ESP32/esp32_deploy.py

#!/usr/bin/env python3
"""
ESP32 Unified Deployment Tool (esp32_deploy)
Combines firmware flashing and device configuration with full control.
Updates:
  - FIXED: Reset logic (DTR=False) to ensure App boot instead of Bootloader
  - AUTO-DETECT: Prioritizes /dev/esp_port_* (udev rules)
  - ROBUSTNESS: Merged "poking" and "retry" logic
  - 'target all' support
"""

import asyncio
import serial_asyncio
import sys
import os
import argparse
import ipaddress
import re
import time
import shutil
import logging
import glob
from pathlib import Path

# Ensure detection script is available
sys.path.append(os.path.dirname(os.path.abspath(__file__)))
try:
    import detect_esp32
except ImportError:
    print("Error: 'detect_esp32.py' not found.")
    sys.exit(1)

# --- Configuration ---
DEFAULT_MAX_CONCURRENT_FLASH = 4

class Colors:
    GREEN = '\033[92m'
    RED = '\033[91m'
    YELLOW = '\033[93m'
    BLUE = '\033[94m'
    CYAN = '\033[96m'
    RESET = '\033[0m'

class DeviceLoggerAdapter(logging.LoggerAdapter):
    def process(self, msg, kwargs):
        return '[%s] %s' % (self.extra['connid'], msg), kwargs

logging.basicConfig(level=logging.INFO, format='%(asctime)s %(message)s', datefmt='%H:%M:%S')
logger = logging.getLogger("Deploy")

def get_project_binary_name(build_dir):
    ignored = {'bootloader.bin', 'partition-table.bin', 'ota_data_initial.bin'}
    found = []
    try:
        for f in os.listdir(build_dir):
            if f.endswith('.bin') and f not in ignored and 'partition' not in f:
                found.append(f)
    except FileNotFoundError:
        return None
    return found[0] if found else None

def generate_config_suffix(target, csi, ampdu):
    csi_str = "csi_on" if csi else "csi_off"
    ampdu_str = "ampdu_on" if ampdu else "ampdu_off"
    return f"{target}_{csi_str}_{ampdu_str}"

def auto_detect_devices():
    """Prioritizes static udev paths (/dev/esp_port_XX) if they exist."""
    try:
        ports = glob.glob('/dev/esp_port_*')
        if ports:
            # Sort by suffix number
            ports.sort(key=lambda x: int(re.search(r'(\d+)$', x).group(1)) if re.search(r'(\d+)$', x) else 0)
            print(f"{Colors.CYAN}Auto-detected {len(ports)} devices using static udev rules.{Colors.RESET}")
            return [type('obj', (object,), {'device': p}) for p in ports]
    except Exception:
        pass
    return detect_esp32.detect_esp32_devices()

class UnifiedDeployWorker:
    def __init__(self, port, target_ip, args, project_dir, flash_sem):
        self.port = port
        self.target_ip = target_ip
        self.args = args
        self.project_dir = Path(project_dir)
        self.flash_sem = flash_sem
        self.log = DeviceLoggerAdapter(logger, {'connid': port})

        self.regex_chip_type = re.compile(r'Detecting chip type... (ESP32\S*)')
        # Matches the log from your updated main.c
        self.regex_ready = re.compile(r'Entering idle loop|esp32>', re.IGNORECASE)
        self.regex_got_ip = re.compile(r'got ip:(\d+\.\d+\.\d+\.\d+)', re.IGNORECASE)
        self.regex_csi_saved = re.compile(r'CSI enable state saved|Config saved', re.IGNORECASE)

    async def run(self):
        try:
            if not self.args.config_only:
                async with self.flash_sem:
                    if self.args.flash_erase:
                        if not await self._erase_flash(): return False
                    if not await self._flash_firmware(): return False
                # Give it a moment to stabilize after flash reset
                await asyncio.sleep(2.0)

            if not self.args.flash_only:
                if self.args.ssid and self.args.password:
                    # Retry logic
                    success = False
                    for attempt in range(1, 4):
                        self.log.info(f"Configuring (Attempt {attempt}/3)...")
                        if await self._configure_device():
                            success = True
                            break
                        self.log.warning(f"Config failed on attempt {attempt}. Retrying...")
                        await asyncio.sleep(2.0)

                    if not success:
                        self.log.error(f"{Colors.RED}Config verify failed after 3 attempts.{Colors.RESET}")
                        return False
                else:
                    self.log.warning("No SSID/Password provided, skipping config")
                    if self.args.config_only: return False
            return True

        except Exception as e:
            self.log.error(f"Worker Exception: {e}")
            return False

    async def _identify_chip(self):
        cmd = ['esptool.py', '-p', self.port, 'chip_id']
        proc = await asyncio.create_subprocess_exec(*cmd, stdout=asyncio.subprocess.PIPE, stderr=asyncio.subprocess.PIPE)
        stdout, stderr = await proc.communicate()
        output = stdout.decode() + stderr.decode()
        match = self.regex_chip_type.search(output)
        if match:
            return match.group(1).lower().replace('-', '')
        return None

    async def _erase_flash(self):
        cmd = ['esptool.py', '-p', self.port, '-b', '115200', 'erase_flash']
        proc = await asyncio.create_subprocess_exec(*cmd, stdout=asyncio.subprocess.PIPE, stderr=asyncio.subprocess.PIPE)
        _, stderr = await proc.communicate()
        if proc.returncode == 0: return True
        self.log.error(f"Erase failed: {stderr.decode()}")
        return False

    async def _flash_firmware(self):
        detected_target = None
        if self.args.target == 'auto':
            detected_target = await self._identify_chip()
            if not detected_target:
                self.log.error("Failed to auto-detect chip type.")
                return False
            self.log.info(f"Auto-detected: {Colors.CYAN}{detected_target}{Colors.RESET}")
            target_to_use = detected_target
        else:
            target_to_use = self.args.target

        suffix = generate_config_suffix(target_to_use, self.args.csi_enable, self.args.ampdu)
        firmware_dir = self.project_dir / "firmware"

        unique_app = None
        if firmware_dir.exists():
            for f in os.listdir(firmware_dir):
                if f.endswith(f"_{suffix}.bin") and not f.startswith("bootloader") and not f.startswith("partition") and not f.startswith("ota_data") and not f.startswith("phy_init"):
                    unique_app = f
                    break

        if not unique_app:
            self.log.error(f"Binary for config '{suffix}' not found in firmware/.")
            return False

        unique_boot = f"bootloader_{suffix}.bin"
        unique_part = f"partition-table_{suffix}.bin"
        unique_ota  = f"ota_data_initial_{suffix}.bin"
        unique_args_file = f"flash_args_{suffix}"

        flash_args_path = firmware_dir / unique_args_file
        if not flash_args_path.exists():
            self.log.error(f"flash_args for {suffix} not found")
            return False

        try:
            with open(flash_args_path, 'r') as f:
                content = f.read().replace('\n', ' ').strip()

            raw_args = [x for x in content.split(' ') if x]
            final_args = []

            for arg in raw_args:
                if arg.endswith('bootloader.bin'):
                    final_args.append(str(firmware_dir / unique_boot))
                elif arg.endswith('partition-table.bin'):
                    final_args.append(str(firmware_dir / unique_part))
                elif arg.endswith('ota_data_initial.bin'):
                    if (firmware_dir / unique_ota).exists():
                        final_args.append(str(firmware_dir / unique_ota))
                    else:
                        continue
                elif arg.endswith('phy_init_data.bin'):
                     final_args.append(arg)
                elif arg.endswith('.bin'):
                    final_args.append(str(firmware_dir / unique_app))
                else:
                    final_args.append(arg)

            cmd = ['esptool.py', '-p', self.port, '-b', str(self.args.baud),
                   '--before', 'default_reset', '--after', 'hard_reset',
                   'write_flash'] + final_args

            full_path = firmware_dir / unique_app
            self.log.info(f"Flashing {full_path}...")

            proc = await asyncio.create_subprocess_exec(*cmd, cwd=self.project_dir, stdout=asyncio.subprocess.PIPE, stderr=asyncio.subprocess.PIPE)
            try:
                stdout, stderr = await asyncio.wait_for(proc.communicate(), timeout=300)
            except asyncio.TimeoutError:
                proc.kill()
                return False

            if proc.returncode == 0: return True
            self.log.error(f"Flash failed: {stderr.decode()}")
            return False

        except Exception as e:
            self.log.error(f"Flash Prep Error: {e}")
            return False

    async def _configure_device(self):
        try:
            reader, writer = await serial_asyncio.open_serial_connection(url=self.port, baudrate=115200)
        except Exception as e:
            return False

        try:
            # 1. Reset
            writer.transport.serial.dtr = False
            writer.transport.serial.rts = True
            await asyncio.sleep(0.1)
            writer.transport.serial.rts = False
            # FIX: DTR Must be False to allow Booting (True=Low=Bootloader Mode)
            writer.transport.serial.dtr = False

            # 2. Robust Wait (with Poke)
            if not await self._wait_for_boot(reader, writer):
                self.log.warning("Boot prompt missed (sending blindly)...")

            # 3. Send
            await self._send_config(writer)

            # 4. Verify
            is_configured = await self._verify_configuration(reader)

            if is_configured:
                self.log.info(f"{Colors.GREEN}Config verified.{Colors.RESET}")
                # Final Reset to apply
                writer.transport.serial.dtr = False
                writer.transport.serial.rts = True
                await asyncio.sleep(0.1)
                writer.transport.serial.rts = False
                return True
            else:
                self.log.error(f"{Colors.RED}Config verification failed.{Colors.RESET}")
                return False

        except Exception as e:
            self.log.error(f"Config Error: {e}")
            return False
        finally:
            writer.close()
            await writer.wait_closed()

    async def _wait_for_boot(self, reader, writer):
        # Timeout covers GPS delay (~3.5s) + boot overhead
        end_time = time.time() + 12
        last_poke = time.time()

        while time.time() < end_time:
            try:
                # Poke every 1.5 seconds if we haven't seen the prompt
                if time.time() - last_poke > 1.5:
                    writer.write(b'\n')
                    await writer.drain()
                    last_poke = time.time()

                try:
                    # Short timeout to allow polling loop
                    line_bytes = await asyncio.wait_for(reader.readline(), timeout=0.1)
                    line = line_bytes.decode('utf-8', errors='ignore').strip()
                    if not line: continue

                    if self.regex_ready.search(line):
                        return True
                except asyncio.TimeoutError:
                    continue

            except Exception as e:
                self.log.error(f"Read error: {e}")
                return False
        return False

    async def _send_config(self, writer):
        # Wait a moment for any last boot logs to clear
        await asyncio.sleep(0.5)

        # Wake up console
        writer.write(b'\n')
        await writer.drain()
        await asyncio.sleep(0.2)

        csi_val = '1' if self.args.csi_enable else '0'
        role_str = "SERVER" if self.args.iperf_server else "CLIENT"
        iperf_enable_val = '0' if self.args.no_iperf else '1'
        period_us = int(self.args.iperf_period * 1000000)

        config_lines = [
            "CFG",
            f"SSID:{self.args.ssid}",
            f"PASS:{self.args.password}",
            f"IP:{self.target_ip}",
            f"MASK:{self.args.netmask}",
            f"GW:{self.args.gateway}",
            f"DHCP:0",
            f"BAND:{self.args.band}",
            f"BW:{self.args.bandwidth}",
            f"POWERSAVE:{self.args.powersave}",
            f"MODE:{self.args.mode}",
            f"MON_CH:{self.args.monitor_channel}",
            f"CSI:{csi_val}",
            f"IPERF_PERIOD_US:{period_us}",
            f"IPERF_ROLE:{role_str}",
            f"IPERF_PROTO:{self.args.iperf_proto}",
            f"IPERF_DEST_IP:{self.args.iperf_dest_ip}",
            f"IPERF_PORT:{self.args.iperf_port}",
            f"IPERF_BURST:{self.args.iperf_burst}",
            f"IPERF_LEN:{self.args.iperf_len}",
            f"IPERF_ENABLED:{iperf_enable_val}",
            "END"
        ]

        # CHANGED: Send line-by-line with a small delay to prevent UART FIFO overflow
        for line in config_lines:
            cmd = line + "\r\n"
            writer.write(cmd.encode('utf-8'))
            await writer.drain()
            # 50ms delay allows the ESP32 (running at 115200 baud) to process the line
            await asyncio.sleep(0.05)

    async def _verify_configuration(self, reader):
        timeout = time.time() + 15
        while time.time() < timeout:
            try:
                line_bytes = await asyncio.wait_for(reader.readline(), timeout=1.0)
                line = line_bytes.decode('utf-8', errors='ignore').strip()
                if not line: continue

                if self.regex_csi_saved.search(line): return True
                m = self.regex_got_ip.search(line)
                if m and m.group(1) == self.target_ip: return True
            except asyncio.TimeoutError: continue
        return False

def parse_args():
    parser = argparse.ArgumentParser(description='ESP32 Unified Deployment Tool')
    parser.add_argument('-i', '--interactive', action='store_true', help='Prompt for build options')
    parser.add_argument('--target', choices=['esp32', 'esp32s3', 'esp32c5', 'all', 'auto'], help="Target Chip")
    parser.add_argument('--ampdu', action='store_true', help='Enable AMPDU in build')
    parser.add_argument('--no-ampdu', action='store_false', dest='ampdu', help='Disable AMPDU')
    parser.set_defaults(ampdu=True)
    parser.add_argument('--config-only', action='store_true')
    parser.add_argument('--flash-only', action='store_true')
    parser.add_argument('--flash-erase', action='store_true')
    parser.add_argument('-d', '--dir', default=os.getcwd())
    parser.add_argument('-b', '--baud', type=int, default=460800)
    parser.add_argument('--devices', type=str)
    parser.add_argument('--max-concurrent', type=int, default=None)
    parser.add_argument('--start-ip', help='Start IP (Required unless --target all)')
    parser.add_argument('-s', '--ssid', default='ClubHouse2G')
    parser.add_argument('-P', '--password', default='ez2remember')
    parser.add_argument('-g', '--gateway', default='192.168.1.1')
    parser.add_argument('-m', '--netmask', default='255.255.255.0')
    parser.add_argument('--band', default='2.4G')
    parser.add_argument('-B', '--bandwidth', default='HT20')
    parser.add_argument('-ps', '--powersave', default='NONE')
    parser.add_argument('--iperf-period', type=float, default=0.01)
    parser.add_argument('--iperf-burst', type=int, default=1)
    parser.add_argument('--iperf-len', type=int, default=1470)
    parser.add_argument('--iperf-proto', default='UDP')
    parser.add_argument('--iperf-dest-ip', default='192.168.1.50')
    parser.add_argument('--iperf-port', type=int, default=5001)
    parser.add_argument('--no-iperf', action='store_true')
    parser.add_argument('--iperf-client', action='store_true')
    parser.add_argument('--iperf-server', action='store_true')
    parser.add_argument('-M', '--mode', default='STA')
    parser.add_argument('-mc', '--monitor-channel', type=int, default=36)
    parser.add_argument('--csi', dest='csi_enable', action='store_true')

    args = parser.parse_args()
    if args.target != 'all' and not args.start_ip:
        parser.error("the following arguments are required: --start-ip")
    if args.config_only and args.flash_only: parser.error("Conflicting modes")
    if not args.config_only and not args.flash_only and args.target != 'all':
        if not args.ssid or not args.password:
            parser.error("SSID/PASS required")
    return args

def extract_device_number(device_path):
    match = re.search(r'(\d+)$', device_path)
    return int(match.group(1)) if match else 0

def ask_user(prompt, default=None, choices=None):
    choice_str = f" [{'|'.join(choices)}]" if choices else ""
    default_str = f" [{default}]" if default else ""
    while True:
        val = input(f"{Colors.CYAN}{prompt}{choice_str}{default_str}: {Colors.RESET}").strip()
        if not val and default: return default
        if choices:
            if val in choices: return val
            print(f"{Colors.RED}Invalid choice.{Colors.RESET}")
        else: return val

def ask_bool(prompt, default=True):
    choice_str = " [Y/n]" if default else " [y/N]"
    val = input(f"{Colors.CYAN}{prompt}{choice_str}: {Colors.RESET}").strip().lower()
    if not val: return default
    return val.startswith('y')

def get_sdkconfig_defaults(target, csi_enabled, ampdu_enabled):
    defaults = ["sdkconfig.defaults"]
    suffix = "csi" if csi_enabled else ""
    defaults.append(f"sdkconfig.defaults.{target}{suffix}")
    defaults.append("sdkconfig.defaults.ampdu" if ampdu_enabled else "sdkconfig.defaults.noampdu")
    return ";".join(defaults)

async def build_task(project_dir, target, csi, ampdu, current_step=None, total_steps=None):
    defaults_str = get_sdkconfig_defaults(target, csi, ampdu)
    desc = f"Target={target}, CSI={'ON' if csi else 'OFF'}, AMPDU={'ON' if ampdu else 'OFF'}"
    prefix = f"[{current_step}/{total_steps}] " if current_step else ""
    print(f"  {prefix}Building [{desc}] ... ", end='', flush=True)

    try:
        output_dir = project_dir / "firmware"
        output_dir.mkdir(exist_ok=True)

        sdkconfig_path = project_dir / "sdkconfig"
        build_path = project_dir / "build"
        if sdkconfig_path.exists(): os.remove(sdkconfig_path)
        if build_path.exists(): shutil.rmtree(build_path)

        proc = await asyncio.create_subprocess_exec('idf.py', 'set-target', target, cwd=project_dir, stdout=asyncio.subprocess.PIPE, stderr=asyncio.subprocess.PIPE)
        _, stderr = await proc.communicate()
        if proc.returncode != 0:
             print(f"{Colors.RED}FAIL (Set Target){Colors.RESET}")
             return False, f"Set Target Failed", 0

        start_time = time.time()
        build_cmd = ['idf.py', '-D', f'SDKCONFIG_DEFAULTS={defaults_str}', 'build']
        proc = await asyncio.create_subprocess_exec(*build_cmd, cwd=project_dir, stdout=asyncio.subprocess.PIPE, stderr=asyncio.subprocess.PIPE)
        _, stderr = await proc.communicate()
        duration = time.time() - start_time
        if proc.returncode != 0:
            print(f"{Colors.RED}FAIL{Colors.RESET}")
            return False, f"Build Failed", duration

        build_dir = project_dir / 'build'
        suffix = generate_config_suffix(target, csi, ampdu)
        unique_app_name = "Unknown"

        project_bin = get_project_binary_name(build_dir)
        if project_bin:
            unique_app_name = f"{os.path.splitext(project_bin)[0]}_{suffix}.bin"
            shutil.copy2(build_dir / project_bin, output_dir / unique_app_name)

        boot_src = build_dir / "bootloader" / "bootloader.bin"
        if boot_src.exists(): shutil.copy2(boot_src, output_dir / f"bootloader_{suffix}.bin")

        part_src = build_dir / "partition_table" / "partition-table.bin"
        if part_src.exists(): shutil.copy2(part_src, output_dir / f"partition-table_{suffix}.bin")

        # Fix: Save OTA data binary if it exists
        ota_src = build_dir / "ota_data_initial.bin"
        if ota_src.exists(): shutil.copy2(ota_src, output_dir / f"ota_data_initial_{suffix}.bin")

        flash_src = build_dir / "flash_args"
        if flash_src.exists(): shutil.copy2(flash_src, output_dir / f"flash_args_{suffix}")

        full_path = output_dir / unique_app_name
        print(f"{Colors.GREEN}OK ({duration:.1f}s) -> {full_path}{Colors.RESET}")
        return True, "Success", duration

    except Exception as e:
        print(f"{Colors.RED}ERROR: {e}{Colors.RESET}")
        return False, str(e), 0

async def run_deployment(args):
    print(f"\n{Colors.BLUE}{'='*60}{Colors.RESET}\n  ESP32 Unified Deployment Tool\n{Colors.BLUE}{'='*60}{Colors.RESET}")
    project_dir = Path(args.dir).resolve()

    # --- Target 'ALL' Mode ---
    if args.target == 'all':
        print(f"{Colors.YELLOW}Starting Batch Build Verification (12 Combinations){Colors.RESET}")

        # SAFETY: Wipe firmware dir to ensure no stale binaries exist
        firmware_dir = project_dir / "firmware"
        if firmware_dir.exists():
            try:
                shutil.rmtree(firmware_dir)
                print(f"{Colors.YELLOW}  [Clean] Removed old firmware/ directory.{Colors.RESET}")
            except Exception as e:
                print(f"{Colors.RED}  [Error] Could not clean firmware dir: {e}{Colors.RESET}")
                return

        # Re-create it fresh
        firmware_dir.mkdir(exist_ok=True)
        print("") # Spacer

        targets = ['esp32', 'esp32s3', 'esp32c5']
        booleans = [False, True]
        results = []

        total_steps = len(targets) * len(booleans) * len(booleans)
        current_step = 0

        for target in targets:
            for csi in booleans:
                for ampdu in booleans:
                    current_step += 1
                    success, msg, dur = await build_task(project_dir, target, csi, ampdu, current_step, total_steps)
                    results.append({"cfg": f"{target.ljust(9)} CSI:{'ON ' if csi else 'OFF'} AMPDU:{'ON ' if ampdu else 'OFF'}", "ok": success, "dur": dur})

        print(f"\n{Colors.BLUE}Batch Summary:{Colors.RESET}")
        for r in results:
            status = f"{Colors.GREEN}PASS{Colors.RESET}" if r['ok'] else f"{Colors.RED}FAIL{Colors.RESET}"
            print(f"  {r['cfg']} : {status} ({r['dur']:.1f}s)")
        return

    # --- Single Build Configuration ---
    # Skip build if we are in AUTO mode (we assume binaries exist in firmware/)
    if not args.config_only and args.target != 'auto':
        target = args.target if args.target else 'esp32s3'
        csi = args.csi_enable
        ampdu = args.ampdu

        if args.interactive:
            print(f"\n{Colors.YELLOW}--- Build Configuration ---{Colors.RESET}")
            target = ask_user("Target Chip", default=target, choices=['esp32', 'esp32s3', 'esp32c5'])
            csi = ask_bool(f"Enable CSI Support?", default=csi)
            ampdu = ask_bool(f"Enable AMPDU Aggregation?", default=ampdu)
            args.csi_enable = csi
            args.target = target
            args.ampdu = ampdu

        success, msg, _ = await build_task(project_dir, target, csi, ampdu, 1, 1)
        if not success:
            print(f"{Colors.RED}{msg}{Colors.RESET}")
            return
    elif args.target == 'auto' and not args.config_only:
        print(f"{Colors.YELLOW}Target 'auto' selected. Skipping build step (assuming artifacts in firmware/).{Colors.RESET}")

    # --- Device Detection & Flash ---
    if args.devices:
        devs = [type('obj', (object,), {'device': d.strip()}) for d in args.devices.split(',')]
    else:
        # Use AUTO DETECT first (for static names), then standard fallback
        devs = auto_detect_devices()
        if not devs: print("No devices found"); return

        # Sort naturally (esp_port_01 before esp_port_10)
        # We rely on the internal sort of auto_detect or detect_esp32,
        # but a final sort by string length/digits helps with mixing types.
        devs.sort(key=lambda d: [int(c) if c.isdigit() else c for c in re.split(r'(\d+)', d.device)])

    print(f"\n{Colors.GREEN}Found {len(devs)} devices{Colors.RESET}")
    start_ip = ipaddress.IPv4Address(args.start_ip)
    max_c = args.max_concurrent if args.max_concurrent else (1 if args.devices and not args.config_only else DEFAULT_MAX_CONCURRENT_FLASH)
    flash_sem = asyncio.Semaphore(max_c)

    tasks = []
    for i, dev in enumerate(devs):
        offset = extract_device_number(dev.device) if args.devices else i
        target_ip = str(start_ip + offset)
        tasks.append(UnifiedDeployWorker(dev.device, target_ip, args, project_dir, flash_sem).run())

    results = await asyncio.gather(*tasks)
    success = results.count(True)
    print(f"\n{Colors.BLUE}Summary: {success}/{len(devs)} Success{Colors.RESET}")

def main():
    if os.name == 'nt': asyncio.set_event_loop(asyncio.ProactorEventLoop())
    try: asyncio.run(run_deployment(parse_args()))
    except KeyboardInterrupt: sys.exit(1)

if __name__ == '__main__':
    main()