From 5dbc2e2e99aada7b9d4472d1e209fee602d99699 Mon Sep 17 00:00:00 2001 From: Joel Sherrill Date: Thu, 8 Apr 1999 16:09:11 +0000 Subject: First attempt to build. --- doc/networking/decdriver.t | 569 ++++++++++++++++++++++++--------------------- 1 file changed, 305 insertions(+), 264 deletions(-) (limited to 'doc/networking/decdriver.t') diff --git a/doc/networking/decdriver.t b/doc/networking/decdriver.t index b55b192f24..4b845900c5 100644 --- a/doc/networking/decdriver.t +++ b/doc/networking/decdriver.t @@ -1,264 +1,305 @@ -%% This LaTeX-file was created by Wed Apr 7 17:10:33 1999 -%% LyX 1.0 (C) 1995-1999 by Matthias Ettrich and the LyX Team - -%% Do not edit this file unless you know what you are doing. -\documentclass[10pt,american]{article} -\usepackage[T1]{fontenc} -\usepackage{a4wide} -\pagestyle{plain} -\usepackage{babel} -\usepackage[dvips]{graphics} - -\makeatletter - - -%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% LyX specific LaTeX commands. -\providecommand{\LyX}{L\kern-.1667em\lower.25em\hbox{Y}\kern-.125emX\@} - -%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% User specified LaTeX commands. -\usepackage[dvips]{epsfig} - -\makeatother - -\begin{document} - -\resizebox*{1\textwidth}{!}{\includegraphics{garde.eps}} - -{\par\centering \newpage\par} -\vspace{0.3cm} - -\bigskip{} -{\par\centering \textbf{\Huge Ethernet Driver for PCI DEC board}\Huge \par} -\bigskip{} - -\tableofcontents{} - -\listoffigures{} - -\newpage - - -\section{\noindent Introduction} - -One aim of our project is to port RTEMS on a standard PowerPC platform. To achieve -it, we have chosen a Motorola MCP750 board. This board includes an Ethernet -controller based on a DEC21140 chip. Because RTEMS has a TCP/IP stack, we will -have to develop the DEC21140 related ethernet driver for the PowerPC port of -RTEMS. As this controller is able to support 100Mbps network and as there is -a lot of PCI card using this DEC chip (cf \ref{List}), we have decided to first -implement this driver on an Intel PC386 target to provide a solution for using -RTEMS on PC with the 100Mbps network and then to port this code on PowerPC in -a second phase.\\ - - -\noindent The aim of this document is to give some PCI board generalities and -to explain the software architecture of the RTEMS driver. Finally, we will see -what will be done for ChorusOs and Netboot environment . - - -\section{Document Revision History} - -\underbar{Current release} : - -\begin{itemize} -\item \noindent Current applicable release is 1.0. -\end{itemize} -\noindent \underbar{Existing releases} : - -\begin{itemize} -\item \noindent 1.0 : Released the 10/02/98. First version of this document. -\item 0.1 : First draft of this document -\end{itemize} -\noindent \underbar{Planned releases} : - -\begin{itemize} -\item \noindent None planned today. -\end{itemize} - -\section{DEC21140 PCI Board Generalities} - -This chapter describes rapidely the PCI interface of this Ethernet controller. -The board we have chosen for our PC386 implementation is a D-Link DFE-500TX. -This is a dual-speed 10/100Mbps Ethernet PCI adapter with a DEC21140AF chip. -Like other PCI devices, this board has a PCI device's header containing some -required configuration registers, as shown in figure \ref{PCI reg}. By reading -or writing these registers, a driver can obtain information about the type of -the board, the interrupt it uses, the mapping of the chip specific registers,~... -\\ - - -\noindent On Intel target, the chip specific registers can be accessed via 2 -methods : I/O port access or PCI address mapped access. We have chosen to implement -the PCI address access to obtain compatible source code to the port the driver -on a PowerPC target.\\ - - -\begin{figure} -{\par\centering \includegraphics{PCI_reg.eps} \par} - - -\caption{\label{PCI reg}PCI device's configuration header space format} -\end{figure} -On RTEMS, a PCI API exists. We have used it to configure the board. After initializing -this PCI module via the \textbf{\textit{pcib\_init()}} function, we try to detect -the DEC21140 based ethernet board. This board is characterized by its Vendor -ID (0x1011) and its Device ID (0x0009). We give these arguments to the \textbf{\textit{pcib\_find\_by\_deviceid}} -function which returns , if the device is present, a pointer to the configuration -header space (cf fig \ref{PCI reg}). Once this operation performed, the driver -is able to extract the information it needs to configure the board internal -registers, like the interrupt line, the base address,... The board internal -registers will not be detailled here. You can find them in \cite{1}.\newpage - - -\section{\noindent RTEMS Driver Software Architecture} - -In this chapter will see the initialization phase, how the controller uses the -host memory and the 2 threads launched at the initialization time. - - -\subsection{Initialization phase} - -The DEC21140 Ethernet driver keeps the same software architecture than the other -RTEMS ethernet drivers. The only API the programmer can use is the \textbf{\textit{``rtems\_dec21140\_driver\_attach}}\\ -\textbf{\textit{(struct rtems\_bsdnet\_ifconfig {*}config)''}} function which -detects the board and initializes the associated data structure (with registers -base address, entry points to low-level initialization function,...), if the -board is found. - -\noindent Once the attach function executed, the driver initializes the DEC -chip. Then the driver connects an interrupt handler to the interrupt line driven -by the Ethernet controller (the only interrupt which will be treated is the -receive interrupt) and launches 2 threads : a receiver thread and a transmitter -thread. Then the driver waits for incoming frame to give to the protocol stack -or outcoming frame to send on the physical link. - - -\subsection{Memory Buffer} - -This DEC chip uses the host memory to store the incoming Ethernet frames and -the descriptor of these frames. We have chosen to use 7 receive buffers and -1 transmit buffer to optimize memory allocation due to cache and paging problem -that will be explained in paragraph \ref{Problem}).\\ - - -\noindent To reference these buffers to the DEC chip we use a buffer descriptors -ring. The descriptor structure is defined in figure \ref{bdescr}. Each descriptor -can reference one or two memory buffers. We choose to use only one buffer of -1520 bytes per descriptor.\\ - - -\noindent The difference between a receive and a transmit buffer descriptor -is located in the status and control bits fields. We do not give details here, -please refer to \cite{1}. - -\begin{figure} -{\par\centering \includegraphics{recv_bd.eps} \par} - - -\caption{\label{bdescr}Buffer Descriptor} -\end{figure} - - - -\subsection{Receiver Thread} - -This thread is event driven. Each time a DEC PCI board interrupt occurs, the -handler checks if this is a receive interrupt and send an event ``reception'' -to the receiver thread which looks into the entire buffer descriptors ring the -ones that contain a valid incoming frame (bit OWN=0 means descriptor belongs -to host processor). Each valid incoming ethernet frame is sent to the protocol -stack and the buffer descriptor is given back to the DEC board (the host processor -reset bit OWN, which means descriptor belongs to 21140). - - -\subsection{Transmitter Thread} - -This thread is also event driven. Each time an Ethernet frame is put in the -transmit queue, an event is sent to the transmit thread, which empty the queue -by sending each outcoming frame. Because we use only one transmit buffer, we -are sure that the frame is well-sent before sending the next. - - -\section{\label{Problem}Encountered Problems} - -On Intel PC386 target, we were faced with a problem of memory cache management. -Because the DEC chip uses the host memory to store the incoming frame and because -the DEC21140 configuration registers are mapped into the PCI address space, -we must ensure that the data read (or written) by the host processor are the -ones written (or read) by the DEC21140 device in the host memory and not old -data stored in the cache memory. Therefore, we had to provide a way to manage -the cache. This module is described in the document \cite{2}. On Intel, the -memory region cache management is available only if the paging unit is enabled. -We have used this paging mechanism, with 4Kb page. All the buffers allocated -to store the incoming or outcoming frames, buffer descriptor and also the PCI -address space of the DEC board are located in a memory space with cache disable.\\ - - -\noindent Concerning the buffers and their descriptors, we have tried to optimize -the memory space in term of allocated page. One buffer has 1520 bytes, one descriptor -has 16 bytes. We have 7 receive buffers and 1 transmit buffer, and for each, -1 descriptor : (7+1){*}(1520+16) = 12288 bytes = 12Kb = 3 entire pages. This -allows not to lose too much memory or not to disable cache memory for a page -which contains other data than buffer, which could decrease performance. - - -\section{ChorusOs DEC Driver} - -Because ChorusOs is used in several Canon CRF projects, we must provide such -a driver on this OS to ensure compatibility between the RTEMS and ChorusOs developments. -On ChorusOs, a DEC driver source code already exists but only for a PowerPC -target. We plan to port this code (which uses ChorusOs API) on Intel target. -This will allow us to have homogeneous developments. Moreover, the port of the -development performed with ChorusOs environment to RTEMS environment will be -easier for the developers. - - -\section{Netboot DEC driver} - -We use Netboot tool to load our development from a server to the target via -an ethernet network. Currently, this tool does not support the DEC board. We -plan to port the DEC driver for the Netboot tool.\\ - - -\noindent But concerning the port of the DEC driver into Netboot, we are faced -with a problem : in RTEMS environment, the DEC driver is interrupt or event -driven, in Netboot environment, it must be used in polling mode. It means that -we will have to re-write some mechanisms of this driver. - - -\section{\label{List}List of Ethernet cards using the DEC chip} - -Many Ethernet adapter cards use the Tulip chip. Here is a non exhaustive list -of adapters which support this driver : - -\begin{itemize} -\item Accton EtherDuo PCI. -\item Accton EN1207 All three media types supported. -\item Adaptec ANA6911/TX 21140-AC. -\item Cogent EM110 21140-A with DP83840 N-Way MII transceiver. -\item Cogent EM400 EM100 with 4 21140 100mbps-only ports + PCI Bridge. -\item Danpex EN-9400P3. -\item D-Link DFE500-Tx 21140-A with DP83840 transceiver. -\item Kingston EtherX KNE100TX 21140AE. -\item Netgear FX310 TX 10/100 21140AE. -\item SMC EtherPower10/100 With DEC21140 and 68836 SYM transceiver. -\item SMC EtherPower10/100 With DEC21140-AC and DP83840 MII transceiver. \\ -Note: The EtherPower II uses the EPIC chip, which requires a different driver. -\item Surecom EP-320X DEC 21140. -\item Thomas Conrad TC5048. -\item Znyx ZX345 21140-A, usually with the DP83840 N-Way MII transciever. Some ZX345 -cards made in 1996 have an ICS 1890 transciver instead. -\item ZNYX ZX348 Two 21140-A chips using ICS 1890 transcievers and either a 21052 -or 21152 bridge. Early versions used National 83840 transcievers, but later -versions are depopulated ZX346 boards. -\item ZNYX ZX351 21140 chip with a Broadcom 100BaseT4 transciever. -\end{itemize} -Our DEC driver has not been tested with all these cards, only with the D-Link -DFE500-TX. - -\begin{thebibliography}{DEC21140 Hardware Manual} -\bibitem[DEC21140 Hardware Manual]{1}DIGITAL, \textit{DIGITAL Semiconductor 21140A PCI Fast Ethernet LAN Controller -- Hardware Reference Manual.} -\bibitem[99.TA.0021.M.ER]{2}Emmanuel Raguet, \textit{RTEMS Cache Management For Intel.} -\end{thebibliography} -\end{document} +@c +@c RTEMS Remote Debugger Server Specifications +@c +@c Written by: Emmanuel Raguet +@c +@c +@c $Id$ +@c + +@chatper DEC 21140 Driver + +@section Introduction + +@c XXX add back in cross reference to list of boards. + +One aim of our project is to port RTEMS on a standard PowerPC platform. To achieve +it, we have chosen a Motorola MCP750 board. This board includes an Ethernet +controller based on a DEC21140 chip. Because RTEMS has a TCP/IP stack, we will +have to develop the DEC21140 related ethernet driver for the PowerPC port of +RTEMS. As this controller is able to support 100Mbps network and as there is +a lot of PCI card using this DEC chip, we have decided to first +implement this driver on an Intel PC386 target to provide a solution for using +RTEMS on PC with the 100Mbps network and then to port this code on PowerPC in +a second phase. + + +The aim of this document is to give some PCI board generalities and +to explain the software architecture of the RTEMS driver. Finally, we will see +what will be done for ChorusOs and Netboot environment . + + +@section Document Revision History + +@b{Current release}: + +@itemize @bullet +@item Current applicable release is 1.0. +@end itemize +@b{Existing releases}: + +@itemize @bullet +@item 1.0 : Released the 10/02/98. First version of this document. +@item 0.1 : First draft of this document +@end itemize +@b{Planned releases}: + +@itemize @bullet +@item None planned today. +@end itemize + +@section DEC21140 PCI Board Generalities + +@c XXX add crossreference to PCI Register Figure +This chapter describes rapidely the PCI interface of this Ethernet controller. +The board we have chosen for our PC386 implementation is a D-Link DFE-500TX. +This is a dual-speed 10/100Mbps Ethernet PCI adapter with a DEC21140AF chip. +Like other PCI devices, this board has a PCI device's header containing some +required configuration registers, as shown in the PCI Register Figure. +By reading +or writing these registers, a driver can obtain information about the type of +the board, the interrupt it uses, the mapping of the chip specific registers, ... + + + +On Intel target, the chip specific registers can be accessed via 2 +methods : I/O port access or PCI address mapped access. We have chosen to implement +the PCI address access to obtain compatible source code to the port the driver +on a PowerPC target. + +@c +@c PCI Device's Configuration Header Space Format +@c + +@ifset use-ascii +@example +@group +XXXXX reference it in the previous paragraph +XXXXX insert PCI_reg.eps +XXXXX Caption PCI Device's Configuration Header Space Format +@end group +@end example +@end ifset + +@ifset use-tex +@example +@group +XXXXX reference it in the previous paragraph +XXXXX insert PCI_reg.eps +XXXXX Caption PCI Device's Configuration Header Space Format +@end group +@end example +@end ifset + +@c @image{PCI_reg} + +@ifset use-html +@c PCI Device's Configuration Header Space Format +@html +PCI Device's Configuration Header Space Format +@end html +@end ifset + + +@c XXX add crossreference to PCI Register Figure + +On RTEMS, a PCI API exists. We have used it to configure the board. After initializing +this PCI module via the @code{pcib_init()} function, we try to detect +the DEC21140 based ethernet board. This board is characterized by its Vendor +ID (0x1011) and its Device ID (0x0009). We give these arguments to the +@code{pcib_find_by_deviceid} +function which returns , if the device is present, a pointer to the configuration +header space (see PCI Registers Fgure). Once this operation performed, +the driver +is able to extract the information it needs to configure the board internal +registers, like the interrupt line, the base address,... The board internal +registers will not be detailled here. You can find them in @title{DIGITAL +Semiconductor 21140A PCI Fast Ethernet LAN Controller +- Hardware Reference Manual}. + +@c fix citation + + +@section RTEMS Driver Software Architecture + +In this chapter will see the initialization phase, how the controller uses the +host memory and the 2 threads launched at the initialization time. + + +@subsection Initialization phase + +The DEC21140 Ethernet driver keeps the same software architecture than the other +RTEMS ethernet drivers. The only API the programmer can use is the @code{rtems_dec21140_driver_attach} +@code{(struct rtems_bsdnet_ifconfig *config)} function which +detects the board and initializes the associated data structure (with registers +base address, entry points to low-level initialization function,...), if the +board is found. + +Once the attach function executed, the driver initializes the DEC +chip. Then the driver connects an interrupt handler to the interrupt line driven +by the Ethernet controller (the only interrupt which will be treated is the +receive interrupt) and launches 2 threads : a receiver thread and a transmitter +thread. Then the driver waits for incoming frame to give to the protocol stack +or outcoming frame to send on the physical link. + + +@subsection Memory Buffer + +@c XXX add cross reference to Problem +This DEC chip uses the host memory to store the incoming Ethernet frames and +the descriptor of these frames. We have chosen to use 7 receive buffers and +1 transmit buffer to optimize memory allocation due to cache and paging problem +that will be explained in the section @b{Encountered Problems. + + +To reference these buffers to the DEC chip we use a buffer descriptors +ring. The descriptor structure is defined in the Buffer Descriptor Figure. +Each descriptor +can reference one or two memory buffers. We choose to use only one buffer of +1520 bytes per descriptor. + + +The difference between a receive and a transmit buffer descriptor +is located in the status and control bits fields. We do not give details here, +please refer to the [DEC21140 Hardware Manual]. + +@c +@c Buffer Descriptor +@c + +@ifset use-ascii +@example +@group +XXXXX reference it in the previous paragraph +XXXXX insert recv_bd.eps +XXXXX Caption Buffer Descriptor +@end group +@end example +@end ifset + +@ifset use-tex +@example +@group +XXXXX reference it in the previous paragraph +XXXXX insert recv_bd.eps +XXXXX Caption Buffer Descriptor +@end group +@end example +@end ifset + +@c @image{recv_bd} + +@ifset use-html +@c Buffer Descriptor +@html +Buffer Descriptor +@end html +@end ifset + + + +@subsection Receiver Thread + +This thread is event driven. Each time a DEC PCI board interrupt occurs, the +handler checks if this is a receive interrupt and send an event ``reception'' +to the receiver thread which looks into the entire buffer descriptors ring the +ones that contain a valid incoming frame (bit OWN=0 means descriptor belongs +to host processor). Each valid incoming ethernet frame is sent to the protocol +stack and the buffer descriptor is given back to the DEC board (the host processor +reset bit OWN, which means descriptor belongs to 21140). + + +@subsection Transmitter Thread + +This thread is also event driven. Each time an Ethernet frame is put in the +transmit queue, an event is sent to the transmit thread, which empty the queue +by sending each outcoming frame. Because we use only one transmit buffer, we +are sure that the frame is well-sent before sending the next. + + +@section Encountered Problems + +On Intel PC386 target, we were faced with a problem of memory cache management. +Because the DEC chip uses the host memory to store the incoming frame and because +the DEC21140 configuration registers are mapped into the PCI address space, +we must ensure that the data read (or written) by the host processor are the +ones written (or read) by the DEC21140 device in the host memory and not old +data stored in the cache memory. Therefore, we had to provide a way to manage +the cache. This module is described in the document @b{RTEMS +Cache Management For Intel}. On Intel, the +memory region cache management is available only if the paging unit is enabled. +We have used this paging mechanism, with 4Kb page. All the buffers allocated +to store the incoming or outcoming frames, buffer descriptor and also the PCI +address space of the DEC board are located in a memory space with cache disable. + + +Concerning the buffers and their descriptors, we have tried to optimize +the memory space in term of allocated page. One buffer has 1520 bytes, one descriptor +has 16 bytes. We have 7 receive buffers and 1 transmit buffer, and for each, +1 descriptor : (7+1)*(1520+16) = 12288 bytes = 12Kb = 3 entire pages. This +allows not to lose too much memory or not to disable cache memory for a page +which contains other data than buffer, which could decrease performance. + + +@section ChorusOs DEC Driver + +Because ChorusOs is used in several Canon CRF projects, we must provide such +a driver on this OS to ensure compatibility between the RTEMS and ChorusOs developments. +On ChorusOs, a DEC driver source code already exists but only for a PowerPC +target. We plan to port this code (which uses ChorusOs API) on Intel target. +This will allow us to have homogeneous developments. Moreover, the port of the +development performed with ChorusOs environment to RTEMS environment will be +easier for the developers. + + +@section Netboot DEC driver + +We use Netboot tool to load our development from a server to the target via +an ethernet network. Currently, this tool does not support the DEC board. We +plan to port the DEC driver for the Netboot tool. + + +But concerning the port of the DEC driver into Netboot, we are faced +with a problem : in RTEMS environment, the DEC driver is interrupt or event +driven, in Netboot environment, it must be used in polling mode. It means that +we will have to re-write some mechanisms of this driver. + + +@section List of Ethernet cards using the DEC chip + +Many Ethernet adapter cards use the Tulip chip. Here is a non exhaustive list +of adapters which support this driver : + +@itemize @bullet +@item Accton EtherDuo PCI. +@item Accton EN1207 All three media types supported. +@item Adaptec ANA6911/TX 21140-AC. +@item Cogent EM110 21140-A with DP83840 N-Way MII transceiver. +@item Cogent EM400 EM100 with 4 21140 100mbps-only ports + PCI Bridge. +@item Danpex EN-9400P3. +@item D-Link DFE500-Tx 21140-A with DP83840 transceiver. +@item Kingston EtherX KNE100TX 21140AE. +@item Netgear FX310 TX 10/100 21140AE. +@item SMC EtherPower10/100 With DEC21140 and 68836 SYM transceiver. +@item SMC EtherPower10/100 With DEC21140-AC and DP83840 MII transceiver. +Note: The EtherPower II uses the EPIC chip, which requires a different driver. +@item Surecom EP-320X DEC 21140. +@item Thomas Conrad TC5048. +@item Znyx ZX345 21140-A, usually with the DP83840 N-Way MII transciever. Some ZX345 +cards made in 1996 have an ICS 1890 transciver instead. +@item ZNYX ZX348 Two 21140-A chips using ICS 1890 transcievers and either a 21052 +or 21152 bridge. Early versions used National 83840 transcievers, but later +versions are depopulated ZX346 boards. +@item ZNYX ZX351 21140 chip with a Broadcom 100BaseT4 transciever. +@end itemize + +Our DEC driver has not been tested with all these cards, only with the D-Link +DFE500-TX. + +@itemize @code{ } +@item @cite{[DEC21140 Hardware Manual] DIGITAL, @b{DIGITAL +Semiconductor 21140A PCI Fast Ethernet LAN Controller - Hardware +Reference Manual}}. + +@item @cite{[99.TA.0021.M.ER]Emmanuel Raguet, +@b{RTEMS Cache Management For Intel}}. -- cgit v1.2.3