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2 Commits
v1.5.0 ... iio_change

Author SHA1 Message Date
Abhishek Malik
93054c382b Cmake: Bumping up required MRAA version 
Signed-off-by: Abhishek Malik <abhishek.malik@intel.com>
 2017-09-15 11:25:20 -07:00
Abhishek Malik
6ac2557b7d IIO: Changes modules as per new MRAA API 
Signed-off-by: Abhishek Malik <abhishek.malik@intel.com>
 2017-09-15 11:03:17 -07:00
304 changed files with 8661 additions and 8263 deletions
Expand all files Collapse all files

94
CMakeLists.txt
View File

@ -216,7 +216,7 @@ include (GetGitRevisionDescription)
git_describe (VERSION "--tags")
# If git_describe fails, use a dirty version
if (${VERSION} MATCHES -NOTFOUND)
set (VERSION "v1.5.0")
set (VERSION "v1.3.0")
message (WARNING "Failed to retrieve UPM version with 'git describe' (using "
"${VERSION}). Check that git is installed and this is a valid git repo.")
endif ()
@ -310,67 +310,55 @@ endif()
#
if (BUILDDOC)
# Add a target to generate API documentation with Doxygen
find_package (Doxygen 1.8 REQUIRED)
if (DOXYGEN_FOUND AND DOXYGEN_VERSION VERSION_GREATER "1.8")
configure_file (${CMAKE_CURRENT_SOURCE_DIR}/doxy/Doxyfile.in ${CMAKE_CURRENT_BINARY_DIR}/Doxyfile @ONLY)
if (BUILDSWIGJAVA)
configure_file (${CMAKE_CURRENT_SOURCE_DIR}/doxy/Doxyfile.java.in ${CMAKE_CURRENT_BINARY_DIR}/Doxyfile-java @ONLY)
endif()
file(GLOB PNG_FILES RELATIVE ${CMAKE_CURRENT_SOURCE_DIR}/docs docs/icons/*.png)
foreach(PNG_FILE ${PNG_FILES})
configure_file(${CMAKE_CURRENT_SOURCE_DIR}/docs/${PNG_FILE} ${CMAKE_CURRENT_BINARY_DIR}/html/docs/${PNG_FILE} COPYONLY)
endforeach()
add_custom_target (doc
${DOXYGEN_EXECUTABLE} ${CMAKE_CURRENT_BINARY_DIR}/Doxyfile
COMMAND tar -czf html/xml.tar.gz -C xml .
WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR}
COMMENT "Generating API documentation with Doxygen" VERBATIM
)
else ()
message (SEND_ERROR "ERROR - Failed to find a compatible version of Doxygen. API doc will not be generated")
endif (DOXYGEN_FOUND AND DOXYGEN_VERSION VERSION_GREATER "1.8")
find_package (Doxygen REQUIRED)
configure_file (${CMAKE_CURRENT_SOURCE_DIR}/doxy/Doxyfile.in ${CMAKE_CURRENT_BINARY_DIR}/Doxyfile @ONLY)
if (BUILDSWIGJAVA)
configure_file (${CMAKE_CURRENT_SOURCE_DIR}/doxy/Doxyfile.java.in ${CMAKE_CURRENT_BINARY_DIR}/Doxyfile-java @ONLY)
endif()
file(GLOB PNG_FILES RELATIVE ${CMAKE_CURRENT_SOURCE_DIR}/docs docs/icons/*.png)
foreach(PNG_FILE ${PNG_FILES})
configure_file(${CMAKE_CURRENT_SOURCE_DIR}/docs/${PNG_FILE} ${CMAKE_CURRENT_BINARY_DIR}/html/docs/${PNG_FILE} COPYONLY)
endforeach()
add_custom_target (doc
${DOXYGEN_EXECUTABLE} ${CMAKE_CURRENT_BINARY_DIR}/Doxyfile
COMMAND tar -czf html/xml.tar.gz -C xml .
WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR}
COMMENT "Generating API documentation with Doxygen" VERBATIM
)
# Check if Sphinx is installed and add target to generate API documentation
# Currently, the per-module documentation for python is generated from the
# python2 modules.
if(BUILDSWIGPYTHON)
find_package (Sphinx 1.3 REQUIRED)
if (SPHINX_FOUND AND SPHINX_VERSION VERSION_GREATER "1.3")
configure_file (${CMAKE_CURRENT_SOURCE_DIR}/doxy/conf.py.in ${CMAKE_CURRENT_BINARY_DIR}/pydoc/conf.py @ONLY)
configure_file (${CMAKE_CURRENT_SOURCE_DIR}/doxy/index.rst ${CMAKE_CURRENT_BINARY_DIR}/pydoc/index.rst COPYONLY)
add_custom_target (pydoc ALL
COMMAND rm -r -f ${CMAKE_BINARY_DIR}/pyupm && mkdir -p ${CMAKE_BINARY_DIR}/pyupm
COMMAND find ${CMAKE_BINARY_DIR}/src -name "_pyupm_*.so" -exec cp {} ${CMAKE_BINARY_DIR}/pyupm \;
COMMAND find ${CMAKE_BINARY_DIR}/src -name "pyupm_*.py" -exec cp {} ${CMAKE_BINARY_DIR}/pyupm \;
COMMAND ${SPHINX_API_EXECUTABLE} -f -o pydoc ${CMAKE_BINARY_DIR}/pyupm
# TODO: use a separate cmake FILE module for string replacement instead
COMMAND ${SPHINX_EXECUTABLE} -b html pydoc html/python
COMMAND sed -i.bak s|\">pyupm_|\">|g html/python/index.html html/python/modules.html
COMMAND sed -i.bak s|[[:space:]][mM]odule</a>|</a>|g html/python/index.html html/python/modules.html
DEPENDS doc
WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR}
COMMENT "Generating API documentation with Sphinx" VERBATIM
)
else ()
message (SEND_ERROR "ERROR - Failed to find a compatible version of Sphinx. Python API doc will not be generated")
endif ()
find_package (Sphinx REQUIRED)
configure_file (${CMAKE_CURRENT_SOURCE_DIR}/doxy/conf.py.in ${CMAKE_CURRENT_BINARY_DIR}/pydoc/conf.py @ONLY)
configure_file (${CMAKE_CURRENT_SOURCE_DIR}/doxy/index.rst ${CMAKE_CURRENT_BINARY_DIR}/pydoc/index.rst COPYONLY)
add_custom_target (pydoc ALL
COMMAND rm -r -f ${CMAKE_BINARY_DIR}/pyupm && mkdir -p ${CMAKE_BINARY_DIR}/pyupm
COMMAND find ${CMAKE_BINARY_DIR}/src -name "_pyupm_*.so" -exec cp {} ${CMAKE_BINARY_DIR}/pyupm \;
COMMAND find ${CMAKE_BINARY_DIR}/src -name "pyupm_*.py" -exec cp {} ${CMAKE_BINARY_DIR}/pyupm \;
COMMAND ${SPHINX_API_EXECUTABLE} -f -o pydoc ${CMAKE_BINARY_DIR}/pyupm
# TODO: use a separate cmake FILE module for string replacement instead
COMMAND ${SPHINX_EXECUTABLE} -b html pydoc html/python
COMMAND sed -i.bak s|\">pyupm_|\">|g html/python/index.html html/python/modules.html
COMMAND sed -i.bak s|[[:space:]][mM]odule</a>|</a>|g html/python/index.html html/python/modules.html
DEPENDS doc
WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR}
COMMENT "Generating API documentation with Sphinx" VERBATIM
)
endif(BUILDSWIGPYTHON)
# Check if Yuidoc is installed and add target for API documentation
if(BUILDSWIGNODE)
find_package (Yuidoc 0.10 REQUIRED)
if (YUIDOC_FOUND AND YUIDOC_VERSION VERSION_GREATER "0.10")
add_custom_target (jsdoc ALL
COMMAND ${CMAKE_SOURCE_DIR}/doxy/doxygen2jsdoc/docgen.js -m upm -i xml -o jsdoc -t ${CMAKE_CURRENT_SOURCE_DIR}/src -g ../../
COMMAND ${YUIDOC_EXECUTABLE} -C --no-sort --helpers ${CMAKE_SOURCE_DIR}/doxy/node/generators/yuidoc/helper.js --themedir ${CMAKE_SOURCE_DIR}/doxy/node/generators/yuidoc/tmpl -o html/node jsdoc/yuidoc/upm
COMMAND ${CMAKE_SOURCE_DIR}/doxy/doxygen2jsdoc/tolower.js -i html/node
DEPENDS doc
WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR}
COMMENT "Generating API documentation with Yuidoc" VERBATIM
)
else ()
message (SEND_ERROR "ERROR - Failed to find a compatible version of Yuidoc. Node.js API doc will not be generated")
endif ()
find_package(Yuidoc REQUIRED)
add_custom_target(jsdoc ALL
COMMAND ${CMAKE_SOURCE_DIR}/doxy/doxygen2jsdoc/docgen.js -m upm -i xml -o jsdoc -t ${CMAKE_CURRENT_SOURCE_DIR}/src -g ../../
COMMAND ${YUIDOC_EXECUTABLE} -C --no-sort --helpers ${CMAKE_SOURCE_DIR}/doxy/node/generators/yuidoc/helper.js --themedir ${CMAKE_SOURCE_DIR}/doxy/node/generators/yuidoc/tmpl -o html/node jsdoc/yuidoc/upm
COMMAND ${CMAKE_SOURCE_DIR}/doxy/doxygen2jsdoc/tolower.js -i html/node
DEPENDS doc
WORKING_DIRECTORY ${CMAKE_CURRENT_BINARY_DIR}
COMMENT "Generating API documentation with Yuidoc" VERBATIM
)
endif(BUILDSWIGNODE)
endif (BUILDDOC)

25
README.md
View File

@ -1,7 +1,3 @@
<p align="center">
<img src="https://github.com/intel-iot-devkit/upm/blob/master/docs/icons/upm_logo.png" height="150px" width="auto" algt="UPM Logo"/>
</p>
UPM (Useful Packages & Modules) Sensor/Actuator repository for MRAA
==============
@ -15,9 +11,8 @@ corresponding header file and instantiating the associated sensor class. In the
typical use case, a constructor initializes the sensor based on parameters that
identify the sensor, the I/O protocol used and the pin location of the sensor.
We endorse additions that implement the generic C and C++ interfaces provided
with the libraries. Multiple sensor and actuator types have been defined, for
instance:
C++ interfaces have been defined for the following sensor/actuator types, but
they are subject to change:
* Light controller
* Light sensor
@ -27,8 +22,8 @@ instance:
* Gas sensor
* Analog to digital converter
The developer community is welcome to submit feedback on existing categories or
suggest new ones.
The developer community is encouraged to help expand the list of supported
sensors and actuators and provide feedback on interface design.
### Example
@ -72,16 +67,12 @@ Supported [sensor list](http://iotdk.intel.com/docs/master/upm/modules.html) fro
You can also refer to the [Intel® IoT Developer Zone](https://software.intel.com/iot/hardware/sensors).
### IDE Support
### IDE Integration
The UPM sensor libraries are directly supported by the IDEs listed on the Intel®
Developer Zone Tools & IDEs page.
If you would like to create projects and run the UPM samples using an Intel recommended IDE,
please refer to the Intel Developer Zone IDE page.
<a href="https://software.intel.com/iot/tools"><img src="docs/icons/iss.png"/></a>
Intel® System Studio integration offers IoT specific features such as a sensor explorer,
library sync tools and the ability to easily import existing projects and samples that
use the UPM libraries. For further details please refer to the IoT User Guides on IDZ.
<a href="https://software.intel.com/iot/software/ide"><img src="docs/icons/allides.png"/></a>
### Installing UPM

14
cmake/modules/FindSphinx.cmake
View File

@ -17,16 +17,14 @@ find_package_handle_standard_args (Sphinx DEFAULT_MSG
SPHINX_API_EXECUTABLE
)
# Get Sphinx Version
# Get Sphinx version
if (SPHINX_EXECUTABLE)
execute_process(COMMAND ${SPHINX_EXECUTABLE} --version
OUTPUT_VARIABLE SPHINX_VERSION_STRING
OUTPUT_STRIP_TRAILING_WHITESPACE
ERROR_STRIP_TRAILING_WHITESPACE)
if (SPHINX_VERSION_STRING)
string(REPLACE "Sphinx (sphinx-build) " "" SPHINX_VERSION ${SPHINX_VERSION_STRING})
message (STATUS "Sphinx version is ${SPHINX_VERSION}")
endif ()
OUTPUT_VARIABLE SPHINX_VERSION)
if(SPHINX_VERSION)
string(REGEX MATCH "([0-9]\\.[0-9]\\.[0-9])" SPHINX_VERSION_STR ${SPHINX_VERSION})
message (STATUS "Sphinx version is ${SPHINX_VERSION_STR}")
endif()
endif ()
mark_as_advanced (SPHINX_EXECUTABLE)

6
docs/apichanges.md
View File

@ -4,12 +4,6 @@ API Changes {#apichanges}
Here's a list of other API changes made to the library that break source/binary
compatibility between releases:
# v1.5.0
* **VEML6070** This sensor class no longer needs an I2C address when
initialized, since they are fixed. Only the I2C bus number needs to
be provided.
# v1.3.0
* **The lsm303 driver has been renamed** There are a variety of

7
docs/building.md
View File

@ -34,12 +34,7 @@ make install
The last command will create the include/ and lib/ directories with a copy of
the headers and library objects respectively in your build location. Note that
doing an out-of-source build may cause issues when rebuilding later on. In many
cases you'll need elevated permissions to install:
~~~~~~~~~~~~~{.sh}
sudo make install
~~~~~~~~~~~~~
doing an out-of-source build may cause issues when rebuilding later on.
Our cmake configure has a number of options, *cmake-gui* or *ccmake* can show
you all the options. The interesting ones are detailed below:

14
docs/changelog.md
View File

@ -4,20 +4,6 @@ Changelog {#changelog}
Here's a list summarizing some of the key undergoing changes to our library
from earlier versions:
### v1.5.0
* Introduced a flexible JSON format for technical sensor specifications, notes
and classification. This is also used by our [new UPM website](http://upm.mraa.io)
* Revised all C++ sensor examples and switched to stack allocations where
possible along with other code and formatting clean-up
* Significantly improved docker workflow, CI integration, sanity and
consistency tests, static code scans and documentation generation
* Several improvements to a couple of existing sensor drivers and better
compatibility with subplatforms
* Added new std::vector to AbstractList<> typemap for Java bindings and
examples
* New sensors: lis2ds12, lsm6ds3h, lsm6dsl, lidarlitev3
### v1.3.0
* Finalized all required build system and JAVA binding changes to release the

38
docs/creating_java_bindings.md
View File

@ -12,25 +12,25 @@ Creating Java Bindings Guide
* [Implementing callbacks in Java](#implementing-callbacks-in-java)
## Overview
##Overview
The "Creating Java Bindings Guide" serves as a basic tutorial for using the SWIG software development tool to create 'glue code' required for Java to call into C/C++ code. It contains: guides for dealing with type conversions, exception handling, callbacks; recommendations on how to write/modify the native API to avoid issues on the Java side, and also workarounds for those issues that can't be avoided.
This guide was created with the [upm](https://github.com/intel-iot-devkit/upm/) and [mraa](https://github.com/intel-iot-devkit/mraa) libraries in mind, and uses examples taken from these sources, but its usage can be extended to any project of creating Java bindings for C/C++ libraries.
## Tools of trade
##Tools of trade
[SWIG General Documentation](http://www.swig.org/Doc3.0/SWIGDocumentation.html)
[SWIG Java-specific Documentation](http://www.swig.org/Doc3.0/Java.html)
## Recommendations for the native API
##Recommendations for the native API
### Pointers
###Pointers
As much as possible, avoid passing values/returning values through pointers given as as arguments to methods. As the Java language does not have pointers, SWIG provides a [workaround](http://www.swig.org/Doc3.0/Java.html#Java_tips_techniques) in the typemaps.i library.
#### Alternatives:
####Alternatives:
1. Functions that read data from a driver, return it through a pointer given as argument, and return a bool value, should be __replaced by__ functions that return the value directly and throw a std::runtime_error if a read error occurs. E.g.:
```c++
/*
@ -67,6 +67,7 @@ As much as possible, avoid passing values/returning values through pointers give
```
3. Functions that return N values through pointers, that do not make sense to grouped together (e.g. a general purpose function that returns both the light intensity and air pollution), should be __replaced by__ N functions (one for each value) that read only one specific value. E.g.:
```c++
/*
* Function returns the light intensity and air pollution
@ -81,6 +82,7 @@ As much as possible, avoid passing values/returning values through pointers give
```
4. Functions that return N values through pointers; values that do not make sense to be grouped together, but are time dependent, and make sense to be read at the same time. For example, a sensor that reads air humidity and temperature. A user may want to know the temperature value _temp_ read at the exact moment the humidity value _humid_ was read. These should be __replaced by__ N+1 functions: a _getData()_ function that reads all values at the same time and stores them in global variables; and N getter functions, one for each value. E.g.
```c++
/*
* Function returns the light intensity and air pollution
@ -101,8 +103,8 @@ __Notice:__
Sometimes, you may be required to write JNI code. Be aware of the difference between the C JNI calling syntax and the C++ JNI calling syntax.The C++ calling syntax will not compile as C and also vice versa. It is however possible to write JNI calls which will compile under both C and C++ and is covered in the [Typemaps for both C and C++ compilation](http://www.swig.org/Doc3.0/Java.html#Java_typemaps_for_c_and_cpp) section of the SWIG Documentation.
### Throwing Exceptions in Java
#### Language independent:
###Throwing Exceptions in Java
####Language independent:
The %exception directive allows you to define a general purpose exception handler. For example, you can specify the following:
```c++
@ -153,7 +155,7 @@ The upm_exception.i interface file is included in the upm.i file, therefor SWIG
* std::exception
#### Java specific:
####Java specific:
To throw a specific Java exception:
```c++
@ -194,12 +196,12 @@ In the upm library, the java_exceptions.i library file provides the functionalit
void function throws IOException ();
```
## Caveats & Challenges
##Caveats & Challenges
### Wrapping C arrays with Java arrays
###Wrapping C arrays with Java arrays
SWIG can wrap arrays in a more natural Java manner than the default by using the arrays_java.i library file. Just include this file into your SWIG interface file.
### Wrapping unbound C arrays with Java arrays if array is output
###Wrapping unbound C arrays with Java arrays if array is output
Functions that return arrays, return a pointer to that array. E.g.:
```c++
@ -227,7 +229,7 @@ __SWIG:__
}
```
### Wrapping unbound C arrays with Java arrays if array is input
###Wrapping unbound C arrays with Java arrays if array is input
In C, arrays are tipically passed as pointers, with an integer value representig the length of the array. In Java, the length of an array is always known, so the length argument is redundant. This example shows how to wrap the C array and also get rid the length argument. E.g.:
```c++
@ -250,7 +252,7 @@ __SWIG:__
!!!! There is a difference between TYPE *name and TYPE * name in typemaps!!!!!
### Implementing callbacks in Java
###Implementing callbacks in Java
Callbacks in the UPM Java library (as well as the MRAA Java library) make use of the _void mraa\_java\_isr\_callback(void\* data\)_ method from MRAA.
__Callbacks in the UPM Java library are implemented as follows (we use the a110x Hall Effect sensors as example):__
@ -311,7 +313,7 @@ class A110XISR implements Runnable {
}
}
```
#### Issues with java callbacks and workarounds
####Issues with java callbacks and workarounds
__SWIGJAVA not defined at compile time__
@ -323,16 +325,18 @@ Consider the following files:
The build process of a java module using SWIG is split into two steps:
1. Generating the intermediate files, from the SWIG interface file. This will produce the java class file (Example.java), the JNI file (exampleJNI.java) and wrapper file (example_wrap.cxx). The source file (example.cxx) is not needed in the first step.
```
swig -c++ -java example.i
swig -c++ -java example.i
```
2. Generating the shared library from the C++ sources and wrapper file
```
g++ -fPIC -c example.cxx example_wrap.cxx -I/usr/lib/jvm/java-1.8.0/include -I/usr/lib/jvm/java-1.8.0/include/linux
g++ -shared example_wrap.o sensor.o -o libexample.so
g++ -fPIC -c example.cxx example_wrap.cxx -I/usr/lib/jvm/java-1.8.0/include -I/usr/lib/jvm/java-1.8.0/include/linux
g++ -shared example_wrap.o sensor.o -o libexample.so
```
SWIGJAVA is always defined when SWIG parses the interface file, meaning it will be defined when it parses the header file (example.h) that is included in the interface file (example.i).
SWIG also adds the "#define SWIGJAVA" directive in the wrapper file (example_wrap.cxx).
However, in generating the shared library the SWIGJAVA symbol is only defined in the example_wrap.cxx file, because of the added "#define SWIGJAVA" directive. But we have also used the "#if defined(SWIGJAVA)" check in the source file (example.cxx), and thus need to define SWIGJAVA for it too. If we define the SWIGJAVA symbol as a compile flag, when compiling the source code to object code, the SWIGJAVA compile flag and #define SWIGJAVA" directive will clash and give a double definition warning (only a warning).

214
docs/documentation.md
View File

@ -10,132 +10,93 @@ sensors that you want to add to UPM:
- Have the specific sensor manufacturer/model & version that you used, if you
support multiple versions please list.
- Simple comments do not need full stops.
- Stick to <80 chars per line where possible.
- Stick to <80 chars per line even in comments.
- No text is allowed on the same line as the start or end of a comment /** */.
We currently document our libraries in the following way:
####The sensor block
* **Doxygen** is used for documenting the API and generating the categories on
the [UPM Libraries page](https://iotdk.intel.com/docs/master/upm/modules.html).
You can learn more about the Doxygen syntax [here](http://www.stack.nl/~dimitri/doxygen/manual/docblocks.html).
* **JSON** is used to provide sensor specifications, descriptions, supported
platforms, links and other details.
This is added just before the class declaration in your header(.h) file and has
mandatory fields. For single sensor libraries, this block will actually
follow immediately after the library block. If you have multiple physical
sensors, add this to every one.
Here's an example (disregard the "@verbatim" tags in your actual code):
When submitting a new driver, you will have to at least fill out the mandatory
fields as described below.
### The library JSON file
Let's use the BME280 class snippet from the bmp280.json file as an example:
```json
{
"Library": "bmp280",
"Description": "Bosch Atmospheric Sensor Library",
"Sensor Class":
{
"BME280":
{
"Name": "Digital Humidity, Pressure, and Temperature Sensor",
"Description": "The BME280 is as combined digital humidity, pressure and temperature sensor based on proven sensing principles. The sensor module is housed in an extremely compact metal-lid LGA package with a footprint of only 2.5 * 2.5 mm2 with a height of 0.93 mm. Its small dimensions and its low power consumption allow the implementation in battery driven devices such as handsets, GPS modules or watches. The BME280 is register and performance compatible to the Bosch Sensortec BMP280 digital pressure sensor",
"Aliases": ["bme280", "Grove - Barometer Sensor(BME280)"],
"Categories": ["pressure", "humidity", "temperature"],
"Connections": ["gpio", "i2c", "spi"],
"Project Type": ["prototyping", "industrial"],
"Manufacturers": ["adafruit", "seeed", "bosch"],
"Examples":
{
"Java": ["BMP280_Example.java"],
"Python": ["bmp280.py"],
"Node.js": ["bmp280.js"],
"C++": ["bmp280.cxx"],
"C": ["bmp280.c"]
},
"Specifications":
{
"Vdd": {"unit": "v", "low" : 1.7, "high": 3.6},
"Ioff" : {"unit": "mA", "low" : 0.0, "high": 0.0},
"Iavg": {"unit": "mA", "low" : 1, "high": 2},
"Pressure Range": {"unit": "hpA", "low" : 300, "high": 1100},
"Temperature Range": {"unit": "C", "low" : -40, "high": 85}
},
"Platforms":
{
"Intel Joule Module":
{
"Notes": ["Requires pull-up resistors with carrier board"]
}
},
"Urls" :
{
"Product Pages": ["https://www.adafruit.com/products/2652"],
"Datasheets": ["https://ae-bst.resource.bosch.com/media/_tech/media/datasheets/BST-BME280_DS001-11.pdf"],
"Schematics": ["https://learn.adafruit.com/assets/26693"]
}
}
}
}
```
@verbatim
/**
* @library <lib-name>
* @sensor <chip-id>
* @comname <component-name>
* @altname <alt-name>
* @altid <alt-id>
* @type <component-category>
* @man <component-manufacturer>
* @web <component-weblinks>
* @con <connection-type>
* @kit <component-kit>
*
* @brief Short class/sensor description
*
* Then add a longer
* description here.
*
* @image html <component-img.jpeg>
* @snippet <example-name.cxx> Interesting
*/
@endverbatim
```
#### Mandatory fields:
- `<lib-name>` When adding to an existing library this needs to match that
library's "@defgroup", otherwise this is a new library name, generally the
same as chip id. *Mandatory*
- `<chip-id>` Usually the chip number used by the sensor. When this is not
available or relevant, use a unique descriptor that makes sense. Must match
class name. *Mandatory*
- `<component-name>` Title Case descriptive name for your sensor, try to avoid
including the manufacturer's name here. Examples: Digital Pressure Sensor,
Serial MP3 Module, etc... *Mandatory*
- `<alt-name>` Alternative names that your sensor driver might have. This may
include manufacturer's name. *Optional*
- `<alt-id>` Alternative chip-ids that your sensor driver supports. *Optional*
- `<component-category>` Mention one or more categories the sensor fits in. Can
be 'other'. *Mandatory*
- `<component-manufacturer>` Sensor manufacturer. Can be 'generic'. *Mandatory*
- `<component-weblinks>` Links to vendors or data-sheets. *Optional*
- `<connection-type>` Specifies how does the sensor connect to the board
*Mandatory*
- `<component-kit>` Specifies if the sensor is part of a kit. *Optional*
For the library:
Existing groups that can be used for the manufacturer, connection, category and
kit tags are found in the *src/groups.md* file.
- `Library` The name of the library. This is appended to the upm prefix during
a build.
- `Description` A short description of the library and what it contains.
Optionally, a small representative image can be placed in the "docs/images"
subfolder and linked with the "@image" tag.
**Please do not use existing, copyrighted images with your sensors!**
For the sensor classes:
The example should have an 'Interesting' section which will be highlighted as
a code sample in doxygen. Everything in between such tags will show up in the
class documentation when "@snippet" is added at the end of a class docstring.
Tags use this format (in "example-name.cxx"):
- `Sensor Class` This is the object containing the sensor class(es) within the
library. Class objects need to match the name used in code.
- `Name` Title Case descriptive names for your sensor. Multiple values can be
used to capture the chip name, generic name, or specific name for a vendor.
Examples: Digital Pressure Sensor, Serial MP3 Module
- `Description` A more detailed explanation what the sensor does and how it
works.
- `Categories` Mention one or more categories the sensor fits in. Accepted
values are listed in the groups.md file.
- `Connections` Specifies how does the sensor connect to the board. Accepted
values are listed in the groups.md file.
- `Project Type` What time of projects is the sensor suited for. For example:
prototyping, industrial, commercial.
- `Manufacturers` List of sensor manufacturers or vendors. Can be 'generic',
other accepted values in groups.md.
- `Examples` Names of the example files provided with the library. At a minimum,
the `C++` example needs to be provided.
- `Urls` At least one link for `Product Pages` needs to be provided. Additional
links to `Datasheets` or `Schematics` can be added.
```
@verbatim
//! [Interesting]
#### Optional and customizable fields
...example code here...
- `Kits` Specifies if the sensor is part of a kit. Accepted values are listed
in the groups.md file.
- `Image` Name of the image file provided with the sensor class.
- `Specifications` Relevant sensor specifications as listed in the datasheet.
- `Platforms` Platform specific notes or known limitations and workarounds.
//! [Interesting]
@endverbatim
```
As mentioned, accepted values for some of the fields are listed under the
[groups.md](../src/groups.md) file. If needed, you can add new categories
for your sensor library following the existing format.
For more examples take a look at the existing headers in our github repository.
JSON files are automatically checked for correctness and required fields on
code submissions.
**Please do not use copyrighted images with your sensors!**
Images from Seeed, DFRobot, Sparkfun or Adafruit are permitted.
### Doxygen tags
#### The library doxygen block
####The library block
New libraries must have the "@brief", "@defgroup" and "@ingroup" tags in one
block. This usually follows the namespace and it is common to have one sensor
per library.
You should end up with something like this (disregard the "@verbatim" tags in
your actual code):
You should end up with something like this:
```
@verbatim
@ -150,43 +111,8 @@ your actual code):
@endverbatim
```
Use `<lib-name>` to name the library.
In "@defgroup" use the same `<lib-name>` used in the sensor block. Multiple
sensors can be added to the same library this way.
For "@ingroup" add the same values as in the sensor block for manufacturer,
category, connection type and kit. If you have multiple classes or sensors
per library, only use the "@ingroup" tags that are common for all of them.
Existing groups that can be used for the manufacturer, connection, category and
kit tags are found in the *src/groups.md* file.
#### The sensor doxygen block
This is added just before the class declaration in your header(.hpp) file and has
one mandatory field. For single sensor libraries, this block will actually follow
immediately after the library block. If you have multiple sensor classes, add
this to every one.
Here's an example:
```
@verbatim
/**
* @library <lib-name>
* @brief Short class/sensor description
*
* Then add a longer
* description here.
*/
@endverbatim
```
When adding to an existing library, `<lib-name>` needs to match that library's
"@defgroup".
For more examples take a look at the existing headers in our github repository.
Also, make sure to check our [sensortemplate](contributions.md#creating-a-new-sensor-library-using-the-sensortemplate)
as it can facilitate new sensor additions.
Existing header files might have additional fields under the sensor block. These
have been used in the past to generate sensor pages outside of doxygen, but they
are now deprecated and not required for new additions.

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6
docs/installing.md
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@ -48,11 +48,11 @@ To install:
```bash
sudo add-apt-repository ppa:mraa/mraa
sudo apt-get update
sudo apt-get install libupm-dev libupm-java python-upm python3-upm node-upm upm-examples
sudo apt-get install libupm-dev python-upm python3-upm upm-examples
```
Running UPM applications on Ubuntu systems requires elevated permissions
(e.g. run with `sudo`).
Note that the Ubuntu PPA only provides the C/C++ and Python packages. Node.js
developers will have to install MRAA and UPM using NPM instead.
### Node.js bindings only (NPM)

3
doxy/Doxyfile.in
View File

@ -860,8 +860,7 @@ EXCLUDE_SYMLINKS = NO
# bmi160 driver contains code provided by bosch. This source contains
# tags which are picked up by doxygen (namely \mainpage) and
# incorrectly get added to docs.
EXCLUDE_PATTERNS = bosch_* \
sensortemplate*
EXCLUDE_PATTERNS = bosch_*
# The EXCLUDE_SYMBOLS tag can be used to specify one or more symbol names
# (namespaces, classes, functions, etc.) that should be excluded from the

2
examples/CMakeLists.txt
View File

@ -99,7 +99,7 @@ function (add_example example_src)
# Add each dependency to the library target
foreach(_dep_target ${lib_target_names})
target_link_libraries(${this_target_name} ${_dep_target} ${CMAKE_THREAD_LIBS_INIT} utilities-c)
target_link_libraries(${this_target_name} ${_dep_target} ${CMAKE_THREAD_LIBS_INIT})
endforeach ()
endfunction (add_example example_src)

53
examples/c++/a110x-intr.cxx
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@ -22,58 +22,55 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stddef.h>
#include "a110x.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
// Our pulse counter
volatile unsigned int counter = 0;
// Our interrupt handler
void
hallISR(void* arg)
void hallISR(void *arg)
{
counter++;
counter++;
}
int
main()
int main ()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an A110X sensor on digital pin D2
upm::A110X hall(2);
//! [Interesting]
// Instantiate an A110X sensor on digital pin D2
upm::A110X* hall = new upm::A110X(2);
// This example uses a user-supplied interrupt handler to count
// pulses that occur when a magnetic field of the correct polarity
// is detected. This could be used to measure the rotations per
// minute (RPM) of a rotor for example.
// This example uses a user-supplied interrupt handler to count
// pulses that occur when a magnetic field of the correct polarity
// is detected. This could be used to measure the rotations per
// minute (RPM) of a rotor for example.
hall->installISR(hallISR, NULL);
hall.installISR(hallISR, NULL);
while (shouldRun)
{
cout << "Pulses detected: " << counter << endl;
while (shouldRun) {
cout << "Pulses detected: " << counter << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete hall;
return 0;
}

50
examples/c++/a110x.cxx
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@ -22,46 +22,46 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "a110x.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main ()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an A110X sensor on digital pin D2
upm::A110X hall(2);
//! [Interesting]
// Instantiate an A110X sensor on digital pin D2
upm::A110X* hall = new upm::A110X(2);
// check every second for the presence of a magnetic field (south
// polarity)
while (shouldRun)
{
bool val = hall->magnetDetected();
if (val)
cout << "Magnet (south polarity) detected." << endl;
else
cout << "No magnet detected." << endl;
// check every second for the presence of a magnetic field (south
// polarity)
while (shouldRun) {
bool val = hall.magnetDetected();
if (val)
cout << "Magnet (south polarity) detected." << endl;
else
cout << "No magnet detected." << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete hall;
return 0;
}

27
examples/c++/abp.cxx
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@ -21,42 +21,41 @@
* OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "abp.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main ()
{
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate an ABP sensor on i2c bus 0
upm::ABP abp(0, ABP_DEFAULT_ADDRESS);
upm::ABP* abp = new upm::ABP(0, ABP_DEFAULT_ADDRESS);
while (shouldRun) {
abp.update();
cout << "Retrieved pressure: " << abp.getPressure() << endl;
cout << "Retrieved Temperature: " << abp.getTemperature() << endl;
abp->update();
cout << "Retrieved pressure: " << abp->getPressure() << endl;
cout << "Retrieved Temperature: " << abp->getTemperature() << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
delete abp;
return 0;
}

49
examples/c++/ad8232.cxx
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@ -22,45 +22,44 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "ad8232.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a Ad8232 sensor on digital pins 10 (LO+), 11 (LO-)
// and an analog pin, 0 (OUTPUT)
upm::AD8232 ad8232(10, 11, 0);
// Output the raw numbers from the ADC, for plotting elsewhere.
// A return of 0 indicates a Lead Off (LO) condition.
// In theory, this data could be fed to software like Processing
// (https://www.processing.org/) to plot the data just like an
// EKG you would see in a hospital.
while (shouldRun) {
cout << ad8232.value() << endl;
upm_delay_us(1000);
//! [Interesting]
// Instantiate a Ad8232 sensor on digital pins 10 (LO+), 11 (LO-)
// and an analog pin, 0 (OUTPUT)
upm::AD8232 *ad8232 = new upm::AD8232(10, 11, 0);
// Output the raw numbers from the ADC, for plotting elsewhere.
// A return of 0 indicates a Lead Off (LO) condition.
// In theory, this data could be fed to software like Processing
// (https://www.processing.org/) to plot the data just like an
// EKG you would see in a hospital.
while (shouldRun)
{
cout << ad8232->value() << endl;
usleep(1000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete ad8232;
return 0;
}

67
examples/c++/adafruitms1438-stepper.cxx
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@ -22,56 +22,61 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <signal.h>
#include <iostream>
#include "adafruitms1438.hpp"
#include "upm_utilities.h"
using namespace std;
using namespace upm;
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
//! [Interesting]
// Instantiate an Adafruit MS 1438 on I2C bus 0
//! [Interesting]
// Instantiate an Adafruit MS 1438 on I2C bus 0
upm::AdafruitMS1438 ms(ADAFRUITMS1438_I2C_BUS, ADAFRUITMS1438_DEFAULT_I2C_ADDR);
upm::AdafruitMS1438 *ms =
new upm::AdafruitMS1438(ADAFRUITMS1438_I2C_BUS,
ADAFRUITMS1438_DEFAULT_I2C_ADDR);
// Setup for use with a stepper motor connected to the M1 & M2 ports
// Setup for use with a stepper motor connected to the M1 & M2 ports
// set a PWM period of 50Hz
// set a PWM period of 50Hz
// disable first, to be safe
ms.disableStepper(AdafruitMS1438::STEPMOTOR_M12);
// disable first, to be safe
ms->disableStepper(AdafruitMS1438::STEPMOTOR_M12);
// configure for a NEMA-17, 200 steps per revolution
ms.stepConfig(AdafruitMS1438::STEPMOTOR_M12, 200);
// configure for a NEMA-17, 200 steps per revolution
ms->stepConfig(AdafruitMS1438::STEPMOTOR_M12, 200);
// set speed at 10 RPM's
ms.setStepperSpeed(AdafruitMS1438::STEPMOTOR_M12, 10);
ms.setStepperDirection(AdafruitMS1438::STEPMOTOR_M12, AdafruitMS1438::DIR_CW);
// set speed at 10 RPM's
ms->setStepperSpeed(AdafruitMS1438::STEPMOTOR_M12, 10);
ms->setStepperDirection(AdafruitMS1438::STEPMOTOR_M12,
AdafruitMS1438::DIR_CW);
// enable
cout << "Enabling..." << endl;
ms.enableStepper(AdafruitMS1438::STEPMOTOR_M12);
// enable
cout << "Enabling..." << endl;
ms->enableStepper(AdafruitMS1438::STEPMOTOR_M12);
cout << "Rotating 1 full revolution at 10 RPM speed." << endl;
ms.stepperSteps(AdafruitMS1438::STEPMOTOR_M12, 200);
cout << "Rotating 1 full revolution at 10 RPM speed." << endl;
ms->stepperSteps(AdafruitMS1438::STEPMOTOR_M12, 200);
cout << "Sleeping for 2 seconds..." << endl;
upm_delay(2);
cout << "Rotating 1/2 revolution in opposite direction at 10 RPM speed." << endl;
cout << "Sleeping for 2 seconds..." << endl;
sleep(2);
cout << "Rotating 1/2 revolution in opposite direction at 10 RPM speed."
<< endl;
ms.setStepperDirection(AdafruitMS1438::STEPMOTOR_M12, AdafruitMS1438::DIR_CCW);
ms.stepperSteps(AdafruitMS1438::STEPMOTOR_M12, 100);
ms->setStepperDirection(AdafruitMS1438::STEPMOTOR_M12,
AdafruitMS1438::DIR_CCW);
ms->stepperSteps(AdafruitMS1438::STEPMOTOR_M12, 100);
cout << "Disabling..." << endl;
ms.disableStepper(AdafruitMS1438::STEPMOTOR_M12);
cout << "Disabling..." << endl;
ms->disableStepper(AdafruitMS1438::STEPMOTOR_M12);
cout << "Exiting" << endl;
cout << "Exiting" << endl;
//! [Interesting]
//! [Interesting]
return 0;
delete ms;
return 0;
}

55
examples/c++/adafruitms1438.cxx
View File

@ -22,51 +22,54 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <signal.h>
#include <iostream>
#include "adafruitms1438.hpp"
#include "upm_utilities.h"
using namespace std;
using namespace upm;
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
//! [Interesting]
// Instantiate an Adafruit MS 1438 on I2C bus 0
//! [Interesting]
// Instantiate an Adafruit MS 1438 on I2C bus 0
upm::AdafruitMS1438 ms(ADAFRUITMS1438_I2C_BUS, ADAFRUITMS1438_DEFAULT_I2C_ADDR);
upm::AdafruitMS1438 *ms =
new upm::AdafruitMS1438(ADAFRUITMS1438_I2C_BUS,
ADAFRUITMS1438_DEFAULT_I2C_ADDR);
// Setup for use with a DC motor connected to the M3 port
// Setup for use with a DC motor connected to the M3 port
// set a PWM period of 50Hz
ms.setPWMPeriod(50);
// set a PWM period of 50Hz
ms->setPWMPeriod(50);
// disable first, to be safe
ms.disableMotor(AdafruitMS1438::MOTOR_M3);
// disable first, to be safe
ms->disableMotor(AdafruitMS1438::MOTOR_M3);
// set speed at 50%
ms.setMotorSpeed(AdafruitMS1438::MOTOR_M3, 50);
ms.setMotorDirection(AdafruitMS1438::MOTOR_M3, AdafruitMS1438::DIR_CW);
// set speed at 50%
ms->setMotorSpeed(AdafruitMS1438::MOTOR_M3, 50);
ms->setMotorDirection(AdafruitMS1438::MOTOR_M3, AdafruitMS1438::DIR_CW);
cout << "Spin M3 at half speed for 3 seconds, then reverse for 3 seconds." << endl;
cout << "Spin M3 at half speed for 3 seconds, then reverse for 3 seconds."
<< endl;
ms.enableMotor(AdafruitMS1438::MOTOR_M3);
ms->enableMotor(AdafruitMS1438::MOTOR_M3);
upm_delay(3);
sleep(3);
cout << "Reversing M3" << endl;
ms.setMotorDirection(AdafruitMS1438::MOTOR_M3, AdafruitMS1438::DIR_CCW);
cout << "Reversing M3" << endl;
ms->setMotorDirection(AdafruitMS1438::MOTOR_M3, AdafruitMS1438::DIR_CCW);
upm_delay(3);
sleep(3);
cout << "Stopping M3" << endl;
ms.disableMotor(AdafruitMS1438::MOTOR_M3);
cout << "Stopping M3" << endl;
ms->disableMotor(AdafruitMS1438::MOTOR_M3);
cout << "Exiting" << endl;
cout << "Exiting" << endl;
//! [Interesting]
//! [Interesting]
return 0;
delete ms;
return 0;
}

67
examples/c++/adafruitss.cxx
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@ -22,57 +22,56 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
/**
* Description
* Demo program for Adafruit 16 channel servo shield/controller
* Physical setup for tests is a single servo attached to one channel.
* Note - when 3 or more GWS servos attached results unpredictable.
* Adafruit do recommend a Cap be installed on the board which should alleviate
* the issue.
* Adafruit do recommend a Cap be installed on the board which should alleviate the issue.
* I (and Adafruit) are unable to give any Capacitor sizing data.
*/
#include <iostream>
#include "adafruitss.hpp"
#include "upm_utilities.h"
#include <unistd.h>
using namespace std;
int
main()
{
int n;
int main() {
//! [Interesting]
upm::adafruitss servos(6, 0x40);
int n;
for (;;) {
cout << "Setting all to 0" << endl;
for (n = 0; n < 16; n++)
servos.servo(n, 1, 0); // GWS Mini Servo = Type 1.
upm_delay_us(1000000); // Wait 1 second
//! [Interesting]
upm::adafruitss* servos = new upm::adafruitss(6,0x40);
cout << "Setting all to 45" << endl;
for (n = 0; n < 16; n++)
servos.servo(n, 1, 45);
upm_delay_us(1000000); // Wait 1 second
for (;;)
{
cout << "Setting all to 0" << endl;
for (n = 0; n < 16; n++)
servos->servo(n, 1, 0); // GWS Mini Servo = Type 1.
usleep(1000000); // Wait 1 second
cout << "Setting all to 90" << endl;
for (n = 0; n < 16; n++)
servos.servo(n, 1, 90);
upm_delay_us(1000000); // Wait 1 second
cout << "Setting all to 45" << endl;
for (n = 0; n < 16; n++)
servos->servo(n, 1, 45);
usleep(1000000); // Wait 1 second
cout << "Setting all to 135" << endl;
for (n = 0; n < 16; n++)
servos.servo(n, 1, 135);
upm_delay_us(1000000); // Wait 1 second
cout << "Setting all to 90" << endl;
for (n = 0; n < 16; n++)
servos->servo(n, 1, 90);
usleep(1000000); // Wait 1 second
cout << "Setting all to 180" << endl;
for (n = 0; n < 16; n++)
servos.servo(n, 1, 160);
upm_delay_us(2000000); // Wait 1 second
}
//! [Interesting]
return 0;
cout << "Setting all to 135" << endl;
for (n = 0; n < 16; n++)
servos->servo(n, 1, 135);
usleep(1000000); // Wait 1 second
cout << "Setting all to 180" << endl;
for (n = 0; n < 16; n++)
servos->servo(n, 1, 160);
usleep(2000000); // Wait 1 second
}
//! [Interesting]
return 0;
}

47
examples/c++/adc121c021.cxx
View File

@ -22,44 +22,45 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <unistd.h>
#include <signal.h>
#include <iostream>
#include "adc121c021.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an ADC121C021 on I2C bus 0
//! [Interesting]
// Instantiate an ADC121C021 on I2C bus 0
upm::ADC121C021 adc(ADC121C021_I2C_BUS, ADC121C021_DEFAULT_I2C_ADDR);
upm::ADC121C021 *adc = new upm::ADC121C021(ADC121C021_I2C_BUS,
ADC121C021_DEFAULT_I2C_ADDR);
// An analog sensor, such as a Grove light sensor,
// must be attached to the adc
// Prints the value and corresponding voltage every 50 milliseconds
while (shouldRun) {
uint16_t val = adc.value();
cout << "ADC value: " << val << " Volts = " << adc.valueToVolts(val) << endl;
upm_delay_us(50000);
// An analog sensor, such as a Grove light sensor,
// must be attached to the adc
// Prints the value and corresponding voltage every 50 milliseconds
while (shouldRun)
{
uint16_t val = adc->value();
cout << "ADC value: " << val << " Volts = "
<< adc->valueToVolts(val) << endl;
usleep(50000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete adc;
return 0;
}

39
examples/c++/adis16448.cxx
View File

@ -12,12 +12,9 @@
// This example code runs on an Intel Edison and uses mraa to acquire data
// from an ADIS16448. This data is then scaled and printed onto the terminal.
//
// This software has been tested to connect to an ADIS16448 through a level
// shifter
// such as the TI TXB0104. The SPI lines (DIN, DOUT, SCLK, /CS) are all wired
// through
// the level shifter and the ADIS16448 is also being powered by the Intel
// Edison.
// This software has been tested to connect to an ADIS16448 through a level shifter
// such as the TI TXB0104. The SPI lines (DIN, DOUT, SCLK, /CS) are all wired through
// the level shifter and the ADIS16448 is also being powered by the Intel Edison.
//
// Permission is hereby granted, free of charge, to any person obtaining
// a copy of this software and associated documentation files (the
@ -39,29 +36,31 @@
// WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
//
//////////////////////////////////////////////////////////////////////////////////////
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "adis16448.hpp"
#include "upm_utilities.h"
int
main(int argc, char** argv)
main(int argc, char **argv)
{
while (true) {
//! [Interesting]
upm::ADIS16448 imu(0, 3); // upm::ADIS16448(SPI,RST)
while(true)
{
//! [Interesting]
upm::ADIS16448* imu = new upm::ADIS16448(0,3); //upm::ADIS16448(SPI,RST)
// Read the specified register, scale it, and display it on the screen
std::cout << "XGYRO_OUT:" << imu.gyroScale(imu.regRead(XGYRO_OUT)) << std::endl;
std::cout << "YGYRO_OUT:" << imu.gyroScale(imu.regRead(YGYRO_OUT)) << std::endl;
std::cout << "ZGYRO_OUT:" << imu.gyroScale(imu.regRead(ZGYRO_OUT)) << std::endl;
//Read the specified register, scale it, and display it on the screen
std::cout << "XGYRO_OUT:" << imu->gyroScale(imu->regRead(XGYRO_OUT)) << std::endl;
std::cout << "YGYRO_OUT:" << imu->gyroScale(imu->regRead(YGYRO_OUT)) << std::endl;
std::cout << "ZGYRO_OUT:" << imu->gyroScale(imu->regRead(ZGYRO_OUT)) << std::endl;
std::cout << " " << std::endl;
std::cout << "XACCL_OUT:" << imu.accelScale(imu.regRead(XACCL_OUT)) << std::endl;
std::cout << "YACCL_OUT:" << imu.accelScale(imu.regRead(YACCL_OUT)) << std::endl;
std::cout << "ZACCL_OUT:" << imu.accelScale(imu.regRead(ZACCL_OUT)) << std::endl;
std::cout << "XACCL_OUT:" << imu->accelScale(imu->regRead(XACCL_OUT)) << std::endl;
std::cout << "YACCL_OUT:" << imu->accelScale(imu->regRead(YACCL_OUT)) << std::endl;
std::cout << "ZACCL_OUT:" << imu->accelScale(imu->regRead(ZACCL_OUT)) << std::endl;
std::cout << " " << std::endl;
//! [Interesting]
upm_delay(1);
//! [Interesting]
sleep(1);
}
return (0);
}

77
examples/c++/ads1x15-adc-sensor.cxx
View File

@ -22,50 +22,59 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <exception>
#include <unistd.h>
#include <iostream>
#include <stddef.h>
#include "ads1015.hpp"
#include "iADC.hpp"
#include "mraa/gpio.hpp"
#include "upm_utilities.h"
#define EDISON_I2C_BUS 1
#define FT4222_I2C_BUS 0
#define EDISON_GPIO_SI7005_CS 20
int
main()
//! [Interesting]
// Simple example of using IADC to determine
// which sensor is present and return its name.
// IADC is then used to get readings from sensor
upm::IADC* getADC()
{
/* Create an instance of the ADS1015 sensor */
upm::ADS1015 sensor(EDISON_I2C_BUS);
mraa::Gpio gpio(EDISON_GPIO_SI7005_CS);
gpio.dir(mraa::DIR_OUT_HIGH);
upm::IADC* adc = NULL;
try {
adc = new upm::ADS1015(EDISON_I2C_BUS);
mraa::Gpio gpio(EDISON_GPIO_SI7005_CS);
gpio.dir(mraa::DIR_OUT_HIGH);
return adc;
} catch (std::exception& e) {
std::cerr << "ADS1015: " << e.what() << std::endl;
}
return adc;
}
/* Show usage from the IADC interface */
upm::IADC* adc = static_cast<upm::IADC*>(&sensor);
if (adc == NULL) {
std::cout << "ADC not detected" << std::endl;
return 1;
}
std::cout << "ADC " << adc->getModuleName() << " detected. ";
std::cout << adc->getNumInputs() << " inputs available" << std::endl;
while (true) {
for (unsigned int i = 0; i < adc->getNumInputs(); ++i) {
std::cout << "Input " << i;
try {
float voltage = adc->getVoltage(i);
std::cout << ": Voltage = " << voltage << "V" << std::endl;
} catch (std::exception& e) {
std::cerr << e.what() << std::endl;
}
}
upm_delay(1);
}
return 0;
int main ()
{
upm::IADC* adc = getADC();
if (adc == NULL) {
std::cout << "ADC not detected" << std::endl;
return 1;
}
std::cout << "ADC " << adc->getModuleName() << " detected. " ;
std::cout << adc->getNumInputs() << " inputs available" << std::endl;
while (true) {
for (unsigned int i=0; i<adc->getNumInputs(); ++i) {
std::cout << "Input " << i;
try {
float voltage = adc->getVoltage(i);
std::cout << ": Voltage = " << voltage << "V" << std::endl;
} catch (std::exception& e) {
std::cerr << e.what() << std::endl;
}
}
sleep(1);
}
delete adc;
return 0;
}
//! [Interesting]

38
examples/c++/ads1x15-ads1015.cxx
View File

@ -29,13 +29,11 @@
*/
#include <fstream>
#include <iostream>
#include <string>
#include <thread>
#include <unistd.h>
#include "ads1015.hpp"
#include "ads1x15.hpp"
#include "upm_utilities.h"
using namespace std;
using namespace upm;
@ -43,41 +41,39 @@ using namespace upm;
bool running = true; // Controls main read/write loop
// Thread function
void
stop()
void stop()
{
upm_delay(10);
sleep(10);
running = false;
}
int
main()
int main()
{
//! [Interesting]
long id = 0; // Sample number
long id = 0; // Sample number
string fileName = "./ads1015.data"; // Output filename
ofstream f;
// Initialize and configure the ADS1015
ADS1015 ads1015(0, 0x48);
ADS1015 *ads1015 = new upm::ADS1015(0, 0x48);
// Put the ADC into differential mode for pins A0 and A1
ads1015.getSample(ADS1X15::DIFF_0_1);
ads1015->getSample(ADS1X15::DIFF_0_1);
// Set the gain based on expected VIN range to -/+ 2.048 V
// Can be adjusted based on application to as low as -/+ 0.256 V, see API
// documentation for details
ads1015.setGain(ADS1X15::GAIN_TWO);
ads1015->setGain(ADS1X15::GAIN_TWO);
// Set the sample rate to 3300 samples per second (max) and turn on continuous
// sampling
ads1015.setSPS(ADS1015::SPS_3300);
ads1015.setContinuous(true);
ads1015->setSPS(ADS1015::SPS_3300);
ads1015->setContinuous(true);
// Enable exceptions from the output stream
f.exceptions(ofstream::failbit | ofstream::badbit);
// Open the file
try {
try{
f.open(fileName);
// Output formatting
@ -85,18 +81,19 @@ main()
f.precision(7);
// Start the thread that will stop logging after 10 seconds
thread timer(stop);
thread timer (stop);
// Read sensor data and write it to the output file every ms
while (running) {
f << id++ << " " << ads1015.getLastSample() << endl;
upm_delay_us(1000);
while(running){
f << id++ << " " << ads1015->getLastSample() << endl;
usleep(1000);
}
// Clean-up and exit
timer.join();
f.close();
} catch (ios_base::failure& e) {
delete ads1015;
} catch (ios_base::failure &e) {
cout << "Failed to write to file: " << e.what() << endl;
return 1;
}
@ -104,3 +101,4 @@ main()
//! [Interesting]
return 0;
}

38
examples/c++/ads1x15-ads1115.cxx
View File

@ -28,13 +28,11 @@
*/
#include <fstream>
#include <iostream>
#include <string>
#include <thread>
#include <unistd.h>
#include "ads1115.hpp"
#include "ads1x15.hpp"
#include "upm_utilities.h"
using namespace std;
using namespace upm;
@ -42,18 +40,16 @@ using namespace upm;
bool running = true; // Controls main read/write loop
// Thread function
void
stop()
void stop()
{
upm_delay(10);
sleep(10);
running = false;
}
int
main()
int main()
{
//! [Interesting]
long id = 0; // Sample number
long id = 0; // Sample number
string fileName = "./ads1115.data"; // Output filename
ofstream f;
@ -61,26 +57,26 @@ main()
// There are two ADS1115 chips on the DFRobot Joule Shield on the same I2C bus
// - 0x48 gives access to pins A0 - A3
// - 0x49 gives access to pins A4 - A7
ADS1115 ads1115(0, 0x48);
ADS1115 *ads1115 = new upm::ADS1115(0, 0x48);
// Put the ADC into differential mode for pins A0 and A1,
// the SM-24 Geophone is connected to these pins
ads1115.getSample(ADS1X15::DIFF_0_1);
ads1115->getSample(ADS1X15::DIFF_0_1);
// Set the gain based on expected VIN range to -/+ 2.048 V
// Can be adjusted based on application to as low as -/+ 0.256 V, see API
// documentation for details
ads1115.setGain(ADS1X15::GAIN_TWO);
ads1115->setGain(ADS1X15::GAIN_TWO);
// Set the sample rate to 860 samples per second (max) and turn on continuous
// sampling
ads1115.setSPS(ADS1115::SPS_860);
ads1115.setContinuous(true);
ads1115->setSPS(ADS1115::SPS_860);
ads1115->setContinuous(true);
// Enable exceptions from the output stream
f.exceptions(ofstream::failbit | ofstream::badbit);
// Open the file
try {
try{
f.open(fileName);
// Output formatting
@ -88,18 +84,19 @@ main()
f.precision(7);
// Start the thread that will stop logging after 10 seconds
thread timer(stop);
thread timer (stop);
// Read sensor data and write it to the output file every ms
while (running) {
f << id++ << " " << ads1115.getLastSample() << endl;
upm_delay_us(1000);
while(running){
f << id++ << " " << ads1115->getLastSample() << endl;
usleep(1000);
}
// Clean-up and exit
timer.join();
f.close();
} catch (ios_base::failure& e) {
delete ads1115;
} catch (ios_base::failure &e) {
cout << "Failed to write to file: " << e.what() << endl;
return 1;
}
@ -107,3 +104,4 @@ main()
//! [Interesting]
return 0;
}

555
examples/c++/ads1x15.cxx
View File

@ -22,306 +22,301 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include "mraa.hpp"
#include <iostream>
#include <unistd.h>
#include "ads1015.hpp"
#include "ads1115.hpp"
#include "ads1x15.hpp"
int
main()
int main()
{
using namespace std;
using namespace upm;
int command;
//! [Interesting]
// Select the device you are testing here and adjust case 6 for the correct
// sample rates.
upm::ADS1115 ads(1, 0x49);
float inputVoltage;
int ans;
do {
cout << endl;
cout << "1 - get Conversion \t";
cout << "2 - get last conversion" << endl;
cout << "3 - get Gain \t\t";
cout << "4 - set Gain" << endl;
;
cout << "5 - get Data Rate \t";
cout << "6 - set Data Rate" << endl;
cout << "7 - Set Upper Threshold \t";
cout << "8 - Set Lower Threshold \t";
cout << "9 - Display Thresholds \t";
cout << "10 - Set Default Thresholds \t";
cout << "11 - Set conversion ready" << endl;
cout << "12 - get Comp Que \t";
cout << "13 - set Comp Que" << endl;
cout << "14 - get Comp Pol \t";
cout << "15 - set Comp Pol" << endl;
cout << "16 - get Comp mode \t";
cout << "17 - set Comp mode " << endl;
cout << "18 - get Comp Latch\t";
cout << "19 - set Comp Latch " << endl;
cout << "20 - get Continuous \t";
cout << "21 - set Continuous \t" << endl;
cout << "-1 - exit" << endl;
cout << "Enter a command: ";
cin >> command;
using namespace std;
using namespace upm;
int command;
//! [Interesting]
//Select the device you are testing here and adjust case 6 for the correct sample rates.
//upm::ADS1015 *ads = new upm::ADS1015(1);
upm::ADS1115 *ads = new upm::ADS1115(1, 0x49);
float inputVoltage;
int ans;
switch (command) {
case 2:
cout << ads.getLastSample() << endl;
break;
case 3:
cout << std::hex << ads.getGain() << endl;
break;
case 5:
cout << std::hex << ads.getSPS() << endl;
break;
case 4:
int gain;
ADS1015::ADSGAIN set_gain;
cout << "select one of the following:" << endl;
cout << "1 -> gain 2/3 \t 2 -> gain1 \t 3 -> gain 2" << endl;
cout << "4 -> gain 4 \t 5 -> gain 8 \t 6 -> gain 15" << endl;
cin >> gain;
switch (gain) {
case 1:
set_gain = ADS1X15::GAIN_TWOTHIRDS;
break;
case 2:
set_gain = ADS1X15::GAIN_ONE;
break;
case 3:
set_gain = ADS1X15::GAIN_TWO;
break;
case 4:
set_gain = ADS1X15::GAIN_FOUR;
break;
case 5:
set_gain = ADS1X15::GAIN_EIGHT;
break;
case 6:
set_gain = ADS1X15::GAIN_SIXTEEN;
break;
default:
set_gain = ADS1X15::GAIN_ONE;
}
ads.setGain(set_gain);
break;
case 6:
int rate;
/*ADS1015::ADSDATARATE set_rate;
cout << "select one of the following:" << endl;
cout << "1 -> SPS_120 \t 2 -> SPS_250 \t 3 -> SPS_490 \t 4 -> SPS_920" <<
endl;
cout << "5 -> SPS_1600 \t 6 -> SPS_2400 \t 7 -> SPS_3300" << endl;
cin >> rate;
switch(rate){
case 1:
set_rate = ADS1015::SPS_128;
break;
do
{
cout << endl;
cout << "1 - get Conversion \t" ;
cout << "2 - get last conversion" << endl;
cout << "3 - get Gain \t\t";
cout << "4 - set Gain" << endl;;
cout << "5 - get Data Rate \t";
cout << "6 - set Data Rate" << endl;
cout << "7 - Set Upper Threshold \t" ;
cout << "8 - Set Lower Threshold \t";
cout << "9 - Display Thresholds \t";
cout << "10 - Set Default Thresholds \t";
cout << "11 - Set conversion ready" << endl;
cout << "12 - get Comp Que \t" ;
cout << "13 - set Comp Que" << endl;
cout << "14 - get Comp Pol \t";
cout << "15 - set Comp Pol" << endl;
cout << "16 - get Comp mode \t";
cout << "17 - set Comp mode " << endl;
cout << "18 - get Comp Latch\t";
cout << "19 - set Comp Latch " << endl;
cout << "20 - get Continuous \t";
cout << "21 - set Continuous \t" << endl;
cout << "-1 - exit" << endl;
cout << "Enter a command: ";
cin >> command;
switch(command)
{
case 2:
set_rate = ADS1015::SPS_250;
cout << ads->getLastSample() << endl;
break;
case 3:
set_rate = ADS1015::SPS_490;
break;
case 4:
set_rate = ADS1015::SPS_920;
cout << std::hex << ads->getGain() << endl;
break;
case 5:
set_rate = ADS1015::SPS_1600;
cout << std::hex << ads->getSPS() << endl;
break;
case 4:
int gain;
ADS1015::ADSGAIN set_gain;
cout << "select one of the following:" << endl;
cout << "1 -> gain 2/3 \t 2 -> gain1 \t 3 -> gain 2" << endl;
cout << "4 -> gain 4 \t 5 -> gain 8 \t 6 -> gain 15" << endl;
cin >> gain;
switch(gain){
case 1:
set_gain = ADS1X15::GAIN_TWOTHIRDS;
break;
case 2:
set_gain = ADS1X15::GAIN_ONE;
break;
case 3:
set_gain = ADS1X15::GAIN_TWO;
break;
case 4:
set_gain = ADS1X15::GAIN_FOUR;
break;
case 5:
set_gain = ADS1X15::GAIN_EIGHT;
break;
case 6:
set_gain = ADS1X15::GAIN_SIXTEEN;
break;
default:
set_gain = ADS1X15::GAIN_ONE;
}
ads->setGain(set_gain);
break;
case 6:
set_rate = ADS1015::SPS_2400;
int rate;
/*ADS1015::ADSDATARATE set_rate;
cout << "select one of the following:" << endl;
cout << "1 -> SPS_120 \t 2 -> SPS_250 \t 3 -> SPS_490 \t 4 -> SPS_920" << endl;
cout << "5 -> SPS_1600 \t 6 -> SPS_2400 \t 7 -> SPS_3300" << endl;
cin >> rate;
switch(rate){
case 1:
set_rate = ADS1015::SPS_128;
break;
case 2:
set_rate = ADS1015::SPS_250;
break;
case 3:
set_rate = ADS1015::SPS_490;
break;
case 4:
set_rate = ADS1015::SPS_920;
break;
case 5:
set_rate = ADS1015::SPS_1600;
break;
case 6:
set_rate = ADS1015::SPS_2400;
break;
case 7:
set_rate = ADS1015::SPS_3300;
break;
default:
set_rate = ADS1015::SPS_1600;
} */
ADS1115::ADSDATARATE set_rate;
cout << "select one of the following:" << endl;
cout << "1 -> SPS_8 \t 2 -> SPS_16 \t 3 -> SPS_32 \t 4 -> SPS_64" << endl;
cout << "5 -> SPS_128 \t 6 -> SPS_250 \t 7 -> SPS_475 \t 8-> SPS_860" << endl;
cin >> rate;
switch(rate){
case 1:
set_rate = ADS1115::SPS_8;
break;
case 2:
set_rate = ADS1115::SPS_16;
break;
case 3:
set_rate = ADS1115::SPS_32;
break;
case 4:
set_rate = ADS1115::SPS_64;
break;
case 5:
set_rate = ADS1115::SPS_128;
break;
case 6:
set_rate = ADS1115::SPS_250;
break;
case 7:
set_rate = ADS1115::SPS_475;
break;
case 8:
set_rate = ADS1115::SPS_860;
break;
default:
set_rate = ADS1115::SPS_128;
}
ads->setSPS(set_rate);
break;
case 1:
int mode;
ADS1X15::ADSMUXMODE set_mode;
cout << "select one of the following:" << endl;
cout << "1 -> MUX_0_1 \t 2 -> MUX_0_3 \t 3 -> MUX_1_3 \t 4 -> MUX_2_3" << endl;
cout << "5 -> SINGLE_0 \t 6 -> SINGLE_1 \t 7 -> SINGLE_2 \t 8 -> SINGLE_3" << endl;
cin >> mode;
switch(mode){
case 1:
set_mode = ADS1X15::DIFF_0_1;
break;
case 2:
set_mode = ADS1X15::DIFF_0_3;
break;
case 3:
set_mode = ADS1X15::DIFF_1_3;
break;
case 4:
set_mode = ADS1X15::DIFF_2_3;
break;
case 5:
set_mode = ADS1X15::SINGLE_0;
break;
case 6:
set_mode = ADS1X15::SINGLE_1;
break;
case 7:
set_mode = ADS1X15::SINGLE_2;
break;
case 8:
set_mode = ADS1X15::SINGLE_3;
break;
default:
set_mode = ADS1X15::DIFF_0_1;
break;
}
cout << ads->getSample(set_mode) << endl;
break;
case 7:
set_rate = ADS1015::SPS_3300;
cout << " enter a float value: " ;
cin >> inputVoltage;
ads->setThresh(ADS1115::THRESH_HIGH, inputVoltage);
break;
case 8:
cout << " enter a float value: " ;
cin >> inputVoltage;
ads->setThresh(ADS1115::THRESH_LOW, inputVoltage);
break;
case 9:
cout << "Upper " << ads->getThresh(ADS1X15::THRESH_HIGH) << endl;
cout << "Lower " << ads->getThresh(ADS1X15::THRESH_LOW) << endl;
break;
case 10:
ads->setThresh(ADS1115::THRESH_DEFAULT);
break;
case 11:
ads->setThresh(ADS1015::CONVERSION_RDY);
break;
case 12:
cout << ads->getCompQue() << endl;
break;
case 13:
int que;
cout << "select one of the following:" << endl;
cout << "1 -> CQUE_1CONV \t 2 -> CQUE_2CONV \t 3 -> CQUE_3CONV \t 4 -> CQUE_NONE" << endl;
cin >> que;
switch(que){
case 1:
ads->setCompQue(ADS1X15::CQUE_1CONV);
break;
case 2:
ads->setCompQue(ADS1X15::CQUE_2CONV);
break;
case 3:
ads->setCompQue(ADS1X15::CQUE_4CONV);
break;
case 4:
default:
ads->setCompQue(ADS1X15::CQUE_NONE);
break;
}
break;
case 14:
cout << ads->getCompPol() << endl;
break;
case 15:
cout << "select one of the following:" << endl;
cout << "1 -> active high \t 2 -> active low" << endl;
cin >> ans;
if(ans == 1) ads->setCompPol(true);
else ads->setCompPol(false);
break;
case 16:
cout << ads->getCompMode() << endl;
break;
case 17:
cout << "select one of the following:" << endl;
cout << "1 -> Window \t 2 -> Traditional (default)" << endl;
cin >> ans;
if(ans == 1) ads->setCompMode(true);
else ads->setCompMode();
break;
case 18:
cout << ads->getCompLatch() << endl;
break;
case 19:
cout << "select one of the following:" << endl;
cout << "1 -> Latching \t 2 -> Non-latching (default)" << endl;
cin >> ans;
if(ans == 1) ads->setCompLatch(true);
else ads->setCompLatch();
break;
case 20:
cout << ads->getContinuous() << endl;
break;
case 21:
cout << "select one of the following:" << endl;
cout << "1 -> Power Down (default) \t 2 -> Continuous" << endl;
cin >> ans;
if(ans == 1) ads->setContinuous(true);
else ads->setContinuous();
break;
case -1:
break;
default:
set_rate = ADS1015::SPS_1600;
} */
ADS1115::ADSDATARATE set_rate;
cout << "select one of the following:" << endl;
cout << "1 -> SPS_8 \t 2 -> SPS_16 \t 3 -> SPS_32 \t 4 -> SPS_64" << endl;
cout << "5 -> SPS_128 \t 6 -> SPS_250 \t 7 -> SPS_475 \t 8-> SPS_860" << endl;
cin >> rate;
switch (rate) {
case 1:
set_rate = ADS1115::SPS_8;
break;
case 2:
set_rate = ADS1115::SPS_16;
break;
case 3:
set_rate = ADS1115::SPS_32;
break;
case 4:
set_rate = ADS1115::SPS_64;
break;
case 5:
set_rate = ADS1115::SPS_128;
break;
case 6:
set_rate = ADS1115::SPS_250;
break;
case 7:
set_rate = ADS1115::SPS_475;
break;
case 8:
set_rate = ADS1115::SPS_860;
break;
default:
set_rate = ADS1115::SPS_128;
}
ads.setSPS(set_rate);
break;
case 1:
int mode;
ADS1X15::ADSMUXMODE set_mode;
cout << "select one of the following:" << endl;
cout << "1 -> MUX_0_1 \t 2 -> MUX_0_3 \t 3 -> MUX_1_3 \t 4 -> MUX_2_3" << endl;
cout << "5 -> SINGLE_0 \t 6 -> SINGLE_1 \t 7 -> SINGLE_2 \t 8 -> "
"SINGLE_3"
<< endl;
cin >> mode;
switch (mode) {
case 1:
set_mode = ADS1X15::DIFF_0_1;
break;
case 2:
set_mode = ADS1X15::DIFF_0_3;
break;
case 3:
set_mode = ADS1X15::DIFF_1_3;
break;
case 4:
set_mode = ADS1X15::DIFF_2_3;
break;
case 5:
set_mode = ADS1X15::SINGLE_0;
break;
case 6:
set_mode = ADS1X15::SINGLE_1;
break;
case 7:
set_mode = ADS1X15::SINGLE_2;
break;
case 8:
set_mode = ADS1X15::SINGLE_3;
break;
default:
set_mode = ADS1X15::DIFF_0_1;
break;
}
cout << ads.getSample(set_mode) << endl;
break;
case 7:
cout << " enter a float value: ";
cin >> inputVoltage;
ads.setThresh(ADS1115::THRESH_HIGH, inputVoltage);
break;
case 8:
cout << " enter a float value: ";
cin >> inputVoltage;
ads.setThresh(ADS1115::THRESH_LOW, inputVoltage);
break;
case 9:
cout << "Upper " << ads.getThresh(ADS1X15::THRESH_HIGH) << endl;
cout << "Lower " << ads.getThresh(ADS1X15::THRESH_LOW) << endl;
break;
case 10:
ads.setThresh(ADS1115::THRESH_DEFAULT);
break;
case 11:
ads.setThresh(ADS1015::CONVERSION_RDY);
break;
case 12:
cout << ads.getCompQue() << endl;
break;
case 13:
int que;
cout << "select one of the following:" << endl;
cout << "1 -> CQUE_1CONV \t 2 -> CQUE_2CONV \t 3 -> CQUE_3CONV \t 4 -> "
"CQUE_NONE"
<< endl;
cin >> que;
switch (que) {
case 1:
ads.setCompQue(ADS1X15::CQUE_1CONV);
break;
case 2:
ads.setCompQue(ADS1X15::CQUE_2CONV);
break;
case 3:
ads.setCompQue(ADS1X15::CQUE_4CONV);
break;
case 4:
default:
ads.setCompQue(ADS1X15::CQUE_NONE);
break;
}
break;
case 14:
cout << ads.getCompPol() << endl;
break;
case 15:
cout << "select one of the following:" << endl;
cout << "1 -> active high \t 2 -> active low" << endl;
cin >> ans;
if (ans == 1)
ads.setCompPol(true);
else
ads.setCompPol(false);
break;
case 16:
cout << ads.getCompMode() << endl;
break;
case 17:
cout << "select one of the following:" << endl;
cout << "1 -> Window \t 2 -> Traditional (default)" << endl;
cin >> ans;
if (ans == 1)
ads.setCompMode(true);
else
ads.setCompMode();
break;
case 18:
cout << ads.getCompLatch() << endl;
break;
case 19:
cout << "select one of the following:" << endl;
cout << "1 -> Latching \t 2 -> Non-latching (default)" << endl;
cin >> ans;
if (ans == 1)
ads.setCompLatch(true);
else
ads.setCompLatch();
break;
case 20:
cout << ads.getContinuous() << endl;
break;
case 21:
cout << "select one of the following:" << endl;
cout << "1 -> Power Down (default) \t 2 -> Continuous" << endl;
cin >> ans;
if (ans == 1)
ads.setContinuous(true);
else
ads.setContinuous();
break;
case -1:
break;
default:
break;
}
break;
}
} while (command != -1);
}while (command != -1 );
//! [Interesting]
delete ads;
//! [Interesting]
return 0;
return 0;
}

65
examples/c++/adxl335.cxx
View File

@ -22,58 +22,57 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <string>
#include "adxl335.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main ()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an ADXL335 accelerometer on analog pins A0, A1, and A2
upm::ADXL335 accel(0, 1, 2);
//! [Interesting]
// Instantiate an ADXL335 accelerometer on analog pins A0, A1, and A2
upm::ADXL335* accel = new upm::ADXL335(0, 1, 2);
cout << "Please make sure the sensor is completely still. Sleeping for"
<< " 2 seconds." << endl;
upm_delay(2);
cout << "Calibrating..." << endl;
cout << "Please make sure the sensor is completely still. Sleeping for"
<< " 2 seconds." << endl;
sleep(2);
cout << "Calibrating..." << endl;
accel.calibrate();
accel->calibrate();
while (shouldRun)
{
int x, y, z;
float aX, aY, aZ;
while (shouldRun) {
int x, y, z;
float aX, aY, aZ;
accel->values(&x, &y, &z);
cout << "Raw Values: X: " << x << " Y: " << y << " Z: " << z << endl;
accel.values(&x, &y, &z);
cout << "Raw Values: X: " << x << " Y: " << y << " Z: " << z << endl;
accel->acceleration(&aX, &aY, &aZ);
cout << "Acceleration: X: " << aX << "g" << endl;
cout << "Acceleration: Y: " << aY << "g" << endl;
cout << "Acceleration: Z: " << aZ << "g" << endl;
cout << endl;
accel.acceleration(&aX, &aY, &aZ);
cout << "Acceleration: X: " << aX << "g" << endl;
cout << "Acceleration: Y: " << aY << "g" << endl;
cout << "Acceleration: Z: " << aZ << "g" << endl;
cout << endl;
upm_delay_us(200000);
usleep(200000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete accel;
return 0;
}

28
examples/c++/adxl345.cxx
View File

@ -22,32 +22,30 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <stdio.h>
#include <unistd.h>
#include "adxl345.hpp"
#include "upm_utilities.h"
int
main(int argc, char** argv)
main(int argc, char **argv)
{
//! [Interesting]
int16_t* raw;
float* acc;
//! [Interesting]
int16_t *raw;
float *acc;
// Note: Sensor only works at 3.3V on the Intel Edison with Arduino breakout
upm::Adxl345 accel(0);
upm::Adxl345* accel = new upm::Adxl345(0);
while (true) {
accel.update(); // Update the data
raw = accel.getRawValues(); // Read raw sensor data
acc = accel.getAcceleration(); // Read acceleration (g)
fprintf(stdout, "Current scale: 0x%2xg\n", accel.getScale());
while(true){
accel->update(); // Update the data
raw = accel->getRawValues(); // Read raw sensor data
acc = accel->getAcceleration(); // Read acceleration (g)
fprintf(stdout, "Current scale: 0x%2xg\n", accel->getScale());
fprintf(stdout, "Raw: %6d %6d %6d\n", raw[0], raw[1], raw[2]);
fprintf(stdout, "AccX: %5.2f g\n", acc[0]);
fprintf(stdout, "AccY: %5.2f g\n", acc[1]);
fprintf(stdout, "AccZ: %5.2f g\n", acc[2]);
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
return 0;
}

53
examples/c++/adxrs610.cxx
View File

@ -22,51 +22,50 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "adxrs610.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate a ADXRS610 sensor on analog pin A0 (dataout), and
// analog A1 (temp out) with an analog reference voltage of
// 5.0
upm::ADXRS610 sensor(0, 1, 5.0);
// Instantiate a ADXRS610 sensor on analog pin A0 (dataout), and
// analog A1 (temp out) with an analog reference voltage of
// 5.0
upm::ADXRS610 *sensor = new upm::ADXRS610(0, 1, 5.0);
// set a deadband region around the zero point to report 0.0 (optional)
sensor->setDeadband(0.015);
// set a deadband region around the zero point to report 0.0 (optional)
sensor.setDeadband(0.015);
// Every tenth of a second, sample the ADXRS610 and output it's
// corresponding temperature and angular velocity
// Every tenth of a second, sample the ADXRS610 and output it's
// corresponding temperature and angular velocity
while (shouldRun) {
cout << "Vel (deg/s): " << sensor.getAngularVelocity() << endl;
cout << "Temp (C): " << sensor.getTemperature() << endl;
upm_delay_us(100000);
while (shouldRun)
{
cout << "Vel (deg/s): " << sensor->getAngularVelocity() << endl;
cout << "Temp (C): " << sensor->getTemperature() << endl;
usleep(100000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete sensor;
return 0;
}

27
examples/c++/am2315.cxx
View File

@ -22,15 +22,16 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdio.h>
#include "am2315.hpp"
#include "upm_utilities.h"
volatile int doWork = 0;
upm::AM2315 *sensor = NULL;
void
sig_handler(int signo)
{
@ -41,30 +42,34 @@ sig_handler(int signo)
}
int
main(int argc, char** argv)
main(int argc, char **argv)
{
// Register signal handler
signal(SIGINT, sig_handler);
//! [Interesting]
float humidity = 0.0;
float humidity = 0.0;
float temperature = 0.0;
upm::AM2315 sensor(0, AM2315_I2C_ADDRESS);
sensor = new upm::AM2315(0, AM2315_I2C_ADDRESS);
sensor.testSensor();
sensor->testSensor();
while (!doWork) {
humidity = sensor.getHumidity();
temperature = sensor.getTemperature();
humidity = sensor->getHumidity();
temperature = sensor->getTemperature();
std::cout << "humidity value = " << humidity << ", temperature value = " << temperature
<< std::endl;
upm_delay_us(500000);
std::cout << "humidity value = " <<
humidity <<
", temperature value = " <<
temperature << std::endl;
usleep (500000);
}
//! [Interesting]
std::cout << "exiting application" << std::endl;
delete sensor;
return 0;
}

12
examples/c++/apa102.cxx
View File

@ -23,6 +23,9 @@
*/
#include "apa102.hpp"
#include <iostream>
#include <signal.h>
#include <unistd.h>
using namespace std;
@ -31,17 +34,18 @@ main(int argc, char** argv)
{
//! [Interesting]
// Instantiate a strip of 30 LEDs on SPI bus 0
upm::APA102 ledStrip(800, 0);
upm::APA102* ledStrip = new upm::APA102(800, 0);
// Set all LEDs to Red
ledStrip.setAllLeds(31, 255, 0, 0);
ledStrip->setAllLeds(31, 255, 0, 0);
// Set a section (10 to 20) to blue
ledStrip.setLeds(10, 20, 31, 0, 0, 255);
ledStrip->setLeds(10, 20, 31, 0, 0, 255);
// Set a single LED to green
ledStrip.setLed(15, 31, 0, 255, 0);
ledStrip->setLed(15, 31, 0, 255, 0);
delete ledStrip;
//! [Interesting]
return 0;
}

40
examples/c++/apds9002.cxx
View File

@ -22,41 +22,41 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "apds9002.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main ()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a Grove Luminance sensor on analog pin A0
upm::APDS9002 luminance(0);
//! [Interesting]
// Instantiate a Grove Luminance sensor on analog pin A0
upm::APDS9002* luminance = new upm::APDS9002(0);
while (shouldRun)
{
int val = luminance->value();
cout << "Luminance value is " << val << endl;
while (shouldRun) {
int val = luminance.value();
cout << "Luminance value is " << val << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete luminance;
return 0;
}

28
examples/c++/apds9930.cxx
View File

@ -22,11 +22,10 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "apds9930.hpp"
#include "upm_utilities.h"
using namespace std;
@ -45,30 +44,31 @@ main()
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a Digital Proximity and Ambient Light sensor on iio device 4
upm::APDS9930 light_proximity(4);
upm::APDS9930* light_proximity = new upm::APDS9930(4);
// Kernel driver implement upm_delay 5000-5100us after enable illuminance
// sensor
light_proximity.enableIlluminance(true);
// Kernel driver implement sleep 5000-5100us after enable illuminance sensor
light_proximity->enableIlluminance(true);
// Kernel driver implement upm_delay 5000-5100us after enable proximity sensor
light_proximity.enableProximity(true);
// Kernel driver implement sleep 5000-5100us after enable proximity sensor
light_proximity->enableProximity(true);
// Tested this value works. Please change it on your platform
upm_delay_us(120000);
usleep(120000);
while (shouldRun) {
float lux = light_proximity.getAmbient();
float lux = light_proximity->getAmbient();
cout << "Luminance value is " << lux << endl;
float proximity = light_proximity.getProximity();
float proximity = light_proximity->getProximity();
cout << "Proximity value is " << proximity << endl;
upm_delay(1);
sleep(1);
}
light_proximity.enableProximity(false);
light_proximity.enableIlluminance(false);
light_proximity->enableProximity(false);
light_proximity->enableIlluminance(false);
//! [Interesting]
cout << "Exiting" << endl;
delete light_proximity;
return 0;
}

73
examples/c++/at42qt1070.cxx
View File

@ -22,68 +22,69 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <unistd.h>
#include <signal.h>
#include <iostream>
#include "at42qt1070.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
void
printButtons(upm::AT42QT1070& touch)
void printButtons(upm::AT42QT1070 *touch)
{
bool buttonPressed = false;
uint8_t buttons = touch.getButtons();
bool buttonPressed = false;
uint8_t buttons = touch->getButtons();
cout << "Buttons Pressed: ";
for (int i = 0; i < 7; i++) {
if (buttons & (1 << i)) {
cout << i << " ";
buttonPressed = true;
cout << "Buttons Pressed: ";
for (int i=0; i<7; i++)
{
if (buttons & (1 << i))
{
cout << i << " ";
buttonPressed = true;
}
}
if (!buttonPressed)
cout << "None";
if (!buttonPressed)
cout << "None";
cout << endl;
cout << endl;
if (touch.isCalibrating())
cout << "Calibration is occurring." << endl;
if (touch->isCalibrating())
cout << "Calibration is occurring." << endl;
if (touch.isOverflowed())
cout << "Overflow was detected." << endl;
if (touch->isOverflowed())
cout << "Overflow was detected." << endl;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an AT42QT1070 on I2C bus 0
//! [Interesting]
// Instantiate an AT42QT1070 on I2C bus 0
upm::AT42QT1070 touch(AT42QT1070_I2C_BUS, AT42QT1070_DEFAULT_I2C_ADDR);
upm::AT42QT1070 *touch = new upm::AT42QT1070(AT42QT1070_I2C_BUS,
AT42QT1070_DEFAULT_I2C_ADDR);
while (shouldRun) {
touch.updateState();
printButtons(touch);
upm_delay_us(100000);
while (shouldRun)
{
touch->updateState();
printButtons(touch);
usleep(100000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete touch;
return 0;
}

41
examples/c++/bh1750.cxx
View File

@ -22,45 +22,44 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bh1750.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate a BH1750 sensor using defaults (I2C bus (0), using
// the default I2C address (0x23), and setting the mode to highest
// resolution, lowest power mode).
upm::BH1750 sensor;
// Instantiate a BH1750 sensor using defaults (I2C bus (0), using
// the default I2C address (0x23), and setting the mode to highest
// resolution, lowest power mode).
upm::BH1750 *sensor = new upm::BH1750();
// Every second, sample the BH1750 and output the measured lux value
// Every second, sample the BH1750 and output the measured lux value
while (shouldRun) {
cout << "Detected Light Level (lux): " << sensor.getLux() << endl;
upm_delay(1);
while (shouldRun)
{
cout << "Detected Light Level (lux): " << sensor->getLux() << endl;
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete sensor;
return 0;
}

50
examples/c++/biss0001.cxx
View File

@ -22,47 +22,47 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "biss0001.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main ()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a Grove Motion sensor on GPIO pin D2
upm::BISS0001 motion(2);
//! [Interesting]
// Instantiate a Grove Motion sensor on GPIO pin D2
upm::BISS0001* motion = new upm::BISS0001(2);
while (shouldRun)
{
bool val = motion->value();
while (shouldRun) {
bool val = motion.value();
if (val)
cout << "Detecting moving object";
else
cout << "No moving objects detected";
if (val)
cout << "Detecting moving object";
else
cout << "No moving objects detected";
cout << endl;
cout << endl;
sleep(1);
}
//! [Interesting]
upm_delay(1);
}
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete motion;
return 0;
}

53
examples/c++/bma220.cxx
View File

@ -22,48 +22,49 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bma220.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an BMA220 using default parameters (bus 0, addr 0x0a)
upm::BMA220 sensor;
// Instantiate an BMA220 using default parameters (bus 0, addr 0x0a)
upm::BMA220 *sensor = new upm::BMA220();
// Output data every half second until interrupted
while (shouldRun) {
sensor.update();
// Output data every half second until interrupted
while (shouldRun)
{
sensor->update();
float x, y, z;
sensor->getAccelerometer(&x, &y, &z);
cout << "Accelerometer: ";
cout << "AX: " << x << " AY: " << y << " AZ: " << z << endl;
float x, y, z;
sensor.getAccelerometer(&x, &y, &z);
cout << "Accelerometer: ";
cout << "AX: " << x << " AY: " << y << " AZ: " << z << endl;
upm_delay_us(500000);
usleep(500000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
return 0;
cout << "Exiting..." << endl;
delete sensor;
return 0;
}

60
examples/c++/bma250e.cxx
View File

@ -22,56 +22,60 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bma250e.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an BMA250E using default I2C parameters
upm::BMA250E sensor;
// Instantiate an BMA250E using default I2C parameters
upm::BMA250E sensor;
// For SPI, bus 0, you would pass -1 as the address, and a valid pin
// for CS: BMA250E(0, -1, 10);
// For SPI, bus 0, you would pass -1 as the address, and a valid pin
// for CS: BMA250E(0, -1, 10);
// now output data every 250 milliseconds
while (shouldRun) {
float x, y, z;
// now output data every 250 milliseconds
while (shouldRun)
{
float x, y, z;
sensor.update();
sensor.update();
sensor.getAccelerometer(&x, &y, &z);
cout << "Accelerometer x: " << x << " y: " << y << " z: " << z << " g" << endl;
sensor.getAccelerometer(&x, &y, &z);
cout << "Accelerometer x: " << x
<< " y: " << y
<< " z: " << z
<< " g"
<< endl;
// we show both C and F for temperature
cout << "Compensation Temperature: " << sensor.getTemperature() << " C / "
<< sensor.getTemperature(true) << " F" << endl;
// we show both C and F for temperature
cout << "Compensation Temperature: " << sensor.getTemperature()
<< " C / " << sensor.getTemperature(true) << " F"
<< endl;
cout << endl;
cout << endl;
upm_delay_us(250000);
usleep(250000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
return 0;
}

60
examples/c++/bmg160.cxx
View File

@ -22,56 +22,60 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bmg160.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an BMG160 using default I2C parameters
upm::BMG160 sensor;
// Instantiate an BMG160 using default I2C parameters
upm::BMG160 sensor;
// For SPI, bus 0, you would pass -1 as the address, and a valid pin
// for CS: BMG160(0, -1, 10);
// For SPI, bus 0, you would pass -1 as the address, and a valid pin
// for CS: BMG160(0, -1, 10);
// now output data every 250 milliseconds
while (shouldRun) {
float x, y, z;
// now output data every 250 milliseconds
while (shouldRun)
{
float x, y, z;
sensor.update();
sensor.update();
sensor.getGyroscope(&x, &y, &z);
cout << "Gyroscope x: " << x << " y: " << y << " z: " << z << " degrees/s" << endl;
sensor.getGyroscope(&x, &y, &z);
cout << "Gyroscope x: " << x
<< " y: " << y
<< " z: " << z
<< " degrees/s"
<< endl;
// we show both C and F for temperature
cout << "Compensation Temperature: " << sensor.getTemperature() << " C / "
<< sensor.getTemperature(true) << " F" << endl;
// we show both C and F for temperature
cout << "Compensation Temperature: " << sensor.getTemperature()
<< " C / " << sensor.getTemperature(true) << " F"
<< endl;
cout << endl;
cout << endl;
upm_delay_us(250000);
usleep(250000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
return 0;
}

64
examples/c++/bmi160.cxx
View File

@ -22,57 +22,61 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bmi160.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a BMI160 instance using default i2c bus and address
upm::BMI160 sensor;
// Instantiate a BMI160 instance using default i2c bus and address
upm::BMI160 *sensor = new upm::BMI160();
while (shouldRun) {
// update our values from the sensor
sensor.update();
while (shouldRun)
{
// update our values from the sensor
sensor->update();
float dataX, dataY, dataZ;
float dataX, dataY, dataZ;
sensor.getAccelerometer(&dataX, &dataY, &dataZ);
cout << "Accelerometer: ";
cout << "AX: " << dataX << " AY: " << dataY << " AZ: " << dataZ << endl;
sensor->getAccelerometer(&dataX, &dataY, &dataZ);
cout << "Accelerometer: ";
cout << "AX: " << dataX << " AY: " << dataY << " AZ: "
<< dataZ << endl;
sensor.getGyroscope(&dataX, &dataY, &dataZ);
cout << "Gryoscope: ";
cout << "GX: " << dataX << " GY: " << dataY << " GZ: " << dataZ << endl;
sensor->getGyroscope(&dataX, &dataY, &dataZ);
cout << "Gryoscope: ";
cout << "GX: " << dataX << " GY: " << dataY << " GZ: "
<< dataZ << endl;
sensor.getMagnetometer(&dataX, &dataY, &dataZ);
cout << "Magnetometer: ";
cout << "MX: " << dataX << " MY: " << dataY << " MZ: " << dataZ << endl;
sensor->getMagnetometer(&dataX, &dataY, &dataZ);
cout << "Magnetometer: ";
cout << "MX: " << dataX << " MY: " << dataY << " MZ: "
<< dataZ << endl;
cout << endl;
cout << endl;
upm_delay_us(500000);
usleep(500000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete sensor;
return 0;
}

53
examples/c++/bmm150.cxx
View File

@ -22,52 +22,55 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bmm150.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an BMM150 using default I2C parameters
upm::BMM150 sensor;
// Instantiate an BMM150 using default I2C parameters
upm::BMM150 sensor;
// For SPI, bus 0, you would pass -1 as the address, and a valid pin
// for CS: BMM150(0, -1, 10);
// For SPI, bus 0, you would pass -1 as the address, and a valid pin
// for CS: BMM150(0, -1, 10);
// now output data every 250 milliseconds
while (shouldRun) {
float x, y, z;
// now output data every 250 milliseconds
while (shouldRun)
{
float x, y, z;
sensor.update();
sensor.update();
sensor.getMagnetometer(&x, &y, &z);
cout << "Magnetometer x: " << x << " y: " << y << " z: " << z << " uT" << endl;
sensor.getMagnetometer(&x, &y, &z);
cout << "Magnetometer x: " << x
<< " y: " << y
<< " z: " << z
<< " uT"
<< endl;
cout << endl;
cout << endl;
upm_delay_us(250000);
usleep(250000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
return 0;
}

57
examples/c++/bmp280-bme280.cxx
View File

@ -22,54 +22,57 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bme280.hpp"
#include "upm_utilities.h"
using namespace std;
using namespace upm;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a BME280 instance using default i2c bus and address
upm::BME280 sensor;
// Instantiate a BME280 instance using default i2c bus and address
upm::BME280 *sensor = new upm::BME280();
// For SPI, bus 0, you would pass -1 as the address, and a valid pin for CS:
// BME280(0, -1, 10);
// For SPI, bus 0, you would pass -1 as the address, and a valid pin for CS:
// BME280(0, -1, 10);
while (shouldRun) {
// update our values from the sensor
sensor.update();
while (shouldRun)
{
// update our values from the sensor
sensor->update();
// we show both C and F for temperature
cout << "Compensation Temperature: " << sensor.getTemperature() << " C / "
<< sensor.getTemperature(true) << " F" << endl;
cout << "Pressure: " << sensor.getPressure() << " Pa" << endl;
cout << "Computed Altitude: " << sensor.getAltitude() << " m" << endl;
cout << "Humidity: " << sensor.getHumidity() << " %RH" << endl;
// we show both C and F for temperature
cout << "Compensation Temperature: " << sensor->getTemperature()
<< " C / " << sensor->getTemperature(true) << " F"
<< endl;
cout << "Pressure: " << sensor->getPressure() << " Pa" << endl;
cout << "Computed Altitude: " << sensor->getAltitude() << " m" << endl;
cout << "Humidity: " << sensor->getHumidity() << " %RH" << endl;
cout << endl;
cout << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete sensor;
return 0;
}

55
examples/c++/bmp280.cxx
View File

@ -24,53 +24,56 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bmp280.hpp"
#include "upm_utilities.h"
using namespace std;
using namespace upm;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a BMP280 instance using default i2c bus and address
upm::BMP280 sensor;
// Instantiate a BMP280 instance using default i2c bus and address
upm::BMP280 *sensor = new upm::BMP280();
// For SPI, bus 0, you would pass -1 as the address, and a valid pin for CS:
// BMP280(0, -1, 10);
// For SPI, bus 0, you would pass -1 as the address, and a valid pin for CS:
// BMP280(0, -1, 10);
while (shouldRun) {
// update our values from the sensor
sensor.update();
while (shouldRun)
{
// update our values from the sensor
sensor->update();
// we show both C and F for temperature
cout << "Compensation Temperature: " << sensor.getTemperature() << " C / "
<< sensor.getTemperature(true) << " F" << endl;
cout << "Pressure: " << sensor.getPressure() << " Pa" << endl;
cout << "Computed Altitude: " << sensor.getAltitude() << " m" << endl;
// we show both C and F for temperature
cout << "Compensation Temperature: " << sensor->getTemperature()
<< " C / " << sensor->getTemperature(true) << " F"
<< endl;
cout << "Pressure: " << sensor->getPressure() << " Pa" << endl;
cout << "Computed Altitude: " << sensor->getAltitude() << " m" << endl;
cout << endl;
cout << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete sensor;
return 0;
}

31
examples/c++/bmpx8x.cxx
View File

@ -27,47 +27,52 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bmpx8x.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate a BMPX8X sensor on I2C using defaults.
upm::BMPX8X sensor;
// Print the pressure, altitude, sea level, and
// temperature values every 0.5 seconds
while (shouldRun) {
while (shouldRun)
{
sensor.update();
cout << "Pressure: " << sensor.getPressure()
<< " Pa, Temperature: " << sensor.getTemperature()
<< " C, Altitude: " << sensor.getAltitude()
<< " m, Sea level: " << sensor.getSealevelPressure() << " Pa" << endl;
cout << "Pressure: "
<< sensor.getPressure()
<< " Pa, Temperature: "
<< sensor.getTemperature()
<< " C, Altitude: "
<< sensor.getAltitude()
<< " m, Sea level: "
<< sensor.getSealevelPressure()
<< " Pa"
<< endl;
upm_delay_us(500000);
usleep(500000);
}
cout << "Exiting..." << endl;
//! [Interesting]
//! [Interesting]
return 0;
}

57
examples/c++/bmx055-bmc150.cxx
View File

@ -22,52 +22,59 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bmc150.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an BMC150 using default I2C parameters
upm::BMC150 sensor;
// Instantiate an BMC150 using default I2C parameters
upm::BMC150 sensor;
// now output data every 250 milliseconds
while (shouldRun) {
float x, y, z;
// now output data every 250 milliseconds
while (shouldRun)
{
float x, y, z;
sensor.update();
sensor.update();
sensor.getAccelerometer(&x, &y, &z);
cout << "Accelerometer x: " << x << " y: " << y << " z: " << z << " g" << endl;
sensor.getAccelerometer(&x, &y, &z);
cout << "Accelerometer x: " << x
<< " y: " << y
<< " z: " << z
<< " g"
<< endl;
sensor.getMagnetometer(&x, &y, &z);
cout << "Magnetometer x: " << x << " y: " << y << " z: " << z << " uT" << endl;
sensor.getMagnetometer(&x, &y, &z);
cout << "Magnetometer x: " << x
<< " y: " << y
<< " z: " << z
<< " uT"
<< endl;
cout << endl;
cout << endl;
upm_delay_us(250000);
usleep(250000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
return 0;
}

57
examples/c++/bmx055-bmi055.cxx
View File

@ -22,52 +22,59 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bmi055.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an BMI055 using default I2C parameters
upm::BMI055 sensor;
// Instantiate an BMI055 using default I2C parameters
upm::BMI055 sensor;
// now output data every 250 milliseconds
while (shouldRun) {
float x, y, z;
// now output data every 250 milliseconds
while (shouldRun)
{
float x, y, z;
sensor.update();
sensor.update();
sensor.getAccelerometer(&x, &y, &z);
cout << "Accelerometer x: " << x << " y: " << y << " z: " << z << " g" << endl;
sensor.getAccelerometer(&x, &y, &z);
cout << "Accelerometer x: " << x
<< " y: " << y
<< " z: " << z
<< " g"
<< endl;
sensor.getGyroscope(&x, &y, &z);
cout << "Gyroscope x: " << x << " y: " << y << " z: " << z << " degrees/s" << endl;
sensor.getGyroscope(&x, &y, &z);
cout << "Gyroscope x: " << x
<< " y: " << y
<< " z: " << z
<< " degrees/s"
<< endl;
cout << endl;
cout << endl;
upm_delay_us(250000);
usleep(250000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
return 0;
}

65
examples/c++/bmx055.cxx
View File

@ -22,55 +22,66 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bmx055.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an BMX055 using default I2C parameters
upm::BMX055 sensor;
// Instantiate an BMX055 using default I2C parameters
upm::BMX055 sensor;
// now output data every 250 milliseconds
while (shouldRun) {
float x, y, z;
// now output data every 250 milliseconds
while (shouldRun)
{
float x, y, z;
sensor.update();
sensor.update();
sensor.getAccelerometer(&x, &y, &z);
cout << "Accelerometer x: " << x << " y: " << y << " z: " << z << " g" << endl;
sensor.getAccelerometer(&x, &y, &z);
cout << "Accelerometer x: " << x
<< " y: " << y
<< " z: " << z
<< " g"
<< endl;
sensor.getGyroscope(&x, &y, &z);
cout << "Gyroscope x: " << x << " y: " << y << " z: " << z << " degrees/s" << endl;
sensor.getGyroscope(&x, &y, &z);
cout << "Gyroscope x: " << x
<< " y: " << y
<< " z: " << z
<< " degrees/s"
<< endl;
sensor.getMagnetometer(&x, &y, &z);
cout << "Magnetometer x: " << x << " y: " << y << " z: " << z << " uT" << endl;
sensor.getMagnetometer(&x, &y, &z);
cout << "Magnetometer x: " << x
<< " y: " << y
<< " z: " << z
<< " uT"
<< endl;
cout << endl;
cout << endl;
upm_delay_us(250000);
usleep(250000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
return 0;
}

122
examples/c++/bno055.cxx
View File

@ -22,82 +22,108 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "bno055.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
//! [Interesting]
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate an BNO055 using default parameters (bus 0, addr
// 0x28). The default running mode is NDOF absolute orientation
// mode.
upm::BNO055 sensor;
// Instantiate an BNO055 using default parameters (bus 0, addr
// 0x28). The default running mode is NDOF absolute orientation
// mode.
upm::BNO055 *sensor = new upm::BNO055();
// First we need to calibrate....
cout << "First we need to calibrate. 4 numbers will be output every" << endl;
cout << "second for each sensor. 0 means uncalibrated, and 3 means" << endl;
cout << "fully calibrated." << endl;
cout << "See the UPM documentation on this sensor for instructions on" << endl;
cout << "what actions are required to calibrate." << endl;
cout << endl;
// First we need to calibrate....
cout << "First we need to calibrate. 4 numbers will be output every"
<< endl;
cout << "second for each sensor. 0 means uncalibrated, and 3 means"
<< endl;
cout << "fully calibrated."
<< endl;
cout << "See the UPM documentation on this sensor for instructions on"
<< endl;
cout << "what actions are required to calibrate."
<< endl;
cout << endl;
// do the calibration...
while (shouldRun && !sensor.isFullyCalibrated()) {
int mag, acc, gyr, sys;
sensor.getCalibrationStatus(&mag, &acc, &gyr, &sys);
// do the calibration...
while (shouldRun && !sensor->isFullyCalibrated())
{
int mag, acc, gyr, sys;
sensor->getCalibrationStatus(&mag, &acc, &gyr, &sys);
cout << "Magnetometer: " << mag << " Accelerometer: " << acc << " Gyroscope: " << gyr
<< " System: " << sys << endl;
cout << "Magnetometer: " << mag
<< " Accelerometer: " << acc
<< " Gyroscope: " << gyr
<< " System: " << sys
<< endl;
upm_delay(1);
sleep(1);
}
cout << endl;
cout << "Calibration complete." << endl;
cout << endl;
cout << endl;
cout << "Calibration complete." << endl;
cout << endl;
// now output various fusion data every 250 milliseconds
while (shouldRun) {
float w, x, y, z;
// now output various fusion data every 250 milliseconds
while (shouldRun)
{
float w, x, y, z;
sensor.update();
sensor->update();
sensor.getEulerAngles(&x, &y, &z);
cout << "Euler: Heading: " << x << " Roll: " << y << " Pitch: " << z << " degrees" << endl;
sensor->getEulerAngles(&x, &y, &z);
cout << "Euler: Heading: " << x
<< " Roll: " << y
<< " Pitch: " << z
<< " degrees"
<< endl;
sensor.getQuaternions(&w, &x, &y, &z);
cout << "Quaternion: W: " << w << " X: " << x << " Y: " << y << " Z: " << z << endl;
sensor->getQuaternions(&w, &x, &y, &z);
cout << "Quaternion: W: " << w
<< " X: " << x
<< " Y: " << y
<< " Z: " << z
<< endl;
sensor.getLinearAcceleration(&x, &y, &z);
cout << "Linear Acceleration: X: " << x << " Y: " << y << " Z: " << z << " m/s^2" << endl;
sensor->getLinearAcceleration(&x, &y, &z);
cout << "Linear Acceleration: X: " << x
<< " Y: " << y
<< " Z: " << z
<< " m/s^2"
<< endl;
sensor.getGravityVectors(&x, &y, &z);
cout << "Gravity Vector: X: " << x << " Y: " << y << " Z: " << z << " m/s^2" << endl;
sensor->getGravityVectors(&x, &y, &z);
cout << "Gravity Vector: X: " << x
<< " Y: " << y
<< " Z: " << z
<< " m/s^2"
<< endl;
cout << endl;
upm_delay_us(250000);
cout << endl;
usleep(250000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete sensor;
return 0;
}

18
examples/c++/button.cxx
View File

@ -22,28 +22,28 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include "button.hpp"
#include "upm_utilities.h"
int
main(int argc, char** argv)
main(int argc, char **argv)
{
// This example uses GPIO 0
//! [Interesting]
//! [Interesting]
// Create the button object using GPIO pin 0
upm::Button button(0);
upm::Button* button = new upm::Button(0);
// Read the input and print, waiting one second between readings
while (1) {
std::cout << button.name() << " value is " << button.value() << std::endl;
upm_delay(1);
while( 1 ) {
std::cout << button->name() << " value is " << button->value() << std::endl;
sleep(1);
}
// Delete the button object
//! [Interesting]
delete button;
//! [Interesting]
return 0;
}

23
examples/c++/buzzer.cxx
View File

@ -22,32 +22,37 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "buzzer.hpp"
#include "buzzer_tones.h"
#include "upm_utilities.h"
int
main(int argc, char** argv)
{
main(int argc, char **argv) {
//! [Interesting]
int chord[] = { BUZZER_DO, BUZZER_RE, BUZZER_MI, BUZZER_FA, BUZZER_SOL, BUZZER_LA, BUZZER_SI };
int chord[] = { BUZZER_DO, BUZZER_RE, BUZZER_MI,
BUZZER_FA, BUZZER_SOL, BUZZER_LA,
BUZZER_SI };
// create Buzzer instance
upm::Buzzer sound(5);
upm::Buzzer* sound = new upm::Buzzer(5);
// print sensor name
std::cout << sound.name() << std::endl;
std::cout << sound->name() << std::endl;
// play each sound (DO, RE, MI, etc...) for .5 seconds, pausing
// for 0.1 seconds between notes
for (int chord_ind = 0; chord_ind < 7; chord_ind++) {
std::cout << sound.playSound(chord[chord_ind], 500000) << std::endl;
for (int chord_ind = 0; chord_ind < 7; chord_ind++)
{
std::cout << sound->playSound(chord[chord_ind], 500000) << std::endl;
upm_delay_ms(100);
}
//! [Interesting]
std::cout << "exiting application" << std::endl;
delete sound;
return 0;
}

42
examples/c++/cjq4435.cxx
View File

@ -22,54 +22,56 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "cjq4435.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main ()
{
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate a CJQ4435 MOSFET on a PWM capable digital pin D3
upm::CJQ4435 mosfet(3);
upm::CJQ4435* mosfet = new upm::CJQ4435(3);
mosfet.setPeriodMS(10);
mosfet.enable(true);
mosfet->setPeriodMS(10);
mosfet->enable(true);
while (shouldRun) {
while (shouldRun)
{
// start with a duty cycle of 0.0 (off) and increment to 1.0 (on)
for (float i = 0.0; i <= 1.0; i += 0.1) {
mosfet.setDutyCycle(i);
upm_delay_us(100000);
for (float i=0.0; i <= 1.0; i+=0.1)
{
mosfet->setDutyCycle(i);
usleep(100000);
}
upm_delay(1);
sleep(1);
// Now take it back down
// start with a duty cycle of 1.0 (on) and decrement to 0.0 (off)
for (float i = 1.0; i >= 0.0; i -= 0.1) {
mosfet.setDutyCycle(i);
upm_delay_us(100000);
for (float i=1.0; i >= 0.0; i-=0.1)
{
mosfet->setDutyCycle(i);
usleep(100000);
}
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
delete mosfet;
return 0;
}

55
examples/c++/collision.cxx
View File

@ -22,45 +22,48 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <unistd.h>
#include <signal.h>
#include "collision.hpp"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// The was tested with the Collision Sensor
// Instantiate a Collision on digital pin D2
upm::Collision collision(2);
//! [Interesting]
// The was tested with the Collision Sensor
// Instantiate a Collision on digital pin D2
upm::Collision* collision = new upm::Collision(2);
bool collisionState = false;
cout << "No collision" << endl;
while (shouldRun) {
if (collision.isColliding() && !collisionState) {
cout << "Collision!" << endl;
collisionState = true;
} else if (collisionState) {
cout << "No collision" << endl;
collisionState = false;
}
}
bool collisionState = false;
cout << "No collision" << endl;
while (shouldRun)
{
if (collision->isColliding() && !collisionState)
{
cout << "Collision!" << endl;
collisionState = true;
}
else if (collisionState)
{
cout << "No collision" << endl;
collisionState = false;
}
}
//! [Interesting]
cout << "Exiting" << endl;
//! [Interesting]
cout << "Exiting" << endl;
return 0;
delete collision;
return 0;
}

52
examples/c++/curieimu.cxx
View File

@ -24,50 +24,58 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include "curieimu.hpp"
#include "upm_utilities.h"
#include "mraa.h"
#include "mraa/firmata.h"
#include <iostream>
#include <math.h>
#include <unistd.h>
int
main(int argc, char** argv)
main(int argc, char **argv)
{
//! [Interesting]
mraa_init();
mraa_add_subplatform(MRAA_GENERIC_FIRMATA, "/dev/ttyACM0");
upm::CurieImu sensor;
upm::CurieImu* sensor = new upm::CurieImu();
std::cout << "temperature is: " << (sensor.getTemperature() * pow(0.5, 9) + 23) << std::endl;
std::cout << "temperature is: " << (sensor->getTemperature() * pow(0.5, 9) + 23) << std::endl;
sensor.updateAccel();
int x = sensor.getAccelX(), y = sensor.getAccelY(), z = sensor.getAccelZ();
sensor->updateAccel();
int x = sensor->getAccelX(),
y = sensor->getAccelY(),
z = sensor->getAccelZ();
printf("accelerometer is: %d, %d, %d\n", x, y, z);
sensor.updateGyro();
int a = sensor.getGyroX(), b = sensor.getGyroY(), c = sensor.getGyroZ();
sensor->updateGyro();
int a = sensor->getGyroX(),
b = sensor->getGyroY(),
c = sensor->getGyroZ();
printf("gyroscope is: %d, %d, %d\n", a, b, c);
int axis, direction;
sensor.enableShockDetection(true);
for (int i = 0; i < 300; i++) {
if (sensor.isShockDetected()) {
sensor.getNextShock();
axis = sensor.getAxis();
direction = sensor.getDirection();
printf("shock data is: %d, %d\n", axis, direction);
}
upm_delay_us(10000);
sensor->enableShockDetection(true);
for(int i=0; i<300; i++) {
if (sensor->isShockDetected()) {
sensor->getNextShock();
axis = sensor->getAxis();
direction = sensor->getDirection();
printf("shock data is: %d, %d\n", axis, direction);
}
usleep(10000);
}
sensor.updateMotion();
int m = sensor.getAccelX(), n = sensor.getAccelY(), o = sensor.getAccelZ(),
p = sensor.getGyroX(), q = sensor.getGyroY(), r = sensor.getGyroZ();
sensor->updateMotion();
int m = sensor->getAccelX(),
n = sensor->getAccelY(),
o = sensor->getAccelZ(),
p = sensor->getGyroX(),
q = sensor->getGyroY(),
r = sensor->getGyroZ();
printf("motion is: %d, %d, %d, %d, %d, %d\n", m, n, o, p, q, r);
delete sensor;
//! [Interesting]
return 0;

58
examples/c++/cwlsxxa.cxx
View File

@ -22,57 +22,61 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "cwlsxxa.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
cout << "Initializing..." << endl;
cout << "Initializing..." << endl;
// Instantiate an CWLSXXA instance, using A0 for CO2, A1 for
// humidity and A2 for temperature
upm::CWLSXXA sensor(0, 1, 2);
// Instantiate an CWLSXXA instance, using A0 for CO2, A1 for
// humidity and A2 for temperature
upm::CWLSXXA *sensor = new upm::CWLSXXA(0, 1, 2);
// update and print available values every second
while (shouldRun) {
// update our values from the sensor
sensor.update();
// update and print available values every second
while (shouldRun)
{
// update our values from the sensor
sensor->update();
// we show both C and F for temperature
cout << "Temperature: " << sensor.getTemperature() << " C / " << sensor.getTemperature(true)
<< " F" << endl;
// we show both C and F for temperature
cout << "Temperature: " << sensor->getTemperature()
<< " C / " << sensor->getTemperature(true) << " F"
<< endl;
cout << "Humidity: " << sensor.getHumidity() << " %" << endl;
cout << "Humidity: " << sensor->getHumidity()
<< " %" << endl;
cout << "CO2: " << sensor.getCO2() << " ppm" << endl;
cout << "CO2: " << sensor->getCO2()
<< " ppm" << endl;
cout << endl;
cout << endl;
upm_delay(1);
sleep(1);
}
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
//! [Interesting]
delete sensor;
return 0;
//! [Interesting]
return 0;
}

57
examples/c++/dfrec.cxx
View File

@ -22,53 +22,60 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "dfrec.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate a DFRobot EC sensor on analog pin A0, with a ds18b20
// temperature sensor connected to UART 0, and a device index (for
// the ds1820b uart bus) of 0, and an analog reference voltage of
// 5.0.
upm::DFREC sensor(0, 0, 0, 5.0);
// Instantiate a DFRobot EC sensor on analog pin A0, with a ds18b20
// temperature sensor connected to UART 0, and a device index (for
// the ds1820b uart bus) of 0, and an analog reference voltage of
// 5.0.
upm::DFREC *sensor = new upm::DFREC(0, 0, 0, 5.0);
// Every 2 seconds, update and print values
while (shouldRun) {
sensor.update();
// Every 2 seconds, update and print values
while (shouldRun)
{
sensor->update();
cout << "EC = " << sensor.getEC() << " ms/cm" << endl;
cout << "EC = "
<< sensor->getEC()
<< " ms/cm"
<< endl;
cout << "Volts = " << sensor.getVolts() << ", Temperature = " << sensor.getTemperature()
<< " C" << endl;
cout << "Volts = "
<< sensor->getVolts()
<< ", Temperature = "
<< sensor->getTemperature()
<< " C"
<< endl;
cout << endl;
cout << endl;
upm_delay(2);
sleep(2);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete sensor;
return 0;
}

73
examples/c++/dfrorp.cxx
View File

@ -22,63 +22,66 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "dfrorp.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate a DFRobot ORP sensor on analog pin A0 with an analog
// reference voltage of 5.0.
upm::DFRORP sensor(0, 5.0);
// Instantiate a DFRobot ORP sensor on analog pin A0 with an analog
// reference voltage of 5.0.
upm::DFRORP *sensor = new upm::DFRORP(0, 5.0);
// To calibrate:
//
// Disconnect the sensor probe (but leave the sensor interface board
// connected). Then run one of the examples while holding down the
// 'calibrate' button on the device. Read the ORP value reported
// (it should be fairly small).
//
// This value is what you should supply to setCalibrationOffset().
// Then reconnect the probe to the interface board and you should be
// ready to go.
//
// DO NOT press the calibrate button on the interface board while
// the probe is attached or you can permanently damage the probe.
sensor.setCalibrationOffset(0.97);
// To calibrate:
//
// Disconnect the sensor probe (but leave the sensor interface board
// connected). Then run one of the examples while holding down the
// 'calibrate' button on the device. Read the ORP value reported
// (it should be fairly small).
//
// This value is what you should supply to setCalibrationOffset().
// Then reconnect the probe to the interface board and you should be
// ready to go.
//
// DO NOT press the calibrate button on the interface board while
// the probe is attached or you can permanently damage the probe.
sensor->setCalibrationOffset(0.97);
// Every second, update and print values
while (shouldRun) {
sensor.update();
// Every second, update and print values
while (shouldRun)
{
sensor->update();
cout << "ORP: " << sensor.getORP() << " mV" << endl;
cout << "ORP: "
<< sensor->getORP()
<< " mV"
<< endl;
cout << endl;
cout << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete sensor;
return 0;
}

56
examples/c++/dfrph.cxx
View File

@ -22,55 +22,55 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "dfrph.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
#define DFRPH_AREF 5.0
#define DFRPH_AREF 5.0
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate a DFRPH sensor on analog pin A0, with an analog
// reference voltage of DFRPH_AREF
upm::DFRPH sensor(0, DFRPH_AREF);
// Instantiate a DFRPH sensor on analog pin A0, with an analog
// reference voltage of DFRPH_AREF
upm::DFRPH *sensor = new upm::DFRPH(0, DFRPH_AREF);
// After calibration, set the offset (based on calibration with a pH
// 7.0 buffer solution). See the UPM sensor documentation for
// calibrations instructions.
sensor.setOffset(0.065);
// After calibration, set the offset (based on calibration with a pH
// 7.0 buffer solution). See the UPM sensor documentation for
// calibrations instructions.
sensor->setOffset(0.065);
// Every second, sample the pH and output it's corresponding
// analog voltage.
// Every second, sample the pH and output it's corresponding
// analog voltage.
while (shouldRun) {
cout << "Detected volts: " << sensor.volts() << endl;
cout << "pH value: " << sensor.pH() << endl;
cout << endl;
while (shouldRun)
{
cout << "Detected volts: " << sensor->volts() << endl;
cout << "pH value: " << sensor->pH() << endl;
cout << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete sensor;
return 0;
}

66
examples/c++/ds1307.cxx
View File

@ -22,54 +22,56 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <string>
#include "ds1307.hpp"
using namespace std;
void
printTime(upm::DS1307& rtc)
void printTime(upm::DS1307 *rtc)
{
cout << "The time is: " << rtc.month << "/" << rtc.dayOfMonth << "/" << rtc.year << " "
<< rtc.hours << ":" << rtc.minutes << ":" << rtc.seconds;
cout << "The time is: " <<
rtc->month << "/" << rtc->dayOfMonth << "/" << rtc->year << " "
<< rtc->hours << ":" << rtc->minutes << ":" << rtc->seconds;
if (rtc.amPmMode)
cout << ((rtc.pm) ? " PM " : " AM ");
if (rtc->amPmMode)
cout << ((rtc->pm) ? " PM " : " AM ");
cout << endl;
cout << endl;
cout << "Clock is in " << ((rtc.amPmMode) ? "AM/PM mode" : "24hr mode") << endl;
cout << "Clock is in " << ((rtc->amPmMode) ? "AM/PM mode" : "24hr mode")
<< endl;
}
int
main(int argc, char** argv)
main(int argc, char **argv)
{
//! [Interesting]
// Instantiate a DS1037 on I2C bus 0
upm::DS1307 rtc(0);
// always do this first
cout << "Loading the current time... " << endl;
if (!rtc.loadTime()) {
cerr << "rtc.loadTime() failed." << endl;
return 0;
//! [Interesting]
// Instantiate a DS1037 on I2C bus 0
upm::DS1307 *rtc = new upm::DS1307(0);
// always do this first
cout << "Loading the current time... " << endl;
if (!rtc->loadTime())
{
cerr << "rtc->loadTime() failed." << endl;
return 0;
}
printTime(rtc);
printTime(rtc);
// set the year as an example
cout << "setting the year to 50" << endl;
rtc->year = 50;
// set the year as an example
cout << "setting the year to 50" << endl;
rtc.year = 50;
rtc->setTime();
rtc.setTime();
// reload the time and print it
rtc->loadTime();
printTime(rtc);
// reload the time and print it
rtc.loadTime();
printTime(rtc);
//! [Interesting]
return 0;
//! [Interesting]
delete rtc;
return 0;
}

40
examples/c++/ds1808lc.cxx
View File

@ -1,41 +1,43 @@
#include <iostream>
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <iostream>
#include <string>
#include "ds1808lc.hpp"
#define EDISON_I2C_BUS 1 // Edison I2C-1
#define DS1808_GPIO_PWR 15 // Edison GP165
#define EDISON_I2C_BUS 1 // Edison I2C-1
#define DS1808_GPIO_PWR 15 // Edison GP165
void
printState(upm::ILightController& lightController)
void printState(upm::ILightController &lightController)
{
if (lightController.isPowered()) {
std::cout << "Light is powered, brightness = " << lightController.getBrightness()
<< std::endl;
} else {
if (lightController.isPowered())
{
std::cout << "Light is powered, brightness = " << lightController.getBrightness() << std::endl;
}
else
{
std::cout << "Light is not powered." << std::endl;
}
}
int
main(int argc, char** argv)
int main( int argc, char **argv )
{
//! [Interesting]
upm::DS1808LC lightController(DS1808_GPIO_PWR, EDISON_I2C_BUS);
std::cout << "Existing state: ";
printState(lightController);
if (argc == 2) {
std::cout << "Existing state: "; printState(lightController);
if (argc == 2)
{
std::string arg = argv[1];
int brightness = ::atoi(argv[1]);
if (brightness > 0) {
if (brightness > 0)
{
lightController.setPowerOn();
lightController.setBrightness(brightness);
} else
}
else
lightController.setPowerOff();
}
std::cout << "Now: ";
printState(lightController);
std::cout << "Now: ";printState(lightController);
//! [Interesting]
return 0;
}

68
examples/c++/ds18b20.cxx
View File

@ -22,61 +22,65 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "ds18b20.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
cout << "Initializing..." << endl;
cout << "Initializing..." << endl;
// Instantiate an DS18B20 instance using the default values (uart 0)
upm::DS18B20 sensor;
// Instantiate an DS18B20 instance using the default values (uart 0)
upm::DS18B20 sensor;
cout << "Found " << sensor.devicesFound() << " device(s)" << endl;
cout << endl;
cout << "Found " << sensor.devicesFound() << " device(s)" << endl;
cout << endl;
// bail if we didn't find anything
if (!sensor.devicesFound())
return 1;
// bail if we didn't find anything
if (!sensor.devicesFound())
return 1;
// update and print available values every 2 seconds
while (shouldRun) {
// update our values for all of the detected sensors
sensor.update(-1);
// update and print available values every 2 seconds
while (shouldRun)
{
// update our values for all of the detected sensors
sensor.update(-1);
// we show both C and F for temperature for the sensors
int i;
for (i = 0; i < sensor.devicesFound(); i++) {
cout << "Device " << i << ": Temperature: " << sensor.getTemperature(i) << " C / "
<< sensor.getTemperature(i, true) << " F" << endl;
}
cout << endl;
// we show both C and F for temperature for the sensors
int i;
for (i=0; i<sensor.devicesFound(); i++)
{
cout << "Device "
<< i
<< ": Temperature: "
<< sensor.getTemperature(i)
<< " C / " << sensor.getTemperature(i, true) << " F"
<< endl;
}
cout << endl;
upm_delay(2);
sleep(2);
}
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
//! [Interesting]
//! [Interesting]
return 0;
return 0;
}

41
examples/c++/ds2413.cxx
View File

@ -22,37 +22,38 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <stdio.h>
#include "ds2413.hpp"
using namespace std;
using namespace upm;
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
//! [Interesting]
// Instantiate a DS2413 Module on a Dallas 1-wire bus connected to UART 0
upm::DS2413 sensor(0);
//! [Interesting]
// Instantiate a DS2413 Module on a Dallas 1-wire bus connected to UART 0
upm::DS2413* sensor = new upm::DS2413(0);
// find all of the DS2413 devices present on the bus
sensor.init();
// find all of the DS2413 devices present on the bus
sensor->init();
// how many devices were found?
cout << "Found " << sensor.devicesFound() << " device(s)" << endl;
// how many devices were found?
cout << "Found "<< sensor->devicesFound() << " device(s)" << endl;
// read the gpio and latch values from the first device
// the lower 4 bits are of the form:
// <gpioB latch> <gpioB value> <gpioA latch> <gpioA value>
cout << "GPIO device 0 values: " << sensor.readGpios(0) << endl;
// read the gpio and latch values from the first device
// the lower 4 bits are of the form:
// <gpioB latch> <gpioB value> <gpioA latch> <gpioA value>
cout << "GPIO device 0 values: " << sensor->readGpios(0) << endl;
// set the gpio latch values of the first device
cout << "Setting GPIO latches to on" << endl;
sensor.writeGpios(0, 0x03);
// set the gpio latch values of the first device
cout << "Setting GPIO latches to on" << endl;
sensor->writeGpios(0, 0x03);
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
//! [Interesting]
return 0;
delete sensor;
//! [Interesting]
return 0;
}

105
examples/c++/e50hx.cxx
View File

@ -22,84 +22,91 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <string>
#include "e50hx.hpp"
#include "upm_utilities.h"
using namespace std;
using namespace upm;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// You will need to edit this example to conform to your site and your
// devices, specifically the Device Object Instance ID passed to the
// constructor, and the arguments to initMaster() that are
// appropriate for your BACnet network.
//! [Interesting]
// You will need to edit this example to conform to your site and your
// devices, specifically the Device Object Instance ID passed to the
// constructor, and the arguments to initMaster() that are
// appropriate for your BACnet network.
string defaultDev = "/dev/ttyUSB0";
string defaultDev = "/dev/ttyUSB0";
// if an argument was specified, use it as the device instead
if (argc > 1)
defaultDev = string(argv[1]);
// if an argument was specified, use it as the device instead
if (argc > 1)
defaultDev = string(argv[1]);
cout << "Using device " << defaultDev << endl;
cout << "Initializing..." << endl;
cout << "Using device " << defaultDev << endl;
cout << "Initializing..." << endl;
// Instantiate an E50HX object for an E50HX device that has 1075425
// as it's unique Device Object Instance ID. NOTE: You will
// certainly want to change this to the correct value for your
// device(s).
E50HX sensor(1075425);
// Instantiate an E50HX object for an E50HX device that has 1075425
// as it's unique Device Object Instance ID. NOTE: You will
// certainly want to change this to the correct value for your
// device(s).
E50HX *sensor = new E50HX(1075425);
// Initialize our BACnet master, if it has not already been
// initialized, with the device and baudrate, choosing 1000001 as
// our unique Device Object Instance ID, 2 as our MAC address and
// using default values for maxMaster and maxInfoFrames
sensor.initMaster(defaultDev, 38400, 1000001, 2);
// Initialize our BACnet master, if it has not already been
// initialized, with the device and baudrate, choosing 1000001 as
// our unique Device Object Instance ID, 2 as our MAC address and
// using default values for maxMaster and maxInfoFrames
sensor->initMaster(defaultDev, 38400, 1000001, 2);
// Uncomment to enable debugging output
// sensor.setDebug(true);
// Uncomment to enable debugging output
// sensor->setDebug(true);
cout << endl;
cout << "Device Description: " << sensor.getDeviceDescription() << endl;
cout << "Device Location: " << sensor.getDeviceLocation() << endl;
cout << endl;
cout << endl;
cout << "Device Description: " << sensor->getDeviceDescription() << endl;
cout << "Device Location: " << sensor->getDeviceLocation() << endl;
cout << endl;
// update and print a few values every 5 seconds
while (shouldRun) {
cout << "System Voltage: " << sensor.getAnalogValue(E50HX::AV_System_Voltage) << " "
<< sensor.getAnalogValueUnits(E50HX::AV_System_Voltage) << endl;
// update and print a few values every 5 seconds
while (shouldRun)
{
cout << "System Voltage: "
<< sensor->getAnalogValue(E50HX::AV_System_Voltage)
<< " " << sensor->getAnalogValueUnits(E50HX::AV_System_Voltage)
<< endl;
cout << "System Type: " << sensor.getAnalogValue(E50HX::AV_System_Type) << endl;
cout << "System Type: "
<< sensor->getAnalogValue(E50HX::AV_System_Type)
<< endl;
cout << "Energy Consumption: " << sensor.getAnalogInput(E50HX::AI_Energy) << " "
<< sensor.getAnalogInputUnits(E50HX::AI_Energy) << endl;
cout << "Energy Consumption: " << sensor->getAnalogInput(E50HX::AI_Energy)
<< " " << sensor->getAnalogInputUnits(E50HX::AI_Energy)
<< endl;
cout << "Power Up Counter: " << sensor.getAnalogInput(E50HX::AI_Power_Up_Count) << endl;
cout << "Power Up Counter: "
<< sensor->getAnalogInput(E50HX::AI_Power_Up_Count)
<< endl;
cout << endl;
upm_delay(5);
cout << endl;
sleep(5);
}
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
//! [Interesting]
delete sensor;
return 0;
//! [Interesting]
return 0;
}

37
examples/c++/ecezo.cxx
View File

@ -22,44 +22,51 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <ecezo.hpp>
#include <iostream>
#include <unistd.h>
#include <signal.h>
#include <upm_utilities.h>
#include <ecezo.hpp>
using namespace std;
using namespace upm;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a ECEZO sensor on uart 0 at 9600 baud.
upm::ECEZO sensor(0, 9600, false);
upm::ECEZO *sensor = new upm::ECEZO(0, 9600, false);
// For I2C, assuming the device is configured for address 0x64 on
// I2C bus 0, you could use something like:
//
// upm::ECEZO sensor(0, 0x64, true);
// upm::ECEZO *sensor = new upm::ECEZO(0, 0x64, true);
while (shouldRun) {
while (shouldRun)
{
// this will take about 1 second to complete
sensor.update();
sensor->update();
cout << "EC " << sensor.getEC() << " uS/cm, TDS " << sensor.getTDS() << " mg/L, Salinity "
<< sensor.getSalinity() << " PSS-78, SG " << sensor.getSG() << endl;
cout << "EC "
<< sensor->getEC()
<< " uS/cm, TDS "
<< sensor->getTDS()
<< " mg/L, Salinity "
<< sensor->getSalinity()
<< " PSS-78, SG "
<< sensor->getSG()
<< endl;
upm_delay(5);
}
@ -68,5 +75,7 @@ main()
cout << "Exiting..." << endl;
delete sensor;
return 0;
}

17
examples/c++/ecs1030.cxx
View File

@ -22,13 +22,14 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include "ecs1030.hpp"
int is_running = 0;
upm::ECS1030 *sensor = NULL;
void
sig_handler(int signo)
@ -41,20 +42,20 @@ sig_handler(int signo)
//! [Interesting]
int
main(int argc, char** argv)
main(int argc, char **argv)
{
upm::ECS1030 sensor(0);
sensor = new upm::ECS1030(0);
signal(SIGINT, sig_handler);
while (!is_running) {
std::cout << "I = " << sensor.getCurrency_A() << ", Power = " << sensor.getPower_A()
<< std::endl;
std::cout << "I = " << sensor.getCurrency_B() << ", Power = " << sensor.getPower_B()
<< std::endl;
std::cout << "I = " << sensor->getCurrency_A () << ", Power = " << sensor->getPower_A () << std::endl;
std::cout << "I = " << sensor->getCurrency_B () << ", Power = " << sensor->getPower_B () << std::endl;
}
std::cout << "exiting application" << std::endl;
delete sensor;
return 0;
}
//! [Interesting]

66
examples/c++/ehr.cxx
View File

@ -22,57 +22,57 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "ehr.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a Ear-clip Heart Rate sensor on digital pin D2
upm::EHR heart(2);
//! [Interesting]
// Instantiate a Ear-clip Heart Rate sensor on digital pin D2
upm::EHR* heart = new upm::EHR(2);
// set the beat counter to 0, init the clock and start counting beats
heart->clearBeatCounter();
heart->initClock();
heart->startBeatCounter();
// set the beat counter to 0, init the clock and start counting beats
heart.clearBeatCounter();
heart.initClock();
heart.startBeatCounter();
while (shouldRun)
{
// we grab these just for display purposes in this example
uint32_t millis = heart->getMillis();
uint32_t beats = heart->beatCounter();
while (shouldRun) {
// we grab these just for display purposes in this example
uint32_t millis = heart.getMillis();
uint32_t beats = heart.beatCounter();
// heartRate() requires that at least 5 seconds pass before
// returning anything other than 0
int hr = heart->heartRate();
// heartRate() requires that at least 5 seconds pass before
// returning anything other than 0
int hr = heart.heartRate();
// output milliseconds passed, beat count, and computed heart rate
cout << "Millis: " << millis << " Beats: " << beats;
cout << " Heart Rate: " << hr << endl;
// output milliseconds passed, beat count, and computed heart rate
cout << "Millis: " << millis << " Beats: " << beats;
cout << " Heart Rate: " << hr << endl;
upm_delay(1);
sleep(1);
}
heart.stopBeatCounter();
//! [Interesting]
heart->stopBeatCounter();
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
}
delete heart;
return 0;
}

51
examples/c++/eldriver.cxx
View File

@ -22,46 +22,45 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <unistd.h>
#include <signal.h>
#include "eldriver.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// This was tested with the El Driver Module
// Instantiate an El Driver on digital pin D2
upm::ElDriver eldriver(2);
//! [Interesting]
// The was tested with the El Driver Module
// Instantiate a El Driver on digital pin D2
upm::ElDriver* eldriver = new upm::ElDriver(2);
bool lightState = true;
bool lightState = true;
while (shouldRun) {
if (lightState)
eldriver.on();
else
eldriver.off();
lightState = !lightState;
upm_delay(1);
}
while (shouldRun)
{
if (lightState)
eldriver->on();
else
eldriver->off();
lightState = !lightState;
sleep(1);
}
//! [Interesting]
eldriver.off();
cout << "Exiting" << endl;
//! [Interesting]
eldriver->off();
cout << "Exiting" << endl;
return 0;
delete eldriver;
return 0;
}

72
examples/c++/electromagnet.cxx
View File

@ -22,60 +22,58 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <signal.h>
#include <sys/time.h>
#include <time.h>
#include <signal.h>
#include "electromagnet.hpp"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
float
get_time()
float get_time()
{
return ((float) (clock())) / CLOCKS_PER_SEC;
return ((float)(clock()))/CLOCKS_PER_SEC;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// The was tested with the Electromagnetic Module
// Instantiate a Electromagnet on digital pin D2
upm::Electromagnet magnet(2);
cout << "Starting up magnet...." << endl;
magnet.off();
//! [Interesting]
// The was tested with the Electromagnetic Module
// Instantiate a Electromagnet on digital pin D2
upm::Electromagnet* magnet = new upm::Electromagnet(2);
cout << "Starting up magnet...." << endl;
magnet->off();
bool magnetState = false;
float time_passed = get_time();
bool magnetState = false;
float time_passed = get_time();
// Turn magnet on and off every 5 seconds
while (shouldRun) {
if ((get_time() - time_passed) > 5.0) {
magnetState = !magnetState;
if (magnetState)
magnet.on();
else
magnet.off();
cout << "Turning magnet " << ((magnetState) ? "on" : "off") << endl;
time_passed = get_time();
}
}
// Turn magnet on and off every 5 seconds
while (shouldRun)
{
if ((get_time() - time_passed) > 5.0)
{
magnetState = !magnetState;
if (magnetState)
magnet->on();
else
magnet->off();
cout << "Turning magnet " << ((magnetState) ? "on" : "off") << endl;
time_passed = get_time();
}
}
//! [Interesting]
magnet.off();
cout << "Exiting" << endl;
//! [Interesting]
magnet->off();
cout << "Exiting" << endl;
return 0;
delete magnet;
return 0;
}

45
examples/c++/emg.cxx
View File

@ -21,41 +21,40 @@
* OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "emg.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// The was tested with the EMG Muscle Signal Reader Sensor Module
// Instantiate a EMG on analog pin A0
upm::EMG emg(0);
cout << "Calibrating...." << endl;
emg.calibrate();
//! [Interesting]
// The was tested with the EMG Muscle Signal Reader Sensor Module
// Instantiate a EMG on analog pin A0
upm::EMG *emg = new upm::EMG(0);
cout << "Calibrating...." << endl;
emg->calibrate();
while (shouldRun)
{
cout << emg->value() << endl;
usleep(100000);
}
while (shouldRun) {
cout << emg.value() << endl;
upm_delay_us(100000);
}
//! [Interesting]
cout << "Exiting" << endl;
return 0;
//! [Interesting]
cout << "Exiting" << endl;
delete emg;
return 0;
}

33
examples/c++/enc03r.cxx
View File

@ -22,11 +22,10 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "enc03r.hpp"
#include "upm_utilities.h"
using namespace std;
@ -35,43 +34,47 @@ bool shouldRun = true;
// analog voltage, usually 3.3 or 5.0
#define CALIBRATION_SAMPLES 1000
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate a ENC03R on analog pin A0
upm::ENC03R gyro(0);
upm::ENC03R *gyro = new upm::ENC03R(0);
// The first thing we need to do is calibrate the sensor.
cout << "Please place the sensor in a stable location, and do not" << endl;
cout << "move it while calibration takes place." << endl;
cout << "This may take a couple of minutes." << endl;
gyro.calibrate(CALIBRATION_SAMPLES);
cout << "Calibration complete. Reference value: " << gyro.calibrationValue() << endl;
gyro->calibrate(CALIBRATION_SAMPLES);
cout << "Calibration complete. Reference value: "
<< gyro->calibrationValue() << endl;
// Read the input and print both the raw value and the angular velocity,
// waiting 0.1 seconds between readings
while (shouldRun) {
gyro.update();
while (shouldRun)
{
gyro->update();
cout << "Angular velocity: " << gyro.angularVelocity() << " deg/s" << endl;
cout << "Angular velocity: "
<< gyro->angularVelocity()
<< " deg/s"
<< endl;
upm_delay_us(100000);
usleep(100000);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
delete gyro;
return 0;
}

49
examples/c++/flex.cxx
View File

@ -22,46 +22,45 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "flex.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// The was tested with a Spectra Symbol flex sensor.
// We attached a 22K resistor to a breadboard,
// with 1 end attached to GND and the other connected to
// both the flex sensor and A0.
// The flex sensor was connected on 1 pin to the 22K resistor and A0
// and on the other pin to 5V.
//! [Interesting]
// The was tested with a Spectra Symbol flex sensor.
// We attached a 22K resistor to a breadboard,
// with 1 end attached to GND and the other connected to
// both the flex sensor and A0.
// The flex sensor was connected on 1 pin to the 22K resistor and A0
// and on the other pin to 5V.
// Instantiate a Flex sensor on analog pin A0
upm::Flex flex(0);
while (shouldRun) {
cout << "Flex value: " << flex.value() << endl;
upm_delay(1);
// Instantiate a Flex sensor on analog pin A0
upm::Flex *flex = new upm::Flex(0);
while (shouldRun)
{
cout << "Flex value: " << flex->value() << endl;
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete flex;
return 0;
}

26
examples/c++/gas-mq2.cxx
View File

@ -22,16 +22,16 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdint.h>
#include <stdio.h>
#include "gas.hpp"
#include "mq2.hpp"
#include <signal.h>
#include <stdlib.h>
#include <sys/time.h>
int is_running = 0;
uint16_t buffer[128];
uint16_t buffer [128];
upm::MQ2 *sensor = NULL;
void
sig_handler(int signo)
@ -44,26 +44,26 @@ sig_handler(int signo)
//! [Interesting]
int
main(int argc, char** argv)
main(int argc, char **argv)
{
// Attach gas sensor to A0
upm::MQ2 sensor(0);
sensor = new upm::MQ2(0);
signal(SIGINT, sig_handler);
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 milliseconds;
// find the average of 128 samples; and
// print a running graph of the averages using a resolution of 5
while (!is_running) {
int len = sensor.getSampledWindow(2, 128, buffer);
int len = sensor->getSampledWindow (2, 128, buffer);
if (len) {
int thresh = sensor.findThreshold(&ctx, 30, buffer, len);
sensor.printGraph(&ctx, 5);
int thresh = sensor->findThreshold (&ctx, 30, buffer, len);
sensor->printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
@ -72,6 +72,8 @@ main(int argc, char** argv)
std::cout << "exiting application" << std::endl;
delete sensor;
return 0;
}
//! [Interesting]

26
examples/c++/gas-mq3.cxx
View File

@ -22,16 +22,16 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdint.h>
#include <stdio.h>
#include "gas.hpp"
#include "mq3.hpp"
#include <signal.h>
#include <stdlib.h>
#include <sys/time.h>
int is_running = 0;
uint16_t buffer[128];
uint16_t buffer [128];
upm::MQ3 *sensor = NULL;
void
sig_handler(int signo)
@ -44,26 +44,26 @@ sig_handler(int signo)
//! [Interesting]
int
main(int argc, char** argv)
main(int argc, char **argv)
{
// Attach gas sensor to A0
upm::MQ3 sensor(0);
sensor = new upm::MQ3(0);
signal(SIGINT, sig_handler);
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 milliseconds;
// find the average of 128 samples; and
// print a running graph of the averages using a resolution of 5
while (!is_running) {
int len = sensor.getSampledWindow(2, 128, buffer);
int len = sensor->getSampledWindow (2, 128, buffer);
if (len) {
int thresh = sensor.findThreshold(&ctx, 30, buffer, len);
sensor.printGraph(&ctx, 5);
int thresh = sensor->findThreshold (&ctx, 30, buffer, len);
sensor->printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
@ -72,6 +72,8 @@ main(int argc, char** argv)
std::cout << "exiting application" << std::endl;
delete sensor;
return 0;
}
//! [Interesting]

71
examples/c++/gas-mq4.cxx
View File

@ -22,12 +22,12 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdint.h>
#include "gas.hpp"
#include "mq4.hpp"
#include <signal.h>
#include <stdlib.h>
#include <sys/time.h>
bool shouldRun = true;
@ -36,43 +36,46 @@ using namespace std;
void
sig_handler(int signo)
{
if (signo == SIGINT) {
shouldRun = false;
if (signo == SIGINT)
{
shouldRun = false;
}
}
//! [Interesting]
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
// Attach gas sensor to Analog A0
upm::MQ4 sensor(0);
signal(SIGINT, sig_handler);
// Attach gas sensor to Analog A0
upm::MQ4 *sensor = new upm::MQ4(0);
signal(SIGINT, sig_handler);
uint16_t buffer [128];
uint16_t buffer[128];
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 microseconds;
// find the average of 128 samples; and
// print a running graph of asteriskss as averages
while (shouldRun) {
int len = sensor.getSampledWindow(2, 128, buffer);
if (len) {
int thresh = sensor.findThreshold(&ctx, 30, buffer, len);
sensor.printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 microseconds;
// find the average of 128 samples; and
// print a running graph of asteriskss as averages
while (shouldRun)
{
int len = sensor->getSampledWindow (2, 128, buffer);
if (len) {
int thresh = sensor->findThreshold (&ctx, 30, buffer, len);
sensor->printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
}
}
cout << "Exiting" << endl;
return 0;
cout << "Exiting" << endl;
delete sensor;
return 0;
}
//! [Interesting]

26
examples/c++/gas-mq5.cxx
View File

@ -22,16 +22,16 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdint.h>
#include <stdio.h>
#include "gas.hpp"
#include "mq5.hpp"
#include <signal.h>
#include <stdlib.h>
#include <sys/time.h>
int is_running = 0;
uint16_t buffer[128];
uint16_t buffer [128];
upm::MQ5 *sensor = NULL;
void
sig_handler(int signo)
@ -44,21 +44,21 @@ sig_handler(int signo)
//! [Interesting]
int
main(int argc, char** argv)
main(int argc, char **argv)
{
upm::MQ5 sensor(0);
sensor = new upm::MQ5(0);
signal(SIGINT, sig_handler);
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
ctx.averagedOver = 2;
while (!is_running) {
int len = sensor.getSampledWindow(2, 128, buffer);
int len = sensor->getSampledWindow (2, 128, buffer);
if (len) {
int thresh = sensor.findThreshold(&ctx, 30, buffer, len);
sensor.printGraph(&ctx, 7);
int thresh = sensor->findThreshold (&ctx, 30, buffer, len);
sensor->printGraph(&ctx, 7);
if (thresh) {
// do something ....
}
@ -67,6 +67,8 @@ main(int argc, char** argv)
std::cout << "exiting application" << std::endl;
delete sensor;
return 0;
}
//! [Interesting]

71
examples/c++/gas-mq6.cxx
View File

@ -22,12 +22,12 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdint.h>
#include "gas.hpp"
#include "mq6.hpp"
#include <signal.h>
#include <stdlib.h>
#include <sys/time.h>
bool shouldRun = true;
@ -36,43 +36,46 @@ using namespace std;
void
sig_handler(int signo)
{
if (signo == SIGINT) {
shouldRun = false;
if (signo == SIGINT)
{
shouldRun = false;
}
}
//! [Interesting]
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
// Attach gas sensor to Analog A0
upm::MQ6 sensor(0);
signal(SIGINT, sig_handler);
// Attach gas sensor to Analog A0
upm::MQ6 *sensor = new upm::MQ6(0);
signal(SIGINT, sig_handler);
uint16_t buffer [128];
uint16_t buffer[128];
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 microseconds;
// find the average of 128 samples; and
// print a running graph of asteriskss as averages
while (shouldRun) {
int len = sensor.getSampledWindow(2, 128, buffer);
if (len) {
int thresh = sensor.findThreshold(&ctx, 30, buffer, len);
sensor.printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 microseconds;
// find the average of 128 samples; and
// print a running graph of asteriskss as averages
while (shouldRun)
{
int len = sensor->getSampledWindow (2, 128, buffer);
if (len) {
int thresh = sensor->findThreshold (&ctx, 30, buffer, len);
sensor->printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
}
}
cout << "Exiting" << endl;
return 0;
cout << "Exiting" << endl;
delete sensor;
return 0;
}
//! [Interesting]

71
examples/c++/gas-mq7.cxx
View File

@ -22,12 +22,12 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdint.h>
#include "gas.hpp"
#include "mq7.hpp"
#include <signal.h>
#include <stdlib.h>
#include <sys/time.h>
bool shouldRun = true;
@ -36,43 +36,46 @@ using namespace std;
void
sig_handler(int signo)
{
if (signo == SIGINT) {
shouldRun = false;
if (signo == SIGINT)
{
shouldRun = false;
}
}
//! [Interesting]
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
// Attach gas sensor to Analog A0
upm::MQ7 sensor(0);
signal(SIGINT, sig_handler);
// Attach gas sensor to Analog A0
upm::MQ7 *sensor = new upm::MQ7(0);
signal(SIGINT, sig_handler);
uint16_t buffer [128];
uint16_t buffer[128];
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 microseconds;
// find the average of 128 samples; and
// print a running graph of asteriskss as averages
while (shouldRun) {
int len = sensor.getSampledWindow(2, 128, buffer);
if (len) {
int thresh = sensor.findThreshold(&ctx, 30, buffer, len);
sensor.printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 microseconds;
// find the average of 128 samples; and
// print a running graph of asteriskss as averages
while (shouldRun)
{
int len = sensor->getSampledWindow (2, 128, buffer);
if (len) {
int thresh = sensor->findThreshold (&ctx, 30, buffer, len);
sensor->printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
}
}
cout << "Exiting" << endl;
return 0;
cout << "Exiting" << endl;
delete sensor;
return 0;
}
//! [Interesting]

71
examples/c++/gas-mq8.cxx
View File

@ -22,12 +22,12 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdint.h>
#include "gas.hpp"
#include "mq8.hpp"
#include <signal.h>
#include <stdlib.h>
#include <sys/time.h>
bool shouldRun = true;
@ -36,43 +36,46 @@ using namespace std;
void
sig_handler(int signo)
{
if (signo == SIGINT) {
shouldRun = false;
if (signo == SIGINT)
{
shouldRun = false;
}
}
//! [Interesting]
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
// Attach gas sensor to Analog A0
upm::MQ8 sensor(0);
signal(SIGINT, sig_handler);
// Attach gas sensor to Analog A0
upm::MQ8 *sensor = new upm::MQ8(0);
signal(SIGINT, sig_handler);
uint16_t buffer [128];
uint16_t buffer[128];
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 microseconds;
// find the average of 128 samples; and
// print a running graph of asteriskss as averages
while (shouldRun) {
int len = sensor.getSampledWindow(2, 128, buffer);
if (len) {
int thresh = sensor.findThreshold(&ctx, 30, buffer, len);
sensor.printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
// Infinite loop, ends when script is cancelled
// Repeatedly, take a sample every 2 microseconds;
// find the average of 128 samples; and
// print a running graph of asteriskss as averages
while (shouldRun)
{
int len = sensor->getSampledWindow (2, 128, buffer);
if (len) {
int thresh = sensor->findThreshold (&ctx, 30, buffer, len);
sensor->printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
}
}
cout << "Exiting" << endl;
return 0;
cout << "Exiting" << endl;
delete sensor;
return 0;
}
//! [Interesting]

26
examples/c++/gas-mq9.cxx
View File

@ -22,16 +22,16 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdint.h>
#include <stdio.h>
#include "gas.hpp"
#include "mq9.hpp"
#include <signal.h>
#include <stdlib.h>
#include <sys/time.h>
int is_running = 0;
uint16_t buffer[128];
uint16_t buffer [128];
upm::MQ9 *sensor = NULL;
void
sig_handler(int signo)
@ -44,21 +44,21 @@ sig_handler(int signo)
//! [Interesting]
int
main(int argc, char** argv)
main(int argc, char **argv)
{
upm::MQ9 sensor(0);
sensor = new upm::MQ9(0);
signal(SIGINT, sig_handler);
thresholdContext ctx;
ctx.averageReading = 0;
ctx.runningAverage = 0;
ctx.averagedOver = 2;
ctx.averagedOver = 2;
while (!is_running) {
int len = sensor.getSampledWindow(2, 128, buffer);
int len = sensor->getSampledWindow (2, 128, buffer);
if (len) {
int thresh = sensor.findThreshold(&ctx, 30, buffer, len);
sensor.printGraph(&ctx, 5);
int thresh = sensor->findThreshold (&ctx, 30, buffer, len);
sensor->printGraph(&ctx, 5);
if (thresh) {
// do something ....
}
@ -67,6 +67,8 @@ main(int argc, char** argv)
std::cout << "exiting application" << std::endl;
delete sensor;
return 0;
}
//! [Interesting]

41
examples/c++/gas-tp401.cxx
View File

@ -22,13 +22,10 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <stdint.h>
#include <stdio.h>
#include <string>
#include <unistd.h>
#include <iostream>
#include "tp401.hpp"
#include "upm_utilities.h"
using namespace std;
@ -37,41 +34,37 @@ using namespace std;
std::string
airQuality(uint16_t value)
{
if (value < 50)
return "Fresh Air";
if (value < 200)
return "Normal Indoor Air";
if (value < 400)
return "Low Pollution";
if (value < 600)
return "High Pollution - Action Recommended";
if(value < 50) return "Fresh Air";
if(value < 200) return "Normal Indoor Air";
if(value < 400) return "Low Pollution";
if(value < 600) return "High Pollution - Action Recommended";
return "Very High Pollution - Take Action Immediately";
}
int
main()
int main ()
{
upm::TP401 airSensor(0);
upm::TP401* airSensor = new upm::TP401(0); // Instantiate new grove air quality sensor on analog pin A0
cout << airSensor.name() << endl;
cout << airSensor->name() << endl;
fprintf(stdout, "Heating sensor for 3 minutes...\n");
// wait 3 minutes for sensor to warm up
for (int i = 0; i < 3; i++) {
if (i) {
for(int i = 0; i < 3; i++) {
if(i) {
fprintf(stdout, "Please wait, %d minute(s) passed..\n", i);
}
upm_delay(60);
sleep(60);
}
fprintf(stdout, "Sensor ready!\n");
while (true) {
uint16_t value = airSensor.getSample(); // Read raw value
float ppm = airSensor.getPPM(); // Read CO ppm (can vary slightly from previous read)
while(true) {
uint16_t value = airSensor->getSample(); // Read raw value
float ppm = airSensor->getPPM(); // Read CO ppm (can vary slightly from previous read)
fprintf(stdout, "raw: %4d ppm: %5.2f %s\n", value, ppm, airQuality(value).c_str());
upm_delay_us(2500000); // Sleep for 2.5s
usleep(2500000); // Sleep for 2.5s
}
delete airSensor;
return 0;
}
//! [Interesting]

56
examples/c++/gp2y0a.cxx
View File

@ -22,52 +22,52 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "gp2y0a.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
// analog voltage, usually 3.3 or 5.0
#define GP2Y0A_AREF 5.0
#define GP2Y0A_AREF 5.0
#define SAMPLES_PER_QUERY 20
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Note, for the Grove 80cm version of this sensor, due to the way
// it is wired, you need to plug this into the A0 port, where it
// will use the available A1 pin for data.
//! [Interesting]
// Note, for the Grove 80cm version of this sensor, due to the way
// it is wired, you need to plug this into the A0 port, where it
// will use the available A1 pin for data.
// Instantiate a GP2Y0A on analog pin A1
upm::GP2Y0A volts(1);
// The higher the voltage (closer to AREF) the closer the object is. NOTE:
// the measured voltage will probably not exceed 3.3 volts.
// Every second, print the averaged voltage value (averaged over 20 samples).
while (shouldRun) {
cout << "AREF: " << GP2Y0A_AREF << ", Voltage value (higher means closer): "
<< volts.value(GP2Y0A_AREF, SAMPLES_PER_QUERY) << endl;
upm_delay(1);
// Instantiate a GP2Y0A on analog pin A1
upm::GP2Y0A *volts = new upm::GP2Y0A(1);
// The higher the voltage (closer to AREF) the closer the object is. NOTE:
// the measured voltage will probably not exceed 3.3 volts.
// Every second, print the averaged voltage value (averaged over 20 samples).
while (shouldRun)
{
cout << "AREF: " << GP2Y0A_AREF
<< ", Voltage value (higher means closer): "
<< volts->value(GP2Y0A_AREF, SAMPLES_PER_QUERY) << endl;
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete volts;
return 0;
}

109
examples/c++/gprs.cxx
View File

@ -22,81 +22,90 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdio.h>
#include "gprs.hpp"
#include "upm_utilities.h"
using namespace std;
using namespace upm;
void
printUsage(char* progname)
void printUsage(char *progname)
{
cout << "Usage: " << progname << " [AT command]" << endl;
cout << endl;
cout << "Usage: " << progname << " [AT command]" << endl;
cout << endl;
cout << "If an argument is supplied on the command line, that argument is" << endl;
cout << "sent to the module and the response is printed out." << endl;
cout << endl;
cout << "If no argument is used, then the manufacturer and the current" << endl;
cout << "saved profiles are queried and the results printed out." << endl;
cout << endl;
cout << endl;
cout << "If an argument is supplied on the command line, that argument is"
<< endl;
cout << "sent to the module and the response is printed out." << endl;
cout << endl;
cout << "If no argument is used, then the manufacturer and the current"
<< endl;
cout << "saved profiles are queried and the results printed out." << endl;
cout << endl;
cout << endl;
}
// simple helper function to send a command and wait for a response
void
sendCommand(upm::GPRS& sensor, string cmd)
void sendCommand(upm::GPRS* sensor, string cmd)
{
// commands need to be terminated with a carriage return
cmd += "\r";
// commands need to be terminated with a carriage return
cmd += "\r";
sensor.writeDataStr(cmd);
// wait up to 1 second
if (sensor.dataAvailable(1000)) {
cout << "Returned: " << sensor.readDataStr(1024) << endl;
} else {
cerr << "Timed out waiting for response" << endl;
sensor->writeDataStr(cmd);
// wait up to 1 second
if (sensor->dataAvailable(1000))
{
cout << "Returned: " << sensor->readDataStr(1024) << endl;
}
else
{
cerr << "Timed out waiting for response" << endl;
}
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
//! [Interesting]
//! [Interesting]
// Instantiate a GPRS Module on UART 0
upm::GPRS sensor(0);
// Instantiate a GPRS Module on UART 0
upm::GPRS* sensor = new upm::GPRS(0);
// Set the baud rate, 19200 baud is the default.
if (sensor.setBaudRate(19200) != 0) {
cerr << "Failed to set tty baud rate" << endl;
return 1;
// Set the baud rate, 19200 baud is the default.
if (sensor->setBaudRate(19200) != mraa::SUCCESS)
{
cerr << "Failed to set tty baud rate" << endl;
return 1;
}
printUsage(argv[0]);
printUsage(argv[0]);
if (argc > 1) {
cout << "Sending command line argument (" << argv[1] << ")..." << endl;
sendCommand(sensor, argv[1]);
} else {
// query the module manufacturer
cout << "Querying module manufacturer (AT+CGMI)..." << endl;
sendCommand(sensor, "AT+CGMI");
if (argc > 1)
{
cout << "Sending command line argument (" << argv[1] << ")..." << endl;
sendCommand(sensor, argv[1]);
}
else
{
// query the module manufacturer
cout << "Querying module manufacturer (AT+CGMI)..." << endl;
sendCommand(sensor, "AT+CGMI");
upm_delay(1);
sleep(1);
// query the saved profiles
cout << "Querying the saved profiles (AT&V)..." << endl;
sendCommand(sensor, "AT&V");
// query the saved profiles
cout << "Querying the saved profiles (AT&V)..." << endl;
sendCommand(sensor, "AT&V");
// A comprehensive list is available from the datasheet at:
// http://www.seeedstudio.com/wiki/images/7/72/AT_Commands_v1.11.pdf
// A comprehensive list is available from the datasheet at:
// http://www.seeedstudio.com/wiki/images/7/72/AT_Commands_v1.11.pdf
}
//! [Interesting]
//! [Interesting]
return 0;
}
delete sensor;
return 0;
}

21
examples/c++/grove-grovebutton.cxx
View File

@ -22,29 +22,28 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <string>
#include "grovebutton.hpp"
#include "upm_utilities.h"
#include "grove.hpp"
int
main(int argc, char** argv)
main(int argc, char **argv)
{
// This example uses GPIO 0
//! [Interesting]
//! [Interesting]
// Create the button object using GPIO pin 0
upm::GroveButton button(0);
upm::GroveButton* button = new upm::GroveButton(0);
// Read the input and print, waiting one second between readings
while (1) {
std::cout << button.name() << " value is " << button.value() << std::endl;
upm_delay(1);
while( 1 ) {
std::cout << button->name() << " value is " << button->value() << std::endl;
sleep(1);
}
// Delete the button object
//! [Interesting]
delete button;
//! [Interesting]
return 0;
}

52
examples/c++/grove-groveled-multi.cxx
View File

@ -22,47 +22,47 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "groveled.hpp"
#include "upm_utilities.h"
#include "grove.hpp"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
//! [Interesting]
// Instantiate a grove LED on D2. Here we are controlling a Grove
// Multi-color flash LED. We just just need to turn it on - it will
// then cycle through various colors (red, green, blue, purple) on it's
// own until turned off.
upm::GroveLed led(2);
// Instantiate a grove LED on D2. Here we are controlling a Grove
// Multi-color flash LED. We just just need to turn it on - it will
// then cycle through various colors (red, green, blue, purple) on it's
// own until turned off.
upm::GroveLed* led = new upm::GroveLed(2);
// start the light show
led.on();
// start the light show
led->on();
// just upm_delay until interrupted
while (shouldRun)
upm_delay(1);
// just sleep until interrupted
while (shouldRun)
sleep(1);
//! [Interesting]
//! [Interesting]
led->off();
cout << "Exiting..." << endl;
led.off();
cout << "Exiting..." << endl;
return 0;
delete led;
return 0;
}

27
examples/c++/grove-groveled.cxx
View File

@ -23,34 +23,33 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <string>
#include "groveled.hpp"
#include "upm_utilities.h"
#include "grove.hpp"
int
main(int argc, char** argv)
main(int argc, char **argv)
{
//! [Interesting]
//! [Interesting]
// Create the Grove LED object using GPIO pin 2
upm::GroveLed led(2);
upm::GroveLed* led = new upm::GroveLed(2);
// Print the name
std::cout << led.name() << std::endl;
std::cout << led->name() << std::endl;
// Turn the LED on and off 10 times, pausing one second
// between transitions
for (int i = 0; i < 10; i++) {
led.on();
upm_delay(1);
led.off();
upm_delay(1);
for (int i=0; i < 10; i++) {
led->on();
sleep(1);
led->off();
sleep(1);
}
// Delete the Grove LED object
//! [Interesting]
delete led;
//! [Interesting]
return 0;
}

23
examples/c++/grove-grovelight.cxx
View File

@ -23,28 +23,27 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <string>
#include "grovelight.hpp"
#include "upm_utilities.h"
#include "grove.hpp"
int
main(int argc, char** argv)
main(int argc, char **argv)
{
//! [Interesting]
//! [Interesting]
// Create the light sensor object using AIO pin 0
upm::GroveLight light(0);
upm::GroveLight* light = new upm::GroveLight(0);
// Read the input and print both the raw value and a rough lux value,
// waiting one second between readings
while (1) {
std::cout << light.name() << " raw value is " << light.raw_value() << ", which is roughly "
<< light.value() << " lux" << std::endl;
upm_delay(1);
while( 1 ) {
std::cout << light->name() << " raw value is " << light->raw_value() <<
", which is roughly " << light->value() << " lux" << std::endl;
sleep(1);
}
// Delete the light sensor object
//! [Interesting]
delete light;
//! [Interesting]
return 0;
}

33
examples/c++/grove-groverelay.cxx
View File

@ -22,38 +22,37 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <string>
#include "groverelay.hpp"
#include "upm_utilities.h"
#include "grove.hpp"
int
main(int argc, char** argv)
main(int argc, char **argv)
{
// This example uses GPIO 0
//! [Interesting]
//! [Interesting]
// Create the relay switch object using GPIO pin 0
upm::GroveRelay relay(0);
upm::GroveRelay* relay = new upm::GroveRelay(0);
// Close and then open the relay switch 3 times,
// waiting one second each time. The LED on the relay switch
// will light up when the switch is on (closed).
// The switch will also make a noise between transitions.
for (int i = 0; i < 3; i++) {
relay.on();
if (relay.isOn())
std::cout << relay.name() << " is on" << std::endl;
upm_delay(1);
relay.off();
if (relay.isOff())
std::cout << relay.name() << " is off" << std::endl;
upm_delay(1);
for ( int i = 0; i < 3; i++ ) {
relay->on();
if ( relay->isOn() )
std::cout << relay->name() << " is on" << std::endl;
sleep(1);
relay->off();
if ( relay->isOff() )
std::cout << relay->name() << " is off" << std::endl;
sleep(1);
}
// Delete the relay switch object
//! [Interesting]
delete relay;
//! [Interesting]
return 0;
}

48
examples/c++/grove-groverotary.cxx
View File

@ -22,46 +22,36 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <stdint.h>
#include <stdio.h>
#include <string>
#include "groverotary.hpp"
#include "upm_utilities.h"
#include <iomanip>
#include "grove.hpp"
using namespace std;
int
main()
int main ()
{
//! [Interesting]
//! [Interesting]
// Instantiate a rotary sensor on analog pin A0
upm::GroveRotary knob(0);
upm::GroveRotary* knob = new upm::GroveRotary(0);
// Print sensor name to confirm it initialized properly
cout << knob.name() << endl;
cout << knob->name() << endl;
while (true) {
float abs_value = knob.abs_value(); // Absolute raw value
float abs_deg = knob.abs_deg(); // Absolute degrees
float abs_rad = knob.abs_rad(); // Absolute radians
float rel_value = knob.rel_value(); // Relative raw value
float rel_deg = knob.rel_deg(); // Relative degrees
float rel_rad = knob.rel_rad(); // Relative radians
while(true) {
float abs_value = knob->abs_value(); // Absolute raw value
float abs_deg = knob->abs_deg(); // Absolute degrees
float abs_rad = knob->abs_rad(); // Absolute radians
float rel_value = knob->rel_value(); // Relative raw value
float rel_deg = knob->rel_deg(); // Relative degrees
float rel_rad = knob->rel_rad(); // Relative radians
fprintf(stdout,
"Absolute: %4d raw %5.2f deg = %3.2f rad Relative: %4d raw %5.2f "
"deg %3.2f rad\n",
(int16_t) abs_value,
abs_deg,
abs_rad,
(int16_t) rel_value,
rel_deg,
rel_rad);
fprintf(stdout, "Absolute: %4d raw %5.2f deg = %3.2f rad Relative: %4d raw %5.2f deg %3.2f rad\n",
(int16_t)abs_value, abs_deg, abs_rad, (int16_t)rel_value, rel_deg, rel_rad);
upm_delay_us(2500000); // Sleep for 2.5s
usleep(2500000); // Sleep for 2.5s
}
//! [Interesting]
//! [Interesting]
delete knob;
return 0;
}

32
examples/c++/grove-groveslide.cxx
View File

@ -22,31 +22,29 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <stdint.h>
#include <stdio.h>
#include <string>
#include "groveslide.hpp"
#include "upm_utilities.h"
#include <unistd.h>
#include <iostream>
#include <iomanip>
#include "grove.hpp"
using namespace std;
int
main()
int main ()
{
//! [Interesting]
upm::GroveSlide slide(0);
//! [Interesting]
upm::GroveSlide* slide = new upm::GroveSlide(0); // Instantiate new grove slide potentiometer on analog pin A0
cout << slide.name() << endl;
cout << slide->name() << endl;
while (true) {
float adc_value = slide.raw_value(); // Read raw value
float volts = slide.voltage_value(); // Read voltage, board reference set at 5.0V
fprintf(stdout, "%4d = %.2f V\n", (uint16_t) adc_value, volts);
while(true) {
float adc_value = slide->raw_value(); // Read raw value
float volts = slide->voltage_value(); // Read voltage, board reference set at 5.0V
fprintf(stdout, "%4d = %.2f V\n", (uint16_t)adc_value, volts);
upm_delay_us(2500000); // Sleep for 2.5s
usleep(2500000); // Sleep for 2.5s
}
//! [Interesting]
//! [Interesting]
delete slide;
return 0;
}

30
examples/c++/grove-grovetemp.cxx
View File

@ -23,33 +23,33 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <stdio.h>
#include <string>
#include "grovetemp.hpp"
#include "upm_utilities.h"
#include <iomanip>
#include "grove.hpp"
int
main(int argc, char** argv)
main(int argc, char **argv)
{
//! [Interesting]
//! [Interesting]
// Create the temperature sensor object using AIO pin 0
upm::GroveTemp temp(0);
std::cout << temp.name() << std::endl;
upm::GroveTemp* temp = new upm::GroveTemp(0);
std::cout << temp->name() << std::endl;
// Read the temperature ten times, printing both the Celsius and
// equivalent Fahrenheit temperature, waiting one second between readings
for (int i = 0; i < 10; i++) {
int celsius = temp.value();
int fahrenheit = (int) (celsius * 9.0 / 5.0 + 32.0);
printf("%d degrees Celsius, or %d degrees Fahrenheit\n", celsius, fahrenheit);
upm_delay(1);
for (int i=0; i < 10; i++) {
int celsius = temp->value();
int fahrenheit = (int) (celsius * 9.0/5.0 + 32.0);
printf("%d degrees Celsius, or %d degrees Fahrenheit\n",
celsius, fahrenheit);
sleep(1);
}
// Delete the temperature sensor object
//! [Interesting]
delete temp;
//! [Interesting]
return 0;
}

55
examples/c++/grovecollision.cxx
View File

@ -22,45 +22,48 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <unistd.h>
#include <signal.h>
#include "grovecollision.hpp"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// The was tested with the Grove Collision Sensor
// Instantiate a Grove Collision on digital pin D2
upm::GroveCollision collision(2);
//! [Interesting]
// The was tested with the Grove Collision Sensor
// Instantiate a Grove Collision on digital pin D2
upm::GroveCollision* collision = new upm::GroveCollision(2);
bool collisionState = false;
cout << "No collision" << endl;
while (shouldRun) {
if (collision.isColliding() && !collisionState) {
cout << "Collision!" << endl;
collisionState = true;
} else if (collisionState) {
cout << "No collision" << endl;
collisionState = false;
}
}
bool collisionState = false;
cout << "No collision" << endl;
while (shouldRun)
{
if (collision->isColliding() && !collisionState)
{
cout << "Collision!" << endl;
collisionState = true;
}
else if (collisionState)
{
cout << "No collision" << endl;
collisionState = false;
}
}
//! [Interesting]
cout << "Exiting" << endl;
//! [Interesting]
cout << "Exiting" << endl;
return 0;
delete collision;
return 0;
}

64
examples/c++/groveehr.cxx
View File

@ -22,57 +22,57 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "groveehr.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a Grove Ear-clip Heart Rate sensor on digital pin D2
upm::GroveEHR heart(2);
//! [Interesting]
// Instantiate a Grove Ear-clip Heart Rate sensor on digital pin D2
upm::GroveEHR* heart = new upm::GroveEHR(2);
// set the beat counter to 0, init the clock and start counting beats
heart->clearBeatCounter();
heart->initClock();
heart->startBeatCounter();
// set the beat counter to 0, init the clock and start counting beats
heart.clearBeatCounter();
heart.initClock();
heart.startBeatCounter();
while (shouldRun)
{
// we grab these just for display purposes in this example
uint32_t millis = heart->getMillis();
uint32_t beats = heart->beatCounter();
while (shouldRun) {
// we grab these just for display purposes in this example
uint32_t millis = heart.getMillis();
uint32_t beats = heart.beatCounter();
// heartRate() requires that at least 5 seconds pass before
// returning anything other than 0
int hr = heart->heartRate();
// heartRate() requires that at least 5 seconds pass before
// returning anything other than 0
int hr = heart.heartRate();
// output milliseconds passed, beat count, and computed heart rate
cout << "Millis: " << millis << " Beats: " << beats;
cout << " Heart Rate: " << hr << endl;
// output milliseconds passed, beat count, and computed heart rate
cout << "Millis: " << millis << " Beats: " << beats;
cout << " Heart Rate: " << hr << endl;
upm_delay(1);
sleep(1);
}
heart.stopBeatCounter();
//! [Interesting]
heart->stopBeatCounter();
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete heart;
return 0;
}

51
examples/c++/groveeldriver.cxx
View File

@ -22,46 +22,45 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <unistd.h>
#include <signal.h>
#include "groveeldriver.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// The was tested with the Grove El Driver Module
// Instantiate a Grove El Driver on digital pin D2
upm::GroveElDriver eldriver(2);
//! [Interesting]
// The was tested with the Grove El Driver Module
// Instantiate a Grove El Driver on digital pin D2
upm::GroveElDriver* eldriver = new upm::GroveElDriver(2);
bool lightState = true;
bool lightState = true;
while (shouldRun) {
if (lightState)
eldriver.on();
else
eldriver.off();
lightState = !lightState;
upm_delay(1);
}
while (shouldRun)
{
if (lightState)
eldriver->on();
else
eldriver->off();
lightState = !lightState;
sleep(1);
}
//! [Interesting]
eldriver.off();
cout << "Exiting" << endl;
//! [Interesting]
eldriver->off();
cout << "Exiting" << endl;
return 0;
delete eldriver;
return 0;
}

72
examples/c++/groveelectromagnet.cxx
View File

@ -22,60 +22,58 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <iostream>
#include <signal.h>
#include <sys/time.h>
#include <time.h>
#include <signal.h>
#include "groveelectromagnet.hpp"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
float
get_time()
float get_time()
{
return ((float) (clock())) / CLOCKS_PER_SEC;
return ((float)(clock()))/CLOCKS_PER_SEC;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// The was tested with the Grove Electromagnetic Module
// Instantiate a Grove Electromagnet on digital pin D2
upm::GroveElectromagnet magnet(2);
cout << "Starting up magnet...." << endl;
magnet.off();
//! [Interesting]
// The was tested with the Grove Electromagnetic Module
// Instantiate a Grove Electromagnet on digital pin D2
upm::GroveElectromagnet* magnet = new upm::GroveElectromagnet(2);
cout << "Starting up magnet...." << endl;
magnet->off();
bool magnetState = false;
float time_passed = get_time();
bool magnetState = false;
float time_passed = get_time();
// Turn magnet on and off every 5 seconds
while (shouldRun) {
if ((get_time() - time_passed) > 5.0) {
magnetState = !magnetState;
if (magnetState)
magnet.on();
else
magnet.off();
cout << "Turning magnet " << ((magnetState) ? "on" : "off") << endl;
time_passed = get_time();
}
}
// Turn magnet on and off every 5 seconds
while (shouldRun)
{
if ((get_time() - time_passed) > 5.0)
{
magnetState = !magnetState;
if (magnetState)
magnet->on();
else
magnet->off();
cout << "Turning magnet " << ((magnetState) ? "on" : "off") << endl;
time_passed = get_time();
}
}
//! [Interesting]
magnet.off();
cout << "Exiting" << endl;
//! [Interesting]
magnet->off();
cout << "Exiting" << endl;
return 0;
delete magnet;
return 0;
}

45
examples/c++/groveemg.cxx
View File

@ -21,41 +21,40 @@
* OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "groveemg.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// The was tested with the GroveEMG Muscle Signal Reader Sensor Module
// Instantiate a GroveEMG on analog pin A0
upm::GroveEMG emg(0);
cout << "Calibrating...." << endl;
emg.calibrate();
//! [Interesting]
// The was tested with the GroveEMG Muscle Signal Reader Sensor Module
// Instantiate a GroveEMG on analog pin A0
upm::GroveEMG *emg = new upm::GroveEMG(0);
cout << "Calibrating...." << endl;
emg->calibrate();
while (shouldRun)
{
cout << emg->value() << endl;
usleep(100000);
}
while (shouldRun) {
cout << emg.value() << endl;
upm_delay_us(100000);
}
//! [Interesting]
cout << "Exiting" << endl;
return 0;
//! [Interesting]
cout << "Exiting" << endl;
delete emg;
return 0;
}

107
examples/c++/grovegprs.cxx
View File

@ -22,81 +22,90 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include <stdio.h>
#include "grovegprs.hpp"
#include "upm_utilities.h"
using namespace std;
using namespace upm;
void
printUsage(char* progname)
void printUsage(char *progname)
{
cout << "Usage: " << progname << " [AT command]" << endl;
cout << endl;
cout << "Usage: " << progname << " [AT command]" << endl;
cout << endl;
cout << "If an argument is supplied on the command line, that argument is" << endl;
cout << "sent to the module and the response is printed out." << endl;
cout << endl;
cout << "If no argument is used, then the manufacturer and the current" << endl;
cout << "saved profiles are queried and the results printed out." << endl;
cout << endl;
cout << endl;
cout << "If an argument is supplied on the command line, that argument is"
<< endl;
cout << "sent to the module and the response is printed out." << endl;
cout << endl;
cout << "If no argument is used, then the manufacturer and the current"
<< endl;
cout << "saved profiles are queried and the results printed out." << endl;
cout << endl;
cout << endl;
}
// simple helper function to send a command and wait for a response
void
sendCommand(upm::GroveGPRS& sensor, string cmd)
void sendCommand(upm::GroveGPRS* sensor, string cmd)
{
// commands need to be terminated with a carriage return
cmd += "\r";
// commands need to be terminated with a carriage return
cmd += "\r";
sensor.writeDataStr(cmd);
// wait up to 1 second
if (sensor.dataAvailable(1000)) {
cout << "Returned: " << sensor.readDataStr(1024) << endl;
} else {
cerr << "Timed out waiting for response" << endl;
sensor->writeDataStr(cmd);
// wait up to 1 second
if (sensor->dataAvailable(1000))
{
cout << "Returned: " << sensor->readDataStr(1024) << endl;
}
else
{
cerr << "Timed out waiting for response" << endl;
}
}
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
//! [Interesting]
//! [Interesting]
// Instantiate a GroveGPRS Module on UART 0
upm::GroveGPRS sensor(0);
// Instantiate a GroveGPRS Module on UART 0
upm::GroveGPRS* sensor = new upm::GroveGPRS(0);
// Set the baud rate, 19200 baud is the default.
if (sensor.setBaudRate(19200) != 0) {
cerr << "Failed to set tty baud rate" << endl;
return 1;
// Set the baud rate, 19200 baud is the default.
if (sensor->setBaudRate(19200) != mraa::SUCCESS)
{
cerr << "Failed to set tty baud rate" << endl;
return 1;
}
printUsage(argv[0]);
printUsage(argv[0]);
if (argc > 1) {
cout << "Sending command line argument (" << argv[1] << ")..." << endl;
sendCommand(sensor, argv[1]);
} else {
// query the module manufacturer
cout << "Querying module manufacturer (AT+CGMI)..." << endl;
sendCommand(sensor, "AT+CGMI");
if (argc > 1)
{
cout << "Sending command line argument (" << argv[1] << ")..." << endl;
sendCommand(sensor, argv[1]);
}
else
{
// query the module manufacturer
cout << "Querying module manufacturer (AT+CGMI)..." << endl;
sendCommand(sensor, "AT+CGMI");
upm_delay(1);
sleep(1);
// query the saved profiles
cout << "Querying the saved profiles (AT&V)..." << endl;
sendCommand(sensor, "AT&V");
// query the saved profiles
cout << "Querying the saved profiles (AT&V)..." << endl;
sendCommand(sensor, "AT&V");
// A comprehensive list is available from the datasheet at:
// http://www.seeedstudio.com/wiki/images/7/72/AT_Commands_v1.11.pdf
// A comprehensive list is available from the datasheet at:
// http://www.seeedstudio.com/wiki/images/7/72/AT_Commands_v1.11.pdf
}
//! [Interesting]
//! [Interesting]
return 0;
delete sensor;
return 0;
}

43
examples/c++/grovegsr.cxx
View File

@ -22,43 +22,42 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "grovegsr.hpp"
#include "upm_utilities.h"
using namespace std;
bool shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// The was tested with the GroveGSR Galvanic Skin Response Sensor module.
//! [Interesting]
// The was tested with the GroveGSR Galvanic Skin Response Sensor module.
// Instantiate a GroveGSR on analog pin A0
upm::GroveGSR gsr(0);
cout << "Calibrating...." << endl;
gsr.calibrate();
// Instantiate a GroveGSR on analog pin A0
upm::GroveGSR *gsr = new upm::GroveGSR(0);
cout << "Calibrating...." << endl;
gsr->calibrate();
while (shouldRun) {
cout << gsr.value() << endl;
upm_delay_us(500000);
}
//! [Interesting]
while (shouldRun)
{
cout << gsr->value() << endl;
usleep(500000);
}
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete gsr;
return 0;
}

48
examples/c++/grovelinefinder.cxx
View File

@ -22,45 +22,45 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "grovelinefinder.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main ()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a Grove Line Finder sensor on digital pin D2
upm::GroveLineFinder finder(2);
//! [Interesting]
// Instantiate a Grove Line Finder sensor on digital pin D2
upm::GroveLineFinder* finder = new upm::GroveLineFinder(2);
// check every second for the presence of white detection
while (shouldRun)
{
bool val = finder->whiteDetected();
if (val)
cout << "White detected." << endl;
else
cout << "Black detected." << endl;
// check every second for the presence of white detection
while (shouldRun) {
bool val = finder.whiteDetected();
if (val)
cout << "White detected." << endl;
else
cout << "Black detected." << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete finder;
return 0;
}

49
examples/c++/grovemd-stepper.cxx
View File

@ -22,44 +22,45 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <signal.h>
#include <iostream>
#include "grovemd.hpp"
#include "upm_utilities.h"
using namespace std;
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
//! [Interesting]
// Instantiate an I2C Grove Motor Driver on I2C bus 0
//! [Interesting]
// Instantiate an I2C Grove Motor Driver on I2C bus 0
upm::GroveMD motors(GROVEMD_I2C_BUS, GROVEMD_DEFAULT_I2C_ADDR);
upm::GroveMD *motors = new upm::GroveMD(GROVEMD_I2C_BUS,
GROVEMD_DEFAULT_I2C_ADDR);
// This example demonstrates using the GroveMD to drive a stepper motor
// This example demonstrates using the GroveMD to drive a stepper motor
// configure it, for this example, we'll assume 200 steps per rev
motors->configStepper(200);
// configure it, for this example, we'll assume 200 steps per rev
motors.configStepper(200);
// set for half a rotation
motors->setStepperSteps(100);
// set for half a rotation
motors.setStepperSteps(100);
// let it go - clockwise rotation, 10 RPM speed
motors->enableStepper(upm::GroveMD::STEP_DIR_CW, 10);
// let it go - clockwise rotation, 10 RPM speed
motors.enableStepper(upm::GroveMD::STEP_DIR_CW, 10);
sleep(3);
upm_delay(3);
// Now do it backwards...
motors->setStepperSteps(100);
motors->enableStepper(upm::GroveMD::STEP_DIR_CCW, 10);
// Now do it backwards...
motors.setStepperSteps(100);
motors.enableStepper(upm::GroveMD::STEP_DIR_CCW, 10);
// now disable
motors->disableStepper();
// now disable
motors.disableStepper();
//! [Interesting]
//! [Interesting]
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete motors;
return 0;
}

45
examples/c++/grovemd.cxx
View File

@ -22,38 +22,39 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <signal.h>
#include <iostream>
#include "grovemd.hpp"
#include "upm_utilities.h"
using namespace std;
int
main(int argc, char** argv)
int main(int argc, char **argv)
{
//! [Interesting]
// Instantiate an I2C Grove Motor Driver on I2C bus 0
//! [Interesting]
// Instantiate an I2C Grove Motor Driver on I2C bus 0
upm::GroveMD motors(GROVEMD_I2C_BUS, GROVEMD_DEFAULT_I2C_ADDR);
upm::GroveMD *motors = new upm::GroveMD(GROVEMD_I2C_BUS,
GROVEMD_DEFAULT_I2C_ADDR);
// set direction to CW and set speed to 50%
cout << "Spin M1 and M2 at half speed for 3 seconds" << endl;
motors.setMotorDirections(upm::GroveMD::DIR_CW, upm::GroveMD::DIR_CW);
motors.setMotorSpeeds(127, 127);
// set direction to CW and set speed to 50%
cout << "Spin M1 and M2 at half speed for 3 seconds" << endl;
motors->setMotorDirections(upm::GroveMD::DIR_CW, upm::GroveMD::DIR_CW);
motors->setMotorSpeeds(127, 127);
sleep(3);
// counter clockwise
cout << "Reversing M1 and M2 for 3 seconds" << endl;
motors->setMotorDirections(upm::GroveMD::DIR_CCW, upm::GroveMD::DIR_CCW);
sleep(3);
upm_delay(3);
// counter clockwise
cout << "Reversing M1 and M2 for 3 seconds" << endl;
motors.setMotorDirections(upm::GroveMD::DIR_CCW, upm::GroveMD::DIR_CCW);
upm_delay(3);
//! [Interesting]
//! [Interesting]
cout << "Stopping motors" << endl;
motors->setMotorSpeeds(0, 0);
cout << "Stopping motors" << endl;
motors.setMotorSpeeds(0, 0);
cout << "Exiting..." << endl;
cout << "Exiting..." << endl;
return 0;
delete motors;
return 0;
}

64
examples/c++/grovemoisture.cxx
View File

@ -22,54 +22,54 @@
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include <unistd.h>
#include <iostream>
#include <signal.h>
#include "grovemoisture.hpp"
#include "upm_utilities.h"
using namespace std;
int shouldRun = true;
void
sig_handler(int signo)
void sig_handler(int signo)
{
if (signo == SIGINT)
shouldRun = false;
if (signo == SIGINT)
shouldRun = false;
}
int
main()
int main ()
{
signal(SIGINT, sig_handler);
signal(SIGINT, sig_handler);
//! [Interesting]
// Instantiate a Grove Moisture sensor on analog pin A0
upm::GroveMoisture moisture(0);
//! [Interesting]
// Instantiate a Grove Moisture sensor on analog pin A0
upm::GroveMoisture* moisture = new upm::GroveMoisture(0);
// Values (approximate):
// 0-300, sensor in air or dry soil
// 300-600, sensor in humid soil
// 600+, sensor in wet soil or submerged in water.
// Read the value every second and print the corresponding moisture level
while (shouldRun)
{
int val = moisture->value();
cout << "Moisture value: " << val << ", ";
if (val >= 0 && val < 300)
cout << "dry";
else if (val >= 300 && val < 600)
cout << "moist";
else
cout << "wet";
// Values (approximate):
// 0-300, sensor in air or dry soil
// 300-600, sensor in humid soil
// 600+, sensor in wet soil or submerged in water.
// Read the value every second and print the corresponding moisture level
while (shouldRun) {
int val = moisture.value();
cout << "Moisture value: " << val << ", ";
if (val >= 0 && val < 300)
cout << "dry";
else if (val >= 300 && val < 600)
cout << "moist";
else
cout << "wet";
cout << endl;
cout << endl;
upm_delay(1);
sleep(1);
}
//! [Interesting]
//! [Interesting]
cout << "Exiting" << endl;
cout << "Exiting" << endl;
return 0;
delete moisture;
return 0;
}

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