When you create a named pipe on ReactOS,
CreateNamedPipe in kernel32.dll calls
NtCreateNamedPipeFile in ntdll.dll, which performs a syscall + index into SSDT to its kernel mode counterpart in ntoskrnl.exe, which calls
IoCreateFile, which calls
IopCreateFile, which will call
ObOpenObjectByName, which calls
ObpLookupObjectName, which calls the object parse routine
ParseRoutine = ObjectHeader->Type->TypeInfo.ParseProcedure, which will be
IopParseRoutine, which sends an IRP with major code IRP_MJ_CREATE_NAMED_PIPE to the NPFS driver, which it acquires by its name
\Device\NamedPipe (it will parse
\??\pipe, which is a symbolic link to the
\Device\NamedPipe DO created by the NPFS driver).
DriverEntry function of the NPFS assigns
DriverObject->MajorFunction[IRP_MJ_CREATE_NAMED_PIPE] = NpFsdCreateNamedPipe;.
NpCreateNewNamedPipe, which will set up the file object and the CCB (Context Control Block) (
FileObject->FsContext2) of the file object with the data queues.
The file object of name
PipeName is accessed via
\\.\pipe\PipeName and translates to
\Device\NamedPipe\PipeName. The file object points to the
NamedPipe device object created by the Npfs, which
IoGetRelatedDeviceObject will return, meaning that all
ReadFile operations result in an IRP, which gets sent to the top of the device stack of this Device Object, passing the pipe name
\PipeName. This is similar to how
\Device\HarddiskVolume1\Windows file object
PDEVICE_OBJECT points to the
Device\HarddiskVolume1 device object, the file name
UNICODE_STRING of the file object being
\Windows. If you look at the file object, you can get the full path by getting the device object name and appending it to the start.
IoCallDriver will be eventually called on the owning driver of the device object. Based on the IRP major code in the IRP passed,
IoCallDriver calls either
DO->DriverObject->MajorFunction[IRP_MJ_Write], which is
DO->DriverObject->MajorFunction[IRP_MJ_Read], which is
NpFsdRead. Those functions will write and read to the data queues
Ccb->DataQueue[FILE_PIPE_INBOUND], which contain the head of a doubly linked list of
DataEntry headers where
DataEntry is the header and
DataEntry is the buffer. If you open the named pipe as a server then it reads from the inbound and writes to the outbound. The client reads from the outbound and writes to the inbound.
If you use
PIPE_TYPE_MESSAGE, then every time you write to the pipe, another
DataEntry will be added to the tail of the linked list (because
NpWriteDataQueue will return with
STATUS_MORE_PROCESSING_REQUIRED in the IRP, which the calling function checks before calling
NpAddDataQueueEntry), and each time you read, a
DataEntry will be removed from the head of the linked list (
NpReadDataQueue will only call
!Peek). You will get an error if you do not read all of the message. If you use
PIPE_TYPE_BYTE, then only the current
DataEntry is used and no
DataEntrys are removed when you write. Simply, the
ByteOffset field of the
DataEntry is increased by the number of bytes read, and I'm really not sure how writing in byte mode works.
DataEntries, CCBs and FileObjects are allocated on the non-paged pool.