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This commit is contained in:
Olivier Demers
2026-01-15 16:08:40 -05:00
commit ec1fac7f0a
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187
.gitignore vendored Normal file
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# This gitignore has been specially created by the WPILib team.
# If you remove items from this file, intellisense might break.
### C++ ###
# Prerequisites
*.d
# Compiled Object files
*.slo
*.lo
*.o
*.obj
# Precompiled Headers
*.gch
*.pch
# Compiled Dynamic libraries
*.so
*.dylib
*.dll
# Fortran module files
*.mod
*.smod
# Compiled Static libraries
*.lai
*.la
*.a
*.lib
# Executables
*.exe
*.out
*.app
### Java ###
# Compiled class file
*.class
# Log file
*.log
# BlueJ files
*.ctxt
# Mobile Tools for Java (J2ME)
.mtj.tmp/
# Package Files #
*.jar
*.war
*.nar
*.ear
*.zip
*.tar.gz
*.rar
# virtual machine crash logs, see http://www.java.com/en/download/help/error_hotspot.xml
hs_err_pid*
### Linux ###
*~
# temporary files which can be created if a process still has a handle open of a deleted file
.fuse_hidden*
# KDE directory preferences
.directory
# Linux trash folder which might appear on any partition or disk
.Trash-*
# .nfs files are created when an open file is removed but is still being accessed
.nfs*
### macOS ###
# General
.DS_Store
.AppleDouble
.LSOverride
# Icon must end with two \r
Icon
# Thumbnails
._*
# Files that might appear in the root of a volume
.DocumentRevisions-V100
.fseventsd
.Spotlight-V100
.TemporaryItems
.Trashes
.VolumeIcon.icns
.com.apple.timemachine.donotpresent
# Directories potentially created on remote AFP share
.AppleDB
.AppleDesktop
Network Trash Folder
Temporary Items
.apdisk
### VisualStudioCode ###
.vscode/*
!.vscode/settings.json
!.vscode/tasks.json
!.vscode/launch.json
!.vscode/extensions.json
### Windows ###
# Windows thumbnail cache files
Thumbs.db
ehthumbs.db
ehthumbs_vista.db
# Dump file
*.stackdump
# Folder config file
[Dd]esktop.ini
# Recycle Bin used on file shares
$RECYCLE.BIN/
# Windows Installer files
*.cab
*.msi
*.msix
*.msm
*.msp
# Windows shortcuts
*.lnk
### Gradle ###
.gradle
/build/
# Ignore Gradle GUI config
gradle-app.setting
# Avoid ignoring Gradle wrapper jar file (.jar files are usually ignored)
!gradle-wrapper.jar
# Cache of project
.gradletasknamecache
# # Work around https://youtrack.jetbrains.com/issue/IDEA-116898
# gradle/wrapper/gradle-wrapper.properties
# # VS Code Specific Java Settings
# DO NOT REMOVE .classpath and .project
.classpath
.project
.settings/
bin/
# IntelliJ
*.iml
*.ipr
*.iws
.idea/
out/
# Fleet
.fleet
# Simulation GUI and other tools window save file
networktables.json
simgui.json
*-window.json
# Simulation data log directory
logs/
# Folder that has CTRE Phoenix Sim device config storage
ctre_sim/
# clangd
/.cache
compile_commands.json
# Eclipse generated file for annotation processors
.factorypath

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{
// Use IntelliSense to learn about possible attributes.
// Hover to view descriptions of existing attributes.
// For more information, visit: https://go.microsoft.com/fwlink/?linkid=830387
"version": "0.2.0",
"configurations": [
{
"type": "wpilib",
"name": "WPILib Desktop Debug",
"request": "launch",
"desktop": true,
},
{
"type": "wpilib",
"name": "WPILib roboRIO Debug",
"request": "launch",
"desktop": false,
}
]
}

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.vscode/settings.json vendored Normal file
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{
"java.configuration.updateBuildConfiguration": "automatic",
"java.server.launchMode": "Standard",
"files.exclude": {
"**/.git": true,
"**/.svn": true,
"**/.hg": true,
"**/CVS": true,
"**/.DS_Store": true,
"bin/": true,
"**/.classpath": true,
"**/.project": true,
"**/.settings": true,
"**/.factorypath": true,
"**/*~": true
},
"java.test.config": [
{
"name": "WPIlibUnitTests",
"workingDirectory": "${workspaceFolder}/build/jni/release",
"vmargs": [ "-Djava.library.path=${workspaceFolder}/build/jni/release" ],
"env": {
"LD_LIBRARY_PATH": "${workspaceFolder}/build/jni/release" ,
"DYLD_LIBRARY_PATH": "${workspaceFolder}/build/jni/release"
}
},
],
"java.test.defaultConfig": "WPIlibUnitTests",
"java.import.gradle.annotationProcessing.enabled": false,
"java.completion.favoriteStaticMembers": [
"org.junit.Assert.*",
"org.junit.Assume.*",
"org.junit.jupiter.api.Assertions.*",
"org.junit.jupiter.api.Assumptions.*",
"org.junit.jupiter.api.DynamicContainer.*",
"org.junit.jupiter.api.DynamicTest.*",
"org.mockito.Mockito.*",
"org.mockito.ArgumentMatchers.*",
"org.mockito.Answers.*",
"edu.wpi.first.units.Units.*"
],
"java.completion.filteredTypes": [
"java.awt.*",
"com.sun.*",
"sun.*",
"jdk.*",
"org.graalvm.*",
"io.micrometer.shaded.*",
"java.beans.*",
"java.util.Base64.*",
"java.util.Timer",
"java.sql.*",
"javax.swing.*",
"javax.management.*",
"javax.smartcardio.*",
"edu.wpi.first.math.proto.*",
"edu.wpi.first.math.**.proto.*",
"edu.wpi.first.math.**.struct.*",
],
"java.dependency.enableDependencyCheckup": false
}

6
.wpilib/wpilib_preferences.json Normal file
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{
"enableCppIntellisense": false,
"currentLanguage": "java",
"projectYear": "2026",
"teamNumber": 7762
}

24
WPILib-License.md Normal file
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Copyright (c) 2009-2026 FIRST and other WPILib contributors
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
* Neither the name of FIRST, WPILib, nor the names of other WPILib
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY FIRST AND OTHER WPILIB CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY NONINFRINGEMENT AND FITNESS FOR A PARTICULAR
PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL FIRST OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

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plugins {
id "java"
id "edu.wpi.first.GradleRIO" version "2026.1.1"
}
java {
sourceCompatibility = JavaVersion.VERSION_17
targetCompatibility = JavaVersion.VERSION_17
}
def ROBOT_MAIN_CLASS = "frc.robot.Main"
// Define my targets (RoboRIO) and artifacts (deployable files)
// This is added by GradleRIO's backing project DeployUtils.
deploy {
targets {
roborio(getTargetTypeClass('RoboRIO')) {
// Team number is loaded either from the .wpilib/wpilib_preferences.json
// or from command line. If not found an exception will be thrown.
// You can use getTeamOrDefault(team) instead of getTeamNumber if you
// want to store a team number in this file.
team = project.frc.getTeamNumber()
debug = project.frc.getDebugOrDefault(false)
artifacts {
// First part is artifact name, 2nd is artifact type
// getTargetTypeClass is a shortcut to get the class type using a string
frcJava(getArtifactTypeClass('FRCJavaArtifact')) {
}
// Static files artifact
frcStaticFileDeploy(getArtifactTypeClass('FileTreeArtifact')) {
files = project.fileTree('src/main/deploy')
directory = '/home/lvuser/deploy'
deleteOldFiles = true // Change to true to delete files on roboRIO that no
// longer exist in deploy directory of this project
}
}
}
}
}
def deployArtifact = deploy.targets.roborio.artifacts.frcJava
// Set to true to use debug for all targets including JNI, which will drastically impact
// performance.
wpi.java.debugJni = false
// Set this to true to enable desktop support.
def includeDesktopSupport = true
// Defining my dependencies. In this case, WPILib (+ friends), and vendor libraries.
// Also defines JUnit 5.
dependencies {
annotationProcessor wpi.java.deps.wpilibAnnotations()
implementation wpi.java.deps.wpilib()
implementation wpi.java.vendor.java()
roborioDebug wpi.java.deps.wpilibJniDebug(wpi.platforms.roborio)
roborioDebug wpi.java.vendor.jniDebug(wpi.platforms.roborio)
roborioRelease wpi.java.deps.wpilibJniRelease(wpi.platforms.roborio)
roborioRelease wpi.java.vendor.jniRelease(wpi.platforms.roborio)
nativeDebug wpi.java.deps.wpilibJniDebug(wpi.platforms.desktop)
nativeDebug wpi.java.vendor.jniDebug(wpi.platforms.desktop)
simulationDebug wpi.sim.enableDebug()
nativeRelease wpi.java.deps.wpilibJniRelease(wpi.platforms.desktop)
nativeRelease wpi.java.vendor.jniRelease(wpi.platforms.desktop)
simulationRelease wpi.sim.enableRelease()
testImplementation 'org.junit.jupiter:junit-jupiter:5.10.1'
testRuntimeOnly 'org.junit.platform:junit-platform-launcher'
}
test {
useJUnitPlatform()
systemProperty 'junit.jupiter.extensions.autodetection.enabled', 'true'
}
// Simulation configuration (e.g. environment variables).
wpi.sim.addGui().defaultEnabled = true
wpi.sim.addDriverstation()
// Setting up my Jar File. In this case, adding all libraries into the main jar ('fat jar')
// in order to make them all available at runtime. Also adding the manifest so WPILib
// knows where to look for our Robot Class.
jar {
from { configurations.runtimeClasspath.collect { it.isDirectory() ? it : zipTree(it) } }
from('src') { into 'backup/src' }
from('vendordeps') { into 'backup/vendordeps' }
from('build.gradle') { into 'backup' }
manifest edu.wpi.first.gradlerio.GradleRIOPlugin.javaManifest(ROBOT_MAIN_CLASS)
duplicatesStrategy = DuplicatesStrategy.INCLUDE
}
// Configure jar and deploy tasks
deployArtifact.jarTask = jar
wpi.java.configureExecutableTasks(jar)
wpi.java.configureTestTasks(test)
// Configure string concat to always inline compile
tasks.withType(JavaCompile) {
options.compilerArgs.add '-XDstringConcat=inline'
}

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gradle/wrapper/gradle-wrapper.properties vendored Normal file
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distributionBase=GRADLE_USER_HOME
distributionPath=permwrapper/dists
distributionUrl=https\://services.gradle.org/distributions/gradle-8.11-bin.zip
networkTimeout=10000
validateDistributionUrl=true
zipStoreBase=GRADLE_USER_HOME
zipStorePath=permwrapper/dists

252
gradlew vendored Normal file
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#!/bin/sh
#
# Copyright © 2015-2021 the original authors.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# https://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#
# SPDX-License-Identifier: Apache-2.0
#
##############################################################################
#
# Gradle start up script for POSIX generated by Gradle.
#
# Important for running:
#
# (1) You need a POSIX-compliant shell to run this script. If your /bin/sh is
# noncompliant, but you have some other compliant shell such as ksh or
# bash, then to run this script, type that shell name before the whole
# command line, like:
#
# ksh Gradle
#
# Busybox and similar reduced shells will NOT work, because this script
# requires all of these POSIX shell features:
# * functions;
# * expansions «$var», «${var}», «${var:-default}», «${var+SET}»,
# «${var#prefix}», «${var%suffix}», and «$( cmd )»;
# * compound commands having a testable exit status, especially «case»;
# * various built-in commands including «command», «set», and «ulimit».
#
# Important for patching:
#
# (2) This script targets any POSIX shell, so it avoids extensions provided
# by Bash, Ksh, etc; in particular arrays are avoided.
#
# The "traditional" practice of packing multiple parameters into a
# space-separated string is a well documented source of bugs and security
# problems, so this is (mostly) avoided, by progressively accumulating
# options in "$@", and eventually passing that to Java.
#
# Where the inherited environment variables (DEFAULT_JVM_OPTS, JAVA_OPTS,
# and GRADLE_OPTS) rely on word-splitting, this is performed explicitly;
# see the in-line comments for details.
#
# There are tweaks for specific operating systems such as AIX, CygWin,
# Darwin, MinGW, and NonStop.
#
# (3) This script is generated from the Groovy template
# https://github.com/gradle/gradle/blob/HEAD/platforms/jvm/plugins-application/src/main/resources/org/gradle/api/internal/plugins/unixStartScript.txt
# within the Gradle project.
#
# You can find Gradle at https://github.com/gradle/gradle/.
#
##############################################################################
# Attempt to set APP_HOME
# Resolve links: $0 may be a link
app_path=$0
# Need this for daisy-chained symlinks.
while
APP_HOME=${app_path%"${app_path##*/}"} # leaves a trailing /; empty if no leading path
[ -h "$app_path" ]
do
ls=$( ls -ld "$app_path" )
link=${ls#*' -> '}
case $link in #(
/*) app_path=$link ;; #(
*) app_path=$APP_HOME$link ;;
esac
done
# This is normally unused
# shellcheck disable=SC2034
APP_BASE_NAME=${0##*/}
# Discard cd standard output in case $CDPATH is set (https://github.com/gradle/gradle/issues/25036)
APP_HOME=$( cd -P "${APP_HOME:-./}" > /dev/null && printf '%s
' "$PWD" ) || exit
# Use the maximum available, or set MAX_FD != -1 to use that value.
MAX_FD=maximum
warn () {
echo "$*"
} >&2
die () {
echo
echo "$*"
echo
exit 1
} >&2
# OS specific support (must be 'true' or 'false').
cygwin=false
msys=false
darwin=false
nonstop=false
case "$( uname )" in #(
CYGWIN* ) cygwin=true ;; #(
Darwin* ) darwin=true ;; #(
MSYS* | MINGW* ) msys=true ;; #(
NONSTOP* ) nonstop=true ;;
esac
CLASSPATH=$APP_HOME/gradle/wrapper/gradle-wrapper.jar
# Determine the Java command to use to start the JVM.
if [ -n "$JAVA_HOME" ] ; then
if [ -x "$JAVA_HOME/jre/sh/java" ] ; then
# IBM's JDK on AIX uses strange locations for the executables
JAVACMD=$JAVA_HOME/jre/sh/java
else
JAVACMD=$JAVA_HOME/bin/java
fi
if [ ! -x "$JAVACMD" ] ; then
die "ERROR: JAVA_HOME is set to an invalid directory: $JAVA_HOME
Please set the JAVA_HOME variable in your environment to match the
location of your Java installation."
fi
else
JAVACMD=java
if ! command -v java >/dev/null 2>&1
then
die "ERROR: JAVA_HOME is not set and no 'java' command could be found in your PATH.
Please set the JAVA_HOME variable in your environment to match the
location of your Java installation."
fi
fi
# Increase the maximum file descriptors if we can.
if ! "$cygwin" && ! "$darwin" && ! "$nonstop" ; then
case $MAX_FD in #(
max*)
# In POSIX sh, ulimit -H is undefined. That's why the result is checked to see if it worked.
# shellcheck disable=SC2039,SC3045
MAX_FD=$( ulimit -H -n ) ||
warn "Could not query maximum file descriptor limit"
esac
case $MAX_FD in #(
'' | soft) :;; #(
*)
# In POSIX sh, ulimit -n is undefined. That's why the result is checked to see if it worked.
# shellcheck disable=SC2039,SC3045
ulimit -n "$MAX_FD" ||
warn "Could not set maximum file descriptor limit to $MAX_FD"
esac
fi
# Collect all arguments for the java command, stacking in reverse order:
# * args from the command line
# * the main class name
# * -classpath
# * -D...appname settings
# * --module-path (only if needed)
# * DEFAULT_JVM_OPTS, JAVA_OPTS, and GRADLE_OPTS environment variables.
# For Cygwin or MSYS, switch paths to Windows format before running java
if "$cygwin" || "$msys" ; then
APP_HOME=$( cygpath --path --mixed "$APP_HOME" )
CLASSPATH=$( cygpath --path --mixed "$CLASSPATH" )
JAVACMD=$( cygpath --unix "$JAVACMD" )
# Now convert the arguments - kludge to limit ourselves to /bin/sh
for arg do
if
case $arg in #(
-*) false ;; # don't mess with options #(
/?*) t=${arg#/} t=/${t%%/*} # looks like a POSIX filepath
[ -e "$t" ] ;; #(
*) false ;;
esac
then
arg=$( cygpath --path --ignore --mixed "$arg" )
fi
# Roll the args list around exactly as many times as the number of
# args, so each arg winds up back in the position where it started, but
# possibly modified.
#
# NB: a `for` loop captures its iteration list before it begins, so
# changing the positional parameters here affects neither the number of
# iterations, nor the values presented in `arg`.
shift # remove old arg
set -- "$@" "$arg" # push replacement arg
done
fi
# Add default JVM options here. You can also use JAVA_OPTS and GRADLE_OPTS to pass JVM options to this script.
DEFAULT_JVM_OPTS='"-Xmx64m" "-Xms64m"'
# Collect all arguments for the java command:
# * DEFAULT_JVM_OPTS, JAVA_OPTS, JAVA_OPTS, and optsEnvironmentVar are not allowed to contain shell fragments,
# and any embedded shellness will be escaped.
# * For example: A user cannot expect ${Hostname} to be expanded, as it is an environment variable and will be
# treated as '${Hostname}' itself on the command line.
set -- \
"-Dorg.gradle.appname=$APP_BASE_NAME" \
-classpath "$CLASSPATH" \
org.gradle.wrapper.GradleWrapperMain \
"$@"
# Stop when "xargs" is not available.
if ! command -v xargs >/dev/null 2>&1
then
die "xargs is not available"
fi
# Use "xargs" to parse quoted args.
#
# With -n1 it outputs one arg per line, with the quotes and backslashes removed.
#
# In Bash we could simply go:
#
# readarray ARGS < <( xargs -n1 <<<"$var" ) &&
# set -- "${ARGS[@]}" "$@"
#
# but POSIX shell has neither arrays nor command substitution, so instead we
# post-process each arg (as a line of input to sed) to backslash-escape any
# character that might be a shell metacharacter, then use eval to reverse
# that process (while maintaining the separation between arguments), and wrap
# the whole thing up as a single "set" statement.
#
# This will of course break if any of these variables contains a newline or
# an unmatched quote.
#
eval "set -- $(
printf '%s\n' "$DEFAULT_JVM_OPTS $JAVA_OPTS $GRADLE_OPTS" |
xargs -n1 |
sed ' s~[^-[:alnum:]+,./:=@_]~\\&~g; ' |
tr '\n' ' '
)" '"$@"'
exec "$JAVACMD" "$@"

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@rem
@rem Copyright 2015 the original author or authors.
@rem
@rem Licensed under the Apache License, Version 2.0 (the "License");
@rem you may not use this file except in compliance with the License.
@rem You may obtain a copy of the License at
@rem
@rem https://www.apache.org/licenses/LICENSE-2.0
@rem
@rem Unless required by applicable law or agreed to in writing, software
@rem distributed under the License is distributed on an "AS IS" BASIS,
@rem WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
@rem See the License for the specific language governing permissions and
@rem limitations under the License.
@rem
@rem SPDX-License-Identifier: Apache-2.0
@rem
@if "%DEBUG%"=="" @echo off
@rem ##########################################################################
@rem
@rem Gradle startup script for Windows
@rem
@rem ##########################################################################
@rem Set local scope for the variables with windows NT shell
if "%OS%"=="Windows_NT" setlocal
set DIRNAME=%~dp0
if "%DIRNAME%"=="" set DIRNAME=.
@rem This is normally unused
set APP_BASE_NAME=%~n0
set APP_HOME=%DIRNAME%
@rem Resolve any "." and ".." in APP_HOME to make it shorter.
for %%i in ("%APP_HOME%") do set APP_HOME=%%~fi
@rem Add default JVM options here. You can also use JAVA_OPTS and GRADLE_OPTS to pass JVM options to this script.
set DEFAULT_JVM_OPTS="-Xmx64m" "-Xms64m"
@rem Find java.exe
if defined JAVA_HOME goto findJavaFromJavaHome
set JAVA_EXE=java.exe
%JAVA_EXE% -version >NUL 2>&1
if %ERRORLEVEL% equ 0 goto execute
echo. 1>&2
echo ERROR: JAVA_HOME is not set and no 'java' command could be found in your PATH. 1>&2
echo. 1>&2
echo Please set the JAVA_HOME variable in your environment to match the 1>&2
echo location of your Java installation. 1>&2
goto fail
:findJavaFromJavaHome
set JAVA_HOME=%JAVA_HOME:"=%
set JAVA_EXE=%JAVA_HOME%/bin/java.exe
if exist "%JAVA_EXE%" goto execute
echo. 1>&2
echo ERROR: JAVA_HOME is set to an invalid directory: %JAVA_HOME% 1>&2
echo. 1>&2
echo Please set the JAVA_HOME variable in your environment to match the 1>&2
echo location of your Java installation. 1>&2
goto fail
:execute
@rem Setup the command line
set CLASSPATH=%APP_HOME%\gradle\wrapper\gradle-wrapper.jar
@rem Execute Gradle
"%JAVA_EXE%" %DEFAULT_JVM_OPTS% %JAVA_OPTS% %GRADLE_OPTS% "-Dorg.gradle.appname=%APP_BASE_NAME%" -classpath "%CLASSPATH%" org.gradle.wrapper.GradleWrapperMain %*
:end
@rem End local scope for the variables with windows NT shell
if %ERRORLEVEL% equ 0 goto mainEnd
:fail
rem Set variable GRADLE_EXIT_CONSOLE if you need the _script_ return code instead of
rem the _cmd.exe /c_ return code!
set EXIT_CODE=%ERRORLEVEL%
if %EXIT_CODE% equ 0 set EXIT_CODE=1
if not ""=="%GRADLE_EXIT_CONSOLE%" exit %EXIT_CODE%
exit /b %EXIT_CODE%
:mainEnd
if "%OS%"=="Windows_NT" endlocal
:omega

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import org.gradle.internal.os.OperatingSystem
pluginManagement {
repositories {
mavenLocal()
gradlePluginPortal()
String frcYear = '2026'
File frcHome
if (OperatingSystem.current().isWindows()) {
String publicFolder = System.getenv('PUBLIC')
if (publicFolder == null) {
publicFolder = "C:\\Users\\Public"
}
def homeRoot = new File(publicFolder, "wpilib")
frcHome = new File(homeRoot, frcYear)
} else {
def userFolder = System.getProperty("user.home")
def homeRoot = new File(userFolder, "wpilib")
frcHome = new File(homeRoot, frcYear)
}
def frcHomeMaven = new File(frcHome, 'maven')
maven {
name = 'frcHome'
url = frcHomeMaven
}
}
}
Properties props = System.getProperties();
props.setProperty("org.gradle.internal.native.headers.unresolved.dependencies.ignore", "true");

3
src/main/deploy/example.txt Normal file
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Files placed in this directory will be deployed to the RoboRIO into the
'deploy' directory in the home folder. Use the 'Filesystem.getDeployDirectory' wpilib function
to get a proper path relative to the deploy directory.

234
src/main/deploy/pathplanner/Tests.path Normal file
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{
"waypoints": [
{
"anchorPoint": {
"x": 7.855128995972278,
"y": 3.8506658441888315
},
"prevControl": null,
"nextControl": {
"x": 9.51563917413549,
"y": 3.864980587104032
},
"holonomicAngle": 0.0,
"isReversal": false,
"velOverride": null,
"isLocked": false,
"isStopPoint": false,
"stopEvent": {
"names": [],
"executionBehavior": "parallel",
"waitBehavior": "none",
"waitTime": 0
}
},
{
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},
"prevControl": {
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},
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},
"holonomicAngle": 0.0,
"isReversal": true,
"velOverride": null,
"isLocked": false,
"isStopPoint": false,
"stopEvent": {
"names": [],
"executionBehavior": "parallel",
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}
},
{
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},
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},
"holonomicAngle": 0,
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"stopEvent": {
"names": [],
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}
},
{
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},
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},
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},
"holonomicAngle": 0,
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"isStopPoint": true,
"stopEvent": {
"names": [],
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}
},
{
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},
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},
"nextControl": {
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},
"holonomicAngle": 125.92486296979446,
"isReversal": true,
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"stopEvent": {
"names": [],
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}
},
{
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},
"prevControl": {
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},
"nextControl": {
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},
"holonomicAngle": -91.03738139006352,
"isReversal": true,
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"stopEvent": {
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}
},
{
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},
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},
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},
"holonomicAngle": 59.62087398863161,
"isReversal": true,
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"stopEvent": {
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}
},
{
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},
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},
"nextControl": {
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},
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"isReversal": true,
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"isStopPoint": false,
"stopEvent": {
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}
},
{
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},
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},
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"isStopPoint": false,
"stopEvent": {
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"waitBehavior": "none",
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}
}
],
"maxVelocity": 2.0,
"maxAcceleration": 3.0,
"isReversed": null,
"markers": [
{
"position": 3.4181818181818175,
"names": [
"marker"
]
}
]
}

19
src/main/deploy/pathplanner/autos/Tests.auto Normal file
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{
"version": "2025.0",
"command": {
"type": "sequential",
"data": {
"commands": [
{
"type": "path",
"data": {
"pathName": "SimplePath"
}
}
]
}
},
"resetOdom": true,
"folder": null,
"choreoAuto": false
}

1
src/main/deploy/pathplanner/navgrid.json Normal file
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75
src/main/deploy/pathplanner/paths/SimplePath.path Normal file
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{
"version": "2025.0",
"waypoints": [
{
"anchor": {
"x": 4.061722123444247,
"y": 5.039
},
"prevControl": null,
"nextControl": {
"x": 4.267799739805012,
"y": 4.6820630981604685
},
"isLocked": false,
"linkedName": null
},
{
"anchor": {
"x": 5.292790014151457,
"y": 4.494829275372837
},
"prevControl": {
"x": 4.519661364176327,
"y": 4.494829275372837
},
"nextControl": {
"x": 5.980046769810262,
"y": 4.494829275372837
},
"isLocked": false,
"linkedName": null
},
{
"anchor": {
"x": 6.152,
"y": 5.296
},
"prevControl": {
"x": 6.066179328079686,
"y": 4.809286783590948
},
"nextControl": null,
"isLocked": false,
"linkedName": null
}
],
"rotationTargets": [
{
"waypointRelativePos": 1.0,
"rotationDegrees": 90.0
}
],
"constraintZones": [],
"pointTowardsZones": [],
"eventMarkers": [],
"globalConstraints": {
"maxVelocity": 3,
"maxAcceleration": 3,
"maxAngularVelocity": 540,
"maxAngularAcceleration": 720,
"nominalVoltage": 12.0,
"unlimited": false
},
"goalEndState": {
"velocity": 0,
"rotation": 0.0
},
"reversed": false,
"folder": null,
"idealStartingState": {
"velocity": 0,
"rotation": 0.0
},
"useDefaultConstraints": false
}

32
src/main/deploy/pathplanner/settings.json Normal file
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{
"robotWidth": 0.762,
"robotLength": 0.762,
"holonomicMode": true,
"pathFolders": [],
"autoFolders": [],
"defaultMaxVel": 3.0,
"defaultMaxAccel": 3.0,
"defaultMaxAngVel": 540.0,
"defaultMaxAngAccel": 720.0,
"defaultNominalVoltage": 12.0,
"robotMass": 75.0,
"robotMOI": 6.883,
"robotTrackwidth": 0.5588,
"driveWheelRadius": 0.05504,
"driveGearing": 7.363636,
"maxDriveSpeed": 4.7,
"driveMotorType": "krakenX60FOC",
"driveCurrentLimit": 120.0,
"wheelCOF": 1.7,
"flModuleX": 0.267,
"flModuleY": 0.2667,
"frModuleX": 0.267,
"frModuleY": -0.267,
"blModuleX": -0.267,
"blModuleY": 0.267,
"brModuleX": -0.267,
"brModuleY": -0.267,
"bumperOffsetX": 0.0,
"bumperOffsetY": 0.0,
"robotFeatures": []
}

1589
src/main/java/frc/robot/LimelightHelpers.java Normal file
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src/main/java/frc/robot/Main.java Normal file
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// Copyright (c) FIRST and other WPILib contributors.
// Open Source Software; you can modify and/or share it under the terms of
// the WPILib BSD license file in the root directory of this project.
package frc.robot;
import edu.wpi.first.wpilibj.RobotBase;
public final class Main {
private Main() {}
public static void main(String... args) {
RobotBase.startRobot(Robot::new);
}
}

106
src/main/java/frc/robot/Robot.java Normal file
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// Copyright (c) FIRST and other WPILib contributors.
// Open Source Software; you can modify and/or share it under the terms of
// the WPILib BSD license file in the root directory of this project.
package frc.robot;
import com.ctre.phoenix6.HootAutoReplay;
import edu.wpi.first.math.util.Units;
import edu.wpi.first.wpilibj.TimedRobot;
import edu.wpi.first.wpilibj2.command.Command;
import edu.wpi.first.wpilibj2.command.CommandScheduler;
public class Robot extends TimedRobot {
private Command m_autonomousCommand;
private final RobotContainer m_robotContainer;
/* log and replay timestamp and joystick data */
private final HootAutoReplay m_timeAndJoystickReplay = new HootAutoReplay()
.withTimestampReplay()
.withJoystickReplay();
private final boolean kUseLimelight = false;
public Robot() {
m_robotContainer = new RobotContainer();
}
@Override
public void robotPeriodic() {
m_timeAndJoystickReplay.update();
CommandScheduler.getInstance().run();
/*
* This example of adding Limelight is very simple and may not be sufficient for on-field use.
* Users typically need to provide a standard deviation that scales with the distance to target
* and changes with number of tags available.
*
* This example is sufficient to show that vision integration is possible, though exact implementation
* of how to use vision should be tuned per-robot and to the team's specification.
*/
if (kUseLimelight) {
var driveState = m_robotContainer.drivetrain.getState();
double headingDeg = driveState.Pose.getRotation().getDegrees();
double omegaRps = Units.radiansToRotations(driveState.Speeds.omegaRadiansPerSecond);
LimelightHelpers.SetRobotOrientation("limelight", headingDeg, 0, 0, 0, 0, 0);
var llMeasurement = LimelightHelpers.getBotPoseEstimate_wpiBlue_MegaTag2("limelight");
if (llMeasurement != null && llMeasurement.tagCount > 0 && Math.abs(omegaRps) < 2.0) {
m_robotContainer.drivetrain.addVisionMeasurement(llMeasurement.pose, llMeasurement.timestampSeconds);
}
}
}
@Override
public void disabledInit() {}
@Override
public void disabledPeriodic() {}
@Override
public void disabledExit() {}
@Override
public void autonomousInit() {
m_autonomousCommand = m_robotContainer.getAutonomousCommand();
if (m_autonomousCommand != null) {
CommandScheduler.getInstance().schedule(m_autonomousCommand);
}
}
@Override
public void autonomousPeriodic() {}
@Override
public void autonomousExit() {}
@Override
public void teleopInit() {
if (m_autonomousCommand != null) {
CommandScheduler.getInstance().cancel(m_autonomousCommand);
}
}
@Override
public void teleopPeriodic() {}
@Override
public void teleopExit() {}
@Override
public void testInit() {
CommandScheduler.getInstance().cancelAll();
}
@Override
public void testPeriodic() {}
@Override
public void testExit() {}
@Override
public void simulationPeriodic() {}
}

106
src/main/java/frc/robot/RobotContainer.java Normal file
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// Copyright (c) FIRST and other WPILib contributors.
// Open Source Software; you can modify and/or share it under the terms of
// the WPILib BSD license file in the root directory of this project.
package frc.robot;
import static edu.wpi.first.units.Units.*;
import com.ctre.phoenix6.swerve.SwerveModule.DriveRequestType;
import com.ctre.phoenix6.swerve.SwerveRequest;
import com.pathplanner.lib.auto.AutoBuilder;
import com.pathplanner.lib.commands.FollowPathCommand;
import edu.wpi.first.math.geometry.Rotation2d;
import edu.wpi.first.wpilibj.smartdashboard.SendableChooser;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
import edu.wpi.first.wpilibj2.command.Command;
import edu.wpi.first.wpilibj2.command.button.CommandXboxController;
import edu.wpi.first.wpilibj2.command.button.RobotModeTriggers;
import edu.wpi.first.wpilibj2.command.sysid.SysIdRoutine.Direction;
import frc.robot.generated.TunerConstants;
import frc.robot.subsystems.CommandSwerveDrivetrain;
public class RobotContainer {
private double MaxSpeed = 1.0 * TunerConstants.kSpeedAt12Volts.in(MetersPerSecond); // kSpeedAt12Volts desired top speed
private double MaxAngularRate = RotationsPerSecond.of(0.75).in(RadiansPerSecond); // 3/4 of a rotation per second max angular velocity
/* Setting up bindings for necessary control of the swerve drive platform */
private final SwerveRequest.FieldCentric drive = new SwerveRequest.FieldCentric()
.withDeadband(MaxSpeed * 0.1).withRotationalDeadband(MaxAngularRate * 0.1) // Add a 10% deadband
.withDriveRequestType(DriveRequestType.OpenLoopVoltage); // Use open-loop control for drive motors
private final SwerveRequest.SwerveDriveBrake brake = new SwerveRequest.SwerveDriveBrake();
private final SwerveRequest.PointWheelsAt point = new SwerveRequest.PointWheelsAt();
private final SwerveRequest.RobotCentric forwardStraight = new SwerveRequest.RobotCentric()
.withDriveRequestType(DriveRequestType.OpenLoopVoltage);
private final Telemetry logger = new Telemetry(MaxSpeed);
private final CommandXboxController joystick = new CommandXboxController(0);
public final CommandSwerveDrivetrain drivetrain = TunerConstants.createDrivetrain();
/* Path follower */
private final SendableChooser<Command> autoChooser;
public RobotContainer() {
autoChooser = AutoBuilder.buildAutoChooser("Tests");
SmartDashboard.putData("Auto Mode", autoChooser);
configureBindings();
// Warmup PathPlanner to avoid Java pauses
FollowPathCommand.warmupCommand().schedule();
}
private void configureBindings() {
// Note that X is defined as forward according to WPILib convention,
// and Y is defined as to the left according to WPILib convention.
drivetrain.setDefaultCommand(
// Drivetrain will execute this command periodically
drivetrain.applyRequest(() ->
drive.withVelocityX(-joystick.getLeftY() * MaxSpeed) // Drive forward with negative Y (forward)
.withVelocityY(-joystick.getLeftX() * MaxSpeed) // Drive left with negative X (left)
.withRotationalRate(-joystick.getRightX() * MaxAngularRate) // Drive counterclockwise with negative X (left)
)
);
// Idle while the robot is disabled. This ensures the configured
// neutral mode is applied to the drive motors while disabled.
final var idle = new SwerveRequest.Idle();
RobotModeTriggers.disabled().whileTrue(
drivetrain.applyRequest(() -> idle).ignoringDisable(true)
);
joystick.a().whileTrue(drivetrain.applyRequest(() -> brake));
joystick.b().whileTrue(drivetrain.applyRequest(() ->
point.withModuleDirection(new Rotation2d(-joystick.getLeftY(), -joystick.getLeftX()))
));
joystick.povUp().whileTrue(drivetrain.applyRequest(() ->
forwardStraight.withVelocityX(0.5).withVelocityY(0))
);
joystick.povDown().whileTrue(drivetrain.applyRequest(() ->
forwardStraight.withVelocityX(-0.5).withVelocityY(0))
);
// Run SysId routines when holding back/start and X/Y.
// Note that each routine should be run exactly once in a single log.
joystick.back().and(joystick.y()).whileTrue(drivetrain.sysIdDynamic(Direction.kForward));
joystick.back().and(joystick.x()).whileTrue(drivetrain.sysIdDynamic(Direction.kReverse));
joystick.start().and(joystick.y()).whileTrue(drivetrain.sysIdQuasistatic(Direction.kForward));
joystick.start().and(joystick.x()).whileTrue(drivetrain.sysIdQuasistatic(Direction.kReverse));
// Reset the field-centric heading on left bumper press.
joystick.leftBumper().onTrue(drivetrain.runOnce(drivetrain::seedFieldCentric));
drivetrain.registerTelemetry(logger::telemeterize);
}
public Command getAutonomousCommand() {
/* Run the path selected from the auto chooser */
return autoChooser.getSelected();
}
}

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src/main/java/frc/robot/Telemetry.java Normal file
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package frc.robot;
import com.ctre.phoenix6.SignalLogger;
import com.ctre.phoenix6.swerve.SwerveDrivetrain.SwerveDriveState;
import edu.wpi.first.math.geometry.Pose2d;
import edu.wpi.first.math.kinematics.ChassisSpeeds;
import edu.wpi.first.math.kinematics.SwerveModulePosition;
import edu.wpi.first.math.kinematics.SwerveModuleState;
import edu.wpi.first.networktables.DoubleArrayPublisher;
import edu.wpi.first.networktables.DoublePublisher;
import edu.wpi.first.networktables.NetworkTable;
import edu.wpi.first.networktables.NetworkTableInstance;
import edu.wpi.first.networktables.StringPublisher;
import edu.wpi.first.networktables.StructArrayPublisher;
import edu.wpi.first.networktables.StructPublisher;
import edu.wpi.first.wpilibj.smartdashboard.Mechanism2d;
import edu.wpi.first.wpilibj.smartdashboard.MechanismLigament2d;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
import edu.wpi.first.wpilibj.util.Color;
import edu.wpi.first.wpilibj.util.Color8Bit;
public class Telemetry {
private final double MaxSpeed;
/**
* Construct a telemetry object, with the specified max speed of the robot
*
* @param maxSpeed Maximum speed in meters per second
*/
public Telemetry(double maxSpeed) {
MaxSpeed = maxSpeed;
SignalLogger.start();
/* Set up the module state Mechanism2d telemetry */
for (int i = 0; i < 4; ++i) {
SmartDashboard.putData("Module " + i, m_moduleMechanisms[i]);
}
}
/* What to publish over networktables for telemetry */
private final NetworkTableInstance inst = NetworkTableInstance.getDefault();
/* Robot swerve drive state */
private final NetworkTable driveStateTable = inst.getTable("DriveState");
private final StructPublisher<Pose2d> drivePose = driveStateTable.getStructTopic("Pose", Pose2d.struct).publish();
private final StructPublisher<ChassisSpeeds> driveSpeeds = driveStateTable.getStructTopic("Speeds", ChassisSpeeds.struct).publish();
private final StructArrayPublisher<SwerveModuleState> driveModuleStates = driveStateTable.getStructArrayTopic("ModuleStates", SwerveModuleState.struct).publish();
private final StructArrayPublisher<SwerveModuleState> driveModuleTargets = driveStateTable.getStructArrayTopic("ModuleTargets", SwerveModuleState.struct).publish();
private final StructArrayPublisher<SwerveModulePosition> driveModulePositions = driveStateTable.getStructArrayTopic("ModulePositions", SwerveModulePosition.struct).publish();
private final DoublePublisher driveTimestamp = driveStateTable.getDoubleTopic("Timestamp").publish();
private final DoublePublisher driveOdometryFrequency = driveStateTable.getDoubleTopic("OdometryFrequency").publish();
/* Robot pose for field positioning */
private final NetworkTable table = inst.getTable("Pose");
private final DoubleArrayPublisher fieldPub = table.getDoubleArrayTopic("robotPose").publish();
private final StringPublisher fieldTypePub = table.getStringTopic(".type").publish();
/* Mechanisms to represent the swerve module states */
private final Mechanism2d[] m_moduleMechanisms = new Mechanism2d[] {
new Mechanism2d(1, 1),
new Mechanism2d(1, 1),
new Mechanism2d(1, 1),
new Mechanism2d(1, 1),
};
/* A direction and length changing ligament for speed representation */
private final MechanismLigament2d[] m_moduleSpeeds = new MechanismLigament2d[] {
m_moduleMechanisms[0].getRoot("RootSpeed", 0.5, 0.5).append(new MechanismLigament2d("Speed", 0.5, 0)),
m_moduleMechanisms[1].getRoot("RootSpeed", 0.5, 0.5).append(new MechanismLigament2d("Speed", 0.5, 0)),
m_moduleMechanisms[2].getRoot("RootSpeed", 0.5, 0.5).append(new MechanismLigament2d("Speed", 0.5, 0)),
m_moduleMechanisms[3].getRoot("RootSpeed", 0.5, 0.5).append(new MechanismLigament2d("Speed", 0.5, 0)),
};
/* A direction changing and length constant ligament for module direction */
private final MechanismLigament2d[] m_moduleDirections = new MechanismLigament2d[] {
m_moduleMechanisms[0].getRoot("RootDirection", 0.5, 0.5)
.append(new MechanismLigament2d("Direction", 0.1, 0, 0, new Color8Bit(Color.kWhite))),
m_moduleMechanisms[1].getRoot("RootDirection", 0.5, 0.5)
.append(new MechanismLigament2d("Direction", 0.1, 0, 0, new Color8Bit(Color.kWhite))),
m_moduleMechanisms[2].getRoot("RootDirection", 0.5, 0.5)
.append(new MechanismLigament2d("Direction", 0.1, 0, 0, new Color8Bit(Color.kWhite))),
m_moduleMechanisms[3].getRoot("RootDirection", 0.5, 0.5)
.append(new MechanismLigament2d("Direction", 0.1, 0, 0, new Color8Bit(Color.kWhite))),
};
private final double[] m_poseArray = new double[3];
/** Accept the swerve drive state and telemeterize it to SmartDashboard and SignalLogger. */
public void telemeterize(SwerveDriveState state) {
/* Telemeterize the swerve drive state */
drivePose.set(state.Pose);
driveSpeeds.set(state.Speeds);
driveModuleStates.set(state.ModuleStates);
driveModuleTargets.set(state.ModuleTargets);
driveModulePositions.set(state.ModulePositions);
driveTimestamp.set(state.Timestamp);
driveOdometryFrequency.set(1.0 / state.OdometryPeriod);
/* Also write to log file */
SignalLogger.writeStruct("DriveState/Pose", Pose2d.struct, state.Pose);
SignalLogger.writeStruct("DriveState/Speeds", ChassisSpeeds.struct, state.Speeds);
SignalLogger.writeStructArray("DriveState/ModuleStates", SwerveModuleState.struct, state.ModuleStates);
SignalLogger.writeStructArray("DriveState/ModuleTargets", SwerveModuleState.struct, state.ModuleTargets);
SignalLogger.writeStructArray("DriveState/ModulePositions", SwerveModulePosition.struct, state.ModulePositions);
SignalLogger.writeDouble("DriveState/OdometryPeriod", state.OdometryPeriod, "seconds");
/* Telemeterize the pose to a Field2d */
fieldTypePub.set("Field2d");
m_poseArray[0] = state.Pose.getX();
m_poseArray[1] = state.Pose.getY();
m_poseArray[2] = state.Pose.getRotation().getDegrees();
fieldPub.set(m_poseArray);
/* Telemeterize each module state to a Mechanism2d */
for (int i = 0; i < 4; ++i) {
m_moduleSpeeds[i].setAngle(state.ModuleStates[i].angle);
m_moduleDirections[i].setAngle(state.ModuleStates[i].angle);
m_moduleSpeeds[i].setLength(state.ModuleStates[i].speedMetersPerSecond / (2 * MaxSpeed));
}
}
}

286
src/main/java/frc/robot/generated/TunerConstants.java Normal file
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package frc.robot.generated;
import static edu.wpi.first.units.Units.*;
import com.ctre.phoenix6.CANBus;
import com.ctre.phoenix6.configs.*;
import com.ctre.phoenix6.hardware.*;
import com.ctre.phoenix6.signals.*;
import com.ctre.phoenix6.swerve.*;
import com.ctre.phoenix6.swerve.SwerveModuleConstants.*;
import edu.wpi.first.math.Matrix;
import edu.wpi.first.math.numbers.N1;
import edu.wpi.first.math.numbers.N3;
import edu.wpi.first.units.measure.*;
import frc.robot.subsystems.CommandSwerveDrivetrain;
// Generated by the 2026 Tuner X Swerve Project Generator
// https://v6.docs.ctr-electronics.com/en/stable/docs/tuner/tuner-swerve/index.html
public class TunerConstants {
// Both sets of gains need to be tuned to your individual robot.
// The steer motor uses any SwerveModule.SteerRequestType control request with the
// output type specified by SwerveModuleConstants.SteerMotorClosedLoopOutput
private static final Slot0Configs steerGains = new Slot0Configs()
.withKP(100).withKI(0).withKD(0.5)
.withKS(0.1).withKV(1.91).withKA(0)
.withStaticFeedforwardSign(StaticFeedforwardSignValue.UseClosedLoopSign);
// When using closed-loop control, the drive motor uses the control
// output type specified by SwerveModuleConstants.DriveMotorClosedLoopOutput
private static final Slot0Configs driveGains = new Slot0Configs()
.withKP(0.1).withKI(0).withKD(0)
.withKS(0).withKV(0.124);
// The closed-loop output type to use for the steer motors;
// This affects the PID/FF gains for the steer motors
private static final ClosedLoopOutputType kSteerClosedLoopOutput = ClosedLoopOutputType.Voltage;
// The closed-loop output type to use for the drive motors;
// This affects the PID/FF gains for the drive motors
private static final ClosedLoopOutputType kDriveClosedLoopOutput = ClosedLoopOutputType.Voltage;
// The type of motor used for the drive motor
private static final DriveMotorArrangement kDriveMotorType = DriveMotorArrangement.TalonFX_Integrated;
// The type of motor used for the drive motor
private static final SteerMotorArrangement kSteerMotorType = SteerMotorArrangement.TalonFX_Integrated;
// The remote sensor feedback type to use for the steer motors;
// When not Pro-licensed, Fused*/Sync* automatically fall back to Remote*
private static final SteerFeedbackType kSteerFeedbackType = SteerFeedbackType.FusedCANcoder;
// The stator current at which the wheels start to slip;
// This needs to be tuned to your individual robot
private static final Current kSlipCurrent = Amps.of(120);
// Initial configs for the drive and steer motors and the azimuth encoder; these cannot be null.
// Some configs will be overwritten; check the `with*InitialConfigs()` API documentation.
private static final TalonFXConfiguration driveInitialConfigs = new TalonFXConfiguration();
private static final TalonFXConfiguration steerInitialConfigs = new TalonFXConfiguration()
.withCurrentLimits(
new CurrentLimitsConfigs()
// Swerve azimuth does not require much torque output, so we can set a relatively low
// stator current limit to help avoid brownouts without impacting performance.
.withStatorCurrentLimit(Amps.of(60))
.withStatorCurrentLimitEnable(true)
);
private static final CANcoderConfiguration encoderInitialConfigs = new CANcoderConfiguration();
// Configs for the Pigeon 2; leave this null to skip applying Pigeon 2 configs
private static final Pigeon2Configuration pigeonConfigs = null;
// CAN bus that the devices are located on;
// All swerve devices must share the same CAN bus
public static final CANBus kCANBus = new CANBus("canivore", "./logs/example.hoot");
// Theoretical free speed (m/s) at 12 V applied output;
// This needs to be tuned to your individual robot
public static final LinearVelocity kSpeedAt12Volts = MetersPerSecond.of(4.54);
// Every 1 rotation of the azimuth results in kCoupleRatio drive motor turns;
// This may need to be tuned to your individual robot
private static final double kCoupleRatio = 3.8181818181818183;
private static final double kDriveGearRatio = 7.363636363636365;
private static final double kSteerGearRatio = 15.42857142857143;
private static final Distance kWheelRadius = Inches.of(2.167);
private static final boolean kInvertLeftSide = false;
private static final boolean kInvertRightSide = true;
private static final int kPigeonId = 1;
// These are only used for simulation
private static final MomentOfInertia kSteerInertia = KilogramSquareMeters.of(0.01);
private static final MomentOfInertia kDriveInertia = KilogramSquareMeters.of(0.01);
// Simulated voltage necessary to overcome friction
private static final Voltage kSteerFrictionVoltage = Volts.of(0.2);
private static final Voltage kDriveFrictionVoltage = Volts.of(0.2);
public static final SwerveDrivetrainConstants DrivetrainConstants = new SwerveDrivetrainConstants()
.withCANBusName(kCANBus.getName())
.withPigeon2Id(kPigeonId)
.withPigeon2Configs(pigeonConfigs);
private static final SwerveModuleConstantsFactory<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> ConstantCreator =
new SwerveModuleConstantsFactory<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration>()
.withDriveMotorGearRatio(kDriveGearRatio)
.withSteerMotorGearRatio(kSteerGearRatio)
.withCouplingGearRatio(kCoupleRatio)
.withWheelRadius(kWheelRadius)
.withSteerMotorGains(steerGains)
.withDriveMotorGains(driveGains)
.withSteerMotorClosedLoopOutput(kSteerClosedLoopOutput)
.withDriveMotorClosedLoopOutput(kDriveClosedLoopOutput)
.withSlipCurrent(kSlipCurrent)
.withSpeedAt12Volts(kSpeedAt12Volts)
.withDriveMotorType(kDriveMotorType)
.withSteerMotorType(kSteerMotorType)
.withFeedbackSource(kSteerFeedbackType)
.withDriveMotorInitialConfigs(driveInitialConfigs)
.withSteerMotorInitialConfigs(steerInitialConfigs)
.withEncoderInitialConfigs(encoderInitialConfigs)
.withSteerInertia(kSteerInertia)
.withDriveInertia(kDriveInertia)
.withSteerFrictionVoltage(kSteerFrictionVoltage)
.withDriveFrictionVoltage(kDriveFrictionVoltage);
// Front Left
private static final int kFrontLeftDriveMotorId = 3;
private static final int kFrontLeftSteerMotorId = 2;
private static final int kFrontLeftEncoderId = 1;
private static final Angle kFrontLeftEncoderOffset = Rotations.of(0.15234375);
private static final boolean kFrontLeftSteerMotorInverted = true;
private static final boolean kFrontLeftEncoderInverted = false;
private static final Distance kFrontLeftXPos = Inches.of(10);
private static final Distance kFrontLeftYPos = Inches.of(10);
// Front Right
private static final int kFrontRightDriveMotorId = 1;
private static final int kFrontRightSteerMotorId = 0;
private static final int kFrontRightEncoderId = 0;
private static final Angle kFrontRightEncoderOffset = Rotations.of(-0.4873046875);
private static final boolean kFrontRightSteerMotorInverted = true;
private static final boolean kFrontRightEncoderInverted = false;
private static final Distance kFrontRightXPos = Inches.of(10);
private static final Distance kFrontRightYPos = Inches.of(-10);
// Back Left
private static final int kBackLeftDriveMotorId = 7;
private static final int kBackLeftSteerMotorId = 6;
private static final int kBackLeftEncoderId = 3;
private static final Angle kBackLeftEncoderOffset = Rotations.of(-0.219482421875);
private static final boolean kBackLeftSteerMotorInverted = true;
private static final boolean kBackLeftEncoderInverted = false;
private static final Distance kBackLeftXPos = Inches.of(-10);
private static final Distance kBackLeftYPos = Inches.of(10);
// Back Right
private static final int kBackRightDriveMotorId = 5;
private static final int kBackRightSteerMotorId = 4;
private static final int kBackRightEncoderId = 2;
private static final Angle kBackRightEncoderOffset = Rotations.of(0.17236328125);
private static final boolean kBackRightSteerMotorInverted = true;
private static final boolean kBackRightEncoderInverted = false;
private static final Distance kBackRightXPos = Inches.of(-10);
private static final Distance kBackRightYPos = Inches.of(-10);
public static final SwerveModuleConstants<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> FrontLeft =
ConstantCreator.createModuleConstants(
kFrontLeftSteerMotorId, kFrontLeftDriveMotorId, kFrontLeftEncoderId, kFrontLeftEncoderOffset,
kFrontLeftXPos, kFrontLeftYPos, kInvertLeftSide, kFrontLeftSteerMotorInverted, kFrontLeftEncoderInverted
);
public static final SwerveModuleConstants<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> FrontRight =
ConstantCreator.createModuleConstants(
kFrontRightSteerMotorId, kFrontRightDriveMotorId, kFrontRightEncoderId, kFrontRightEncoderOffset,
kFrontRightXPos, kFrontRightYPos, kInvertRightSide, kFrontRightSteerMotorInverted, kFrontRightEncoderInverted
);
public static final SwerveModuleConstants<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> BackLeft =
ConstantCreator.createModuleConstants(
kBackLeftSteerMotorId, kBackLeftDriveMotorId, kBackLeftEncoderId, kBackLeftEncoderOffset,
kBackLeftXPos, kBackLeftYPos, kInvertLeftSide, kBackLeftSteerMotorInverted, kBackLeftEncoderInverted
);
public static final SwerveModuleConstants<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> BackRight =
ConstantCreator.createModuleConstants(
kBackRightSteerMotorId, kBackRightDriveMotorId, kBackRightEncoderId, kBackRightEncoderOffset,
kBackRightXPos, kBackRightYPos, kInvertRightSide, kBackRightSteerMotorInverted, kBackRightEncoderInverted
);
/**
* Creates a CommandSwerveDrivetrain instance.
* This should only be called once in your robot program,.
*/
public static CommandSwerveDrivetrain createDrivetrain() {
return new CommandSwerveDrivetrain(
DrivetrainConstants, FrontLeft, FrontRight, BackLeft, BackRight
);
}
/**
* Swerve Drive class utilizing CTR Electronics' Phoenix 6 API with the selected device types.
*/
public static class TunerSwerveDrivetrain extends SwerveDrivetrain<TalonFX, TalonFX, CANcoder> {
/**
* Constructs a CTRE SwerveDrivetrain using the specified constants.
* <p>
* This constructs the underlying hardware devices, so users should not construct
* the devices themselves. If they need the devices, they can access them through
* getters in the classes.
*
* @param drivetrainConstants Drivetrain-wide constants for the swerve drive
* @param modules Constants for each specific module
*/
public TunerSwerveDrivetrain(
SwerveDrivetrainConstants drivetrainConstants,
SwerveModuleConstants<?, ?, ?>... modules
) {
super(
TalonFX::new, TalonFX::new, CANcoder::new,
drivetrainConstants, modules
);
}
/**
* Constructs a CTRE SwerveDrivetrain using the specified constants.
* <p>
* This constructs the underlying hardware devices, so users should not construct
* the devices themselves. If they need the devices, they can access them through
* getters in the classes.
*
* @param drivetrainConstants Drivetrain-wide constants for the swerve drive
* @param odometryUpdateFrequency The frequency to run the odometry loop. If
* unspecified or set to 0 Hz, this is 250 Hz on
* CAN FD, and 100 Hz on CAN 2.0.
* @param modules Constants for each specific module
*/
public TunerSwerveDrivetrain(
SwerveDrivetrainConstants drivetrainConstants,
double odometryUpdateFrequency,
SwerveModuleConstants<?, ?, ?>... modules
) {
super(
TalonFX::new, TalonFX::new, CANcoder::new,
drivetrainConstants, odometryUpdateFrequency, modules
);
}
/**
* Constructs a CTRE SwerveDrivetrain using the specified constants.
* <p>
* This constructs the underlying hardware devices, so users should not construct
* the devices themselves. If they need the devices, they can access them through
* getters in the classes.
*
* @param drivetrainConstants Drivetrain-wide constants for the swerve drive
* @param odometryUpdateFrequency The frequency to run the odometry loop. If
* unspecified or set to 0 Hz, this is 250 Hz on
* CAN FD, and 100 Hz on CAN 2.0.
* @param odometryStandardDeviation The standard deviation for odometry calculation
* in the form [x, y, theta]ᵀ, with units in meters
* and radians
* @param visionStandardDeviation The standard deviation for vision calculation
* in the form [x, y, theta]ᵀ, with units in meters
* and radians
* @param modules Constants for each specific module
*/
public TunerSwerveDrivetrain(
SwerveDrivetrainConstants drivetrainConstants,
double odometryUpdateFrequency,
Matrix<N3, N1> odometryStandardDeviation,
Matrix<N3, N1> visionStandardDeviation,
SwerveModuleConstants<?, ?, ?>... modules
) {
super(
TalonFX::new, TalonFX::new, CANcoder::new,
drivetrainConstants, odometryUpdateFrequency,
odometryStandardDeviation, visionStandardDeviation, modules
);
}
}
}

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package frc.robot.subsystems;
import static edu.wpi.first.units.Units.*;
import java.util.Optional;
import java.util.function.Supplier;
import com.ctre.phoenix6.SignalLogger;
import com.ctre.phoenix6.Utils;
import com.ctre.phoenix6.swerve.SwerveDrivetrainConstants;
import com.ctre.phoenix6.swerve.SwerveModuleConstants;
import com.ctre.phoenix6.swerve.SwerveRequest;
import com.pathplanner.lib.auto.AutoBuilder;
import com.pathplanner.lib.config.PIDConstants;
import com.pathplanner.lib.config.RobotConfig;
import com.pathplanner.lib.controllers.PPHolonomicDriveController;
import edu.wpi.first.math.Matrix;
import edu.wpi.first.math.geometry.Pose2d;
import edu.wpi.first.math.geometry.Rotation2d;
import edu.wpi.first.math.kinematics.ChassisSpeeds;
import edu.wpi.first.math.numbers.N1;
import edu.wpi.first.math.numbers.N3;
import edu.wpi.first.wpilibj.DriverStation;
import edu.wpi.first.wpilibj.DriverStation.Alliance;
import edu.wpi.first.wpilibj.Notifier;
import edu.wpi.first.wpilibj.RobotController;
import edu.wpi.first.wpilibj2.command.Command;
import edu.wpi.first.wpilibj2.command.Subsystem;
import edu.wpi.first.wpilibj2.command.sysid.SysIdRoutine;
import frc.robot.generated.TunerConstants.TunerSwerveDrivetrain;
/**
* Class that extends the Phoenix 6 SwerveDrivetrain class and implements
* Subsystem so it can easily be used in command-based projects.
*
* Generated by the 2026 Tuner X Swerve Project Generator
* https://v6.docs.ctr-electronics.com/en/stable/docs/tuner/tuner-swerve/index.html
*/
public class CommandSwerveDrivetrain extends TunerSwerveDrivetrain implements Subsystem {
private static final double kSimLoopPeriod = 0.004; // 4 ms
private Notifier m_simNotifier = null;
private double m_lastSimTime;
/* Blue alliance sees forward as 0 degrees (toward red alliance wall) */
private static final Rotation2d kBlueAlliancePerspectiveRotation = Rotation2d.kZero;
/* Red alliance sees forward as 180 degrees (toward blue alliance wall) */
private static final Rotation2d kRedAlliancePerspectiveRotation = Rotation2d.k180deg;
/* Keep track if we've ever applied the operator perspective before or not */
private boolean m_hasAppliedOperatorPerspective = false;
/** Swerve request to apply during robot-centric path following */
private final SwerveRequest.ApplyRobotSpeeds m_pathApplyRobotSpeeds = new SwerveRequest.ApplyRobotSpeeds();
/* Swerve requests to apply during SysId characterization */
private final SwerveRequest.SysIdSwerveTranslation m_translationCharacterization = new SwerveRequest.SysIdSwerveTranslation();
private final SwerveRequest.SysIdSwerveSteerGains m_steerCharacterization = new SwerveRequest.SysIdSwerveSteerGains();
private final SwerveRequest.SysIdSwerveRotation m_rotationCharacterization = new SwerveRequest.SysIdSwerveRotation();
/* SysId routine for characterizing translation. This is used to find PID gains for the drive motors. */
private final SysIdRoutine m_sysIdRoutineTranslation = new SysIdRoutine(
new SysIdRoutine.Config(
null, // Use default ramp rate (1 V/s)
Volts.of(4), // Reduce dynamic step voltage to 4 V to prevent brownout
null, // Use default timeout (10 s)
// Log state with SignalLogger class
state -> SignalLogger.writeString("SysIdTranslation_State", state.toString())
),
new SysIdRoutine.Mechanism(
output -> setControl(m_translationCharacterization.withVolts(output)),
null,
this
)
);
/* SysId routine for characterizing steer. This is used to find PID gains for the steer motors. */
private final SysIdRoutine m_sysIdRoutineSteer = new SysIdRoutine(
new SysIdRoutine.Config(
null, // Use default ramp rate (1 V/s)
Volts.of(7), // Use dynamic voltage of 7 V
null, // Use default timeout (10 s)
// Log state with SignalLogger class
state -> SignalLogger.writeString("SysIdSteer_State", state.toString())
),
new SysIdRoutine.Mechanism(
volts -> setControl(m_steerCharacterization.withVolts(volts)),
null,
this
)
);
/*
* SysId routine for characterizing rotation.
* This is used to find PID gains for the FieldCentricFacingAngle HeadingController.
* See the documentation of SwerveRequest.SysIdSwerveRotation for info on importing the log to SysId.
*/
private final SysIdRoutine m_sysIdRoutineRotation = new SysIdRoutine(
new SysIdRoutine.Config(
/* This is in radians per second², but SysId only supports "volts per second" */
Volts.of(Math.PI / 6).per(Second),
/* This is in radians per second, but SysId only supports "volts" */
Volts.of(Math.PI),
null, // Use default timeout (10 s)
// Log state with SignalLogger class
state -> SignalLogger.writeString("SysIdRotation_State", state.toString())
),
new SysIdRoutine.Mechanism(
output -> {
/* output is actually radians per second, but SysId only supports "volts" */
setControl(m_rotationCharacterization.withRotationalRate(output.in(Volts)));
/* also log the requested output for SysId */
SignalLogger.writeDouble("Rotational_Rate", output.in(Volts));
},
null,
this
)
);
/* The SysId routine to test */
private SysIdRoutine m_sysIdRoutineToApply = m_sysIdRoutineTranslation;
/**
* Constructs a CTRE SwerveDrivetrain using the specified constants.
* <p>
* This constructs the underlying hardware devices, so users should not construct
* the devices themselves. If they need the devices, they can access them through
* getters in the classes.
*
* @param drivetrainConstants Drivetrain-wide constants for the swerve drive
* @param modules Constants for each specific module
*/
public CommandSwerveDrivetrain(
SwerveDrivetrainConstants drivetrainConstants,
SwerveModuleConstants<?, ?, ?>... modules
) {
super(drivetrainConstants, modules);
if (Utils.isSimulation()) {
startSimThread();
}
configureAutoBuilder();
}
/**
* Constructs a CTRE SwerveDrivetrain using the specified constants.
* <p>
* This constructs the underlying hardware devices, so users should not construct
* the devices themselves. If they need the devices, they can access them through
* getters in the classes.
*
* @param drivetrainConstants Drivetrain-wide constants for the swerve drive
* @param odometryUpdateFrequency The frequency to run the odometry loop. If
* unspecified or set to 0 Hz, this is 250 Hz on
* CAN FD, and 100 Hz on CAN 2.0.
* @param modules Constants for each specific module
*/
public CommandSwerveDrivetrain(
SwerveDrivetrainConstants drivetrainConstants,
double odometryUpdateFrequency,
SwerveModuleConstants<?, ?, ?>... modules
) {
super(drivetrainConstants, odometryUpdateFrequency, modules);
if (Utils.isSimulation()) {
startSimThread();
}
configureAutoBuilder();
}
/**
* Constructs a CTRE SwerveDrivetrain using the specified constants.
* <p>
* This constructs the underlying hardware devices, so users should not construct
* the devices themselves. If they need the devices, they can access them through
* getters in the classes.
*
* @param drivetrainConstants Drivetrain-wide constants for the swerve drive
* @param odometryUpdateFrequency The frequency to run the odometry loop. If
* unspecified or set to 0 Hz, this is 250 Hz on
* CAN FD, and 100 Hz on CAN 2.0.
* @param odometryStandardDeviation The standard deviation for odometry calculation
* in the form [x, y, theta]ᵀ, with units in meters
* and radians
* @param visionStandardDeviation The standard deviation for vision calculation
* in the form [x, y, theta]ᵀ, with units in meters
* and radians
* @param modules Constants for each specific module
*/
public CommandSwerveDrivetrain(
SwerveDrivetrainConstants drivetrainConstants,
double odometryUpdateFrequency,
Matrix<N3, N1> odometryStandardDeviation,
Matrix<N3, N1> visionStandardDeviation,
SwerveModuleConstants<?, ?, ?>... modules
) {
super(drivetrainConstants, odometryUpdateFrequency, odometryStandardDeviation, visionStandardDeviation, modules);
if (Utils.isSimulation()) {
startSimThread();
}
configureAutoBuilder();
}
private void configureAutoBuilder() {
try {
var config = RobotConfig.fromGUISettings();
AutoBuilder.configure(
() -> getState().Pose, // Supplier of current robot pose
this::resetPose, // Consumer for seeding pose against auto
() -> getState().Speeds, // Supplier of current robot speeds
// Consumer of ChassisSpeeds and feedforwards to drive the robot
(speeds, feedforwards) -> setControl(
m_pathApplyRobotSpeeds.withSpeeds(ChassisSpeeds.discretize(speeds, 0.020))
.withWheelForceFeedforwardsX(feedforwards.robotRelativeForcesXNewtons())
.withWheelForceFeedforwardsY(feedforwards.robotRelativeForcesYNewtons())
),
new PPHolonomicDriveController(
// PID constants for translation
new PIDConstants(10, 0, 0),
// PID constants for rotation
new PIDConstants(7, 0, 0)
),
config,
// Assume the path needs to be flipped for Red vs Blue, this is normally the case
() -> DriverStation.getAlliance().orElse(Alliance.Blue) == Alliance.Red,
this // Subsystem for requirements
);
} catch (Exception ex) {
DriverStation.reportError("Failed to load PathPlanner config and configure AutoBuilder", ex.getStackTrace());
}
}
/**
* Returns a command that applies the specified control request to this swerve drivetrain.
*
* @param request Function returning the request to apply
* @return Command to run
*/
public Command applyRequest(Supplier<SwerveRequest> request) {
return run(() -> this.setControl(request.get()));
}
/**
* Runs the SysId Quasistatic test in the given direction for the routine
* specified by {@link #m_sysIdRoutineToApply}.
*
* @param direction Direction of the SysId Quasistatic test
* @return Command to run
*/
public Command sysIdQuasistatic(SysIdRoutine.Direction direction) {
return m_sysIdRoutineToApply.quasistatic(direction);
}
/**
* Runs the SysId Dynamic test in the given direction for the routine
* specified by {@link #m_sysIdRoutineToApply}.
*
* @param direction Direction of the SysId Dynamic test
* @return Command to run
*/
public Command sysIdDynamic(SysIdRoutine.Direction direction) {
return m_sysIdRoutineToApply.dynamic(direction);
}
@Override
public void periodic() {
/*
* Periodically try to apply the operator perspective.
* If we haven't applied the operator perspective before, then we should apply it regardless of DS state.
* This allows us to correct the perspective in case the robot code restarts mid-match.
* Otherwise, only check and apply the operator perspective if the DS is disabled.
* This ensures driving behavior doesn't change until an explicit disable event occurs during testing.
*/
if (!m_hasAppliedOperatorPerspective || DriverStation.isDisabled()) {
DriverStation.getAlliance().ifPresent(allianceColor -> {
setOperatorPerspectiveForward(
allianceColor == Alliance.Red
? kRedAlliancePerspectiveRotation
: kBlueAlliancePerspectiveRotation
);
m_hasAppliedOperatorPerspective = true;
});
}
}
private void startSimThread() {
m_lastSimTime = Utils.getCurrentTimeSeconds();
/* Run simulation at a faster rate so PID gains behave more reasonably */
m_simNotifier = new Notifier(() -> {
final double currentTime = Utils.getCurrentTimeSeconds();
double deltaTime = currentTime - m_lastSimTime;
m_lastSimTime = currentTime;
/* use the measured time delta, get battery voltage from WPILib */
updateSimState(deltaTime, RobotController.getBatteryVoltage());
});
m_simNotifier.startPeriodic(kSimLoopPeriod);
}
/**
* Adds a vision measurement to the Kalman Filter. This will correct the odometry pose estimate
* while still accounting for measurement noise.
*
* @param visionRobotPoseMeters The pose of the robot as measured by the vision camera.
* @param timestampSeconds The timestamp of the vision measurement in seconds.
*/
@Override
public void addVisionMeasurement(Pose2d visionRobotPoseMeters, double timestampSeconds) {
super.addVisionMeasurement(visionRobotPoseMeters, Utils.fpgaToCurrentTime(timestampSeconds));
}
/**
* Adds a vision measurement to the Kalman Filter. This will correct the odometry pose estimate
* while still accounting for measurement noise.
* <p>
* Note that the vision measurement standard deviations passed into this method
* will continue to apply to future measurements until a subsequent call to
* {@link #setVisionMeasurementStdDevs(Matrix)} or this method.
*
* @param visionRobotPoseMeters The pose of the robot as measured by the vision camera.
* @param timestampSeconds The timestamp of the vision measurement in seconds.
* @param visionMeasurementStdDevs Standard deviations of the vision pose measurement
* in the form [x, y, theta]ᵀ, with units in meters and radians.
*/
@Override
public void addVisionMeasurement(
Pose2d visionRobotPoseMeters,
double timestampSeconds,
Matrix<N3, N1> visionMeasurementStdDevs
) {
super.addVisionMeasurement(visionRobotPoseMeters, Utils.fpgaToCurrentTime(timestampSeconds), visionMeasurementStdDevs);
}
/**
* Return the pose at a given timestamp, if the buffer is not empty.
*
* @param timestampSeconds The timestamp of the pose in seconds.
* @return The pose at the given timestamp (or Optional.empty() if the buffer is empty).
*/
@Override
public Optional<Pose2d> samplePoseAt(double timestampSeconds) {
return super.samplePoseAt(Utils.fpgaToCurrentTime(timestampSeconds));
}
}

38
vendordeps/PathplannerLib.json Normal file
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{
"fileName": "PathplannerLib-2026.1.2.json",
"name": "PathplannerLib",
"version": "2026.1.2",
"uuid": "1b42324f-17c6-4875-8e77-1c312bc8c786",
"frcYear": "2026",
"mavenUrls": [
"https://3015rangerrobotics.github.io/pathplannerlib/repo"
],
"jsonUrl": "https://3015rangerrobotics.github.io/pathplannerlib/PathplannerLib.json",
"javaDependencies": [
{
"groupId": "com.pathplanner.lib",
"artifactId": "PathplannerLib-java",
"version": "2026.1.2"
}
],
"jniDependencies": [],
"cppDependencies": [
{
"groupId": "com.pathplanner.lib",
"artifactId": "PathplannerLib-cpp",
"version": "2026.1.2",
"libName": "PathplannerLib",
"headerClassifier": "headers",
"sharedLibrary": false,
"skipInvalidPlatforms": true,
"binaryPlatforms": [
"windowsx86-64",
"linuxx86-64",
"osxuniversal",
"linuxathena",
"linuxarm32",
"linuxarm64"
]
}
]
}

449
vendordeps/Phoenix6-frc2026-latest.json Normal file
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{
"fileName": "Phoenix6-frc2026-latest.json",
"name": "CTRE-Phoenix (v6)",
"version": "26.1.0",
"frcYear": "2026",
"uuid": "e995de00-2c64-4df5-8831-c1441420ff19",
"mavenUrls": [
"https://maven.ctr-electronics.com/release/"
],
"jsonUrl": "https://maven.ctr-electronics.com/release/com/ctre/phoenix6/latest/Phoenix6-frc2026-latest.json",
"conflictsWith": [
{
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}
]
}

39
vendordeps/WPILibNewCommands.json Normal file
View File

@@ -0,0 +1,39 @@
{
"fileName": "WPILibNewCommands.json",
"name": "WPILib-New-Commands",
"version": "1.0.0",
"uuid": "111e20f7-815e-48f8-9dd6-e675ce75b266",
"frcYear": "2026",
"mavenUrls": [],
"jsonUrl": "",
"javaDependencies": [
{
"groupId": "edu.wpi.first.wpilibNewCommands",
"artifactId": "wpilibNewCommands-java",
"version": "wpilib"
}
],
"jniDependencies": [],
"cppDependencies": [
{
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"libName": "wpilibNewCommands",
"headerClassifier": "headers",
"sourcesClassifier": "sources",
"sharedLibrary": true,
"skipInvalidPlatforms": true,
"binaryPlatforms": [
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"linuxathena",
"linuxarm32",
"linuxarm64",
"windowsx86-64",
"windowsx86",
"linuxx86-64",
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]
}
]
}