Difference between revisions of "Android Software Card Emulation"
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m (→Performances) |
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With CPU locked at 1000MHz (CPU sceduler = performance) and idle |
With CPU locked at 1000MHz (CPU sceduler = performance) and idle |
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* Resp to SelectApp: 32ms (std. dev. 11%) |
* Resp to SelectApp: 32ms (std. dev. 11%) |
||
− | * Resp to VerifyPIN*: 296ms (std. dev. 3%) |
+ | * Resp to VerifyPIN(*): 296ms (std. dev. 3%) |
− | * Resp to GetSign**: 67ms (std.dev. 18%) |
+ | * Resp to GetSign(**): 67ms (std.dev. 18%) |
With CPU locked at 1000MHz (CPU sceduler = performance) and busy with infinite loop |
With CPU locked at 1000MHz (CPU sceduler = performance) and busy with infinite loop |
||
* Resp to SelectApp: 63ms (std. dev. 15%) |
* Resp to SelectApp: 63ms (std. dev. 15%) |
||
− | * Resp to VerifyPIN*: 600ms (std. dev. 4%) |
+ | * Resp to VerifyPIN(*): 600ms (std. dev. 4%) |
− | * Resp to GetSign**: 100ms (std.dev. 20%) |
+ | * Resp to GetSign(**): 100ms (std.dev. 20%) |
− | + | (*) : the phone does a PBKDF2 on the PIN : 5000 x SHA1 hashes |
|
− | + | <br>(**) : the phone does a 1024-bit RSA signature |
Revision as of 15:11, 9 September 2013
Software Card Emulation on Android
Software CE is not possible yet on stock Android but patches have been made for CyanogenMod and they are integrated in the official release since v10.1.
Readings
- Software Card Emulation in NFC-enabled Mobile Phones: Great Advantage or Security Nightmare? (pdf) by Michael Roland, IWSSI2012
- Emulating a PKI smart card with CyanogenMod 9.1 by Nikolay Elenkov
- SimplyTapp by Doug Yeager
Requirements
Android phone with a PN544 NFC chipset
Limitations
ISO14443-4A
- Random UID (starting with "08")
- SAK (SEL_RES): 60
- Compliant with ISO/IEC 14443-4
- Compliant with ISO/IEC 18092
- ATS: 78 33 88 00
- Max Frame Size accepted by PICC: 256 bytes
- Bit Rate Capability:
- PICC to PCD, DS=2, bitrate 212 kbits/s supported
- PICC to PCD, DS=4, bitrate 424 kbits/s supported
- PCD to PICC, DR=2, bitrate 212 kbits/s supported
- PCD to PICC, DR=4, bitrate 424 kbits/s supported
- Frame Waiting Time: 77.33 ms
- Start-up Frame Guard Time: 77.33 ms
- Node Address not supported
- Card IDentifier not supported
- Corresponding ATR: 3B80800101
ISO14443-4B
- Random PUPI
- Application Data: 00 00 00 00
- Protocol Info: 33 81 84
- Bit Rate Capability:
- PICC to PCD, 1etu=64/fc, bitrate 212 kbits/s supported
- PICC to PCD, 1etu=32/fc, bitrate 424 kbits/s supported
- PCD to PICC, 1etu=64/fc, bitrate 212 kbits/s supported
- PCD to PICC, 1etu=32/fc, bitrate 424 kbits/s supported
- Maximum frame sizes: 256 bytes
- Protocol types supported: ISO/IEC 14443-4
- Frame Waiting Time: 77.33 ms
- Bit Rate Capability:
FeliCa
The PN544 chip is also able to emulate FeliCa even if it's not (yet) accessible from Android API but this means if an external FeliCa reader is polling the phone it can get something like FeliCa target:
- Random ID (NFCID2): 01 fe nn nn nn nn nn nn
- Parameter (PAD): c0 c1 c2 c3 c4 c5 c6 c7
- System Code (SC): 0f ab
Performances
On a Nexus S locked at 1000MHz and idle, a delay of about 30ms is still measured. It goes to 60ms if CPU is busy or occasionally even higher under "on demand" CPU scheduler.
Installation
Easiest is to install cyanogenmod 10.1 (or more recent if available), see instructions
Example
This example is taken from this very interesting post and its source code, adapted for CyanogenMod 10.1 and compiled under Linux in command line.
It's a small example emulating a card able to do a PIN verify then a signature, a bit like some eIDs.
Compile application
Following instructions how to compile Android app in command line
git clone https://github.com/nelenkov/virtual-pki-card
cd virtual-pki-card/se-emulator
JAVA_HOME=/usr/lib/jvm/java-6-sun-1.6.0.26/
ANDROID_HOME=/your_path_to/android-sdk-linux_x86/
PACKAGE=org.nick.se.emulator
PACKAGE_SLASH=${PACKAGE//.//}
DEV_HOME=$(pwd)
TARGET=android-17
mkdir -p $DEV_HOME/obj
mkdir -p $DEV_HOME/bin
mkdir -p $DEV_HOME/lib
Create dummy keystore
$JAVA_HOME/bin/keytool -genkeypair \
-validity 10000 \
-dname "CN=company name,
OU=organisational unit,
O=organisation,
L=location,
S=state,
C=country code" \
-keystore $DEV_HOME/AndroidTest.keystore \
-storepass password \
-keypass password \
-alias AndroidTestKey \
-keyalg RSA \
-v
Create R.java
$ANDROID_HOME/platform-tools/aapt package -v -f -m \
-S $DEV_HOME/res -J $DEV_HOME/src -M $DEV_HOME/AndroidManifest.xml \
-I $ANDROID_HOME/platforms/$TARGET/android.jar || exit 1
Compile Java
$JAVA_HOME/bin/javac -verbose -d $DEV_HOME/obj \
-classpath "$ANDROID_HOME/platforms/$TARGET/android.jar:$DEV_HOME/obj" \
-sourcepath $DEV_HOME/src \
$DEV_HOME/src/$PACKAGE_SLASH/*.java || exit 1
Create DEX
$ANDROID_HOME/platform-tools/dx --dex --verbose \
--output=$DEV_HOME/bin/classes.dex \
$DEV_HOME/obj $DEV_HOME/lib || exit 1
Create APK
$ANDROID_HOME/platform-tools/aapt package -v -f \
-S $DEV_HOME/res -M $DEV_HOME/AndroidManifest.xml \
-I $ANDROID_HOME/platforms/$TARGET/android.jar \
-F $DEV_HOME/bin/AndroidTest.unsigned.apk \
$DEV_HOME/bin || exit 1
Sign APK
$JAVA_HOME/bin/jarsigner -verbose \
-keystore $DEV_HOME/AndroidTest.keystore \
-storepass password \
-keypass password \
-signedjar $DEV_HOME/bin/AndroidTest.signed.apk \
$DEV_HOME/bin/AndroidTest.unsigned.apk \
AndroidTestKey || exit 1
Zip-align APK
$ANDROID_HOME/tools/zipalign -v -f 4 \
$DEV_HOME/bin/AndroidTest.signed.apk \
$DEV_HOME/bin/AndroidTest.apk || exit 1
Install application
sudo adb install $DEV_HOME/bin/AndroidTest.apk
Create certificate
As this example is using a certificate to sign data, we need to create it.
cd virtual-pki-card
mkdir cert
cd cert
Create a template mykey.conf:
[ req ]
default_bits = 1024
distinguished_name = req_distinguished_name
prompt = no
output_password = 1234
[ req_distinguished_name ]
C = BE
ST = MyCity
O = MyOrg
Create certificate:
openssl req -new -x509 -keyout mykey.pem -out mycert.pem -config mykey.conf
openssl pkcs12 -export -in mycert.pem -inkey mykey.pem -passin pass:1234 -passout pass: > mykey.pfx
Install it:
sudo adb push mykey.pfx /sdcard/
cp mycert.pem ../se-pki-client/
On the phone:
Run application "PKI Applet Emulator"
- Install PKCS#12
- no passwd
- if needed create a lock PIN on the phone (to be able to store certs)
- choose cert: select this one, ok
- Set PIN=1234
If reading cert fails, check in CyanogenMod developer options that "Protect USB storage" is not activated.
Storing certs require that you defined a screen lock PIN too, do it if needed.
Reader application
Compile:
cd se-pki-client
javac src/org/nick/sepkiclient/Main.java
Execute:
java -cp src org.nick.sepkiclient.Main 1234 mycert.pem
Place phone/card on reader to start --> 00A4040006A0000000010101 <-- 9000 --> 800100000431323334 <-- 9000 --> 80020000087369676E206D6521 <-- 7C19AAE869DD6C2A9C4AAB98E65FEFDF88C0764EDDAD1BE660BBA220237BA7F4D46B08080E925737D7D ... Got signature from card: 7C19AAE869DD6C2A9C4AAB98E65FEFDF88C0764EDDAD1BE660BBA220237BA7F4D46B08080E925737D7D ... Will use certificate from 'mycert.pem' to verify signature Issuer: O=MyOrg, ST=MyCity, C=BE Subject: O=MyOrg, ST=Mycity, C=BE Not Before: Thu Sep 05 11:46:55 CEST 2013 Not After: Sat Oct 05 11:46:55 CEST 2013 Signature is valid: true
Performances
Measured on a Nexus S, stats over 20 runs:
With CPU locked at 1000MHz (CPU sceduler = performance) and idle
- Resp to SelectApp: 32ms (std. dev. 11%)
- Resp to VerifyPIN(*): 296ms (std. dev. 3%)
- Resp to GetSign(**): 67ms (std.dev. 18%)
With CPU locked at 1000MHz (CPU sceduler = performance) and busy with infinite loop
- Resp to SelectApp: 63ms (std. dev. 15%)
- Resp to VerifyPIN(*): 600ms (std. dev. 4%)
- Resp to GetSign(**): 100ms (std.dev. 20%)
(*) : the phone does a PBKDF2 on the PIN : 5000 x SHA1 hashes
(**) : the phone does a 1024-bit RSA signature