max_sweeps,), np.nan, dtype=np.float64)
self.ring_fft = np.full((self.max_sweeps, self.fft_bins), np.nan, dtype=np.float32)
self.ring_fft_input = np.full((self.max_sweeps, self.width), np.nan + 0j, dtype=np.complex64)
self.head = 0
changed = True
elif target_width != self.width:
new_ring = np.full((self.max_sweeps, target_width), np.nan, dtype=np.float32)
new_fft_input = np.full((self.max_sweeps, target_width), np.nan + 0j, dtype=np.complex64)
take = min(self.width, target_width)
new_ring[:, :take] = self.ring[:, :take]
if self.ring_fft_input is not None:
new_fft_input[:, :take] = self.ring_fft_input[:, :take]
self.ring = new_ring
self.ring_fft_input = new_fft_input
self.width = target_width
changed = True
# Обновляем x_shared если пришёл свип большего размера
if self.x_shared is None or sweep_width > self.x_shared.size:
self.x_shared = np.linspace(FREQ_MIN_GHZ, FREQ_MAX_GHZ, sweep_width, dtype=np.float32)
if self.x_shared is None or self.x_shared.size != self.width:
self.x_shared = np.linspace(
SWEEP_FREQ_MIN_GHZ,
SWEEP_FREQ_MAX_GHZ,
self.width,
dtype=np.float32,
)
changed = True
return changed
def set_fft_mode(self, mode: str) -> bool:
"""Switch FFT mode and rebuild cached FFT rows from stored sweeps."""
normalized_mode = str(mode).strip().lower()
if normalized_mode in {"ordinary", "normal"}:
normalized_mode = "direct"
if normalized_mode in {"sym", "mirror"}:
normalized_mode = "symmetric"
if normalized_mode in {"positive-centered", "positive_centered", "zero_left"}:
normalized_mode = "positive_only"
if normalized_mode in {"positive-centered-exact", "positive_centered_exact", "zero_left_exact"}:
normalized_mode = "positive_only_exact"
if normalized_mode not in {"direct", "symmetric", "positive_only", "positive_only_exact"}:
raise ValueError(f"Unsupported FFT mode: {mode!r}")
if normalized_mode == self.fft_mode:
return False
self.fft_mode = normalized_mode
self.y_min_fft = None
self.y_max_fft = None
self.last_push_fft_valid = False
self.last_push_axis_valid = False
if self.ring is None or self.ring_fft is None:
return True
self.ring_fft.fill(np.nan)
for row_idx in range(self.ring.shape[0]):
fft_source_row = self.ring_fft_input[row_idx] if self.ring_fft_input is not None else self.ring[row_idx]
if not np.any(np.isfinite(fft_source_row)):
continue
finite_idx = np.flatnonzero(np.isfinite(fft_source_row))
if finite_idx.size <= 0:
continue
row_width = int(finite_idx[-1]) + 1
fft_source = fft_source_row[:row_width]
freqs = self.last_freqs[:row_width] if self.last_freqs is not None and self.last_freqs.size >= row_width else self.last_freqs
fft_mag = compute_fft_mag_row(
fft_source,
freqs,
self.fft_bins,
mode=self.fft_mode,
)
self.ring_fft[row_idx, :] = fft_mag
if self.last_freqs is not None:
self._promote_distance_axis(
compute_distance_axis(
self.last_freqs,
self.fft_bins,
mode=self.fft_mode,
)
)
last_idx = (self.head - 1) % self.max_sweeps
if self.ring_fft.shape[0] > 0:
last_fft = self.ring_fft[last_idx]
self._promote_fft_cache(last_fft)
finite = self.ring_fft[np.isfinite(self.ring_fft)]
if finite.size > 0:
finite_db = fft_mag_to_db(finite.astype(np.float32, copy=False))
self.y_min_fft = float(np.nanmin(finite_db))
self.y_max_fft = float(np.nanmax(finite_db))
return True
def set_symmetric_fft_enabled(self, enabled: bool) -> bool:
"""Backward-compatible wrapper for the old two-state FFT switch."""
return self.set_fft_mode("symmetric" if enabled else "direct")
def push(
self,
sweep: np.ndarray,
freqs: Optional[np.ndarray] = None,
*,
fft_input: Optional[np.ndarray] = None,
) -> None:
"""Push a processed sweep and refresh raw/FFT buffers."""
if sweep is None or sweep.size == 0:
def push(self, s: np.ndarray):
"""Добавить строку свипа в кольцевой буфер, вычислить FFT-строку."""
if s is None or s.size == 0 or self.ring is None:
return
self.ensure_init(int(sweep.size))
if self.ring is None or self.ring_time is None or self.ring_fft is None or self.ring_fft_input is None:
return
row = np.full((self.width,), np.nan, dtype=np.float32)
take = min(self.width, int(sweep.size))
row[:take] = np.asarray(sweep[:take], dtype=np.float32)
self.last_push_valid_points = int(np.count_nonzero(np.isfinite(row[:take])))
w = self.ring.shape[1]
row = np.full((w,), np.nan, dtype=np.float32)
take = min(w, s.size)
row[:take] = s[:take]
self.ring[self.head, :] = row
self.ring_time[self.head] = time.time()
if freqs is not None:
self.last_freqs = np.asarray(freqs, dtype=np.float64).copy()
self.head = (self.head + 1) % self.ring.shape[0]
fft_source = np.asarray(fft_input if fft_input is not None else sweep).reshape(-1)
fft_row = np.full((self.width,), np.nan + 0j, dtype=np.complex64)
fft_take = min(self.width, int(fft_source.size))
fft_row[:fft_take] = np.asarray(fft_source[:fft_take], dtype=np.complex64)
self.ring_fft_input[self.head, :] = fft_row
self._push_fft(s)
fft_mag = compute_fft_mag_row(fft_source, freqs, self.fft_bins, mode=self.fft_mode)
self.ring_fft[self.head, :] = fft_mag
self._promote_fft_cache(fft_mag)
self._promote_distance_axis(compute_distance_axis(freqs, self.fft_bins, mode=self.fft_mode))
self.head = (self.head + 1) % self.max_sweeps
def _push_fft(self, s: np.ndarray):
empty_thirds = (
np.zeros((0,), dtype=np.float32),
np.zeros((0,), dtype=np.float32),
np.zeros((0,), dtype=np.float32),
)
depth_axis_m, fft_row = compute_ifft_profile_from_sweep(
s,
complex_mode=self.fft_complex_mode,
)
fft_row = np.asarray(fft_row, dtype=np.float32).ravel()
depth_axis_m = np.asarray(depth_axis_m, dtype=np.float32).ravel()
def get_display_raw(self) -> np.ndarray:
n = min(int(fft_row.size), int(depth_axis_m.size))
if n <= 0:
self.last_fft_third_axes_m = empty_thirds
self.last_fft_third_vals = empty_thirds
return
if n != fft_row.size:
fft_row = fft_row[:n]
if n != depth_axis_m.size:
depth_axis_m = depth_axis_m[:n]
# Для отображения храним только первую половину IFFT-профиля:
# вторая половина для текущей схемы симметрична и визуально избыточна.
n_keep = max(1, (n + 1) // 2)
fft_row = fft_row[:n_keep]
depth_axis_m = depth_axis_m[:n_keep]
n = n_keep
needs_reset = (
self.ring_fft is None
or self.fft_depth_axis_m is None
or self.fft_bins != n
or self.ring_fft.shape != (self.max_sweeps, n)
or self.fft_depth_axis_m.size != n
)
if (not needs_reset) and n > 0:
prev_axis = self.fft_depth_axis_m
assert prev_axis is not None
if prev_axis.size != n:
needs_reset = True
else:
# Если ось изменилась (например, изменилась длина/частотная сетка), сбрасываем FFT-водопад.
if not np.allclose(prev_axis[[0, -1]], depth_axis_m[[0, -1]], rtol=1e-6, atol=1e-9):
needs_reset = True
if needs_reset:
self.fft_bins = n
self.ring_fft = np.full((self.max_sweeps, n), np.nan, dtype=np.float32)
self.fft_depth_axis_m = depth_axis_m.astype(np.float32, copy=True)
self.y_min_fft = None
self.y_max_fft = None
assert self.ring_fft is not None
prev_head = (self.head - 1) % self.ring_fft.shape[0]
self.ring_fft[prev_head, :] = fft_row
self.last_fft_vals = fft_row
self.last_fft_third_axes_m, self.last_fft_third_vals = self._compute_fft_thirds(s)
fr_min = np.nanmin(fft_row)
fr_max = float(np.nanpercentile(fft_row, 90))
if self.y_min_fft is None or (not np.isnan(fr_min) and fr_min < self.y_min_fft):
self.y_min_fft = float(fr_min)
if self.y_max_fft is None or (not np.isnan(fr_max) and fr_max > self.y_max_fft):
self.y_max_fft = float(fr_max)
def _compute_fft_thirds(
self, s: np.ndarray
) -> tuple[tuple[np.ndarray, np.ndarray, np.ndarray], tuple[np.ndarray, np.ndarray, np.ndarray]]:
sweep = np.asarray(s, dtype=np.float64).ravel()
total = int(sweep.size)
def _empty() -> np.ndarray:
return np.zeros((0,), dtype=np.float32)
if total <= 0:
return (_empty(), _empty(), _empty()), (_empty(), _empty(), _empty())
freq_hz = build_frequency_axis_hz(total)
edges = np.linspace(0, total, 4, dtype=np.int64)
axes: list[np.ndarray] = []
vals: list[np.ndarray] = []
for idx in range(3):
i0 = int(edges[idx])
i1 = int(edges[idx + 1])
if i1 - i0 < 2:
axes.append(_empty())
vals.append(_empty())
continue
seg = sweep[i0:i1]
seg_freq = freq_hz[i0:i1]
seg_complex = reconstruct_complex_spectrum_from_real_trace(
seg,
complex_mode=self.fft_complex_mode,
)
depth_m, seg_fft = perform_ifft_depth_response(seg_complex, seg_freq, axis="abs")
depth_m = np.asarray(depth_m, dtype=np.float32).ravel()
seg_fft = np.asarray(seg_fft, dtype=np.float32).ravel()
n = min(int(depth_m.size), int(seg_fft.size))
if n <= 0:
axes.append(_empty())
vals.append(_empty())
continue
depth_m = depth_m[:n]
seg_fft = seg_fft[:n]
n_keep = max(1, (n + 1) // 2)
axes.append(depth_m[:n_keep])
vals.append(seg_fft[:n_keep])
return (
axes[0],
axes[1],
axes[2],
), (
vals[0],
vals[1],
vals[2],
)
def get_display_ring(self) -> np.ndarray:
"""Кольцо в порядке от старого к новому, ось времени по X. Форма: (width, time)."""
if self.ring is None:
return np.zeros((1, 1), dtype=np.float32)
base = self.ring if self.head == 0 else np.roll(self.ring, -self.head, axis=0)
return base.T
return base.T # (width, time)
def get_display_raw_decimated(self, max_points: int) -> np.ndarray:
"""Return a display-oriented raw waterfall with optional frequency decimation."""
if self.ring is None:
return np.zeros((1, 1), dtype=np.float32)
limit = int(max_points)
if limit <= 0 or self.width <= limit:
return self.get_display_raw()
row_order = np.arange(self.ring.shape[0], dtype=np.int64)
if self.head:
row_order = np.roll(row_order, -self.head)
col_idx = np.linspace(0, self.width - 1, limit, dtype=np.int64)
return self.ring[np.ix_(row_order, col_idx)].T
def get_display_fft_linear(self) -> np.ndarray:
def get_display_ring_fft(self) -> np.ndarray:
"""FFT-кольцо в порядке от старого к новому. Форма: (bins, time)."""
if self.ring_fft is None:
return np.zeros((1, 1), dtype=np.float32)
base = self.ring_fft if self.head == 0 else np.roll(self.ring_fft, -self.head, axis=0)
return base.T
def get_last_fft_linear(self) -> Optional[np.ndarray]:
if self.last_fft_mag is None:
return None
return np.asarray(self.last_fft_mag, dtype=np.float32).copy()
return base.T # (bins, time)
def get_display_times(self) -> Optional[np.ndarray]:
"""Временные метки строк в порядке от старого к новому."""
if self.ring_time is None:
return None
return self.ring_time if self.head == 0 else np.roll(self.ring_time, -self.head)
def subtract_recent_mean_fft(
self, disp_fft: np.ndarray, spec_mean_sec: float
) -> np.ndarray:
"""Вычесть среднее по каждой частоте за последние spec_mean_sec секунд."""
if spec_mean_sec <= 0.0:
return disp_fft
disp_times = self.get_display_times()
if disp_times is None:
return disp_fft
now_t = time.time()
mask = np.isfinite(disp_times) & (disp_times >= (now_t - spec_mean_sec))
if not np.any(mask):
return disp_fft
try:
mean_spec = np.nanmean(disp_fft[:, mask], axis=1)
except Exception:
return disp_fft
mean_spec = np.nan_to_num(mean_spec, nan=0.0)
return disp_fft - mean_spec[:, None]
def compute_fft_levels(
self, disp_fft: np.ndarray, spec_clip: Optional[Tuple[float, float]]
) -> Optional[Tuple[float, float]]:
"""Вычислить (vmin, vmax) для отображения водопада спектров."""
# 1. По среднему спектру за видимое время
try:
mean_spec = np.nanmean(disp_fft, axis=1)
vmin_v = float(np.nanmin(mean_spec))
vmax_v = float(np.nanmax(mean_spec))
if np.isfinite(vmin_v) and np.isfinite(vmax_v) and vmin_v != vmax_v:
return (vmin_v, vmax_v)
except Exception:
pass
# 2. Процентильная обрезка
if spec_clip is not None:
try:
vmin_v = float(np.nanpercentile(disp_fft, spec_clip[0]))
vmax_v = float(np.nanpercentile(disp_fft, spec_clip[1]))
if np.isfinite(vmin_v) and np.isfinite(vmax_v) and vmin_v != vmax_v:
return (vmin_v, vmax_v)
except Exception:
pass
# 3. Глобальные накопленные мин/макс
if (
self.y_min_fft is not None
and self.y_max_fft is not None
and np.isfinite(self.y_min_fft)
and np.isfinite(self.y_max_fft)
and self.y_min_fft != self.y_max_fft
):
return (self.y_min_fft, self.y_max_fft)
return None

64
rfg_adc_plotter/state/runtime_state.py
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@ -1,64 +0,0 @@
"""Mutable state container for the PyQtGraph backend."""
from __future__ import annotations
from dataclasses import dataclass, field
from typing import Dict, List, Optional
import numpy as np
from rfg_adc_plotter.constants import BACKGROUND_MEDIAN_SWEEPS
from rfg_adc_plotter.state.background_buffer import BackgroundMedianBuffer
from rfg_adc_plotter.state.ring_buffer import RingBuffer
from rfg_adc_plotter.types import SweepAuxCurves, SweepInfo
@dataclass
class RuntimeState:
ring: RingBuffer
range_min_ghz: float = 0.0
range_max_ghz: float = 0.0
full_current_freqs: Optional[np.ndarray] = None
full_current_sweep_raw: Optional[np.ndarray] = None
full_current_sweep_codes: Optional[np.ndarray] = None
full_current_fft_source: Optional[np.ndarray] = None
full_current_aux_curves: SweepAuxCurves = None
full_current_aux_curves_codes: SweepAuxCurves = None
full_do1_tagged_raw_low: Optional[np.ndarray] = None
full_do1_tagged_raw_high: Optional[np.ndarray] = None
full_do1_tagged_aux_low: SweepAuxCurves = None
full_do1_tagged_aux_high: SweepAuxCurves = None
full_do1_tagged_aux_low_codes: SweepAuxCurves = None
full_do1_tagged_aux_high_codes: SweepAuxCurves = None
current_freqs: Optional[np.ndarray] = None
current_distances: Optional[np.ndarray] = None
current_sweep_raw: Optional[np.ndarray] = None
current_fft_source: Optional[np.ndarray] = None
current_fft_input: Optional[np.ndarray] = None
current_fft_complex: Optional[np.ndarray] = None
current_aux_curves: SweepAuxCurves = None
current_do1_tagged_raw_low: Optional[np.ndarray] = None
current_do1_tagged_raw_high: Optional[np.ndarray] = None
current_do1_tagged_aux_low: SweepAuxCurves = None
current_do1_tagged_aux_high: SweepAuxCurves = None
current_sweep_norm: Optional[np.ndarray] = None
current_fft_mag: Optional[np.ndarray] = None
current_fft_db: Optional[np.ndarray] = None
last_calib_sweep: Optional[np.ndarray] = None
calib_envelope: Optional[np.ndarray] = None
calib_file_path: Optional[str] = None
complex_calib_curve: Optional[np.ndarray] = None
complex_calib_file_path: Optional[str] = None
background_buffer: BackgroundMedianBuffer = field(
default_factory=lambda: BackgroundMedianBuffer(BACKGROUND_MEDIAN_SWEEPS)
)
background_profile: Optional[np.ndarray] = None
background_file_path: Optional[str] = None
current_info: Optional[SweepInfo] = None
current_peak_width: Optional[float] = None
current_peak_amplitude: Optional[float] = None
peak_candidates: List[Dict[str, float]] = field(default_factory=list)
plot_dirty: bool = False
def mark_dirty(self) -> None:
self.plot_dirty = True

33
rfg_adc_plotter/types.py
View File

@ -1,36 +1,7 @@
"""Shared runtime and parser types."""
from __future__ import annotations
from dataclasses import dataclass
from typing import Any, Dict, Literal, Optional, Tuple, TypeAlias, Union
from typing import Any, Dict, Tuple, Union
import numpy as np
Number = Union[int, float]
SignalKind = Literal["bin_iq", "bin_logdet", "bin_iq_do1_tagged"]
Do1Level = Literal["low", "high"]
SweepInfo = Dict[str, Any]
SweepData = Dict[str, np.ndarray]
SweepAuxCurves = Optional[Tuple[np.ndarray, np.ndarray]]
SweepPacket = Tuple[np.ndarray, SweepInfo, SweepAuxCurves]
@dataclass(frozen=True)
class StartEvent:
ch: Optional[int] = None
signal_kind: Optional[SignalKind] = None
@dataclass(frozen=True)
class PointEvent:
ch: int
x: int
y: float
aux: Optional[Tuple[float, float]] = None
signal_kind: Optional[SignalKind] = None
do1_level: Optional[Do1Level] = None
ParserEvent: TypeAlias = Union[StartEvent, PointEvent]
SweepPacket = Tuple[np.ndarray, SweepInfo]

2
run_dataplotter Executable file
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@ -0,0 +1,2 @@
#!/usr/bin/bash
python3 -m rfg_adc_plotter.main --bin --backend mpl $@

44
tests/test_background_buffer.py
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@ -1,44 +0,0 @@
from __future__ import annotations
import numpy as np
import unittest
from rfg_adc_plotter.state.background_buffer import BackgroundMedianBuffer
class BackgroundMedianBufferTests(unittest.TestCase):
def test_buffer_returns_median_for_partial_fill(self):
buffer = BackgroundMedianBuffer(max_rows=4)
buffer.push(np.asarray([1.0, 5.0, 9.0], dtype=np.float32))
buffer.push(np.asarray([3.0, 7.0, 11.0], dtype=np.float32))
median = buffer.median()
self.assertIsNotNone(median)
self.assertTrue(np.allclose(median, np.asarray([2.0, 6.0, 10.0], dtype=np.float32)))
def test_buffer_wraparound_keeps_latest_rows(self):
buffer = BackgroundMedianBuffer(max_rows=2)
buffer.push(np.asarray([1.0, 5.0], dtype=np.float32))
buffer.push(np.asarray([3.0, 7.0], dtype=np.float32))
buffer.push(np.asarray([9.0, 11.0], dtype=np.float32))
median = buffer.median()
self.assertIsNotNone(median)
self.assertTrue(np.allclose(median, np.asarray([6.0, 9.0], dtype=np.float32)))
def test_buffer_reset_clears_state(self):
buffer = BackgroundMedianBuffer(max_rows=2)
buffer.push(np.asarray([1.0, 2.0], dtype=np.float32))
buffer.reset()
self.assertIsNone(buffer.rows)
self.assertIsNone(buffer.median())
self.assertEqual(buffer.count, 0)
self.assertEqual(buffer.head, 0)
if __name__ == "__main__":
unittest.main()

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tests/test_capture_reference_loader.py Normal file
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from pathlib import Path
import numpy as np
from rfg_adc_plotter.io.capture_reference_loader import (
aggregate_capture_reference,
detect_reference_file_format,
load_capture_sweeps,
)
from rfg_adc_plotter.processing.pipeline import SweepPreprocessor
ROOT = Path(__file__).resolve().parents[1]
SAMPLE_BG = ROOT / "sample_data" / "empty"
SAMPLE_CALIB = ROOT / "sample_data" / "no_antennas_35dB_attenuators"
def test_detect_reference_file_format_for_sample_capture():
assert detect_reference_file_format(str(SAMPLE_BG)) == "bin_capture"
assert detect_reference_file_format(str(SAMPLE_CALIB)) == "bin_capture"
def test_load_capture_sweeps_parses_binary_capture():
sweeps = load_capture_sweeps(str(SAMPLE_BG), fancy=False, logscale=False)
assert len(sweeps) > 100
sweep0, info0 = sweeps[0]
assert isinstance(sweep0, np.ndarray)
assert "ch" in info0
channels = set()
for _s, info in sweeps:
chs = info.get("chs", [info.get("ch", 0)])
channels.update(int(v) for v in chs)
assert channels == {0}
def test_aggregate_capture_reference_filters_incomplete_sweeps():
sweeps = load_capture_sweeps(str(SAMPLE_BG), fancy=False, logscale=False)
vector, summary = aggregate_capture_reference(sweeps, channel=0, method="median", path=str(SAMPLE_BG))
assert isinstance(vector, np.ndarray)
assert vector.dtype == np.float32
assert summary.sweeps_total == len(sweeps)
assert summary.sweeps_valid > 0
assert summary.sweeps_valid < summary.sweeps_total
assert summary.dominant_width in (759, 758) # sample_data starts at x=1..758 => width=759
def test_preprocessor_can_load_capture_calib_and_background_and_apply():
p = SweepPreprocessor(norm_type="projector", auto_save_live_calib_envelope=False)
p.set_capture_parse_options(fancy=False, logscale=False)
assert p.load_calib_reference(str(SAMPLE_CALIB))
p.set_calib_mode("file")
p.set_calib_enabled(True)
assert p.calib_file_envelope is not None
assert p.calib_external_source_type == "capture"
assert p.load_background_reference(str(SAMPLE_BG))
p.set_background_enabled(True)
assert p.background_source_type == "capture_raw"
n = min(758, int(p.calib_file_envelope.size))
sweep = np.linspace(-100.0, 100.0, n, dtype=np.float32)
res = p.process(sweep, channel=1, update_references=False)
assert res.calibration_applied is True
assert res.background_applied is True
assert res.calibration_source == "capture"
assert "background_capture(raw->calib)" in res.stage_trace
def test_preprocessor_applies_background_for_ch0_reference_too():
p = SweepPreprocessor(norm_type="projector", auto_save_live_calib_envelope=False)
p.set_capture_parse_options(fancy=False, logscale=False)
assert p.load_background_reference(str(SAMPLE_BG))
p.set_background_enabled(True)
n = min(758, int(p.background.size)) if p.background is not None else 758
raw = np.linspace(-10.0, 10.0, n, dtype=np.float32)
res = p.process(raw, channel=0, update_references=True)
assert res.is_calibration_reference is True
assert res.background_applied is True
assert np.any(np.abs(res.processed_sweep - raw) > 0)
assert p.last_calib_sweep is not None
assert np.allclose(p.last_calib_sweep[:n], raw[:n], equal_nan=True)

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tests/test_cli.py
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from __future__ import annotations
import subprocess
import sys
import unittest
from pathlib import Path
from rfg_adc_plotter.cli import build_parser
ROOT = Path(__file__).resolve().parents[1]
def _run(*args: str) -> subprocess.CompletedProcess[str]:
return subprocess.run(
[sys.executable, *args],
cwd=ROOT,
text=True,
capture_output=True,
check=False,
)
class CliTests(unittest.TestCase):
def test_logscale_and_opengl_are_opt_in(self):
args = build_parser().parse_args(["/dev/null"])
self.assertFalse(args.logscale)
self.assertFalse(args.opengl)
self.assertAlmostEqual(float(args.tty_range_v), 5.0, places=6)
args_log = build_parser().parse_args(["/dev/null", "--logscale", "--opengl", "--tty-range-v", "2.5"])
self.assertTrue(args_log.logscale)
self.assertTrue(args_log.opengl)
self.assertAlmostEqual(float(args_log.tty_range_v), 2.5, places=6)
def test_wrapper_help_works(self):
proc = _run("RFG_ADC_dataplotter.py", "--help")
self.assertEqual(proc.returncode, 0)
self.assertIn("usage:", proc.stdout)
self.assertIn("--peak_search", proc.stdout)
def test_module_help_works(self):
proc = _run("-m", "rfg_adc_plotter.main", "--help")
self.assertEqual(proc.returncode, 0)
self.assertIn("usage:", proc.stdout)
self.assertIn("--parser_16_bit_x2", proc.stdout)
self.assertIn("--parser_complex_ascii", proc.stdout)
self.assertIn("--opengl", proc.stdout)
self.assertIn("0x00A3/0x00A4", proc.stdout)
def test_backend_mpl_reports_removal(self):
proc = _run("-m", "rfg_adc_plotter.main", "/dev/null", "--backend", "mpl")
self.assertNotEqual(proc.returncode, 0)
self.assertIn("Matplotlib backend removed", proc.stderr)
if __name__ == "__main__":
unittest.main()

54
tests/test_fourier_complex_modes.py Normal file
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import numpy as np
from rfg_adc_plotter.processing.fourier import (
compute_ifft_profile_from_sweep,
reconstruct_complex_spectrum_from_real_trace,
)
def test_reconstruct_complex_spectrum_arccos_mode_returns_complex128():
sweep = np.linspace(-3.0, 7.0, 128, dtype=np.float32)
z = reconstruct_complex_spectrum_from_real_trace(sweep, complex_mode="arccos")
assert z.dtype == np.complex128
assert z.shape == sweep.shape
assert np.all(np.isfinite(np.real(z)))
assert np.all(np.isfinite(np.imag(z)))
def test_reconstruct_complex_spectrum_diff_mode_returns_complex128():
sweep = np.linspace(-1.0, 1.0, 128, dtype=np.float32)
z = reconstruct_complex_spectrum_from_real_trace(sweep, complex_mode="diff")
assert z.dtype == np.complex128
assert z.shape == sweep.shape
assert np.all(np.isfinite(np.real(z)))
assert np.all(np.isfinite(np.imag(z)))
def test_reconstruct_complex_spectrum_diff_mode_projects_to_unit_circle():
sweep = np.sin(np.linspace(0.0, 6.0 * np.pi, 256)).astype(np.float32)
z = reconstruct_complex_spectrum_from_real_trace(sweep, complex_mode="diff")
mag = np.abs(z)
assert np.all(np.isfinite(mag))
assert np.allclose(mag, np.ones_like(mag), atol=1e-5, rtol=0.0)
def test_compute_ifft_profile_from_sweep_accepts_both_modes():
sweep = np.linspace(-5.0, 5.0, 257, dtype=np.float32)
d1, y1 = compute_ifft_profile_from_sweep(sweep, complex_mode="arccos")
d2, y2 = compute_ifft_profile_from_sweep(sweep, complex_mode="diff")
assert d1.dtype == np.float32 and y1.dtype == np.float32
assert d2.dtype == np.float32 and y2.dtype == np.float32
assert d1.size == y1.size and d2.size == y2.size
assert d1.size > 0 and d2.size > 0
assert np.all(np.diff(d1) >= 0.0)
assert np.all(np.diff(d2) >= 0.0)
def test_invalid_complex_mode_falls_back_deterministically_in_outer_wrapper():
sweep = np.linspace(-1.0, 1.0, 64, dtype=np.float32)
depth, y = compute_ifft_profile_from_sweep(sweep, complex_mode="unknown")
assert depth.dtype == np.float32
assert y.dtype == np.float32
assert depth.size == y.size
assert depth.size > 0

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tests/test_fourier_phase_reconstruction.py Normal file
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import numpy as np
from rfg_adc_plotter.processing.fourier import (
build_frequency_axis_hz,
compute_ifft_profile_from_sweep,
normalize_sweep_for_phase,
perform_ifft_depth_response,
reconstruct_complex_spectrum_from_real_trace,
unwrap_arccos_phase_continuous,
)
def test_normalize_sweep_for_phase_max_abs_and_finite():
sweep = np.array([np.nan, -10.0, 5.0, 20.0, -40.0, np.inf, -np.inf], dtype=np.float32)
x = normalize_sweep_for_phase(sweep)
assert x.dtype == np.float64
assert np.all(np.isfinite(x))
assert np.max(np.abs(x)) <= 1.0 + 1e-12
def test_arccos_unwrap_continuous_recovers_complex_phase_without_large_jumps():
phi_true = np.linspace(0.0, 4.0 * np.pi, 1000, dtype=np.float64)
x = np.cos(phi_true)
phi_rec = unwrap_arccos_phase_continuous(x)
assert phi_rec.shape == phi_true.shape
assert np.max(np.abs(np.diff(phi_rec))) < 0.2
z_true = np.exp(1j * phi_true)
z_rec = np.exp(1j * phi_rec)
assert np.allclose(z_rec, z_true, atol=2e-2, rtol=0.0)
def test_reconstruct_complex_spectrum_from_real_trace_output_complex128():
sweep = np.linspace(-1.0, 1.0, 64, dtype=np.float32)
z = reconstruct_complex_spectrum_from_real_trace(sweep)
assert z.dtype == np.complex128
assert z.shape == sweep.shape
assert np.all(np.isfinite(np.real(z)))
assert np.all(np.isfinite(np.imag(z)))
def test_perform_ifft_depth_response_basic_abs():
n = 128
freqs = build_frequency_axis_hz(n)
s = np.exp(1j * np.linspace(0.0, 2.0 * np.pi, n, dtype=np.float64))
depth_m, y = perform_ifft_depth_response(s, freqs, axis="abs")
assert depth_m.dtype == np.float32
assert y.dtype == np.float32
assert depth_m.ndim == 1 and y.ndim == 1
assert depth_m.size == y.size
assert depth_m.size >= n
assert np.all(np.diff(depth_m) >= 0.0)
assert np.all(y >= 0.0)
def test_perform_ifft_depth_response_bad_grid_returns_fallback_not_exception():
s = np.ones(16, dtype=np.complex128)
freqs_desc = np.linspace(10.0, 1.0, 16, dtype=np.float64)
depth_m, y = perform_ifft_depth_response(s, freqs_desc, axis="abs")
assert depth_m.size == y.size
assert depth_m.size == s.size
assert np.all(np.isfinite(depth_m))
def test_compute_ifft_profile_from_sweep_returns_depth_and_linear_abs():
sweep = np.linspace(-5.0, 7.0, 257, dtype=np.float32)
depth_m, y = compute_ifft_profile_from_sweep(sweep)
assert depth_m.dtype == np.float32
assert y.dtype == np.float32
assert depth_m.size == y.size
assert depth_m.size > 0
assert np.all(np.diff(depth_m) >= 0.0)

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tests/test_processing.py
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from __future__ import annotations
import os
import tempfile
import numpy as np
import unittest
from rfg_adc_plotter.constants import C_M_S, FFT_LEN, SWEEP_FREQ_MAX_GHZ, SWEEP_FREQ_MIN_GHZ
from rfg_adc_plotter.gui.pyqtgraph_backend import (
apply_distance_cut_to_axis,
apply_working_range,
apply_working_range_to_aux_curves,
build_logdet_voltage_fft_input,
build_main_window_layout,
coalesce_packets_for_ui,
compute_background_subtracted_bscan_levels,
compute_aux_phase_curve,
compute_do1_tagged_aggregate,
compute_do1_tagged_phase_curves,
convert_tty_i16_to_voltage,
decimate_bscan_rows_for_display,
decimate_curve_for_display,
is_short_sweep,
resolve_axis_bounds,
resolve_bscan_refresh_stride,
resolve_heavy_refresh_stride,
resolve_initial_window_size,
resolve_distance_cut_start,
update_expected_sweep_width,
sanitize_curve_data_for_display,
sanitize_image_for_display,
set_image_rect_if_ready,
resolve_visible_fft_curves,
resolve_visible_aux_curves,
resolve_visible_do1_tagged_aux_curves,
)
from rfg_adc_plotter.processing.calibration import (
build_calib_envelope,
build_complex_calibration_curve,
calibrate_freqs,
load_calib_envelope,
load_complex_calibration,
recalculate_calibration_c,
save_calib_envelope,
save_complex_calibration,
)
from rfg_adc_plotter.processing.background import (
load_fft_background,
save_fft_background,
subtract_fft_background,
)
from rfg_adc_plotter.processing.fft import (
build_positive_only_exact_centered_ifft_spectrum,
build_positive_only_centered_ifft_spectrum,
build_symmetric_ifft_spectrum,
compute_distance_axis,
compute_fft_complex_row,
compute_fft_mag_row,
compute_fft_row,
fft_mag_to_db,
)
from rfg_adc_plotter.processing.normalization import (
build_calib_envelopes,
fit_complex_calibration_to_width,
normalize_by_calib,
normalize_by_complex_calibration,
normalize_by_envelope,
resample_envelope,
)
from rfg_adc_plotter.processing.peaks import find_peak_width_markers, find_top_peaks_over_ref, rolling_median_ref
class ProcessingTests(unittest.TestCase):
def test_convert_tty_i16_to_voltage_maps_and_clips_full_range(self):
codes = np.asarray([-32768.0, -16384.0, 0.0, 16384.0, 32767.0], dtype=np.float32)
volts = convert_tty_i16_to_voltage(codes, 5.0)
self.assertEqual(volts.shape, codes.shape)
self.assertAlmostEqual(float(volts[0]), -5.0, places=6)
self.assertAlmostEqual(float(volts[2]), 0.0, places=6)
self.assertAlmostEqual(float(volts[-1]), 5.0, places=6)
self.assertTrue(np.all(volts >= -5.0))
self.assertTrue(np.all(volts <= 5.0))
def test_build_logdet_voltage_fft_input_converts_codes_and_exponentiates(self):
codes = np.asarray([-32768.0, 0.0, 32767.0], dtype=np.float32)
volts, fft_input = build_logdet_voltage_fft_input(codes, 5.0)
self.assertEqual(volts.shape, codes.shape)
self.assertEqual(fft_input.shape, codes.shape)
self.assertAlmostEqual(float(volts[0]), -5.0, places=6)
self.assertAlmostEqual(float(volts[1]), 0.0, places=6)
self.assertAlmostEqual(float(volts[2]), 5.0, places=6)
self.assertTrue(np.allclose(fft_input, np.exp(volts.astype(np.float32))))
def test_build_logdet_voltage_fft_input_clips_exp_argument_and_respects_range(self):
codes = np.asarray([32767.0], dtype=np.float32)
volts_5, fft_5 = build_logdet_voltage_fft_input(codes, 5.0, exp_input_limit=2.0)
volts_10, fft_10 = build_logdet_voltage_fft_input(codes, 10.0, exp_input_limit=2.0)
self.assertAlmostEqual(float(volts_5[0]), 5.0, places=6)
self.assertAlmostEqual(float(volts_10[0]), 10.0, places=6)
self.assertAlmostEqual(float(fft_5[0]), float(np.exp(np.float32(2.0))), places=5)
self.assertAlmostEqual(float(fft_10[0]), float(np.exp(np.float32(2.0))), places=5)
self.assertTrue(np.isfinite(fft_5[0]))
self.assertTrue(np.isfinite(fft_10[0]))
def test_recalculate_calibration_preserves_requested_edges(self):
coeffs = recalculate_calibration_c(np.asarray([0.0, 1.0, 0.025], dtype=np.float64), 3.3, 14.3)
y0 = coeffs[0] + coeffs[1] * 3.3 + coeffs[2] * (3.3 ** 2)
y1 = coeffs[0] + coeffs[1] * 14.3 + coeffs[2] * (14.3 ** 2)
self.assertTrue(np.isclose(y0, 3.3))
self.assertTrue(np.isclose(y1, 14.3))
def test_calibrate_freqs_returns_monotonic_axis_and_same_shape(self):
sweep = {"F": np.linspace(3.3, 14.3, 32), "I": np.linspace(-1.0, 1.0, 32)}
calibrated = calibrate_freqs(sweep)
self.assertEqual(calibrated["F"].shape, (32,))
self.assertEqual(calibrated["I"].shape, (32,))
self.assertTrue(np.all(np.diff(calibrated["F"]) >= 0.0))
def test_calibrate_freqs_keeps_complex_payload(self):
sweep = {
"F": np.linspace(3.3, 14.3, 32),
"I": np.exp(1j * np.linspace(0.0, np.pi, 32)).astype(np.complex64),
}
calibrated = calibrate_freqs(sweep)
self.assertEqual(calibrated["F"].shape, (32,))
self.assertEqual(calibrated["I"].shape, (32,))
self.assertTrue(np.iscomplexobj(calibrated["I"]))
self.assertTrue(np.all(np.isfinite(calibrated["I"])))
def test_normalizers_and_envelopes_return_finite_ranges(self):
calib = (np.sin(np.linspace(0.0, 4.0 * np.pi, 64)) * 5.0).astype(np.float32)
raw = calib * 0.75
lower, upper = build_calib_envelopes(calib)
self.assertEqual(lower.shape, calib.shape)
self.assertEqual(upper.shape, calib.shape)
self.assertTrue(np.all(lower <= upper))
self.assertTrue(np.all(np.isfinite(upper)))
self.assertLess(
float(np.mean(np.abs(np.diff(upper, n=2)))),
float(np.mean(np.abs(np.diff(calib, n=2)))),
)
simple = normalize_by_calib(raw, calib + 10.0, norm_type="simple")
projector = normalize_by_calib(raw, calib, norm_type="projector")
self.assertEqual(simple.shape, raw.shape)
self.assertEqual(projector.shape, raw.shape)
self.assertTrue(np.any(np.isfinite(simple)))
self.assertTrue(np.any(np.isfinite(projector)))
def test_file_calibration_envelope_roundtrip_and_division(self):
raw = (np.sin(np.linspace(0.0, 8.0 * np.pi, 128)) * 50.0 + 100.0).astype(np.float32)
envelope = build_calib_envelope(raw)
normalized = normalize_by_envelope(raw, envelope)
resampled = resample_envelope(envelope, 96)
self.assertEqual(envelope.shape, raw.shape)
self.assertEqual(normalized.shape, raw.shape)
self.assertEqual(resampled.shape, (96,))
self.assertTrue(np.any(np.isfinite(normalized)))
self.assertTrue(np.all(np.isfinite(envelope)))
with tempfile.TemporaryDirectory() as tmp_dir:
path = os.path.join(tmp_dir, "calibration_envelope")
saved_path = save_calib_envelope(path, envelope)
loaded = load_calib_envelope(saved_path)
self.assertTrue(saved_path.endswith(".npy"))
self.assertTrue(np.allclose(loaded, envelope))
def test_normalize_by_envelope_adds_small_epsilon_to_zero_denominator(self):
raw = np.asarray([1.0, 2.0, 3.0], dtype=np.float32)
envelope = np.asarray([0.0, 1.0, -1.0], dtype=np.float32)
normalized = normalize_by_envelope(raw, envelope)
self.assertTrue(np.all(np.isfinite(normalized)))
self.assertGreater(normalized[0], 1e8)
self.assertAlmostEqual(float(normalized[1]), 2.0, places=5)
self.assertAlmostEqual(float(normalized[2]), -3.0, places=5)
def test_normalize_by_envelope_supports_complex_input(self):
raw = np.asarray([1.0 + 1.0j, 2.0 - 2.0j], dtype=np.complex64)
envelope = np.asarray([1.0, 2.0], dtype=np.float32)
normalized = normalize_by_envelope(raw, envelope)
self.assertTrue(np.iscomplexobj(normalized))
self.assertTrue(np.all(np.isfinite(normalized)))
self.assertTrue(np.allclose(normalized, np.asarray([1.0 + 1.0j, 1.0 - 1.0j], dtype=np.complex64)))
def test_load_calib_envelope_rejects_empty_payload(self):
with tempfile.TemporaryDirectory() as tmp_dir:
path = os.path.join(tmp_dir, "empty.npy")
np.save(path, np.zeros((0,), dtype=np.float32))
with self.assertRaises(ValueError):
load_calib_envelope(path)
def test_complex_calibration_curve_roundtrip(self):
ch1 = np.asarray([1.0, 2.0, 3.0], dtype=np.float32)
ch2 = np.asarray([0.5, -1.0, 4.0], dtype=np.float32)
curve = build_complex_calibration_curve(ch1, ch2)
expected = np.asarray([1.0 + 0.5j, 2.0 - 1.0j, 3.0 + 4.0j], dtype=np.complex64)
self.assertTrue(np.iscomplexobj(curve))
self.assertTrue(np.allclose(curve, expected))
with tempfile.TemporaryDirectory() as tmp_dir:
path = os.path.join(tmp_dir, "complex_calibration")
saved_path = save_complex_calibration(path, curve)
loaded = load_complex_calibration(saved_path)
self.assertTrue(saved_path.endswith(".npy"))
self.assertEqual(loaded.dtype, np.complex64)
self.assertTrue(np.allclose(loaded, expected))
def test_fit_complex_calibration_to_width_pads_or_trims(self):
calib = np.asarray([1.0 + 1.0j, 2.0 + 2.0j], dtype=np.complex64)
padded = fit_complex_calibration_to_width(calib, 4)
trimmed = fit_complex_calibration_to_width(
np.asarray([1.0 + 1.0j, 2.0 + 2.0j, 3.0 + 3.0j], dtype=np.complex64),
2,
)
self.assertEqual(padded.shape, (4,))
self.assertTrue(np.allclose(padded, np.asarray([1.0 + 1.0j, 2.0 + 2.0j, 1.0 + 0.0j, 1.0 + 0.0j], dtype=np.complex64)))
self.assertEqual(trimmed.shape, (2,))
self.assertTrue(np.allclose(trimmed, np.asarray([1.0 + 1.0j, 2.0 + 2.0j], dtype=np.complex64)))
def test_normalize_by_complex_calibration_handles_zero_and_length_mismatch(self):
signal = np.asarray([2.0 + 2.0j, 4.0 + 0.0j, 3.0 + 3.0j], dtype=np.complex64)
calib = np.asarray([1.0 + 1.0j, 0.0 + 0.0j], dtype=np.complex64)
normalized = normalize_by_complex_calibration(signal, calib)
expected = np.asarray([2.0 + 0.0j, 4.0 + 0.0j, 3.0 + 3.0j], dtype=np.complex64)
self.assertTrue(np.iscomplexobj(normalized))
self.assertTrue(np.all(np.isfinite(normalized)))
self.assertTrue(np.allclose(normalized, expected))
def test_fft_background_roundtrip_and_rejects_non_1d_payload(self):
background = np.asarray([0.5, 1.5, 2.5], dtype=np.float32)
with tempfile.TemporaryDirectory() as tmp_dir:
path = os.path.join(tmp_dir, "fft_background")
saved_path = save_fft_background(path, background)
loaded = load_fft_background(saved_path)
self.assertTrue(saved_path.endswith(".npy"))
self.assertTrue(np.allclose(loaded, background))
invalid_path = os.path.join(tmp_dir, "fft_background_invalid.npy")
np.save(invalid_path, np.zeros((2, 2), dtype=np.float32))
with self.assertRaises(ValueError):
load_fft_background(invalid_path)
def test_subtract_fft_background_clamps_negative_residuals_to_zero(self):
signal = np.asarray([1.0, 2.0, 3.0], dtype=np.float32)
background = np.asarray([1.0, 1.5, 5.0], dtype=np.float32)
subtracted = subtract_fft_background(signal, background)
self.assertTrue(np.allclose(subtracted, np.asarray([0.0, 0.5, 0.0], dtype=np.float32)))
self.assertTrue(np.allclose(subtract_fft_background(signal, signal), 0.0))
def test_apply_working_range_crops_sweep_to_selected_band(self):
freqs = np.linspace(3.3, 14.3, 12, dtype=np.float64)
sweep = np.arange(12, dtype=np.float32)
cropped_freqs, cropped_sweep = apply_working_range(freqs, sweep, 5.0, 9.0)
self.assertGreater(cropped_freqs.size, 0)
self.assertEqual(cropped_freqs.shape, cropped_sweep.shape)
self.assertGreaterEqual(float(np.min(cropped_freqs)), 5.0)
self.assertLessEqual(float(np.max(cropped_freqs)), 9.0)
def test_apply_working_range_returns_empty_when_no_points_match(self):
freqs = np.linspace(3.3, 14.3, 12, dtype=np.float64)
sweep = np.arange(12, dtype=np.float32)
cropped_freqs, cropped_sweep = apply_working_range(freqs, sweep, 20.0, 21.0)
self.assertEqual(cropped_freqs.shape, (0,))
self.assertEqual(cropped_sweep.shape, (0,))
def test_apply_working_range_to_aux_curves_uses_same_mask_as_raw_sweep(self):
freqs = np.linspace(3.3, 14.3, 6, dtype=np.float64)
sweep = np.asarray([0.0, 1.0, np.nan, 3.0, 4.0, 5.0], dtype=np.float32)
aux = (
np.asarray([10.0, 11.0, 12.0, 13.0, 14.0, 15.0], dtype=np.float32),
np.asarray([20.0, 21.0, 22.0, 23.0, 24.0, 25.0], dtype=np.float32),
)
cropped_freqs, cropped_sweep = apply_working_range(freqs, sweep, 4.0, 12.5)
cropped_aux = apply_working_range_to_aux_curves(freqs, sweep, aux, 4.0, 12.5)
self.assertIsNotNone(cropped_aux)
self.assertEqual(cropped_aux[0].shape, cropped_freqs.shape)
self.assertEqual(cropped_aux[1].shape, cropped_freqs.shape)
self.assertEqual(cropped_aux[0].shape, cropped_sweep.shape)
self.assertTrue(np.allclose(cropped_aux[0], np.asarray([11.0, 13.0, 14.0], dtype=np.float32)))
self.assertTrue(np.allclose(cropped_aux[1], np.asarray([21.0, 23.0, 24.0], dtype=np.float32)))
def test_resolve_visible_aux_curves_obeys_checkbox_state(self):
aux = (
np.asarray([1.0, 2.0], dtype=np.float32),
np.asarray([3.0, 4.0], dtype=np.float32),
)
self.assertIsNone(resolve_visible_aux_curves(aux, enabled=False))
visible = resolve_visible_aux_curves(aux, enabled=True)
self.assertIsNotNone(visible)
self.assertTrue(np.allclose(visible[0], aux[0]))
self.assertTrue(np.allclose(visible[1], aux[1]))
def test_compute_aux_phase_curve_returns_atan2_of_aux_channels(self):
aux = (
np.asarray([1.0, 1.0, -1.0, 0.0], dtype=np.float32),
np.asarray([0.0, 1.0, 1.0, 1.0], dtype=np.float32),
)
phase = compute_aux_phase_curve(aux)
self.assertIsNotNone(phase)
expected = np.asarray([0.0, np.pi / 4.0, 3.0 * np.pi / 4.0, np.pi / 2.0], dtype=np.float32)
self.assertEqual(phase.shape, expected.shape)
self.assertTrue(np.allclose(phase, expected, atol=1e-6))
def test_compute_do1_tagged_aggregate_nanmean_merges_low_and_high(self):
low = np.asarray([1.0, np.nan, 5.0, np.nan], dtype=np.float32)
high = np.asarray([3.0, 7.0, np.nan, np.nan], dtype=np.float32)
merged = compute_do1_tagged_aggregate(low, high)
self.assertIsNotNone(merged)
self.assertTrue(np.allclose(merged[:3], np.asarray([2.0, 7.0, 5.0], dtype=np.float32), equal_nan=True))
self.assertTrue(np.isnan(merged[3]))
def test_resolve_visible_do1_tagged_aux_curves_obeys_checkbox_state(self):
aux_low = (
np.asarray([1.0, 2.0], dtype=np.float32),
np.asarray([3.0, 4.0], dtype=np.float32),
)
aux_high = (
np.asarray([5.0, 6.0], dtype=np.float32),
np.asarray([7.0, 8.0], dtype=np.float32),
)
hidden_low, hidden_high = resolve_visible_do1_tagged_aux_curves(aux_low, aux_high, enabled=False)
self.assertIsNone(hidden_low)
self.assertIsNone(hidden_high)
visible_low, visible_high = resolve_visible_do1_tagged_aux_curves(aux_low, aux_high, enabled=True)
self.assertIsNotNone(visible_low)
self.assertIsNotNone(visible_high)
self.assertTrue(np.allclose(visible_low[0], aux_low[0]))
self.assertTrue(np.allclose(visible_high[1], aux_high[1]))
def test_compute_do1_tagged_phase_curves_returns_two_independent_series(self):
aux_low = (
np.asarray([1.0, 1.0], dtype=np.float32),
np.asarray([0.0, 1.0], dtype=np.float32),
)
aux_high = (
np.asarray([1.0, -1.0], dtype=np.float32),
np.asarray([1.0, 1.0], dtype=np.float32),
)
phase_low, phase_high = compute_do1_tagged_phase_curves(aux_low, aux_high)
self.assertIsNotNone(phase_low)
self.assertIsNotNone(phase_high)
self.assertTrue(np.allclose(phase_low, np.asarray([0.0, np.pi / 4.0], dtype=np.float32), atol=1e-6))
self.assertTrue(np.allclose(phase_high, np.asarray([np.pi / 4.0, 3.0 * np.pi / 4.0], dtype=np.float32), atol=1e-6))
def test_decimate_curve_for_display_preserves_small_series(self):
xs = np.linspace(3.3, 14.3, 64, dtype=np.float64)
ys = np.linspace(-1.0, 1.0, 64, dtype=np.float32)
decimated_x, decimated_y = decimate_curve_for_display(xs, ys, max_points=128)
self.assertTrue(np.allclose(decimated_x, xs))
self.assertTrue(np.allclose(decimated_y, ys))
def test_decimate_curve_for_display_limits_points_and_keeps_endpoints(self):
xs = np.linspace(3.3, 14.3, 10000, dtype=np.float64)
ys = np.sin(np.linspace(0.0, 12.0 * np.pi, 10000)).astype(np.float32)
decimated_x, decimated_y = decimate_curve_for_display(xs, ys, max_points=512)
self.assertLessEqual(decimated_x.size, 512)
self.assertEqual(decimated_x.shape, decimated_y.shape)
self.assertAlmostEqual(float(decimated_x[0]), float(xs[0]), places=12)
self.assertAlmostEqual(float(decimated_x[-1]), float(xs[-1]), places=12)
self.assertAlmostEqual(float(decimated_y[0]), float(ys[0]), places=6)
self.assertAlmostEqual(float(decimated_y[-1]), float(ys[-1]), places=6)
def test_coalesce_packets_for_ui_keeps_newest_packets(self):
packets = [
(np.asarray([float(idx)], dtype=np.float32), {"sweep": idx}, None)
for idx in range(12)
]
kept, skipped = coalesce_packets_for_ui(packets, max_packets=8, backlog_packets=12)
self.assertEqual(skipped, 10)
self.assertEqual(len(kept), 2)
self.assertEqual(int(kept[0][1]["sweep"]), 10)
self.assertEqual(int(kept[1][1]["sweep"]), 11)
def test_coalesce_packets_for_ui_never_returns_empty_for_non_empty_input(self):
packets = [
(np.asarray([1.0], dtype=np.float32), {"sweep": 1}, None),
]
kept, skipped = coalesce_packets_for_ui(packets, max_packets=0)
self.assertEqual(skipped, 0)
self.assertEqual(len(kept), 1)
self.assertEqual(int(kept[0][1]["sweep"]), 1)
def test_coalesce_packets_for_ui_switches_to_latest_only_on_large_backlog(self):
packets = [
(np.asarray([float(idx)], dtype=np.float32), {"sweep": idx}, None)
for idx in range(40)
]
kept, skipped = coalesce_packets_for_ui(packets, max_packets=8, backlog_packets=40)
self.assertEqual(skipped, 39)
self.assertEqual(len(kept), 1)
self.assertEqual(int(kept[0][1]["sweep"]), 39)
def test_resolve_heavy_refresh_stride_increases_with_backlog(self):
self.assertEqual(resolve_heavy_refresh_stride(0, max_packets=8), 1)
self.assertEqual(resolve_heavy_refresh_stride(8, max_packets=8), 2)
self.assertEqual(resolve_heavy_refresh_stride(16, max_packets=8), 4)
def test_resolve_bscan_refresh_stride_limits_suppression(self):
self.assertEqual(resolve_bscan_refresh_stride(0, max_packets=8), 1)
self.assertEqual(resolve_bscan_refresh_stride(8, max_packets=8), 1)
self.assertEqual(resolve_bscan_refresh_stride(16, max_packets=8), 2)
def test_decimate_bscan_rows_for_display_keeps_shape_consistent(self):
axis = np.linspace(0.0, 1.0, 10, dtype=np.float64)
data = np.arange(50, dtype=np.float32).reshape(10, 5)
dec_axis, dec_data = decimate_bscan_rows_for_display(axis, data, max_points=4)
self.assertEqual(dec_data.shape, (4, 5))
self.assertIsNotNone(dec_axis)
self.assertEqual(dec_axis.shape, (4,))
self.assertAlmostEqual(float(dec_axis[0]), 0.0, places=12)
self.assertAlmostEqual(float(dec_axis[-1]), 1.0, places=12)
def test_decimate_bscan_rows_for_display_handles_missing_axis(self):
data = np.arange(32, dtype=np.float32).reshape(8, 4)
dec_axis, dec_data = decimate_bscan_rows_for_display(None, data, max_points=3)
self.assertIsNone(dec_axis)
self.assertEqual(dec_data.shape, (3, 4))
def test_update_expected_sweep_width_initializes_from_first_valid_sweep(self):
self.assertEqual(update_expected_sweep_width(0, 411), 411)
def test_update_expected_sweep_width_ignores_tiny_and_short_outliers(self):
expected = update_expected_sweep_width(0, 411)
self.assertEqual(update_expected_sweep_width(expected, 4), 411)
self.assertEqual(update_expected_sweep_width(expected, 180), 411)
def test_update_expected_sweep_width_applies_ema_for_normal_sweeps(self):
self.assertEqual(update_expected_sweep_width(411, 420), 412)
def test_is_short_sweep_compares_against_dynamic_expected_width(self):
self.assertFalse(is_short_sweep(411, 411))
self.assertTrue(is_short_sweep(180, 411))
def test_sanitize_curve_data_for_display_rejects_fully_nonfinite_series(self):
xs, ys = sanitize_curve_data_for_display(
np.asarray([np.nan, np.nan], dtype=np.float64),
np.asarray([np.nan, np.nan], dtype=np.float32),
)
self.assertEqual(xs.shape, (0,))
self.assertEqual(ys.shape, (0,))
def test_sanitize_image_for_display_rejects_fully_nonfinite_frame(self):
data = sanitize_image_for_display(np.full((4, 4), np.nan, dtype=np.float32))
self.assertIsNone(data)
def test_set_image_rect_if_ready_skips_uninitialized_image(self):
class _DummyImageItem:
def __init__(self):
self.calls = 0
def width(self):
return None
def height(self):
return None
def setRect(self, *_args):
self.calls += 1
image_item = _DummyImageItem()
applied = set_image_rect_if_ready(image_item, 0.0, 0.0, 10.0, 1.0)
self.assertFalse(applied)
self.assertEqual(image_item.calls, 0)
def test_resolve_axis_bounds_rejects_nonfinite_ranges(self):
bounds = resolve_axis_bounds(np.asarray([np.nan, np.inf], dtype=np.float64))
self.assertIsNone(bounds)
def test_resolve_distance_cut_start_interpolates_with_percent(self):
axis = np.asarray([0.0, 1.0, 2.0, 3.0], dtype=np.float64)
cut_start = resolve_distance_cut_start(axis, 50.0)
self.assertIsNotNone(cut_start)
self.assertAlmostEqual(float(cut_start), 1.5, places=6)
def test_apply_distance_cut_to_axis_keeps_farthest_point_for_extreme_cut(self):
axis = np.asarray([0.0, 1.0, 2.0, 3.0], dtype=np.float64)
cut_axis, keep_mask = apply_distance_cut_to_axis(axis, 10.0)
self.assertEqual(cut_axis.shape, (1,))
self.assertEqual(keep_mask.shape, axis.shape)
self.assertTrue(bool(keep_mask[-1]))
self.assertAlmostEqual(float(cut_axis[0]), 3.0, places=6)
def test_resolve_initial_window_size_stays_within_small_screen(self):
width, height = resolve_initial_window_size(800, 480)
self.assertLessEqual(width, 800)
self.assertLessEqual(height, 480)
self.assertGreaterEqual(width, 640)
self.assertGreaterEqual(height, 420)
def test_build_main_window_layout_uses_splitter_and_scroll_area(self):
os.environ.setdefault("QT_QPA_PLATFORM", "offscreen")
try:
from PyQt5 import QtCore, QtWidgets
except Exception as exc: # pragma: no cover - environment-dependent
self.skipTest(f"Qt unavailable: {exc}")
app = QtWidgets.QApplication.instance() or QtWidgets.QApplication([])
main_window = QtWidgets.QWidget()
try:
_layout, splitter, _plot_layout, settings_widget, settings_layout, settings_scroll = build_main_window_layout(
QtCore,
QtWidgets,
main_window,
)
self.assertIsInstance(splitter, QtWidgets.QSplitter)
self.assertIsInstance(settings_scroll, QtWidgets.QScrollArea)
self.assertIs(settings_scroll.widget(), settings_widget)
self.assertIsInstance(settings_layout, QtWidgets.QVBoxLayout)
finally:
main_window.close()
def test_background_subtracted_bscan_levels_ignore_zero_floor(self):
disp_fft_lin = np.zeros((4, 8), dtype=np.float32)
disp_fft_lin[1, 2:6] = np.asarray([0.05, 0.1, 0.5, 2.0], dtype=np.float32)
disp_fft_lin[2, 1:6] = np.asarray([0.08, 0.2, 0.7, 3.0, 9.0], dtype=np.float32)
disp_fft = fft_mag_to_db(disp_fft_lin)
levels = compute_background_subtracted_bscan_levels(disp_fft_lin, disp_fft)
self.assertIsNotNone(levels)
positive_vals = disp_fft[disp_fft_lin > 0.0]
self.assertAlmostEqual(levels[0], float(np.nanpercentile(positive_vals, 15.0)), places=5)
self.assertAlmostEqual(levels[1], float(np.nanpercentile(positive_vals, 99.7)), places=5)
zero_floor = disp_fft[disp_fft_lin == 0.0]
self.assertLess(float(np.nanmax(zero_floor)), levels[0])
def test_background_subtracted_bscan_levels_fallback_when_residuals_too_sparse(self):
disp_fft_lin = np.zeros((3, 4), dtype=np.float32)
disp_fft_lin[1, 2] = 1.0
disp_fft = fft_mag_to_db(disp_fft_lin)
levels = compute_background_subtracted_bscan_levels(disp_fft_lin, disp_fft)
self.assertIsNone(levels)
def test_fft_helpers_return_expected_shapes(self):
sweep = np.sin(np.linspace(0.0, 4.0 * np.pi, 128)).astype(np.float32)
freqs = np.linspace(3.3, 14.3, 128, dtype=np.float64)
mag = compute_fft_mag_row(sweep, freqs, 513)
row = compute_fft_row(sweep, freqs, 513)
axis = compute_distance_axis(freqs, 513)
self.assertEqual(mag.shape, (513,))
self.assertEqual(row.shape, (513,))
self.assertEqual(axis.shape, (513,))
self.assertTrue(np.all(np.diff(axis) >= 0.0))
def test_symmetric_ifft_spectrum_has_zero_gap_and_mirrored_band(self):
sweep = np.linspace(1.0, 2.0, 128, dtype=np.float32)
freqs = np.linspace(4.0, 10.0, 128, dtype=np.float64)
spectrum = build_symmetric_ifft_spectrum(sweep, freqs, fft_len=FFT_LEN)
self.assertIsNotNone(spectrum)
freq_axis = np.linspace(-10.0, 10.0, FFT_LEN, dtype=np.float64)
neg_idx_all = np.flatnonzero(freq_axis <= (-4.0))
pos_idx_all = np.flatnonzero(freq_axis >= 4.0)
band_len = int(min(neg_idx_all.size, pos_idx_all.size))
neg_idx = neg_idx_all[:band_len]
pos_idx = pos_idx_all[-band_len:]
zero_mask = (freq_axis > (-4.0)) & (freq_axis < 4.0)
self.assertTrue(np.allclose(spectrum[zero_mask], 0.0))
self.assertTrue(np.allclose(spectrum[neg_idx], spectrum[pos_idx][::-1]))
def test_positive_only_centered_spectrum_keeps_zeros_until_positive_min(self):
sweep = np.linspace(1.0, 2.0, 128, dtype=np.float32)
freqs = np.linspace(4.0, 10.0, 128, dtype=np.float64)
spectrum = build_positive_only_centered_ifft_spectrum(sweep, freqs, fft_len=FFT_LEN)
self.assertIsNotNone(spectrum)
freq_axis = np.linspace(-10.0, 10.0, FFT_LEN, dtype=np.float64)
zero_mask = freq_axis < 4.0
pos_idx = np.flatnonzero(freq_axis >= 4.0)
self.assertTrue(np.allclose(spectrum[zero_mask], 0.0))
self.assertTrue(np.any(np.abs(spectrum[pos_idx]) > 0.0))
def test_positive_only_exact_spectrum_uses_direct_index_insertion_without_window(self):
sweep = np.asarray([1.0, 2.0, 3.0], dtype=np.float32)
freqs = np.asarray([4.0, 5.0, 6.0], dtype=np.float64)
spectrum = build_positive_only_exact_centered_ifft_spectrum(sweep, freqs)
self.assertIsNotNone(spectrum)
df = (6.0 - 4.0) / 2.0
f_shift = np.arange(-6.0, 6.0 + (0.5 * df), df, dtype=np.float64)
idx = np.round((freqs - f_shift[0]) / df).astype(np.int64)
zero_mask = (f_shift > -6.0) & (f_shift < 4.0)
self.assertEqual(int(spectrum.size), int(f_shift.size))
self.assertTrue(np.allclose(spectrum[zero_mask], 0.0))
self.assertTrue(np.allclose(spectrum[idx], sweep))
def test_complex_symmetric_ifft_spectrum_uses_conjugate_mirror(self):
sweep = np.exp(1j * np.linspace(0.0, np.pi, 128)).astype(np.complex64)
freqs = np.linspace(4.0, 10.0, 128, dtype=np.float64)
spectrum = build_symmetric_ifft_spectrum(sweep, freqs, fft_len=FFT_LEN)
self.assertIsNotNone(spectrum)
freq_axis = np.linspace(-10.0, 10.0, FFT_LEN, dtype=np.float64)
neg_idx_all = np.flatnonzero(freq_axis <= (-4.0))
pos_idx_all = np.flatnonzero(freq_axis >= 4.0)
band_len = int(min(neg_idx_all.size, pos_idx_all.size))
neg_idx = neg_idx_all[:band_len]
pos_idx = pos_idx_all[-band_len:]
self.assertTrue(np.iscomplexobj(spectrum))
self.assertTrue(np.allclose(spectrum[neg_idx], np.conj(spectrum[pos_idx][::-1])))
def test_compute_fft_helpers_accept_complex_input(self):
sweep = np.exp(1j * np.linspace(0.0, 2.0 * np.pi, 128)).astype(np.complex64)
freqs = np.linspace(3.3, 14.3, 128, dtype=np.float64)
complex_row = compute_fft_complex_row(sweep, freqs, 513, mode="positive_only")
mag = compute_fft_mag_row(sweep, freqs, 513, mode="positive_only")
row = compute_fft_row(sweep, freqs, 513, mode="positive_only")
self.assertEqual(complex_row.shape, (513,))
self.assertTrue(np.iscomplexobj(complex_row))
self.assertEqual(mag.shape, (513,))
self.assertEqual(row.shape, (513,))
self.assertTrue(np.allclose(mag, np.abs(complex_row), equal_nan=True))
self.assertTrue(np.any(np.isfinite(mag)))
self.assertTrue(np.any(np.isfinite(row)))
def test_compute_fft_complex_row_positive_only_exact_matches_manual_ifftshift_ifft(self):
sweep = np.asarray([1.0 + 1.0j, 2.0 + 0.0j, 3.0 - 1.0j], dtype=np.complex64)
freqs = np.asarray([4.0, 5.0, 6.0], dtype=np.float64)
bins = 16
row = compute_fft_complex_row(sweep, freqs, bins, mode="positive_only_exact")
df = (6.0 - 4.0) / 2.0
f_shift = np.arange(-6.0, 6.0 + (0.5 * df), df, dtype=np.float64)
manual_shift = np.zeros((f_shift.size,), dtype=np.complex64)
idx = np.round((freqs - f_shift[0]) / df).astype(np.int64)
manual_shift[idx] = sweep
manual_ifft = np.fft.ifft(np.fft.ifftshift(manual_shift))
expected = np.full((bins,), np.nan + 0j, dtype=np.complex64)
expected[: manual_ifft.size] = np.asarray(manual_ifft, dtype=np.complex64)
self.assertEqual(row.shape, (bins,))
self.assertTrue(np.allclose(row, expected, equal_nan=True))
def test_positive_only_exact_distance_axis_uses_exact_grid_geometry(self):
freqs = np.asarray([4.0, 5.0, 6.0], dtype=np.float64)
bins = 8
axis = compute_distance_axis(freqs, bins, mode="positive_only_exact")
# With a small bins budget the exact-mode grid is downsampled so
# internal IFFT length does not exceed visible bins.
df_hz = 2e9
n_shift = int(np.arange(-6.0, 6.0 + 1.0, 2.0, dtype=np.float64).size)
expected_step = C_M_S / (2.0 * n_shift * df_hz)
expected = np.arange(bins, dtype=np.float64) * expected_step
self.assertEqual(axis.shape, (bins,))
self.assertTrue(np.allclose(axis, expected))
def test_positive_only_exact_mode_remains_stable_when_input_points_double(self):
bins = FFT_LEN // 2 + 1
tau_s = 45e-9
freqs_400 = np.linspace(3.3, 14.3, 400, dtype=np.float64)
freqs_800 = np.linspace(3.3, 14.3, 800, dtype=np.float64)
sweep_400 = np.exp(-1j * 2.0 * np.pi * freqs_400 * 1e9 * tau_s).astype(np.complex64)
sweep_800 = np.exp(-1j * 2.0 * np.pi * freqs_800 * 1e9 * tau_s).astype(np.complex64)
mag_400 = compute_fft_mag_row(sweep_400, freqs_400, bins, mode="positive_only_exact")
mag_800 = compute_fft_mag_row(sweep_800, freqs_800, bins, mode="positive_only_exact")
self.assertEqual(mag_400.shape, mag_800.shape)
finite = np.isfinite(mag_400) & np.isfinite(mag_800)
self.assertGreater(int(np.count_nonzero(finite)), int(0.95 * bins))
idx_400 = int(np.nanargmax(mag_400))
idx_800 = int(np.nanargmax(mag_800))
peak_400 = float(np.nanmax(mag_400))
peak_800 = float(np.nanmax(mag_800))
self.assertLess(abs(idx_400 - idx_800), 64)
self.assertGreater(idx_400, 8)
self.assertGreater(idx_800, 8)
self.assertLess(idx_400, bins - 8)
self.assertLess(idx_800, bins - 8)
self.assertGreater(peak_400, 0.05)
self.assertGreater(peak_800, 0.05)
def test_resolve_visible_fft_curves_handles_complex_mode(self):
complex_row = np.asarray([1.0 + 2.0j, -3.0 + 4.0j], dtype=np.complex64)
mag = np.abs(complex_row).astype(np.float32)
abs_curve, real_curve, imag_curve = resolve_visible_fft_curves(
complex_row,
mag,
complex_mode=True,
show_abs=True,
show_real=False,
show_imag=True,
)
self.assertTrue(np.allclose(abs_curve, mag))
self.assertIsNone(real_curve)
self.assertTrue(np.allclose(imag_curve, np.asarray([2.0, 4.0], dtype=np.float32)))
def test_resolve_visible_fft_curves_preserves_legacy_abs_mode(self):
mag = np.asarray([1.0, 2.0, 3.0], dtype=np.float32)
abs_curve, real_curve, imag_curve = resolve_visible_fft_curves(
None,
mag,
complex_mode=False,
show_abs=True,
show_real=True,
show_imag=True,
)
self.assertTrue(np.allclose(abs_curve, mag))
self.assertIsNone(real_curve)
self.assertIsNone(imag_curve)
def test_symmetric_distance_axis_uses_windowed_frequency_bounds(self):
freqs = np.linspace(4.0, 10.0, 128, dtype=np.float64)
axis = compute_distance_axis(freqs, 513, mode="symmetric")
df_hz = (2.0 * 10.0 / max(1, FFT_LEN - 1)) * 1e9
expected_step = 299_792_458.0 / (2.0 * FFT_LEN * df_hz)
self.assertEqual(axis.shape, (513,))
self.assertTrue(np.all(np.diff(axis) >= 0.0))
self.assertAlmostEqual(float(axis[1] - axis[0]), expected_step, places=15)
def test_peak_helpers_find_reference_and_peak_boxes(self):
xs = np.linspace(0.0, 10.0, 200)
ys = np.exp(-((xs - 5.0) ** 2) / 0.4) * 10.0 + 1.0
ref = rolling_median_ref(xs, ys, 2.0)
peaks = find_top_peaks_over_ref(xs, ys, ref, top_n=3)
width = find_peak_width_markers(xs, ys)
self.assertEqual(ref.shape, ys.shape)
self.assertEqual(len(peaks), 1)
self.assertGreater(peaks[0]["x"], 4.0)
self.assertLess(peaks[0]["x"], 6.0)
self.assertIsNotNone(width)
self.assertGreater(width["width"], 0.0)
if __name__ == "__main__":
unittest.main()

186
tests/test_ring_buffer.py
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@ -1,186 +0,0 @@
from __future__ import annotations
import numpy as np
import unittest
import warnings
from unittest.mock import patch
from rfg_adc_plotter.processing.fft import compute_fft_mag_row
from rfg_adc_plotter.state.ring_buffer import RingBuffer
class RingBufferTests(unittest.TestCase):
def test_ring_buffer_initializes_on_first_push(self):
ring = RingBuffer(max_sweeps=4)
sweep = np.linspace(-1.0, 1.0, 64, dtype=np.float32)
ring.push(sweep, np.linspace(3.3, 14.3, 64))
self.assertIsNotNone(ring.ring)
self.assertIsNotNone(ring.ring_fft)
self.assertIsNotNone(ring.ring_time)
self.assertIsNotNone(ring.distance_axis)
self.assertIsNotNone(ring.get_last_fft_linear())
self.assertIsNotNone(ring.last_fft_db)
self.assertEqual(ring.width, 64)
self.assertEqual(ring.ring.shape[0], 4)
self.assertEqual(ring.ring.shape[1], 64)
self.assertEqual(ring.ring_fft.shape, (4, ring.fft_bins))
def test_ring_buffer_reallocates_when_sweep_width_grows(self):
ring = RingBuffer(max_sweeps=3)
ring.push(np.ones((32,), dtype=np.float32), np.linspace(3.3, 14.3, 32))
first_width = ring.width
ring.push(np.ones((2048,), dtype=np.float32), np.linspace(3.3, 14.3, 2048))
self.assertGreater(ring.width, first_width)
self.assertIsNotNone(ring.ring)
self.assertEqual(ring.ring.shape, (3, ring.width))
def test_ring_buffer_reallocates_when_sweep_width_shrinks(self):
ring = RingBuffer(max_sweeps=3)
ring.push(np.ones((2048,), dtype=np.float32), np.linspace(3.3, 14.3, 2048))
ring.push(np.ones((256,), dtype=np.float32), np.linspace(3.3, 14.3, 256))
self.assertEqual(ring.width, 256)
self.assertIsNotNone(ring.ring)
self.assertEqual(ring.ring.shape, (3, 256))
def test_ring_buffer_tracks_latest_fft_and_display_arrays(self):
ring = RingBuffer(max_sweeps=2)
ring.push(np.linspace(0.0, 1.0, 64, dtype=np.float32), np.linspace(3.3, 14.3, 64))
ring.push(np.linspace(1.0, 0.0, 64, dtype=np.float32), np.linspace(3.3, 14.3, 64))
raw = ring.get_display_raw()
fft = ring.get_display_fft_linear()
self.assertEqual(raw.shape[1], 2)
self.assertEqual(fft.shape[1], 2)
self.assertIsNotNone(ring.last_fft_db)
self.assertEqual(ring.last_fft_db.shape, (ring.fft_bins,))
def test_ring_buffer_can_return_decimated_display_raw(self):
ring = RingBuffer(max_sweeps=3)
sweep_a = np.linspace(0.0, 1.0, 4096, dtype=np.float32)
sweep_b = np.linspace(1.0, 2.0, 4096, dtype=np.float32)
sweep_c = np.linspace(2.0, 3.0, 4096, dtype=np.float32)
freqs = np.linspace(3.3, 14.3, 4096, dtype=np.float64)
ring.push(sweep_a, freqs)
ring.push(sweep_b, freqs)
ring.push(sweep_c, freqs)
raw = ring.get_display_raw_decimated(256)
self.assertEqual(raw.shape, (256, 3))
self.assertAlmostEqual(float(raw[0, -1]), float(sweep_c[0]), places=6)
self.assertAlmostEqual(float(raw[-1, -1]), float(sweep_c[-1]), places=6)
def test_ring_buffer_can_switch_fft_mode_and_rebuild_fft_rows(self):
ring = RingBuffer(max_sweeps=2)
sweep = np.linspace(0.0, 1.0, 64, dtype=np.float32)
freqs = np.linspace(3.3, 14.3, 64, dtype=np.float64)
ring.push(sweep, freqs)
fft_before = ring.last_fft_db.copy()
axis_before = ring.distance_axis.copy()
changed = ring.set_symmetric_fft_enabled(False)
self.assertTrue(changed)
self.assertFalse(ring.fft_symmetric)
self.assertEqual(ring.get_display_raw().shape[1], 2)
self.assertIsNotNone(ring.get_last_fft_linear())
self.assertEqual(ring.last_fft_db.shape, fft_before.shape)
self.assertFalse(np.allclose(ring.last_fft_db, fft_before))
self.assertFalse(np.allclose(ring.distance_axis, axis_before))
def test_ring_buffer_can_switch_to_positive_only_fft_mode(self):
ring = RingBuffer(max_sweeps=2)
sweep = np.linspace(0.0, 1.0, 64, dtype=np.float32)
freqs = np.linspace(3.3, 14.3, 64, dtype=np.float64)
ring.push(sweep, freqs)
changed = ring.set_fft_mode("positive_only")
self.assertTrue(changed)
self.assertEqual(ring.fft_mode, "positive_only")
self.assertIsNotNone(ring.last_fft_db)
self.assertEqual(ring.last_fft_db.shape, (ring.fft_bins,))
self.assertIsNotNone(ring.distance_axis)
def test_ring_buffer_can_switch_to_positive_only_exact_fft_mode(self):
ring = RingBuffer(max_sweeps=2)
sweep = np.linspace(0.0, 1.0, 64, dtype=np.float32)
freqs = np.linspace(3.3, 14.3, 64, dtype=np.float64)
ring.push(sweep, freqs)
changed = ring.set_fft_mode("positive_only_exact")
self.assertTrue(changed)
self.assertEqual(ring.fft_mode, "positive_only_exact")
self.assertIsNotNone(ring.last_fft_db)
self.assertEqual(ring.last_fft_db.shape, (ring.fft_bins,))
self.assertIsNotNone(ring.distance_axis)
def test_ring_buffer_rebuilds_fft_from_complex_input(self):
ring = RingBuffer(max_sweeps=2)
freqs = np.linspace(3.3, 14.3, 64, dtype=np.float64)
complex_input = np.exp(1j * np.linspace(0.0, 2.0 * np.pi, 64)).astype(np.complex64)
display_sweep = np.abs(complex_input).astype(np.float32)
ring.push(display_sweep, freqs, fft_input=complex_input)
ring.set_fft_mode("direct")
expected = compute_fft_mag_row(complex_input, freqs, ring.fft_bins, mode="direct")
self.assertTrue(np.allclose(ring.get_last_fft_linear(), expected))
self.assertFalse(np.iscomplexobj(ring.get_display_fft_linear()))
self.assertTrue(np.allclose(ring.get_display_raw()[: display_sweep.size, -1], display_sweep))
def test_ring_buffer_reset_clears_cached_history(self):
ring = RingBuffer(max_sweeps=2)
ring.push(np.linspace(0.0, 1.0, 64, dtype=np.float32), np.linspace(4.0, 10.0, 64))
ring.reset()
self.assertIsNone(ring.ring)
self.assertIsNone(ring.ring_fft)
self.assertIsNone(ring.distance_axis)
self.assertIsNone(ring.last_fft_db)
self.assertEqual(ring.width, 0)
self.assertEqual(ring.head, 0)
def test_ring_buffer_push_ignores_all_nan_fft_without_runtime_warning(self):
ring = RingBuffer(max_sweeps=2)
freqs = np.linspace(3.3, 14.3, 64, dtype=np.float64)
ring.push(np.linspace(0.0, 1.0, 64, dtype=np.float32), freqs)
fft_before = ring.last_fft_db.copy()
y_min_before = ring.y_min_fft
y_max_before = ring.y_max_fft
with warnings.catch_warnings():
warnings.simplefilter("error", RuntimeWarning)
with patch(
"rfg_adc_plotter.state.ring_buffer.compute_fft_mag_row",
return_value=np.full((ring.fft_bins,), np.nan, dtype=np.float32),
):
ring.push(np.linspace(1.0, 2.0, 64, dtype=np.float32), freqs)
self.assertFalse(ring.last_push_fft_valid)
self.assertTrue(np.allclose(ring.last_fft_db, fft_before))
self.assertEqual(ring.y_min_fft, y_min_before)
self.assertEqual(ring.y_max_fft, y_max_before)
def test_ring_buffer_set_fft_mode_ignores_all_nan_rebuild_without_runtime_warning(self):
ring = RingBuffer(max_sweeps=2)
freqs = np.linspace(3.3, 14.3, 64, dtype=np.float64)
ring.push(np.linspace(0.0, 1.0, 64, dtype=np.float32), freqs)
fft_before = ring.last_fft_db.copy()
with warnings.catch_warnings():
warnings.simplefilter("error", RuntimeWarning)
with patch(
"rfg_adc_plotter.state.ring_buffer.compute_fft_mag_row",
return_value=np.full((ring.fft_bins,), np.nan, dtype=np.float32),
):
ring.set_fft_mode("direct")
self.assertFalse(ring.last_push_fft_valid)
self.assertTrue(np.allclose(ring.last_fft_db, fft_before))
self.assertEqual(ring.fft_mode, "direct")
if __name__ == "__main__":
unittest.main()

101
tests/test_ring_buffer_fft_axis.py Normal file
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@ -0,0 +1,101 @@
import numpy as np
from rfg_adc_plotter.state.ring_buffer import RingBuffer
def test_ring_buffer_allocates_fft_buffers_from_first_push():
ring = RingBuffer(max_sweeps=4)
ring.ensure_init(64)
sweep = np.linspace(-1.0, 1.0, 64, dtype=np.float32)
ring.push(sweep)
assert ring.ring_fft is not None
assert ring.fft_depth_axis_m is not None
assert ring.last_fft_vals is not None
assert ring.fft_bins == ring.ring_fft.shape[1]
assert ring.fft_bins == ring.fft_depth_axis_m.size
assert ring.fft_bins == ring.last_fft_vals.size
assert ring.last_fft_third_axes_m != (None, None, None)
assert ring.last_fft_third_vals != (None, None, None)
for axis, vals in zip(ring.last_fft_third_axes_m, ring.last_fft_third_vals):
assert axis is not None
assert vals is not None
assert axis.dtype == np.float32
assert vals.dtype == np.float32
assert axis.size == vals.size
# Legacy alias kept for compatibility with existing GUI code paths.
assert ring.fft_time_axis is ring.fft_depth_axis_m
def test_ring_buffer_reallocates_fft_buffers_when_ifft_length_changes():
ring = RingBuffer(max_sweeps=4)
ring.ensure_init(512)
ring.push(np.linspace(-1.0, 1.0, 64, dtype=np.float32))
first_bins = ring.fft_bins
first_shape = None if ring.ring_fft is None else ring.ring_fft.shape
ring.push(np.linspace(-1.0, 1.0, 512, dtype=np.float32))
second_bins = ring.fft_bins
second_shape = None if ring.ring_fft is None else ring.ring_fft.shape
assert ring.ring is not None # raw ring сохраняется
assert first_shape is not None and second_shape is not None
assert first_bins != second_bins
assert second_shape == (ring.max_sweeps, second_bins)
assert ring.fft_depth_axis_m is not None
assert ring.fft_depth_axis_m.size == second_bins
def test_ring_buffer_mode_switch_resets_fft_buffers_only():
ring = RingBuffer(max_sweeps=4)
ring.ensure_init(128)
ring.push(np.linspace(-1.0, 1.0, 128, dtype=np.float32))
assert ring.ring is not None
assert ring.ring_fft is not None
raw_before = ring.ring.copy()
assert ring.last_fft_third_axes_m != (None, None, None)
assert ring.last_fft_third_vals != (None, None, None)
changed = ring.set_fft_complex_mode("diff")
assert changed is True
assert ring.fft_complex_mode == "diff"
assert ring.ring is not None
assert np.array_equal(ring.ring, raw_before, equal_nan=True)
assert ring.ring_fft is None
assert ring.fft_depth_axis_m is None
assert ring.last_fft_vals is None
assert ring.last_fft_third_axes_m == (None, None, None)
assert ring.last_fft_third_vals == (None, None, None)
assert ring.fft_bins == 0
ring.push(np.linspace(-1.0, 1.0, 128, dtype=np.float32))
assert ring.ring_fft is not None
assert ring.fft_depth_axis_m is not None
assert ring.last_fft_vals is not None
assert ring.last_fft_third_axes_m != (None, None, None)
assert ring.last_fft_third_vals != (None, None, None)
for axis, vals in zip(ring.last_fft_third_axes_m, ring.last_fft_third_vals):
assert axis is not None
assert vals is not None
assert axis.dtype == np.float32
assert vals.dtype == np.float32
assert axis.size == vals.size
def test_ring_buffer_short_sweeps_keep_third_profiles_well_formed():
for n in (1, 2, 3):
ring = RingBuffer(max_sweeps=4)
ring.ensure_init(n)
ring.push(np.linspace(-1.0, 1.0, n, dtype=np.float32))
assert ring.last_fft_third_axes_m != (None, None, None)
assert ring.last_fft_third_vals != (None, None, None)
for axis, vals in zip(ring.last_fft_third_axes_m, ring.last_fft_third_vals):
assert axis is not None
assert vals is not None
assert axis.dtype == np.float32
assert vals.dtype == np.float32
assert axis.size == vals.size

541
tests/test_sweep_parser_core.py
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@ -1,541 +0,0 @@
from __future__ import annotations
import math
import unittest
from rfg_adc_plotter.io.sweep_parser_core import (
AsciiSweepParser,
ComplexAsciiSweepParser,
LegacyBinaryParser,
LogScale16BitX2BinaryParser,
LogScaleBinaryParser32,
ParserTestStreamParser,
PointEvent,
StartEvent,
SweepAssembler,
log_pair_to_sweep,
)
def _u16le(word: int) -> bytes:
w = int(word) & 0xFFFF
return bytes((w & 0xFF, (w >> 8) & 0xFF))
def _pack_legacy_start(ch: int) -> bytes:
return b"\xff\xff" * 3 + bytes((0x0A, int(ch) & 0xFF))
def _pack_legacy_point(ch: int, step: int, value_i32: int) -> bytes:
value = int(value_i32) & 0xFFFF_FFFF
return b"".join(
[
_u16le(step),
_u16le((value >> 16) & 0xFFFF),
_u16le(value & 0xFFFF),
bytes((0x0A, int(ch) & 0xFF)),
]
)
def _pack_log_start(ch: int) -> bytes:
return b"\xff\xff" * 5 + bytes((0x0A, int(ch) & 0xFF))
def _pack_log_point(step: int, avg1: int, avg2: int, ch: int = 0) -> bytes:
a1 = int(avg1) & 0xFFFF_FFFF
a2 = int(avg2) & 0xFFFF_FFFF
return b"".join(
[
_u16le(step),
_u16le((a1 >> 16) & 0xFFFF),
_u16le(a1 & 0xFFFF),
_u16le((a2 >> 16) & 0xFFFF),
_u16le(a2 & 0xFFFF),
bytes((0x0A, int(ch) & 0xFF)),
]
)
def _pack_log16_start(ch: int) -> bytes:
return b"\xff\xff" * 3 + bytes((0x0A, int(ch) & 0xFF))
def _pack_log16_point(step: int, avg1: int, avg2: int) -> bytes:
return b"".join(
[
_u16le(step),
_u16le(avg1),
_u16le(avg2),
_u16le(0xFFFF),
]
)
def _pack_tty_start() -> bytes:
return b"".join([_u16le(0x000A), _u16le(0xFFFF), _u16le(0xFFFF), _u16le(0xFFFF)])
def _pack_tty_point(step: int, ch1: int, ch2: int) -> bytes:
return b"".join(
[
_u16le(0x000A),
_u16le(step),
_u16le(ch1),
_u16le(ch2),
]
)
def _pack_tty_tagged_point(marker_word0: int, step: int, ch1: int, ch2: int) -> bytes:
return b"".join(
[
_u16le(marker_word0),
_u16le(step),
_u16le(ch1),
_u16le(ch2),
]
)
def _pack_tty_tagged_low_point(step: int, ch1: int, ch2: int) -> bytes:
return _pack_tty_tagged_point(0x00A3, step, ch1, ch2)
def _pack_tty_tagged_high_point(step: int, ch1: int, ch2: int) -> bytes:
return _pack_tty_tagged_point(0x00A4, step, ch1, ch2)
def _pack_logdet_point(step: int, value: int) -> bytes:
return b"".join(
[
_u16le(0x001A),
_u16le(step),
_u16le(value),
_u16le(0x0000),
]
)
class SweepParserCoreTests(unittest.TestCase):
def test_ascii_parser_emits_start_and_points(self):
parser = AsciiSweepParser()
events = parser.feed(b"Sweep_start\ns 1 2 -3\ns2 4 5\n")
self.assertIsInstance(events[0], StartEvent)
self.assertIsInstance(events[1], PointEvent)
self.assertIsInstance(events[2], PointEvent)
self.assertEqual(events[1].ch, 1)
self.assertEqual(events[1].x, 2)
self.assertEqual(events[1].y, -3.0)
self.assertEqual(events[2].ch, 2)
self.assertEqual(events[2].x, 4)
self.assertEqual(events[2].y, 5.0)
def test_legacy_binary_parser_resynchronizes_after_garbage(self):
parser = LegacyBinaryParser()
stream = b"\x00junk" + _pack_legacy_start(3) + _pack_legacy_point(3, 1, -2)
events = parser.feed(stream)
self.assertIsInstance(events[0], StartEvent)
self.assertEqual(events[0].ch, 3)
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].ch, 3)
self.assertEqual(events[1].x, 1)
self.assertEqual(events[1].y, -2.0)
def test_legacy_binary_parser_detects_new_sweep_on_step_reset(self):
parser = LegacyBinaryParser()
stream = b"".join(
[
_pack_legacy_point(3, 1, -2),
_pack_legacy_point(3, 2, -3),
_pack_legacy_point(3, 1, -4),
]
)
events = parser.feed(stream)
self.assertIsInstance(events[0], PointEvent)
self.assertIsInstance(events[1], PointEvent)
self.assertIsInstance(events[2], StartEvent)
self.assertEqual(events[2].ch, 3)
self.assertIsInstance(events[3], PointEvent)
self.assertEqual(events[3].x, 1)
self.assertEqual(events[3].y, -4.0)
def test_legacy_binary_parser_accepts_tty_ch1_ch2_stream(self):
parser = LegacyBinaryParser()
stream = b"".join(
[
_pack_tty_start(),
_pack_tty_point(1, 100, 90),
_pack_tty_point(2, 120, 95),
]
)
events = parser.feed(stream)
self.assertIsInstance(events[0], StartEvent)
self.assertEqual(events[0].ch, 0)
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].x, 1)
self.assertEqual(events[1].y, 18100.0)
self.assertEqual(events[1].aux, (100.0, 90.0))
self.assertEqual(events[1].signal_kind, "bin_iq")
self.assertIsInstance(events[2], PointEvent)
self.assertEqual(events[2].x, 2)
self.assertEqual(events[2].y, 23425.0)
self.assertEqual(events[2].aux, (120.0, 95.0))
self.assertEqual(events[2].signal_kind, "bin_iq")
def test_legacy_binary_parser_detects_new_tty_sweep_on_step_reset(self):
parser = LegacyBinaryParser()
stream = b"".join(
[
_pack_tty_start(),
_pack_tty_point(1, 100, 90),
_pack_tty_point(2, 110, 95),
_pack_tty_point(1, 120, 80),
]
)
events = parser.feed(stream)
self.assertIsInstance(events[0], StartEvent)
self.assertIsInstance(events[1], PointEvent)
self.assertIsInstance(events[2], PointEvent)
self.assertIsInstance(events[3], StartEvent)
self.assertEqual(events[3].ch, 0)
self.assertIsInstance(events[4], PointEvent)
self.assertEqual(events[4].x, 1)
self.assertEqual(events[4].aux, (120.0, 80.0))
self.assertEqual(events[4].signal_kind, "bin_iq")
def test_legacy_binary_parser_accepts_tty_do1_tagged_stream(self):
parser = LegacyBinaryParser()
stream = b"".join(
[
_pack_tty_start(),
_pack_tty_tagged_low_point(1, 100, 90),
_pack_tty_tagged_high_point(1, 120, 95),
]
)
events = parser.feed(stream)
self.assertEqual(len(events), 3)
self.assertIsInstance(events[0], StartEvent)
self.assertEqual(events[0].signal_kind, "bin_iq")
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].signal_kind, "bin_iq_do1_tagged")
self.assertEqual(events[1].do1_level, "low")
self.assertEqual(events[1].x, 1)
self.assertEqual(events[1].aux, (100.0, 90.0))
self.assertIsInstance(events[2], PointEvent)
self.assertEqual(events[2].signal_kind, "bin_iq_do1_tagged")
self.assertEqual(events[2].do1_level, "high")
self.assertEqual(events[2].x, 1)
self.assertEqual(events[2].aux, (120.0, 95.0))
def test_legacy_binary_parser_keeps_same_step_for_different_do1_levels_in_one_sweep(self):
parser = LegacyBinaryParser()
stream = b"".join(
[
_pack_tty_start(),
_pack_tty_tagged_low_point(1, 100, 90),
_pack_tty_tagged_high_point(1, 120, 95),
_pack_tty_tagged_low_point(2, 130, 80),
_pack_tty_tagged_high_point(2, 140, 75),
]
)
events = parser.feed(stream)
start_events = [event for event in events if isinstance(event, StartEvent)]
self.assertEqual(len(start_events), 1)
self.assertEqual(start_events[0].signal_kind, "bin_iq")
point_levels = [event.do1_level for event in events if isinstance(event, PointEvent)]
self.assertEqual(point_levels, ["low", "high", "low", "high"])
def test_legacy_binary_parser_resets_tagged_stream_only_on_same_level_step_reset(self):
parser = LegacyBinaryParser()
stream = b"".join(
[
_pack_tty_start(),
_pack_tty_tagged_low_point(1, 100, 90),
_pack_tty_tagged_high_point(1, 120, 95),
_pack_tty_tagged_low_point(2, 130, 80),
_pack_tty_tagged_high_point(2, 140, 75),
_pack_tty_tagged_low_point(1, 110, 85),
]
)
events = parser.feed(stream)
self.assertIsInstance(events[0], StartEvent)
self.assertIsInstance(events[1], PointEvent)
self.assertIsInstance(events[2], PointEvent)
self.assertIsInstance(events[3], PointEvent)
self.assertIsInstance(events[4], PointEvent)
self.assertIsInstance(events[5], StartEvent)
self.assertEqual(events[5].signal_kind, "bin_iq_do1_tagged")
self.assertIsInstance(events[6], PointEvent)
self.assertEqual(events[6].do1_level, "low")
self.assertEqual(events[6].x, 1)
def test_legacy_binary_parser_tty_mode_does_not_flip_to_legacy_on_ch2_low_byte_0x0a(self):
parser = LegacyBinaryParser()
stream = b"".join(
[
_pack_tty_start(),
_pack_tty_point(1, 100, 0x040A), # low byte is 0x0A: used to be misparsed as legacy
_pack_tty_point(2, 120, 0x0410),
]
)
events = parser.feed(stream)
self.assertEqual(len(events), 3)
self.assertIsInstance(events[0], StartEvent)
self.assertEqual(events[0].ch, 0)
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].ch, 0)
self.assertEqual(events[1].x, 1)
self.assertEqual(events[1].aux, (100.0, 1034.0))
self.assertEqual(events[1].y, 1079156.0)
self.assertIsInstance(events[2], PointEvent)
self.assertEqual(events[2].ch, 0)
self.assertEqual(events[2].x, 2)
self.assertEqual(events[2].aux, (120.0, 1040.0))
self.assertEqual(events[2].y, 1096000.0)
def test_legacy_binary_parser_accepts_logdet_stream(self):
parser = LegacyBinaryParser()
stream = b"".join(
[
_pack_logdet_point(1, 0x0F77),
_pack_logdet_point(2, 0xF234),
]
)
events = parser.feed(stream)
self.assertEqual(len(events), 2)
self.assertIsInstance(events[0], PointEvent)
self.assertEqual(events[0].x, 1)
self.assertEqual(events[0].y, 3959.0)
self.assertIsNone(events[0].aux)
self.assertEqual(events[0].signal_kind, "bin_logdet")
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].x, 2)
self.assertEqual(events[1].y, -3532.0)
self.assertEqual(events[1].signal_kind, "bin_logdet")
def test_legacy_binary_parser_splits_packet_on_bin_signal_kind_change(self):
parser = LegacyBinaryParser()
stream = b"".join(
[
_pack_tty_start(),
_pack_tty_point(1, 100, 90),
_pack_tty_point(2, 110, 95),
_pack_logdet_point(3, 0x0F77),
]
)
events = parser.feed(stream)
self.assertIsInstance(events[0], StartEvent)
self.assertEqual(events[0].signal_kind, "bin_iq")
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].signal_kind, "bin_iq")
self.assertIsInstance(events[2], PointEvent)
self.assertEqual(events[2].signal_kind, "bin_iq")
self.assertIsInstance(events[3], StartEvent)
self.assertEqual(events[3].signal_kind, "bin_logdet")
self.assertIsInstance(events[4], PointEvent)
self.assertEqual(events[4].x, 3)
self.assertEqual(events[4].signal_kind, "bin_logdet")
def test_complex_ascii_parser_detects_new_sweep_on_step_reset(self):
parser = ComplexAsciiSweepParser()
events = parser.feed(b"0 3 4\n1 5 12\n0 8 15\n")
self.assertIsInstance(events[0], PointEvent)
self.assertEqual(events[0].x, 0)
self.assertEqual(events[0].y, 5.0)
self.assertEqual(events[0].aux, (3.0, 4.0))
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].y, 13.0)
self.assertIsInstance(events[2], StartEvent)
self.assertIsInstance(events[3], PointEvent)
self.assertEqual(events[3].aux, (8.0, 15.0))
def test_logscale_32_parser_keeps_channel_and_aux_values(self):
parser = LogScaleBinaryParser32()
stream = _pack_log_start(5) + _pack_log_point(7, 1500, 700, ch=5)
events = parser.feed(stream)
self.assertIsInstance(events[0], StartEvent)
self.assertEqual(events[0].ch, 5)
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].ch, 5)
self.assertEqual(events[1].x, 7)
self.assertAlmostEqual(events[1].y, log_pair_to_sweep(1500, 700), places=6)
self.assertEqual(events[1].aux, (1500.0, 700.0))
def test_logscale_32_parser_detects_new_sweep_on_step_reset(self):
parser = LogScaleBinaryParser32()
stream = b"".join(
[
_pack_log_point(1, 1500, 700, ch=5),
_pack_log_point(2, 1400, 650, ch=5),
_pack_log_point(1, 1300, 600, ch=5),
]
)
events = parser.feed(stream)
self.assertIsInstance(events[0], PointEvent)
self.assertIsInstance(events[1], PointEvent)
self.assertIsInstance(events[2], StartEvent)
self.assertEqual(events[2].ch, 5)
self.assertIsInstance(events[3], PointEvent)
self.assertEqual(events[3].x, 1)
self.assertAlmostEqual(events[3].y, log_pair_to_sweep(1300, 600), places=6)
def test_log_pair_to_sweep_is_order_independent(self):
self.assertAlmostEqual(log_pair_to_sweep(1500, 700), log_pair_to_sweep(700, 1500), places=6)
def test_logscale_16bit_parser_uses_last_start_channel(self):
parser = LogScale16BitX2BinaryParser()
stream = _pack_log16_start(2) + _pack_log16_point(1, 100, 90)
events = parser.feed(stream)
self.assertIsInstance(events[0], StartEvent)
self.assertEqual(events[0].ch, 2)
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].ch, 2)
self.assertAlmostEqual(events[1].y, math.hypot(100.0, 90.0), places=6)
self.assertEqual(events[1].aux, (100.0, 90.0))
def test_logscale_16bit_parser_detects_new_sweep_on_step_reset(self):
parser = LogScale16BitX2BinaryParser()
stream = b"".join(
[
_pack_log16_start(2),
_pack_log16_point(1, 100, 90),
_pack_log16_point(2, 110, 95),
_pack_log16_point(1, 120, 80),
]
)
events = parser.feed(stream)
self.assertIsInstance(events[0], StartEvent)
self.assertIsInstance(events[1], PointEvent)
self.assertIsInstance(events[2], PointEvent)
self.assertIsInstance(events[3], StartEvent)
self.assertEqual(events[3].ch, 2)
self.assertIsInstance(events[4], PointEvent)
self.assertEqual(events[4].x, 1)
self.assertAlmostEqual(events[4].y, math.hypot(120.0, 80.0), places=6)
def test_parser_test_stream_parser_recovers_point_after_single_separator(self):
parser = ParserTestStreamParser()
stream = b"".join(
[
b"\xff\xff\xff\xff",
bytes((0x0A, 4)),
_u16le(1),
_u16le(100),
_u16le(90),
_u16le(0xFFFF),
]
)
events = parser.feed(stream)
events.extend(parser.feed(_u16le(2)))
self.assertIsInstance(events[0], StartEvent)
self.assertEqual(events[0].ch, 4)
self.assertIsInstance(events[1], PointEvent)
self.assertEqual(events[1].ch, 4)
self.assertEqual(events[1].x, 1)
self.assertAlmostEqual(events[1].y, math.hypot(100.0, 90.0), places=6)
self.assertEqual(events[1].aux, (100.0, 90.0))
def test_sweep_assembler_builds_aux_curves_without_inversion(self):
assembler = SweepAssembler(fancy=False, apply_inversion=False)
self.assertIsNone(assembler.consume(StartEvent(ch=1, signal_kind="bin_iq")))
assembler.consume(PointEvent(ch=1, x=1, y=10.0, aux=(100.0, 90.0), signal_kind="bin_iq"))
assembler.consume(PointEvent(ch=1, x=2, y=20.0, aux=(110.0, 95.0), signal_kind="bin_iq"))
sweep, info, aux = assembler.finalize_current()
self.assertEqual(sweep.shape[0], 3)
self.assertEqual(info["ch"], 1)
self.assertEqual(info["signal_kind"], "bin_iq")
self.assertIsNotNone(aux)
self.assertEqual(aux[0][1], 100.0)
self.assertEqual(aux[1][2], 95.0)
def test_sweep_assembler_builds_tagged_payload_and_nanmean_aggregate(self):
assembler = SweepAssembler(fancy=False, apply_inversion=False)
self.assertIsNone(assembler.consume(StartEvent(ch=0, signal_kind="bin_iq_do1_tagged")))
assembler.consume(
PointEvent(
ch=0,
x=1,
y=10.0,
aux=(100.0, 90.0),
signal_kind="bin_iq_do1_tagged",
do1_level="low",
)
)
assembler.consume(
PointEvent(
ch=0,
x=1,
y=20.0,
aux=(120.0, 95.0),
signal_kind="bin_iq_do1_tagged",
do1_level="high",
)
)
sweep, info, aux = assembler.finalize_current()
self.assertIsNone(aux)
self.assertEqual(info["signal_kind"], "bin_iq_do1_tagged")
self.assertAlmostEqual(float(sweep[1]), 15.0, places=6)
payload = info.get("_do1_tagged_payload")
self.assertIsInstance(payload, dict)
self.assertIn("raw_low", payload)
self.assertIn("raw_high", payload)
self.assertIn("aux_low", payload)
self.assertIn("aux_high", payload)
def test_sweep_assembler_splits_packet_on_channel_switch(self):
assembler = SweepAssembler(fancy=False, apply_inversion=False)
self.assertIsNone(assembler.consume(PointEvent(ch=1, x=1, y=10.0)))
packet = assembler.consume(PointEvent(ch=2, x=1, y=20.0))
self.assertIsNotNone(packet)
sweep_1, info_1, aux_1 = packet
self.assertIsNone(aux_1)
self.assertEqual(info_1["ch"], 1)
self.assertEqual(info_1["chs"], [1])
self.assertAlmostEqual(float(sweep_1[1]), 10.0, places=6)
sweep_2, info_2, aux_2 = assembler.finalize_current()
self.assertIsNone(aux_2)
self.assertEqual(info_2["ch"], 2)
self.assertEqual(info_2["chs"], [2])
self.assertAlmostEqual(float(sweep_2[1]), 20.0, places=6)
def test_sweep_assembler_splits_packet_on_signal_kind_switch(self):
assembler = SweepAssembler(fancy=False, apply_inversion=False)
self.assertIsNone(assembler.consume(PointEvent(ch=0, x=1, y=10.0, signal_kind="bin_iq")))
packet = assembler.consume(PointEvent(ch=0, x=1, y=20.0, signal_kind="bin_logdet"))
self.assertIsNotNone(packet)
sweep_1, info_1, aux_1 = packet
self.assertIsNone(aux_1)
self.assertEqual(info_1["signal_kind"], "bin_iq")
self.assertAlmostEqual(float(sweep_1[1]), 10.0, places=6)
sweep_2, info_2, aux_2 = assembler.finalize_current()
self.assertIsNone(aux_2)
self.assertEqual(info_2["signal_kind"], "bin_logdet")
self.assertAlmostEqual(float(sweep_2[1]), 20.0, places=6)
if __name__ == "__main__":
unittest.main()

304
tests/test_sweep_reader.py
View File

@ -1,304 +0,0 @@
from __future__ import annotations
import contextlib
import io
import threading
import time
import unittest
from queue import Queue
from unittest.mock import patch
from rfg_adc_plotter.io import sweep_reader as sweep_reader_module
from rfg_adc_plotter.io.sweep_reader import SweepReader, _PARSER_16_BIT_X2_PROBE_BYTES
def _u16le(word: int) -> bytes:
value = int(word) & 0xFFFF
return bytes((value & 0xFF, (value >> 8) & 0xFF))
def _pack_legacy_point(ch: int, step: int, value_i32: int) -> bytes:
value = int(value_i32) & 0xFFFF_FFFF
return b"".join(
[
_u16le(step),
_u16le((value >> 16) & 0xFFFF),
_u16le(value & 0xFFFF),
bytes((0x0A, int(ch) & 0xFF)),
]
)
def _pack_log16_start(ch: int) -> bytes:
return b"\xff\xff" * 3 + bytes((0x0A, int(ch) & 0xFF))
def _pack_log16_point(step: int, real: int, imag: int) -> bytes:
return b"".join(
[
_u16le(step),
_u16le(real),
_u16le(imag),
_u16le(0xFFFF),
]
)
def _pack_tty_start() -> bytes:
return b"".join(
[
_u16le(0x000A),
_u16le(0xFFFF),
_u16le(0xFFFF),
_u16le(0xFFFF),
]
)
def _pack_tty_point(step: int, ch1: int, ch2: int) -> bytes:
return b"".join(
[
_u16le(0x000A),
_u16le(step),
_u16le(ch1),
_u16le(ch2),
]
)
def _pack_tty_tagged_point(marker_word0: int, step: int, ch1: int, ch2: int) -> bytes:
return b"".join(
[
_u16le(marker_word0),
_u16le(step),
_u16le(ch1),
_u16le(ch2),
]
)
def _pack_tty_tagged_low(step: int, ch1: int, ch2: int) -> bytes:
return _pack_tty_tagged_point(0x00A3, step, ch1, ch2)
def _pack_tty_tagged_high(step: int, ch1: int, ch2: int) -> bytes:
return _pack_tty_tagged_point(0x00A4, step, ch1, ch2)
def _pack_logdet_point(step: int, value: int) -> bytes:
return b"".join(
[
_u16le(0x001A),
_u16le(step),
_u16le(value),
_u16le(0x0000),
]
)
def _chunk_bytes(data: bytes, size: int = 4096) -> list[bytes]:
return [data[idx : idx + size] for idx in range(0, len(data), size)]
class _FakeSerialLineSource:
def __init__(self, path: str, baud: int, timeout: float = 1.0):
self.path = path
self.baud = baud
self.timeout = timeout
self._using = "fake"
def close(self) -> None:
pass
class _FakeChunkReader:
payload_chunks: list[bytes] = []
def __init__(self, src):
self._src = src
self._chunks = list(type(self).payload_chunks)
def read_available(self) -> bytes:
if self._chunks:
return self._chunks.pop(0)
return b""
class SweepReaderTests(unittest.TestCase):
def _start_reader(self, payload: bytes, **reader_kwargs):
queue: Queue = Queue()
stop_event = threading.Event()
stderr = io.StringIO()
_FakeChunkReader.payload_chunks = _chunk_bytes(payload)
reader = SweepReader(
"/tmp/fake-tty",
115200,
queue,
stop_event,
**reader_kwargs,
)
stack = contextlib.ExitStack()
stack.enter_context(patch.object(sweep_reader_module, "SerialLineSource", _FakeSerialLineSource))
stack.enter_context(patch.object(sweep_reader_module, "SerialChunkReader", _FakeChunkReader))
stack.enter_context(contextlib.redirect_stderr(stderr))
reader.start()
return stack, reader, queue, stop_event, stderr
def test_parser_16_bit_x2_falls_back_to_legacy_stream(self):
payload = bytearray()
while len(payload) < (_PARSER_16_BIT_X2_PROBE_BYTES + 24):
payload += _pack_legacy_point(3, 1, -2)
payload += _pack_legacy_point(3, 2, -3)
payload += _pack_legacy_point(3, 1, -4)
stack, reader, queue, stop_event, stderr = self._start_reader(bytes(payload), parser_16_bit_x2=True)
try:
sweep, info, aux = queue.get(timeout=2.0)
self.assertEqual(info["ch"], 3)
self.assertIsNone(aux)
self.assertGreaterEqual(sweep.shape[0], 3)
self.assertIn("fallback -> legacy", stderr.getvalue())
finally:
stop_event.set()
reader.join(timeout=1.0)
stack.close()
def test_parser_16_bit_x2_falls_back_to_tty_ch1_ch2_stream(self):
payload = bytearray()
while len(payload) < (_PARSER_16_BIT_X2_PROBE_BYTES + 24):
payload += _pack_tty_start()
payload += _pack_tty_point(1, 100, 90)
payload += _pack_tty_point(2, 120, 95)
payload += _pack_tty_point(1, 80, 70)
stack, reader, queue, stop_event, stderr = self._start_reader(bytes(payload), parser_16_bit_x2=True)
try:
sweep, info, aux = queue.get(timeout=2.0)
self.assertEqual(info["ch"], 0)
self.assertIsNotNone(aux)
self.assertGreaterEqual(sweep.shape[0], 3)
self.assertAlmostEqual(float(sweep[1]), 18100.0, places=6)
self.assertAlmostEqual(float(sweep[2]), 23425.0, places=6)
self.assertIn("fallback -> legacy", stderr.getvalue())
finally:
stop_event.set()
reader.join(timeout=1.0)
stack.close()
def test_parser_16_bit_x2_falls_back_to_tty_do1_tagged_stream(self):
payload = bytearray()
while len(payload) < (_PARSER_16_BIT_X2_PROBE_BYTES + 40):
payload += _pack_tty_start()
payload += _pack_tty_tagged_low(1, 100, 90)
payload += _pack_tty_tagged_high(1, 120, 95)
payload += _pack_tty_tagged_low(2, 110, 80)
payload += _pack_tty_tagged_high(2, 130, 70)
payload += _pack_tty_tagged_low(1, 105, 85)
stack, reader, queue, stop_event, stderr = self._start_reader(bytes(payload), parser_16_bit_x2=True)
try:
sweep, info, aux = queue.get(timeout=2.0)
self.assertEqual(info["signal_kind"], "bin_iq_do1_tagged")
self.assertIsNone(aux)
self.assertIn("_do1_tagged_payload", info)
self.assertGreaterEqual(sweep.shape[0], 2)
self.assertIn("fallback -> legacy", stderr.getvalue())
finally:
stop_event.set()
reader.join(timeout=1.0)
stack.close()
def test_parser_16_bit_x2_keeps_true_complex_stream(self):
payload = b"".join(
[
_pack_log16_start(2),
_pack_log16_point(1, 3, 4),
_pack_log16_point(2, 5, 12),
_pack_log16_point(1, 8, 15),
]
)
stack, reader, queue, stop_event, stderr = self._start_reader(payload, parser_16_bit_x2=True)
try:
sweep, info, aux = queue.get(timeout=1.0)
self.assertEqual(info["ch"], 2)
self.assertIsNotNone(aux)
self.assertAlmostEqual(float(sweep[1]), 5.0, places=6)
self.assertAlmostEqual(float(sweep[2]), 13.0, places=6)
self.assertNotIn("fallback -> legacy", stderr.getvalue())
finally:
stop_event.set()
reader.join(timeout=1.0)
stack.close()
def test_parser_16_bit_x2_falls_back_to_logdet_1a00_stream(self):
payload = bytearray()
while len(payload) < (_PARSER_16_BIT_X2_PROBE_BYTES + 24):
payload += _pack_logdet_point(1, 0x0F77)
payload += _pack_logdet_point(2, 0x0FCB)
payload += _pack_logdet_point(1, 0x0F88)
stack, reader, queue, stop_event, stderr = self._start_reader(bytes(payload), parser_16_bit_x2=True)
try:
sweep, info, aux = queue.get(timeout=2.0)
self.assertEqual(info["signal_kind"], "bin_logdet")
self.assertIsNone(aux)
self.assertGreaterEqual(sweep.shape[0], 3)
self.assertAlmostEqual(float(sweep[1]), 3959.0, places=6)
self.assertIn("fallback -> legacy", stderr.getvalue())
finally:
stop_event.set()
reader.join(timeout=1.0)
stack.close()
def test_parser_16_bit_x2_probe_inconclusive_logs_hint(self):
payload = b"\x00" * (_PARSER_16_BIT_X2_PROBE_BYTES + 128)
stack, reader, queue, stop_event, stderr = self._start_reader(payload, parser_16_bit_x2=True)
try:
deadline = time.time() + 1.5
logs = ""
while time.time() < deadline:
logs = stderr.getvalue()
if "probe inconclusive" in logs:
break
time.sleep(0.02)
self.assertTrue(queue.empty())
self.assertIn("probe inconclusive", logs)
self.assertIn("try --bin", logs)
finally:
stop_event.set()
reader.join(timeout=1.0)
stack.close()
def test_reader_logs_no_input_warning_when_source_is_idle(self):
with patch.object(sweep_reader_module, "_NO_INPUT_WARN_INTERVAL_S", 0.02), patch.object(
sweep_reader_module, "_NO_PACKET_WARN_INTERVAL_S", 0.02
):
stack, reader, _queue, stop_event, stderr = self._start_reader(b"", parser_16_bit_x2=False)
try:
time.sleep(0.12)
logs = stderr.getvalue()
self.assertIn("no input bytes", logs)
self.assertIn("no sweep packets", logs)
finally:
stop_event.set()
reader.join(timeout=1.0)
stack.close()
def test_reader_join_does_not_raise_when_stopped(self):
stack, reader, _queue, stop_event, _stderr = self._start_reader(b"", parser_16_bit_x2=True)
try:
time.sleep(0.01)
stop_event.set()
reader.join(timeout=1.0)
self.assertFalse(reader.is_alive())
finally:
stop_event.set()
if reader.is_alive():
reader.join(timeout=1.0)
stack.close()
if __name__ == "__main__":
unittest.main()