To build software that uses Npcap, use the latest version of the Npcap Software Development Kit (SDK). The latest SDK can be downloaded on Npcap.org. Updates to the SDK are much less frequent than updates to the Npcap binaries.

Examples of applications using Npcap are available in the Examples directory in the source distribution. Several of these examples are explored in more depth in the the section called “Npcap Development Tutorial”.

Npcap developer Yang Luo has also provided an example: UserBridge, which is a tool to redirect all packets from one interface to another.

For the most part, Npcap is completely compatible with software written for WinPcap. Minor changes need to be made to the section called “DLL loading” and in some cases the section called “Service name”. However, there have been many improvements to the libpcap API between the last release of WinPcap and the current release of Npcap. Reviewing the changes may help improve performance, reliability, and maintainability of software that uses Npcap.

Apart from the libpcap API, WinPcap exported a few functions used by WinDump that were related to porting a Unix-style tool to Windows but unrelated to packet capture. Those functions were not documented in the WinPcap documentation, have never been included in libpcap, and are therefore not in the Npcap API: getservent, endservent, and eproto_db.

One other function exported by WinPcap, wsockinit, is available via the Npcap API as pcap_wsockinit. It calls WSAStartup for Windows Sockets version 1.1 and ensures that WSACleanup is called when the process ends.

Sometimes, our user software needs to detect the existence of Npcap/WinPcap at install-time or run-time. Although Npcap's GUI installer has the ability to handle this, you may want to handle it by yourself in some conditions, like you run Npcap installer in silent-mode. The run-time detection is even more useful. Your software probably has some functions that rely on Npcap's particular features (like loopback capture). You need to know if you are running on top of Npcap or the legacy WinPcap to control whether to switch your functions on. Fortunately, Npcap provides you some methods to detect Npcap/WinPcap at install-time and run-time.

GetDllVersion "C:\Program Files\Npcap\NPFInstall.exe" $R0 $R1 IntOp $R2 $R0 / 0x00010000 IntOp $R3 $R0 & 0x0000FFFF IntOp $R4 $R1 / 0x00010000 IntOp $R5 $R1 & 0x0000FFFF StrCpy $inst_ver "$R2.$R3.$R4.$R5"

char *pcap_version = pcap_lib_version(); printf("%s", pcap_version); // Npcap output: "Npcap version 0.92, based on libpcap version 1.8.1" // WinPcap output: "WinPcap version 4.1.3"

Prerequisite: Uncheck the Install Npcap in WinPcap API-compatible Mode option at install-time (which is by default).

Npcap 0.9983 and newer support loopback traffic capture and injection without requiring a particular installation option.

Npcap's loopback adapter device is reported by pcap_findalldevs() as “\Device\NPF_Loopback”. This name is always available even if “Legacy loopback support” was chosen at install time, which puts the name of the legacy loopback adapter in the LoopbackAdapter REG_SZ value of the HKEY_LOCAL_MACHINE\SYSTEM\CurrentControlSet\Services\npcap\Parameters. Registry key.

Traffic captured and injected on the loopback adapter uses the DLT_NULL data link type, which consists of a 4-byte header in host byte order that is either 2 for IPv4 packets or 24 for IPv6 packets.

The MTU of “Npcap Loopback Adapter” is hard-coded to 65536 by Npcap. Software using Npcap should get this value automatically and no special handling is needed. This value is arbitrary and does not imply a limitation on the Windows loopback stack, so it may be possible to capture packets with a size larger than the adapter's MTU.

Don't try to make OID requests to “Npcap Loopback Adapter” except OID_GEN_MAXIMUM_TOTAL_SIZE (MTU). Those requests will still succeed like other adapters do, but they only make sense for NDIS adapters and Npcap doesn't even use the NDIS way to handle the loopback traffic. The only handled OID request by Npcap is OID_GEN_MAXIMUM_TOTAL_SIZE. If you query its value, you will always get 65550 (65536 + 14). If you try to set its value, the operation will always fail.

If you use IP Helper API to get adapter list, you will get an interface named like “Loopback Pseudo-Interface 1”. This interface is a DUMMY interface by Microsoft and can't be seen in NDIS layer. And it also takes the 127.0.0.1/::1 IP address. A good practice for software is replacing the AdapterName of the “Loopback Pseudo-Interface 1” entry with “NPF_Loopback”, as Nmap does in its enhancements to libdnet.

“Legacy loopback support” installs a copy of the Microsft KM-TEST loopback adapter named “Npcap Loopback Adapter” for software that expects to find the loopback adapter via ordinary Windows API calls. The features and operation are no different from standard loopback support, but the name of the adapter will be written to the LoopbackAdapter Registry value.

Prerequisite: Check the Support raw 802.11 traffic (and monitor mode) for wireless adapters option at install-time.

C:\> WlanHelper.exe WlanHelper for Npcap 0.91 ( https://npcap.com ) Usage: WlanHelper [Commands] or: WlanHelper {Interface Name or GUID} [Options] OPTIONS: mode : Get interface operation mode mode <managed|monitor|master|..> : Set interface operation mode modes : Get all operation modes supported by the interface, comma-separated channel : Get interface channel channel <1-14> : Set interface channel (only works in monitor mode) freq : Get interface frequency freq <VALUE> : Set interface frequency (only works in monitor mode) modu : Get interface modulation modu <dsss|fhss|irbaseband|ofdm|hrdsss|erp|ht|vht|ihv (VALUE)|..> : Set interface modulation modus : Get all modulations supported by the interface, comma-separated COMMANDS: -i : Enter the interactive mode -h : Print this help summary page OPERATION MODES: managed : The Extensible Station (ExtSTA) operation mode monitor : The Network Monitor (NetMon) operation mode master : The Extensible Access Point (ExtAP) operation mode (supported from Windows 7 and later) wfd_device : The Wi-Fi Direct Device operation mode (supported from Windows 8 and later) wfd_owner : The Wi-Fi Direct Group Owner operation mode (supported from Windows 8 and later) wfd_client : The Wi-Fi Direct Client operation mode (supported from Windows 8 and later) 802.11 MODULATIONS (https://en.wikipedia.org/wiki/IEEE_802.11): 802.11-1997 : dsss, fhss 802.11a : ofdm 802.11b : dsss 802.11g : ofdm 802.11n : mimo-ofdm 802.11ac : mimo-ofdm EXAMPLES: WlanHelper Wi-Fi mode WlanHelper 42dfd47a-2764-43ac-b58e-3df569c447da channel 11 WlanHelper 42dfd47a-2764-43ac-b58e-3df569c447da freq 2 WlanHelper "Wireless Network Connection" mode monitor SEE THE MAN PAGE (https://github.com/nmap/npcap) FOR MORE OPTIONS AND EXAMPLES

C:\> netsh wlan show interfaces There is 1 interface on the system: Name : <Wi-Fi> Description : Qualcomm Atheros AR9485WB-EG Wireless Network Adapter GUID : <42dfd47a-2764-43ac-b58e-3df569c447da> Physical address : a4:db:30:d9:3a:9a State : connected SSID : LUO-PC_Network BSSID : d8:15:0d:72:8c:18 Network type : Infrastructure Radio type : 802.11n Authentication : WPA2-Personal Cipher : CCMP Connection mode : Auto Connect Channel : 1 Receive rate (Mbps) : 150 Transmit rate (Mbps) : 150 Signal : 100% Profile : LUO-PC_Network Hosted network status : Not available C:\> WlanHelper.exe <wi-fi> mode managed C:\> WlanHelper.exe <wi-fi> mode monitor Success C:\> WlanHelper.exe <wi-fi> mode  monitor C:\> WlanHelper.exe <wi-fi> mode managed Success C:\> WlanHelper.exe <wi-fi> mode managed