migration
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+6
-6
@@ -1,7 +1,7 @@
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.vscode
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.micropico
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.gitignore
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PiPicoPATLFGGGGG.code-workspace
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dev
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ComicCode-Regular.*
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.vscode
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.micropico
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.gitignore
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PiPicoPATLFGGGGG.code-workspace
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dev
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ComicCode-Regular.*
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logs
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+12
-12
@@ -1,12 +1,12 @@
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DO WHAT THE FUCK YOU WANT TO PUBLIC LICENSE
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||||
Version 2, December 2004
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||||
|
||||
Everyone is permitted to copy and distribute verbatim or modified
|
||||
copies of this license document, and changing it is allowed as long
|
||||
as the name is changed.
|
||||
|
||||
DO WHAT THE FUCK YOU WANT TO PUBLIC LICENSE
|
||||
TERMS AND CONDITIONS FOR COPYING, DISTRIBUTION AND MODIFICATION
|
||||
|
||||
0. You just DO WHAT THE FUCK YOU WANT TO.
|
||||
|
||||
DO WHAT THE FUCK YOU WANT TO PUBLIC LICENSE
|
||||
Version 2, December 2004
|
||||
|
||||
Everyone is permitted to copy and distribute verbatim or modified
|
||||
copies of this license document, and changing it is allowed as long
|
||||
as the name is changed.
|
||||
|
||||
DO WHAT THE FUCK YOU WANT TO PUBLIC LICENSE
|
||||
TERMS AND CONDITIONS FOR COPYING, DISTRIBUTION AND MODIFICATION
|
||||
|
||||
0. You just DO WHAT THE FUCK YOU WANT TO.
|
||||
|
||||
|
||||
@@ -1,114 +1,114 @@
|
||||
# SillyFilly Pi Pico W Power Analysis Tool
|
||||
# LFGGGGGGGGGGG
|
||||
# FRONG
|
||||
A tool for simplifying power analysis attacks against other gadgets.
|
||||
Built on the Raspberry Pi Pico W, it runs a PWM channel to do manual clock control on the nugget you're hacking, and then reads an ADC channel to measure voltage used at each clock cycle.
|
||||
|
||||
## Screenshots
|
||||
Config page
|
||||

|
||||
|
||||
Running page
|
||||

|
||||
|
||||
Serial terminal at boot
|
||||

|
||||
|
||||
Serial terminal while sampling and looping
|
||||

|
||||
|
||||
## Installation
|
||||
Make sure you have Micropython installed on your Pico W.
|
||||
Open up your Pico W in your favorite IDE (Thonny and VS Code are commonly used) and upload main.py.
|
||||
If you're having trouble, see the official [Raspberry Pi Pico W Getting Started Page](https://projects.raspberrypi.org/en/projects/get-started-pico-w)
|
||||
|
||||
## Usage
|
||||
1) Optional: edit the `power_analysis_pin` and `clock_pulse_pin` variables as you see fit
|
||||
2) Edit the `ssid` and `password` variables with your wifi name (ssid) and the password
|
||||
3) Set up the Pico W with pins on a breadboard, connect your power_analysis_pin and clock_pulse pin to the nugget (See Theory and Method)
|
||||
3) Plug the Pico W to USB of your computer
|
||||
4) Open the serial terminal of the Pico W
|
||||
5) Reset the Pico W
|
||||
6) When the Pico W connects, it will display a message like `Open web browser and navigate to http://x.x.x.x` Open a web browser on the same network and navigate to that address
|
||||
7) Configure the options on the page to your liking (see below under Options)
|
||||
|
||||
|
||||
## Options
|
||||
### main.py
|
||||
`power_analysis_pin`
|
||||
This is the pin that is reading the power usage from the device
|
||||
Defaults to GPIO 28
|
||||
|
||||
`clock_pulse_pin`
|
||||
This pin provides the clock signal that you will be using to manually take control of the nuggets clock
|
||||
Defaults to GPIO 20
|
||||
|
||||
`ssid`
|
||||
This is your wifi network name. Only bgn supported (2.4GHz)
|
||||
Dont forget the 's around the name
|
||||
|
||||
`password`
|
||||
Your wifi password
|
||||
Dont forget the 's around the password
|
||||
|
||||
`power_on_pin`
|
||||
The pin that toggles 3.3v on and off to activate and reset the nugget board
|
||||
|
||||
`seconds_awake`
|
||||
The number of seconds to turn on power_on_pin before resetting
|
||||
|
||||
### On the Webpage
|
||||
`Duty Cycle`
|
||||
The Percentage of the time that the clock is on vs off
|
||||
50% is by far the most common, it makes a normal square wave and is the default output
|
||||
for most oscilators that you will be replacing
|
||||
|
||||
`Frequency`
|
||||
Frequency in Hertz (Hz)
|
||||
How many times per second you want your nuggets clock to pulse
|
||||
Dont make this too high
|
||||
|
||||
`Samples Per Manual Clock Pulse`
|
||||
This is how many times per clock pulse to sample the nuggets power usage
|
||||
Dont make this too high
|
||||
|
||||
## Hardware Needed
|
||||
1) Raspberry Pi Pico W or Raspberry Pi Pico WH
|
||||
2) Pins
|
||||
3) Breadboard
|
||||
4) Small capacitior (470uF is fine or anywhere within that range)
|
||||
5) Wires
|
||||
6) Optional: spikey probes
|
||||
|
||||
## Theory
|
||||
Power analysis attacks are very simple in concept.
|
||||
The idea is monitoring the amount of power a device uses very carefully to get some data leaked.
|
||||
Two things are most important during these attacks:
|
||||
1) Getting the most accurate, raw read of the power usage at a high sample rate
|
||||
2) Controlling the clock of the device to slow down the processor enough to get the readings
|
||||
|
||||
To accomplish #1, we will get our power reading probe as close to the action of the processor as possible, while als adding a capacitor ground, which will pull any remaining juice out of the system.
|
||||
|
||||
For #2, we need to remove the builtin crystal oscilator and replace that connection with our clock pulse probe.
|
||||
|
||||
For this example, I will describe a firmware decryption power analysis attack.
|
||||
|
||||
Scenario: You have and ESP32-S3 based device with flash and bootloader encryption set up on it. You Can remove the RF sheield and get a raw dump of the flash chip with a SOP8 test clip and a programmer, but the data is encrypted.
|
||||
|
||||
## Method
|
||||
1) We disassemble the device to the bare board we're interested in
|
||||
2) Then remove the RF shield and crystal oscilator from the ESP32-S3 via reflow
|
||||
3) Clip a SOP8 test clip on the 8pin flash chip and dump the encrypted data with a programmer like a CH431a or T48
|
||||
4) Set up the breadboard with the Pico W.
|
||||
5) Place the clock_pulse_pin probe where the crystal oscillator used to be
|
||||
6) Place power_analysis_pin probe on the rawest vin power spot you can find
|
||||
7) Run the Pico W (see Usage)
|
||||
8) Dump serial data to some manner of logger Todo: figure out this tooling
|
||||
9) Perform statistical attack to dump key! Todo: automate and figure out tooling
|
||||
|
||||
Todo: Make readme not suck
|
||||
--
|
||||
|
||||
Distributed under the [WTFPL - The Do What the Fuck You Want to Public License](http://www.wtfpl.net/)
|
||||
See [COPYING.txt](COPYING.txt)
|
||||

|
||||
# SillyFilly Pi Pico W Power Analysis Tool
|
||||
# LFGGGGGGGGGGG
|
||||
# FRONG
|
||||
A tool for simplifying power analysis attacks against other gadgets.
|
||||
Built on the Raspberry Pi Pico W, it runs a PWM channel to do manual clock control on the nugget you're hacking, and then reads an ADC channel to measure voltage used at each clock cycle.
|
||||
|
||||
## Screenshots
|
||||
Config page
|
||||

|
||||
|
||||
Running page
|
||||

|
||||
|
||||
Serial terminal at boot
|
||||

|
||||
|
||||
Serial terminal while sampling and looping
|
||||

|
||||
|
||||
## Installation
|
||||
Make sure you have Micropython installed on your Pico W.
|
||||
Open up your Pico W in your favorite IDE (Thonny and VS Code are commonly used) and upload main.py.
|
||||
If you're having trouble, see the official [Raspberry Pi Pico W Getting Started Page](https://projects.raspberrypi.org/en/projects/get-started-pico-w)
|
||||
|
||||
## Usage
|
||||
1) Optional: edit the `power_analysis_pin` and `clock_pulse_pin` variables as you see fit
|
||||
2) Edit the `ssid` and `password` variables with your wifi name (ssid) and the password
|
||||
3) Set up the Pico W with pins on a breadboard, connect your power_analysis_pin and clock_pulse pin to the nugget (See Theory and Method)
|
||||
3) Plug the Pico W to USB of your computer
|
||||
4) Open the serial terminal of the Pico W
|
||||
5) Reset the Pico W
|
||||
6) When the Pico W connects, it will display a message like `Open web browser and navigate to http://x.x.x.x` Open a web browser on the same network and navigate to that address
|
||||
7) Configure the options on the page to your liking (see below under Options)
|
||||
|
||||
|
||||
## Options
|
||||
### main.py
|
||||
`power_analysis_pin`
|
||||
This is the pin that is reading the power usage from the device
|
||||
Defaults to GPIO 28
|
||||
|
||||
`clock_pulse_pin`
|
||||
This pin provides the clock signal that you will be using to manually take control of the nuggets clock
|
||||
Defaults to GPIO 20
|
||||
|
||||
`ssid`
|
||||
This is your wifi network name. Only bgn supported (2.4GHz)
|
||||
Dont forget the 's around the name
|
||||
|
||||
`password`
|
||||
Your wifi password
|
||||
Dont forget the 's around the password
|
||||
|
||||
`power_on_pin`
|
||||
The pin that toggles 3.3v on and off to activate and reset the nugget board
|
||||
|
||||
`seconds_awake`
|
||||
The number of seconds to turn on power_on_pin before resetting
|
||||
|
||||
### On the Webpage
|
||||
`Duty Cycle`
|
||||
The Percentage of the time that the clock is on vs off
|
||||
50% is by far the most common, it makes a normal square wave and is the default output
|
||||
for most oscilators that you will be replacing
|
||||
|
||||
`Frequency`
|
||||
Frequency in Hertz (Hz)
|
||||
How many times per second you want your nuggets clock to pulse
|
||||
Dont make this too high
|
||||
|
||||
`Samples Per Manual Clock Pulse`
|
||||
This is how many times per clock pulse to sample the nuggets power usage
|
||||
Dont make this too high
|
||||
|
||||
## Hardware Needed
|
||||
1) Raspberry Pi Pico W or Raspberry Pi Pico WH
|
||||
2) Pins
|
||||
3) Breadboard
|
||||
4) Small capacitior (470uF is fine or anywhere within that range)
|
||||
5) Wires
|
||||
6) Optional: spikey probes
|
||||
|
||||
## Theory
|
||||
Power analysis attacks are very simple in concept.
|
||||
The idea is monitoring the amount of power a device uses very carefully to get some data leaked.
|
||||
Two things are most important during these attacks:
|
||||
1) Getting the most accurate, raw read of the power usage at a high sample rate
|
||||
2) Controlling the clock of the device to slow down the processor enough to get the readings
|
||||
|
||||
To accomplish #1, we will get our power reading probe as close to the action of the processor as possible, while als adding a capacitor ground, which will pull any remaining juice out of the system.
|
||||
|
||||
For #2, we need to remove the builtin crystal oscilator and replace that connection with our clock pulse probe.
|
||||
|
||||
For this example, I will describe a firmware decryption power analysis attack.
|
||||
|
||||
Scenario: You have and ESP32-S3 based device with flash and bootloader encryption set up on it. You Can remove the RF sheield and get a raw dump of the flash chip with a SOP8 test clip and a programmer, but the data is encrypted.
|
||||
|
||||
## Method
|
||||
1) We disassemble the device to the bare board we're interested in
|
||||
2) Then remove the RF shield and crystal oscilator from the ESP32-S3 via reflow
|
||||
3) Clip a SOP8 test clip on the 8pin flash chip and dump the encrypted data with a programmer like a CH431a or T48
|
||||
4) Set up the breadboard with the Pico W.
|
||||
5) Place the clock_pulse_pin probe where the crystal oscillator used to be
|
||||
6) Place power_analysis_pin probe on the rawest vin power spot you can find
|
||||
7) Run the Pico W (see Usage)
|
||||
8) Dump serial data to some manner of logger Todo: figure out this tooling
|
||||
9) Perform statistical attack to dump key! Todo: automate and figure out tooling
|
||||
|
||||
Todo: Make readme not suck
|
||||
--
|
||||
|
||||
Distributed under the [WTFPL - The Do What the Fuck You Want to Public License](http://www.wtfpl.net/)
|
||||
See [COPYING.txt](COPYING.txt)
|
||||
[](http://www.wtfpl.net/)
|
||||
@@ -1,259 +1,259 @@
|
||||
import network
|
||||
import socket
|
||||
import machine
|
||||
from machine import Timer
|
||||
import utime
|
||||
import _thread
|
||||
import math
|
||||
|
||||
# gpio pin to read power analysis off of (int)
|
||||
# reads 16bit (0-65535) between 0.0v and 3.3v
|
||||
# (16 bit is phony, real read is 12 bit)
|
||||
power_analysis_pin = 28
|
||||
|
||||
# output gpio pin generating clock pulse
|
||||
clock_pulse_pin = 20
|
||||
|
||||
# this pin gets power and toggles off and on every X PWM cycles
|
||||
# it powers the board you're targeting
|
||||
power_on_pin = 2
|
||||
|
||||
# how many seconds to power the board before reset
|
||||
seconds_awake = 3
|
||||
|
||||
# Wi-Fi credentials
|
||||
ssid = 'your-wifi-name-here'
|
||||
password = 'your-wifi-password-here'
|
||||
|
||||
# == Clock Pulse Genertor == #
|
||||
# starts a pwm
|
||||
# usage do_pwm(int gpio_pin, float duty_cycle, int hertz frequency, int samples_per_clock_pulse)
|
||||
def do_pwm(outpin, duty_cycle, frequency):
|
||||
global pwm_pin
|
||||
output_pin = machine.Pin(outpin)
|
||||
|
||||
# configure pwm
|
||||
pwm_pin = machine.PWM(output_pin)
|
||||
pwm_pin.freq(frequency) # frequency in Hz
|
||||
pwm_duty = math.floor(duty_cycle*65535) # duty cycle is a uint 16bit
|
||||
|
||||
# run da pwm
|
||||
pwm_pin.duty_u16(pwm_duty)
|
||||
|
||||
# us of sleep calculate4d by ceil(1000000 / (frequency_in_Hz * samples_per_pulse))
|
||||
# 1000000 is one million, 1,000,000 or 10^6
|
||||
def us_samples(frequency, samples_per_pulse):
|
||||
return math.ceil(1000000/(frequency*samples_per_pulse))
|
||||
|
||||
# == Read Value off of device == #
|
||||
# uses ADC, 16bit output is phony, is actualloy 12bit.
|
||||
kill = False # for the thread killing hack
|
||||
def do_adc(adcpin, frequency, samples_per_pulse):
|
||||
analog_value = machine.ADC(adcpin)
|
||||
us_sample = us_samples(frequency, samples_per_pulse)
|
||||
|
||||
global kill
|
||||
while True:
|
||||
reading = analog_value.read_u16() # do the actual reading, actual precision is 12bit
|
||||
print(reading,',',sep='')
|
||||
utime.sleep_us(us_sample)
|
||||
|
||||
# just keep checking if kill is set to True by reset_init()
|
||||
# if it is True, reset kill to False, kill the thread, and break for good measure
|
||||
if kill is True:
|
||||
kill = False
|
||||
_thread.exit()
|
||||
break
|
||||
|
||||
# HTML template for the webpage
|
||||
header = """
|
||||
<!DOCTYPE html>
|
||||
<html>
|
||||
<head>
|
||||
<title>SillyFilly Pi Pico Power Analysis Tool (LFFGGGGG)</title>
|
||||
<meta name="viewport" content="width=device-width, initial-scale=1">
|
||||
<!-- todo: actually host this font file somewhere lmfao -->
|
||||
<link rel="preload" href="http://10.0.0.80/ComicCode-Regular.woff2" as="font" type="font/woff2" crossorigin>
|
||||
<style>
|
||||
body {
|
||||
font-family: 'Comic Code', 'Comic Sans MS', Monospace;
|
||||
font-weight: normal;
|
||||
font-style: normal;
|
||||
}
|
||||
|
||||
form, div {
|
||||
width: 80%;
|
||||
margin: auto;
|
||||
}
|
||||
|
||||
h1 {
|
||||
font-size: 1.15em;'
|
||||
}
|
||||
|
||||
form input[type='number'] {
|
||||
width: 3.6em;
|
||||
}
|
||||
</style>
|
||||
</head>
|
||||
<body>
|
||||
"""
|
||||
|
||||
footer = """
|
||||
</body>
|
||||
</html>
|
||||
"""
|
||||
|
||||
def default_webpage():
|
||||
template = f"""
|
||||
{header}
|
||||
<form action="/action">
|
||||
<h1>SillyFilly Pi Pico Power Analysis Tool (LFFGGGGG)</h1>
|
||||
<b>Config:</b><br>
|
||||
Duty Cycle<br><input id="duty_cycle" name="duty_cycle" type="range" min="0" max="1" step="0.01" value="0.5"> <output id="duty_cycle_output">50%</output><br><br>
|
||||
Frequency (Hz)<br><input type="number" size="5" name="freq" value="2000"><br><br>
|
||||
Samples Per Clock Pulse:<br> <input type="number" size="5" id="samples_per_pulse" name="samples_per_pulse" value="5"><br><br>
|
||||
<input type="submit" value="Go, Baby, Go!">
|
||||
</form>
|
||||
<script>
|
||||
const value = document.querySelector("#duty_cycle_output");
|
||||
const input = document.querySelector("#duty_cycle");
|
||||
|
||||
input.addEventListener("input", (event) => {{
|
||||
value.textContent = (event.target.value*100)+"%";
|
||||
}});
|
||||
</script>
|
||||
{footer}
|
||||
"""
|
||||
return str(template)
|
||||
|
||||
def running_webpage(outpin, adcpin, duty_cycle, frequency, samples_per_pulse, loop_time):
|
||||
dutyy = duty_cycle*100
|
||||
us_sample = us_samples(frequency, samples_per_pulse)
|
||||
template = f"""
|
||||
{header}
|
||||
<div id="sillyrunninfg">
|
||||
<h1>SillyFilly Pi Pico Power Analysis Tool (LFFGGGGG)</h1>
|
||||
<h2>WE RUNNING NOWWWWW LFGGGGGGGGGGGGG</h2>
|
||||
<p>
|
||||
Clock Pulse Pin: <b>{outpin}</b><br>
|
||||
Power Analysis Pin: <b>{adcpin}</b><br>
|
||||
Power On Pin:{power_on_pin} <b></b><br><br><br>
|
||||
|
||||
Frequency: <b>{frequency}Hz</b> (Duty Cycle: <b>{dutyy}%</b><br>
|
||||
Samples Per Pulse: <b>{samples_per_pulse}</b><br>
|
||||
Delay Between Samples: <b>{us_sample}us</b><br><br>
|
||||
Loop length: <b>{loop_time}</b><br><br><br>
|
||||
<b>LFGGGGGGGG FRONG</b>
|
||||
</p>
|
||||
</div>
|
||||
{footer}
|
||||
"""
|
||||
return str(template)
|
||||
|
||||
print("Board Started or Reset\n===========\n\n")
|
||||
|
||||
toggle_power = machine.Pin(power_on_pin, machine.Pin.OUT)
|
||||
toggle_power.value(0)
|
||||
|
||||
# I like to have the LED on :3
|
||||
led = machine.Pin('LED', machine.Pin.OUT)
|
||||
led.value(1)
|
||||
|
||||
# do da thingggggssssss for da loooop
|
||||
def reset_init(t):
|
||||
global kill
|
||||
kill = True # kill da adc thread
|
||||
toggle_power.value(0) # kill power on pin
|
||||
print("==Looping==")
|
||||
pwm_pin.deinit() # stop pwm
|
||||
utime.sleep(1)
|
||||
toggle_power.value(1) # re-enable power on pin
|
||||
do_pwm(clock_pulse_pin, duty_cycle_in, freq_in) # restart pwm
|
||||
|
||||
# restart da threaddyyyyy
|
||||
_thread.start_new_thread(do_adc, (power_analysis_pin, freq_in, samples_per_pulse_in))
|
||||
|
||||
# Connect to WLAN
|
||||
wlan = network.WLAN(network.STA_IF)
|
||||
wlan.active(True)
|
||||
wlan.connect(ssid, password)
|
||||
|
||||
# Wait for Wi-Fi connection
|
||||
connection_timeout = 9
|
||||
while connection_timeout > 0:
|
||||
if wlan.status() >= 3:
|
||||
break
|
||||
connection_timeout -= 1
|
||||
print('Waiting for Wi-Fi connection...')
|
||||
utime.sleep(1)
|
||||
|
||||
# Check if connection is successful
|
||||
if wlan.status() != 3:
|
||||
raise RuntimeError('Failed to establish a network connection')
|
||||
else:
|
||||
print('Connection successful!')
|
||||
network_info = wlan.ifconfig()
|
||||
print(f"\n\nOpen web browser and navigate to http://{network_info[0]}\n\n")
|
||||
|
||||
# Set up socket and start listening
|
||||
addr = socket.getaddrinfo('0.0.0.0', 80)[0][-1]
|
||||
s = socket.socket()
|
||||
s.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
|
||||
s.bind(addr)
|
||||
s.listen()
|
||||
|
||||
while True:
|
||||
try:
|
||||
conn, addr = s.accept()
|
||||
request = conn.recv(1024)
|
||||
request = str(request)
|
||||
|
||||
try:
|
||||
fullreq = request.split()
|
||||
request = fullreq[1]
|
||||
except IndexError:
|
||||
pass
|
||||
|
||||
# Process the action page!
|
||||
if request.startswith('/action?', 0):
|
||||
# parse the request path to extract da GET vars
|
||||
req_string = request.split('?')[1]
|
||||
req_vars = req_string.split('&')
|
||||
for f in req_vars:
|
||||
req_split = f.split('=')
|
||||
# Type strict whitelist for safety and compatibility
|
||||
if req_split[0] == 'duty_cycle':
|
||||
duty_cycle_in = float(req_split[1])
|
||||
elif req_split[0] == 'freq':
|
||||
freq_in = int(req_split[1])
|
||||
elif req_split[0] == 'samples_per_pulse':
|
||||
samples_per_pulse_in = int(req_split[1])
|
||||
|
||||
loop_time = (seconds_awake-1)*1000 # the -1 is because reset_init() adds a 1 second delay
|
||||
dutyyy = duty_cycle_in*100
|
||||
us_sample = us_samples(freq_in, samples_per_pulse_in)
|
||||
|
||||
print(f"Clock pulse pin: {clock_pulse_pin}\n\nPower analysis pin: {power_analysis_pin}\n\nPower on pin: {power_on_pin}\n\nDuty cycle: {duty_cycle_in}%\n\nFrequency: {freq_in}Hz\n\nSamples per clock pulse: {samples_per_pulse_in}\n\nTime between samples: {us_sample}us\n\nLoop length: {loop_time}ms\n\n")
|
||||
|
||||
# run the clock pulse (PWM) task
|
||||
do_pwm(clock_pulse_pin, duty_cycle_in, freq_in)
|
||||
|
||||
# fork the voltage measuring ADC reading to the second core
|
||||
_thread.start_new_thread(do_adc, (power_analysis_pin, freq_in, samples_per_pulse_in))
|
||||
|
||||
Timer(mode=Timer.PERIODIC, period=loop_time, callback=reset_init)
|
||||
|
||||
# outpin, adcpin, duty_cycle, frequency, samples_per_pulse, loop_time
|
||||
response = running_webpage(clock_pulse_pin, power_analysis_pin, dutyyy, freq_in, samples_per_pulse_in, loop_time)
|
||||
|
||||
else:
|
||||
response = default_webpage()
|
||||
|
||||
# Send the HTTP response and close the conn
|
||||
conn.send('HTTP/1.0 200 OK\r\nContent-type: text/html\r\n\r\n')
|
||||
conn.send(response)
|
||||
conn.close()
|
||||
|
||||
except OSError as e:
|
||||
conn.close()
|
||||
import network
|
||||
import socket
|
||||
import machine
|
||||
from machine import Timer
|
||||
import utime
|
||||
import _thread
|
||||
import math
|
||||
|
||||
# gpio pin to read power analysis off of (int)
|
||||
# reads 16bit (0-65535) between 0.0v and 3.3v
|
||||
# (16 bit is phony, real read is 12 bit)
|
||||
power_analysis_pin = 28
|
||||
|
||||
# output gpio pin generating clock pulse
|
||||
clock_pulse_pin = 20
|
||||
|
||||
# this pin gets power and toggles off and on every X PWM cycles
|
||||
# it powers the board you're targeting
|
||||
power_on_pin = 2
|
||||
|
||||
# how many seconds to power the board before reset
|
||||
seconds_awake = 3
|
||||
|
||||
# Wi-Fi credentials
|
||||
ssid = 'your-wifi-name-here'
|
||||
password = 'your-wifi-password-here'
|
||||
|
||||
# == Clock Pulse Genertor == #
|
||||
# starts a pwm
|
||||
# usage do_pwm(int gpio_pin, float duty_cycle, int hertz frequency, int samples_per_clock_pulse)
|
||||
def do_pwm(outpin, duty_cycle, frequency):
|
||||
global pwm_pin
|
||||
output_pin = machine.Pin(outpin)
|
||||
|
||||
# configure pwm
|
||||
pwm_pin = machine.PWM(output_pin)
|
||||
pwm_pin.freq(frequency) # frequency in Hz
|
||||
pwm_duty = math.floor(duty_cycle*65535) # duty cycle is a uint 16bit
|
||||
|
||||
# run da pwm
|
||||
pwm_pin.duty_u16(pwm_duty)
|
||||
|
||||
# us of sleep calculate4d by ceil(1000000 / (frequency_in_Hz * samples_per_pulse))
|
||||
# 1000000 is one million, 1,000,000 or 10^6
|
||||
def us_samples(frequency, samples_per_pulse):
|
||||
return math.ceil(1000000/(frequency*samples_per_pulse))
|
||||
|
||||
# == Read Value off of device == #
|
||||
# uses ADC, 16bit output is phony, is actualloy 12bit.
|
||||
kill = False # for the thread killing hack
|
||||
def do_adc(adcpin, frequency, samples_per_pulse):
|
||||
analog_value = machine.ADC(adcpin)
|
||||
us_sample = us_samples(frequency, samples_per_pulse)
|
||||
|
||||
global kill
|
||||
while True:
|
||||
reading = analog_value.read_u16() # do the actual reading, actual precision is 12bit
|
||||
print(reading,',',sep='')
|
||||
utime.sleep_us(us_sample)
|
||||
|
||||
# just keep checking if kill is set to True by reset_init()
|
||||
# if it is True, reset kill to False, kill the thread, and break for good measure
|
||||
if kill is True:
|
||||
kill = False
|
||||
_thread.exit()
|
||||
break
|
||||
|
||||
# HTML template for the webpage
|
||||
header = """
|
||||
<!DOCTYPE html>
|
||||
<html>
|
||||
<head>
|
||||
<title>SillyFilly Pi Pico Power Analysis Tool (LFFGGGGG)</title>
|
||||
<meta name="viewport" content="width=device-width, initial-scale=1">
|
||||
<!-- todo: actually host this font file somewhere lmfao -->
|
||||
<link rel="preload" href="http://10.0.0.80/ComicCode-Regular.woff2" as="font" type="font/woff2" crossorigin>
|
||||
<style>
|
||||
body {
|
||||
font-family: 'Comic Code', 'Comic Sans MS', Monospace;
|
||||
font-weight: normal;
|
||||
font-style: normal;
|
||||
}
|
||||
|
||||
form, div {
|
||||
width: 80%;
|
||||
margin: auto;
|
||||
}
|
||||
|
||||
h1 {
|
||||
font-size: 1.15em;'
|
||||
}
|
||||
|
||||
form input[type='number'] {
|
||||
width: 3.6em;
|
||||
}
|
||||
</style>
|
||||
</head>
|
||||
<body>
|
||||
"""
|
||||
|
||||
footer = """
|
||||
</body>
|
||||
</html>
|
||||
"""
|
||||
|
||||
def default_webpage():
|
||||
template = f"""
|
||||
{header}
|
||||
<form action="/action">
|
||||
<h1>SillyFilly Pi Pico Power Analysis Tool (LFFGGGGG)</h1>
|
||||
<b>Config:</b><br>
|
||||
Duty Cycle<br><input id="duty_cycle" name="duty_cycle" type="range" min="0" max="1" step="0.01" value="0.5"> <output id="duty_cycle_output">50%</output><br><br>
|
||||
Frequency (Hz)<br><input type="number" size="5" name="freq" value="2000"><br><br>
|
||||
Samples Per Clock Pulse:<br> <input type="number" size="5" id="samples_per_pulse" name="samples_per_pulse" value="5"><br><br>
|
||||
<input type="submit" value="Go, Baby, Go!">
|
||||
</form>
|
||||
<script>
|
||||
const value = document.querySelector("#duty_cycle_output");
|
||||
const input = document.querySelector("#duty_cycle");
|
||||
|
||||
input.addEventListener("input", (event) => {{
|
||||
value.textContent = (event.target.value*100)+"%";
|
||||
}});
|
||||
</script>
|
||||
{footer}
|
||||
"""
|
||||
return str(template)
|
||||
|
||||
def running_webpage(outpin, adcpin, duty_cycle, frequency, samples_per_pulse, loop_time):
|
||||
dutyy = duty_cycle*100
|
||||
us_sample = us_samples(frequency, samples_per_pulse)
|
||||
template = f"""
|
||||
{header}
|
||||
<div id="sillyrunninfg">
|
||||
<h1>SillyFilly Pi Pico Power Analysis Tool (LFFGGGGG)</h1>
|
||||
<h2>WE RUNNING NOWWWWW LFGGGGGGGGGGGGG</h2>
|
||||
<p>
|
||||
Clock Pulse Pin: <b>{outpin}</b><br>
|
||||
Power Analysis Pin: <b>{adcpin}</b><br>
|
||||
Power On Pin:{power_on_pin} <b></b><br><br><br>
|
||||
|
||||
Frequency: <b>{frequency}Hz</b> (Duty Cycle: <b>{dutyy}%</b><br>
|
||||
Samples Per Pulse: <b>{samples_per_pulse}</b><br>
|
||||
Delay Between Samples: <b>{us_sample}us</b><br><br>
|
||||
Loop length: <b>{loop_time}</b><br><br><br>
|
||||
<b>LFGGGGGGGG FRONG</b>
|
||||
</p>
|
||||
</div>
|
||||
{footer}
|
||||
"""
|
||||
return str(template)
|
||||
|
||||
print("Board Started or Reset\n===========\n\n")
|
||||
|
||||
toggle_power = machine.Pin(power_on_pin, machine.Pin.OUT)
|
||||
toggle_power.value(0)
|
||||
|
||||
# I like to have the LED on :3
|
||||
led = machine.Pin('LED', machine.Pin.OUT)
|
||||
led.value(1)
|
||||
|
||||
# do da thingggggssssss for da loooop
|
||||
def reset_init(t):
|
||||
global kill
|
||||
kill = True # kill da adc thread
|
||||
toggle_power.value(0) # kill power on pin
|
||||
print("==Looping==")
|
||||
pwm_pin.deinit() # stop pwm
|
||||
utime.sleep(1)
|
||||
toggle_power.value(1) # re-enable power on pin
|
||||
do_pwm(clock_pulse_pin, duty_cycle_in, freq_in) # restart pwm
|
||||
|
||||
# restart da threaddyyyyy
|
||||
_thread.start_new_thread(do_adc, (power_analysis_pin, freq_in, samples_per_pulse_in))
|
||||
|
||||
# Connect to WLAN
|
||||
wlan = network.WLAN(network.STA_IF)
|
||||
wlan.active(True)
|
||||
wlan.connect(ssid, password)
|
||||
|
||||
# Wait for Wi-Fi connection
|
||||
connection_timeout = 9
|
||||
while connection_timeout > 0:
|
||||
if wlan.status() >= 3:
|
||||
break
|
||||
connection_timeout -= 1
|
||||
print('Waiting for Wi-Fi connection...')
|
||||
utime.sleep(1)
|
||||
|
||||
# Check if connection is successful
|
||||
if wlan.status() != 3:
|
||||
raise RuntimeError('Failed to establish a network connection')
|
||||
else:
|
||||
print('Connection successful!')
|
||||
network_info = wlan.ifconfig()
|
||||
print(f"\n\nOpen web browser and navigate to http://{network_info[0]}\n\n")
|
||||
|
||||
# Set up socket and start listening
|
||||
addr = socket.getaddrinfo('0.0.0.0', 80)[0][-1]
|
||||
s = socket.socket()
|
||||
s.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1)
|
||||
s.bind(addr)
|
||||
s.listen()
|
||||
|
||||
while True:
|
||||
try:
|
||||
conn, addr = s.accept()
|
||||
request = conn.recv(1024)
|
||||
request = str(request)
|
||||
|
||||
try:
|
||||
fullreq = request.split()
|
||||
request = fullreq[1]
|
||||
except IndexError:
|
||||
pass
|
||||
|
||||
# Process the action page!
|
||||
if request.startswith('/action?', 0):
|
||||
# parse the request path to extract da GET vars
|
||||
req_string = request.split('?')[1]
|
||||
req_vars = req_string.split('&')
|
||||
for f in req_vars:
|
||||
req_split = f.split('=')
|
||||
# Type strict whitelist for safety and compatibility
|
||||
if req_split[0] == 'duty_cycle':
|
||||
duty_cycle_in = float(req_split[1])
|
||||
elif req_split[0] == 'freq':
|
||||
freq_in = int(req_split[1])
|
||||
elif req_split[0] == 'samples_per_pulse':
|
||||
samples_per_pulse_in = int(req_split[1])
|
||||
|
||||
loop_time = (seconds_awake-1)*1000 # the -1 is because reset_init() adds a 1 second delay
|
||||
dutyyy = duty_cycle_in*100
|
||||
us_sample = us_samples(freq_in, samples_per_pulse_in)
|
||||
|
||||
print(f"Clock pulse pin: {clock_pulse_pin}\n\nPower analysis pin: {power_analysis_pin}\n\nPower on pin: {power_on_pin}\n\nDuty cycle: {duty_cycle_in}%\n\nFrequency: {freq_in}Hz\n\nSamples per clock pulse: {samples_per_pulse_in}\n\nTime between samples: {us_sample}us\n\nLoop length: {loop_time}ms\n\n")
|
||||
|
||||
# run the clock pulse (PWM) task
|
||||
do_pwm(clock_pulse_pin, duty_cycle_in, freq_in)
|
||||
|
||||
# fork the voltage measuring ADC reading to the second core
|
||||
_thread.start_new_thread(do_adc, (power_analysis_pin, freq_in, samples_per_pulse_in))
|
||||
|
||||
Timer(mode=Timer.PERIODIC, period=loop_time, callback=reset_init)
|
||||
|
||||
# outpin, adcpin, duty_cycle, frequency, samples_per_pulse, loop_time
|
||||
response = running_webpage(clock_pulse_pin, power_analysis_pin, dutyyy, freq_in, samples_per_pulse_in, loop_time)
|
||||
|
||||
else:
|
||||
response = default_webpage()
|
||||
|
||||
# Send the HTTP response and close the conn
|
||||
conn.send('HTTP/1.0 200 OK\r\nContent-type: text/html\r\n\r\n')
|
||||
conn.send(response)
|
||||
conn.close()
|
||||
|
||||
except OSError as e:
|
||||
conn.close()
|
||||
print('Connection closed')
|
||||
Reference in New Issue
Block a user