The NFC plugin allows you to read and write NFC tags. You can also beam to, and receive from, other NFC enabled devices.
Use to
This plugin uses NDEF (NFC Data Exchange Format) for maximum compatibilty between NFC devices, tag types, and operating systems.
$ cordova plugin add phonegap-nfc
$ phonegap plugin add phonegap-nfc
Edit config.xml to install the plugin for PhoneGap Build.
<preference name="phonegap-version" value="cli-9.0.0" />
<plugin name="phonegap-nfc" source="npm" />
Windows Phone 8.1 should use the windows platform. The Silverlight based Windows Phone 8 code is no longer being maintained.
BlackBerry 7 support is only available for Cordova 2.x. For applications targeting BlackBerry 7, you may need to use an older version of phonegap-nfc.
See Getting Started and Getting Started BlackBerry 10for more details.
Reading NFC NDEF tags is supported on iPhone 7 (and newer) since iOS 11. iOS 13 added support for writing NDEF messages to NFC tags. iOS 13 also adds the ability to get the UID from some NFC tags. On iOS, the user must start a NFC session to scan for a tag. This is different from Android which can constantly scan for NFC tags. The nfc.scanNdef and nfc.scanTag functions start a NFC scanning session. The NFC tag is returned to the caller via a Promise. If your existing code uses the deprecated nfc.beginSession, update it to use nfc.scanNdef
.
The scanNdef
function uses NFCNDEFReaderSession to detect NFC Data Exchange Format (NDEF) tags. scanTag
uses the newer NFCTagReaderSession available in iOS 13 to detect ISO15693, FeliCa, and MIFARE tags. The scanTag
function will include the tag UID and tag type for some NFC tags along with the NDEF messages. scanTag
can also read some RFID tags without NDEF messsages. scanTag
will not scan some NDEF tags including Topaz and Mifare Classic.
You must call nfc.scanNdef and nfc.scanTag before every scan.
Writing NFC tags on iOS uses the same nfc.write function as other platforms. Although it's the same function, the behavior is different on iOS. Calling nfc.write
on an iOS device will start a new scanning session and write data to the scanned tag.
The nfc object provides access to the device's NFC sensor.
Registers an event listener for any NDEF tag.
nfc.addNdefListener(callback, [onSuccess], [onFailure]);
Function nfc.addNdefListener
registers the callback for ndef events.
A ndef event is fired when a NDEF tag is read.
For BlackBerry 10, you must configure the type of tags your application will read with an invoke-target in config.xml.
On Android registered mimeTypeListeners takes precedence over this more generic NDEF listener.
On iOS you must call beingSession before scanning a tag.
Removes the previously registered event listener for NDEF tags added via nfc.addNdefListener
.
nfc.removeNdefListener(callback, [onSuccess], [onFailure]);
Removing listeners is not recommended. Instead, consider that your callback can ignore messages you no longer need.
Registers an event listener for tags matching any tag type.
nfc.addTagDiscoveredListener(callback, [onSuccess], [onFailure]);
Function nfc.addTagDiscoveredListener
registers the callback for tag events.
This event occurs when any tag is detected by the phone.
Note that Windows Phones need the newere NXP PN427 chipset to read non-NDEF tags. That tag will be read, but no tag meta-data is available.
Removes the previously registered event listener added via nfc.addTagDiscoveredListener
.
nfc.removeTagDiscoveredListener(callback, [onSuccess], [onFailure]);
Removing listeners is not recommended. Instead, consider that your callback can ignore messages you no longer need.
Registers an event listener for NDEF tags matching a specified MIME type.
nfc.addMimeTypeListener(mimeType, callback, [onSuccess], [onFailure]);
Function nfc.addMimeTypeListener
registers the callback for ndef-mime events.
A ndef-mime event occurs when a Ndef.TNF_MIME_MEDIA
tag is read and matches the specified MIME type.
This function can be called multiple times to register different MIME types. You should use the same handler for all MIME messages.
nfc.addMimeTypeListener("text/json", *onNfc*, success, failure);
nfc.addMimeTypeListener("text/demo", *onNfc*, success, failure);
On Android, MIME types for filtering should always be lower case. (See IntentFilter.addDataType())
Removes the previously registered event listener added via nfc.addMimeTypeListener
.
nfc.removeMimeTypeListener(mimeType, callback, [onSuccess], [onFailure]);
Removing listeners is not recommended. Instead, consider that your callback can ignore messages you no longer need.
Registers an event listener for formatable NDEF tags.
nfc.addNdefFormatableListener(callback, [onSuccess], [onFailure]);
Function nfc.addNdefFormatableListener
registers the callback for ndef-formatable events.
A ndef-formatable event occurs when a tag is read that can be NDEF formatted. This is not fired for tags that are already formatted as NDEF. The ndef-formatable event will not contain an NdefMessage.
Writes an NDEF Message to a NFC tag.
A NDEF Message is an array of one or more NDEF Records
var message = [
ndef.textRecord("hello, world"),
ndef.uriRecord("http://github.com/chariotsolutions/phonegap-nfc")
];
nfc.write(message, [onSuccess], [onFailure]);
Function nfc.write
writes an NdefMessage to a NFC tag.
On Android this method must be called from within an NDEF Event Handler.
On iOS this method can be called outside the NDEF Event Handler, it will start a new scanning session. Optionally you can reuse the read session to write data. See example below.
On Windows this method may be called from within the NDEF Event Handler.
On Windows Phone 8.1 this method should be called outside the NDEF Event Handler, otherwise Windows tries to read the tag contents as you are writing to the tag.
On Android, write must be called inside an event handler
function onNfc(nfcEvent) {
console.log(nfcEvent.tag);
var message = [
ndef.textRecord(new String(new Date()))
];
nfc.write(
message,
success => console.log('wrote data to tag'),
error => console.log(error)
);
nfc.addNdefListener(onNfc);
Calling nfc.write
on iOS will create a new session and write data when the user taps a NFC tag
var message = [
ndef.textRecord("Hello, world")
];
nfc.write(
message,
success => console.log('wrote data to tag'),
error => console.log(error)
);
On iOS you can optionally write to NFC tag using the read session
try {
let tag = await nfc.scanNdef({ keepSessionOpen: true});
// you can read tag data here
console.log(tag);
// this example writes a new message with a timestamp
var message = [
ndef.textRecord(new String(new Date()))
];
nfc.write(
message,
success => console.log('wrote data to tag'),
error => console.log(error)
);
} catch (err) {
console.log(err);
}
Makes a NFC tag read only. Warning this is permanent.
nfc.makeReadOnly([onSuccess], [onFailure]);
Function nfc.makeReadOnly
make a NFC tag read only. Warning this is permanent and can not be undone.
On Android this method must be called from within an NDEF Event Handler.
Example usage
onNfc: function(nfcEvent) {
var record = [
ndef.textRecord("hello, world")
];
var failure = function(reason) {
alert("ERROR: " + reason);
};
var lockSuccess = function() {
alert("Tag is now read only.");
};
var lock = function() {
nfc.makeReadOnly(lockSuccess, failure);
};
nfc.write(record, lock, failure);
},
Shares an NDEF Message via peer-to-peer.
A NDEF Message is an array of one or more NDEF Records
var message = [
ndef.textRecord("hello, world")
];
nfc.share(message, [onSuccess], [onFailure]);
Function nfc.share
writes an NdefMessage via peer-to-peer. This should appear as an NFC tag to another device.
Android - shares message until unshare is called
Blackberry 10 - shares the message one time or until unshare is called
Windows Phone 8 - must be called from within a NFC event handler like nfc.write
Stop sharing NDEF data via peer-to-peer.
nfc.unshare([onSuccess], [onFailure]);
Function nfc.unshare
stops sharing data via peer-to-peer.
Erase a NDEF tag
nfc.erase([onSuccess], [onFailure]);
Function nfc.erase
erases a tag by writing an empty message. Will format unformatted tags before writing.
This method must be called from within an NDEF Event Handler.
Send a file to another device via NFC handover.
var uri = "content://media/external/audio/media/175";
nfc.handover(uri, [onSuccess], [onFailure]);
var uris = [
"content://media/external/audio/media/175",
"content://media/external/audio/media/176",
"content://media/external/audio/media/348"
];
nfc.handover(uris, [onSuccess], [onFailure]);
Function nfc.handover
shares files to a NFC peer using handover. Files are sent by specifying a file:// or context:// URI or a list of URIs. The file transfer is initiated with NFC but the transfer is completed with over Bluetooth or WiFi which is handled by a NFC handover request. The Android code is responsible for building the handover NFC Message.
This is Android only, but it should be possible to add implementations for other platforms.
Stop sharing NDEF data via NFC handover.
nfc.stopHandover([onSuccess], [onFailure]);
Function nfc.stopHandover
stops sharing data via peer-to-peer.
Show the NFC settings on the device.
nfc.showSettings(success, failure);
Function showSettings
opens the NFC settings for the operating system.
nfc.showSettings();
Check if NFC is available and enabled on this device.
nfc.enabled(onSuccess, onFailure);
Function nfc.enabled
explicitly checks to see if the phone has NFC and if NFC is enabled. If
everything is OK, the success callback is called. If there is a problem, the failure callback
will be called with a reason code.
The reason will be NO_NFC if the device doesn't support NFC and NFC_DISABLED if the user has disabled NFC.
Note: that on Android the NFC status is checked before every API call NO_NFC or NFC_DISABLED can be returned in any failure function.
Windows will return NO_NFC_OR_NFC_DISABLED when NFC is not present or disabled. If the user disabled NFC after the application started, Windows may return NFC_DISABLED. Windows checks the NFC status before most API calls, but there are some cases when the NFC state can not be determined.
beginSession
is deprecated. Use scanNdef
or scanTag
iOS requires you to begin a session before scanning a NFC tag.
nfc.beginSession(success, failure);
beginSession
is deprecated. Use scanNdef
or scanTag
Function beginSession
starts the NFCNDEFReaderSession allowing iOS to scan NFC tags. Use nfc.addNdefListener to receive the results of the scan.
nfc.beginSession();
invalidateSession
is deprecated. Use `cancelScan``.
Invalidate the NFC session.
nfc.invalidateSession(success, failure);
Function invalidateSession
stops the NFCNDEFReaderSession returning control to your app.
nfc.invalidateSession();
Calling scanNdef
will being an iOS NFC scanning session. The NFC tag will be returned in a Promise.
nfc.scanNdef();
Function scanNdef
starts the NFCNDEFReaderSession allowing iOS to scan NFC tags.
// Promise
nfc.scanNdef().then(
tag => console.log(JSON.stringify(tag)),
err => console.log(err)
);
// Async Await
try {
let tag = await nfc.scanNdef();
console.log(JSON.stringify(tag));
} catch (err) {
console.log(err);
}
Calling scanTag
will being an iOS NFC scanning session. The NFC tag will be returned in a Promise.
nfc.scanTag();
Function scanTag
starts the NFCTagReaderSession allowing iOS to scan NFC tags.
The Tag reader will attempt to get the UID from the NFC Tag. If can also read the UID from some non-NDEF tags.
Use scanNdef for reading NFC tags on iOS unless you need to get the tag UID.
// Promise
nfc.scanTag().then(
tag => {
console.log(JSON.stringify(tag))
if (tag.id) {
console.log(nfc.bytesToHexString(tag.id));
}
},
err => console.log(err)
);
// Async Await
try {
let tag = await nfc.scanTag();
console.log(JSON.stringify(tag));
if (tag.id) {
console.log(nfc.bytesToHexString(tag.id));
}
} catch (err) {
console.log(err);
}
Invalidate the NFC session started by scanNdef
or scanTag
.
nfc.cancelScan();
Function cancelScan
stops the NFCReaderSession returning control to your app.
nfc.cancelScan().then(
success => { console.log('Cancelled NFC session')},
err => { console.log(`Error cancelling session ${err}`)}
);
Read NFC tags sending the tag data to the success callback.
nfc.readerMode(flags, readCallback, errorCallback);
In reader mode, when a NFC tags is read, the results are returned to read callback as a tag object. Note that the normal event listeners are not used in reader mode. The callback receives the tag object without the event wrapper.
{
"isWritable": true,
"id": [4, 96, 117, 74, -17, 34, -128],
"techTypes": ["android.nfc.tech.IsoDep", "android.nfc.tech.NfcA", "android.nfc.tech.Ndef"],
"type": "NFC Forum Type 4",
"canMakeReadOnly": false,
"maxSize": 2046,
"ndefMessage": [{
"id": [],
"type": [116, 101, 120, 116, 47, 112, 103],
"payload": [72, 101, 108, 108, 111, 32, 80, 104, 111, 110, 101, 71, 97, 112],
"tnf": 2
}]
}
Foreground dispatching and peer-to-peer functions are disabled when reader mode is enabled.
The flags control which tags are scanned. One benefit to reader mode, is the system sounds can be disabled when a NFC tag is scanned by adding the nfc.FLAG_READER_NO_PLATFORM_SOUNDS flag. See Android's NfcAdapter.enableReaderMode() documentation for more info on the flags.
nfc.readerMode(
nfc.FLAG_READER_NFC_A | nfc.FLAG_READER_NO_PLATFORM_SOUNDS,
nfcTag => console.log(JSON.stringify(nfcTag)),
error => console.log('NFC reader mode failed', error)
);
Disable NFC reader mode.
nfc.disableNfcReaderMode(successCallback, errorCallback);
Disable NFC reader mode.
nfc.disableReaderMode(
() => console.log('NFC reader mode disabled'),
error => console.log('Error disabling NFC reader mode', error)
)
The tag technology functions provide access to I/O operations on a tag. Connect to a tag, send commands with transceive, close the tag. See the Android TagTechnology and implementations like IsoDep and NfcV for more details. These new APIs are promise based rather than using callbacks.
const DESFIRE_SELECT_PICC = '00 A4 04 00 07 D2 76 00 00 85 01 00';
const DESFIRE_SELECT_AID = '90 5A 00 00 03 AA AA AA 00'
async function handleDesfire(nfcEvent) {
const tagId = nfc.bytesToHexString(nfcEvent.tag.id);
console.log('Processing', tagId);
try {
await nfc.connect('android.nfc.tech.IsoDep', 500);
console.log('connected to', tagId);
let response = await nfc.transceive(DESFIRE_SELECT_PICC);
ensureResponseIs('9000', response);
response = await nfc.transceive(DESFIRE_SELECT_AID);
ensureResponseIs('9100', response);
// 91a0 means the requested application not found
alert('Selected application AA AA AA');
// more transcieve commands go here
} catch (error) {
alert(error);
} finally {
await nfc.close();
console.log('closed');
}
}
function ensureResponseIs(expectedResponse, buffer) {
const responseString = util.arrayBufferToHexString(buffer);
if (expectedResponse !== responseString) {
const error = 'Expecting ' + expectedResponse + ' but received ' + responseString;
throw error;
}
}
function onDeviceReady() {
nfc.addTagDiscoveredListener(handleDesfire);
}
document.addEventListener('deviceready', onDeviceReady, false);
Connect to the tag and enable I/O operations to the tag from this TagTechnology object.
nfc.connect(tech);
nfc.connect(tech, timeout);
Function connect
enables I/O operations to the tag from this TagTechnology object. nfc.connect
should be called after receiving a nfcEvent from the addTagDiscoveredListener
or the readerMode
callback. Only one TagTechnology object can be connected to a Tag at a time.
See Android's [TagTechnology.connect()](https://developer.android.com/reference/android/nfc/tech/TagTechnology.html#connect()) for more info.
nfc.addTagDiscoveredListener(function(nfcEvent) {
nfc.connect('android.nfc.tech.IsoDep', 500).then(
() => console.log('connected to', nfc.bytesToHexString(nfcEvent.tag.id)),
(error) => console.log('connection failed', error)
);
})
Send raw command to the tag and receive the response.
nfc.transceive(data);
Function transceive
sends raw commands to the tag and receives the response. nfc.connect
must be called before calling transceive
. Data passed to transceive can be a hex string representation of bytes or an ArrayBuffer. The response is returned as an ArrayBuffer in the promise.
See Android's documentation IsoDep.transceive(), NfcV.transceive(), MifareUltralight.transceive() for more info.
// Promise style
nfc.transceive('90 5A 00 00 03 AA AA AA 00').then(
response => console.log(util.arrayBufferToHexString(response)),
error => console.log('Error selecting DESFire application')
)
// async await
const response = await nfc.transceive('90 5A 00 00 03 AA AA AA 00');
console.log('response =',util.arrayBufferToHexString(response));
Close TagTechnology connection.
nfc.close();
Function close
disabled I/O operations to the tag from this TagTechnology object, and releases resources.
See Android's [TagTechnology.close()](https://developer.android.com/reference/android/nfc/tech/TagTechnology.html#close()) for more info.
nfc.transceive().then(
() => console.log('connection closed'),
(error) => console.log('error closing connection', error);
)
The
ndef
object provides NDEF constants, functions for creating NdefRecords, and functions for converting data. See android.nfc.NdefRecord for documentation about constants
Represents an NDEF (NFC Data Exchange Format) data message that contains one or more NdefRecords. This plugin uses an array of NdefRecords to represent an NdefMessage.
Represents a logical (unchunked) NDEF (NFC Data Exchange Format) record.
The ndef
object has a function for creating NdefRecords
var type = "text/pg",
id = [],
payload = nfc.stringToBytes("Hello World"),
record = ndef.record(ndef.TNF_MIME_MEDIA, type, id, payload);
There are also helper functions for some types of records
Create a URI record
var record = ndef.uriRecord("http://chariotsolutions.com");
Create a plain text record
var record = ndef.textRecord("Plain text message");
Create a mime type record
var mimeType = "text/pg",
payload = "Hello Phongap",
record = ndef.mimeMediaRecord(mimeType, nfc.stringToBytes(payload));
Create an Empty record
var record = ndef.emptyRecord();
Create an Android Application Record (AAR)
var record = ndef.androidApplicationRecord('com.example');
See ndef.record
, ndef.textRecord
, ndef.mimeMediaRecord
, and ndef.uriRecord
.
The Ndef object has functions to convert some data types to and from byte arrays.
See the phonegap-nfc.js source for more documentation.
Events are fired when NFC tags are read. Listeners are added by registering callback functions with the nfc
object. For example nfc.addNdefListener(myNfcListener, win, fail);
The tag contents are platform dependent.
id
and techTypes
may be included when scanning a tag on Android. serialNumber
may be included on BlackBerry 7.
id
and serialNumber
are different names for the same value. id
is typically displayed as a hex string nfc.bytesToHexString(tag.id)
.
Windows, Windows Phone 8, and BlackBerry 10 read the NDEF information from a tag, but do not have access to the tag id or other meta data like capacity, read-only status or tag technologies.
Assuming the following NDEF message is written to a tag, it will produce the following events when read.
var ndefMessage = [
ndef.createMimeRecord('text/pg', 'Hello PhoneGap')
];
{
type: 'ndef',
tag: {
"isWritable": true,
"id": [4, 96, 117, 74, -17, 34, -128],
"techTypes": ["android.nfc.tech.IsoDep", "android.nfc.tech.NfcA", "android.nfc.tech.Ndef"],
"type": "NFC Forum Type 4",
"canMakeReadOnly": false,
"maxSize": 2046,
"ndefMessage": [{
"id": [],
"type": [116, 101, 120, 116, 47, 112, 103],
"payload": [72, 101, 108, 108, 111, 32, 80, 104, 111, 110, 101, 71, 97, 112],
"tnf": 2
}]
}
}
{
type: 'ndef',
tag: {
"tagType": "4",
"isLocked": false,
"isLockable": false,
"freeSpaceSize": "2022",
"serialNumberLength": "7",
"serialNumber": [4, 96, 117, 74, -17, 34, -128],
"name": "Desfire EV1 2K",
"ndefMessage": [{
"tnf": 2,
"type": [116, 101, 120, 116, 47, 112, 103],
"id": [],
"payload": [72, 101, 108, 108, 111, 32, 80, 104, 111, 110, 101, 71, 97, 112]
}]
}
}
{
type: 'ndef',
tag: {
"ndefMessage": [{
"tnf": 2,
"type": [116, 101, 120, 116, 47, 112, 103],
"id": [],
"payload": [72, 101, 108, 108, 111, 32, 80, 104, 111, 110, 101, 71, 97, 112]
}]
}
}
The raw contents of the scanned tags are written to the log before the event is fired. Use adb logcat
on Android and Event Log (hold alt + lglg) on BlackBerry.
You can also log the tag contents in your event handlers. console.log(JSON.stringify(nfcEvent.tag))
Note that you want to stringify the tag not the event to avoid a circular reference.
Only Android and BlackBerry 7 can read data from non-NDEF NFC tags. Newer Windows Phones with NXP PN427 chipset can read non-NDEF tags, but can not get any tag meta data.
BlackBerry 7, BlackBerry 10 and many newer Android phones will not read Mifare Classic tags. Mifare Ultralight tags will work since they are NFC Forum Type 2 tags. Newer Windows 8.1 phones (Lumia 640) can read Mifare Classic tags.
Windows Phone 8, BlackBerry 10, and Windows read the NDEF information from a tag, but do not have access to the tag id or other meta data like capacity, read-only status or tag technologies.
Multiple listeners can be registered in JavaScript. e.g. addNdefListener, addTagDiscoveredListener, addMimeTypeListener.
On Android, only the most specific event will fire. If a Mime Media Tag is scanned, only the addMimeTypeListener callback is called and not the callback defined in addNdefListener. You can use the same event handler for multiple listeners.
For Windows, this plugin mimics the Android behavior. If an ndef event is fired, a tag event will not be fired. You should receive one event per tag.
On BlackBerry 7, all the events fire if a Mime Media Tag is scanned.
On Android, addTagDiscoveredListener scans non-NDEF tags and NDEF tags. The tag event does NOT contain an ndefMessage even if there are NDEF messages on the tag. Use addNdefListener or addMimeTypeListener to get the NDEF information.
Windows can scan non-NDEF (unformatted) tags using addTagDiscoveredListener. The tag event will not include any data.
On BlackBerry 7, addTagDiscoveredListener does NOT scan non-NDEF tags. Webworks returns the ndefMessage in the event.
{
type: 'tag',
tag: {
"id": [-81, 105, -4, 64],
"techTypes": ["android.nfc.tech.MifareClassic", "android.nfc.tech.NfcA", "android.nfc.tech.NdefFormatable"]
}
}
{
type: 'tag',
tag: {
"id": [4, 96, 117, 74, -17, 34, -128],
"techTypes": ["android.nfc.tech.IsoDep", "android.nfc.tech.NfcA", "android.nfc.tech.Ndef"]
}
}
{
type: 'tag',
tag: {
}
}
This plugin uses the BlackBerry Invocation Framework to read NFC tags on BlackBerry 10. This means that you need to register an invoke target in the config.xml.
If your project supports multiple platforms, copy www/config.xml to merges/config.xml and add a rim:invoke-target
tag. The invoke-target determines which tags your app will scan when it is running. If your application is not running, BlackBerry will launch it when a matching tag is scanned.
This sample configuration attempts to open any NDEF tag.
<rim:invoke-target id="your.unique.id.here">
<type>APPLICATION</type>
<filter>
<action>bb.action.OPEN</action>
<mime-type>application/vnd.rim.nfc.ndef</mime-type>
<!-- any TNF Empty(0), Well Known(1), MIME Media(2), Absolute URI(3), External(4) -->
<property var="uris" value="ndef://0,ndef://1,ndef://2,ndef://3,ndef://4" />
</filter>
</rim:invoke-target>
You can configure you application to handle only certain tags.
For example to scan only MIME Media tags of type "text/pg" use
<rim:invoke-target id="your.unique.id.here">
<type>APPLICATION</type>
<filter>
<action>bb.action.OPEN</action>
<mime-type>application/vnd.rim.nfc.ndef</mime-type>
<!-- TNF MIME Media(2) with type "text/pg" -->
<property var="uris" value="ndef://2/text/pg" />
</filter>
</rim:invoke-target>
Or to scan only Plain Text tags use
<rim:invoke-target id="your.unique.id.here">
<type>APPLICATION</type>
<filter>
<action>bb.action.OPEN</action>
<mime-type>application/vnd.rim.nfc.ndef</mime-type>
<!-- TNF Well Known(1), RTD T -->
<property var="uris" value="ndef://1/T" />
</filter>
</rim:invoke-target>
See the BlackBerry documentation for more info.
On Android, intents can be used to launch your application when a NFC tag is read. This is optional and configured in AndroidManifest.xml.
<intent-filter>
<action android:name="android.nfc.action.NDEF_DISCOVERED" />
<data android:mimeType="text/pg" />
<category android:name="android.intent.category.DEFAULT" />
</intent-filter>
Note: data android:mimeType="text/pg"
should match the data type you specified in JavaScript
We have found it necessary to add android:noHistory="true"
to the activity element so that scanning a tag launches the application after the user has pressed the home button.
See the Android documentation for more information about filtering for NFC intents.
Tests require the Cordova Plugin Test Framework
Create a new project
git clone https://github.com/chariotsolutions/phonegap-nfc
cordova create nfc-test com.example.nfc.test NfcTest
cd nfc-test
cordova platform add android
cordova plugin add ../phonegap-nfc
cordova plugin add ../phonegap-nfc/tests
cordova plugin add https://github.com/apache/cordova-plugin-test-framework.git
Change the start page in config.xml
<content src="https://github.com/chariotsolutions/phonegap-nfc/raw/master/cdvtests/index.html" />
Run the app on your phone
cordova run
For Host Card Emulation (HCE), try the Cordova HCE Plugin.
Need more info? Check out my book Beginning NFC: Near Field Communication with Arduino, Android, and PhoneGap
The MIT License
Copyright (c) 2011-2020 Chariot Solutions
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.