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mayhem-firmware/firmware/application/ui/external/ui_grapheq.cpi
RocketGod fb2e576b34 Super secret dont look (#2690) 
* Add new jammer modes

Overview

This PR enhances the PortaPack Jammer app by introducing eight new signal types, ported from my Flipper Zero RF Jammer app (https://github.com/RocketGod-git/flipper-zero-rf-jammer). These modes expand the app's capability to disrupt a wide range of RF communication protocols, from analog radios to modern digital systems. The implementation preserves the original app structure, resolves namespace conflicts, and ensures compatibility with the Mayhem firmware.

New Modes

The following modes have been added to the options_type in ui_jammer.hpp, with corresponding signal generation in proc_jammer.cpp:

Noise: Generates broadband white noise to interfere with analog and digital signals (e.g., Wi-Fi, Bluetooth, key fobs). Highly effective for overwhelming receivers across a frequency range.

Sine: Produces a continuous, unmodulated sine wave to jam narrowband receivers, ideal for analog FM/AM radios or telemetry systems.

Square: Emits a harmonic-rich square wave, disrupting digital protocols (e.g., OOK, ASK) and systems sensitive to sharp transitions, such as remote keyless entry.

Sawtooth (Experimental): Generates a sawtooth wave with a unique harmonic profile, useful for testing interference against PWM-based or niche analog systems.

Triangle (Experimental): Creates a triangle wave with minimal harmonics, suitable for exploratory jamming of narrowband systems or receiver linearity testing.

Chirp: Outputs a rapid frequency-sweeping chirp signal, effective against frequency-hopping and spread-spectrum systems (e.g., some Wi-Fi, Bluetooth, or military radios).

Gauss: Generates Gaussian noise to mimic natural interference, targeting digital systems like GPS or data links by degrading signal-to-noise ratios.

Brute (Experimental): Transmits a constant maximum-amplitude signal to saturate simple receiver front-ends, useful for brute-force jamming of basic analog devices.

* Super secret

* You gotta get (Get) that (That) dirt off your shoulder
2025-06-10 13:36:26 -07:00

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/*
* Copyright (C) 2025 RocketGod
* Copyright (C) 2025 HTotoo
*
* This file is part of PortaPack.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#include "ui_grapheq.hpp"
/* GraphEq *************************************************************/
GraphEq::GraphEq(
Rect parent_rect,
bool clickable)
: Widget{parent_rect},
clickable_{clickable},
bar_heights(NUM_BARS, 0),
prev_bar_heights(NUM_BARS, 0) {
if (clickable) {
set_focusable(true);
// previous_data.resize(length_, 0);
}
}
void GraphEq::set_parent_rect(const Rect new_parent_rect) {
Widget::set_parent_rect(new_parent_rect);
calculate_params();
}
void GraphEq::calculate_params() {
y_top = screen_rect().top();
RENDER_HEIGHT = parent_rect().height();
BAR_WIDTH = (parent_rect().width() - (BAR_SPACING * (NUM_BARS - 1))) / NUM_BARS;
HORIZONTAL_OFFSET = screen_rect().left();
}
bool GraphEq::is_paused() const {
return paused_;
}
void GraphEq::set_paused(bool paused) {
paused_ = paused;
needs_background_redraw = true;
set_dirty();
}
bool GraphEq::is_clickable() const {
return clickable_;
}
void GraphEq::getAccessibilityText(std::string& result) {
result = paused_ ? "paused GraphEq" : "GraphEq";
}
void GraphEq::getWidgetName(std::string& result) {
result = "GraphEq";
}
bool GraphEq::on_key(const KeyEvent key) {
if (!clickable_) return false;
if (key == KeyEvent::Select) {
set_paused(!paused_);
if (on_select) {
on_select(*this);
}
return true;
}
return false;
}
bool GraphEq::on_keyboard(const KeyboardEvent key) {
if (!clickable_) return false;
if (key == 32 || key == 10) {
set_paused(!paused_);
if (on_select) {
on_select(*this);
}
return true;
}
return false;
}
bool GraphEq::on_touch(const TouchEvent event) {
if (!clickable_) return false;
switch (event.type) {
case TouchEvent::Type::Start:
focus();
return true;
case TouchEvent::Type::End:
set_paused(!paused_);
if (on_select) {
on_select(*this);
}
return true;
default:
return false;
}
}
void GraphEq::set_theme(Color base_color_, Color peak_color_) {
base_color = base_color_;
peak_color = peak_color_;
set_dirty();
}
void GraphEq::update_audio_spectrum(const AudioSpectrum& spectrum) {
const float bin_frequency_size = 48000.0f / 128;
for (int bar = 0; bar < NUM_BARS; bar++) {
float start_freq = FREQUENCY_BANDS[bar];
float end_freq = FREQUENCY_BANDS[bar + 1];
int start_bin = std::max(1, (int)(start_freq / bin_frequency_size));
int end_bin = std::min(127, (int)(end_freq / bin_frequency_size));
if (start_bin >= end_bin) {
end_bin = start_bin + 1;
}
float total_energy = 0;
int bin_count = 0;
for (int bin = start_bin; bin <= end_bin; bin++) {
total_energy += spectrum.db[bin];
bin_count++;
}
float avg_db = bin_count > 0 ? (total_energy / bin_count) : 0;
// Manually boost highs for better visual balance
float treble_boost = 1.0f;
if (bar == 10)
treble_boost = 1.7f;
else if (bar >= 9)
treble_boost = 1.3f;
else if (bar >= 7)
treble_boost = 1.3f;
// Mid emphasis for a V-shape effect
float mid_boost = 1.0f;
if (bar == 4 || bar == 5 || bar == 6) mid_boost = 1.2f;
float amplified_db = avg_db * treble_boost * mid_boost;
if (amplified_db > 255) amplified_db = 255;
float band_scale = 1.0f;
int target_height = (amplified_db * RENDER_HEIGHT * band_scale) / 255;
if (target_height > RENDER_HEIGHT) {
target_height = RENDER_HEIGHT;
}
// Adjusted to look nice to my eyes
float rise_speed = 0.8f;
float fall_speed = 1.0f;
if (target_height > bar_heights[bar]) {
bar_heights[bar] = bar_heights[bar] * (1.0f - rise_speed) + target_height * rise_speed;
} else {
bar_heights[bar] = bar_heights[bar] * (1.0f - fall_speed) + target_height * fall_speed;
}
}
set_dirty();
}
void GraphEq::paint(Painter& painter) {
if (!visible()) return;
if (!is_calculated) { // calc positions first
calculate_params();
is_calculated = true;
}
if (needs_background_redraw) {
painter.fill_rectangle(screen_rect(), Theme::getInstance()->bg_darkest->background);
needs_background_redraw = false;
}
if (paused_) {
return;
}
const int num_segments = RENDER_HEIGHT / SEGMENT_HEIGHT;
uint16_t bottom = screen_rect().bottom();
for (int bar = 0; bar < NUM_BARS; bar++) {
int x = HORIZONTAL_OFFSET + bar * (BAR_WIDTH + BAR_SPACING);
int active_segments = (bar_heights[bar] * num_segments) / RENDER_HEIGHT;
if (prev_bar_heights[bar] > active_segments) {
int clear_height = (prev_bar_heights[bar] - active_segments) * SEGMENT_HEIGHT;
int clear_y = bottom - prev_bar_heights[bar] * SEGMENT_HEIGHT;
painter.fill_rectangle({x, clear_y, BAR_WIDTH, clear_height}, Theme::getInstance()->bg_darkest->background);
}
for (int seg = 0; seg < active_segments; seg++) {
int y = bottom - (seg + 1) * SEGMENT_HEIGHT;
if (y < y_top) break;
Color segment_color = (seg >= active_segments - 2 && seg < active_segments) ? peak_color : base_color;
painter.fill_rectangle({x, y, BAR_WIDTH, SEGMENT_HEIGHT - 1}, segment_color);
}
prev_bar_heights[bar] = active_segments;
}
}
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