[email protected]
original by Greg Hankins
This HOWTO covers basic info on the serial port which is missing on newer personal computers but is being used in recent embedded systems as well as for routers, point-of-sale equipment, etc. It includes multiport serial cards. It was written when the serial port was a major port for connecting a PC to modems and printers, etc. and the style of this article reflects this. If you're having problems with the serial port, want to understand how it works, or need a detailed introduction to it before studying serial programming, this is one place to find out about it.
This HOWTO is about the original serial port which uses a UART chip and is sometimes called a "UART serial port" to differentiate it from the newer types of serial devices: Universal Serial Bus or Firewire. It's slow compared to newer serial devices but can send text several times faster than you can read it. Information specific to devices which use serial ports: analog modems, text-terminals, infrared devices, and a few printers are found in Modem-HOWTO, Text-Terminal-HOWTO, Infrared-HOWTO, and Printing-HOWTO. Info on getty (the program that runs the login process or the like) has been also moved to other related HOWTOs since mgetty and uugetty are best for modems while agetty is best for text-terminals. If you are dealing with a modem, text terminal, infrared device, or printer, then you may not need to consult this HOWTO. But if you are using the serial port for some other device, using a multiport serial card, trouble-shooting the serial port itself, or want to understand more technical details of the serial port, then you may want to use this HOWTO as well as some of the other HOWTOs. (See Related HOWTO's) This HOWTO lists info on various multiport serial cards. This HOWTO addresses Linux running on PCs (ISA and/or PCI buses), although it might be valid for other architectures.
Copyright (c) 1993-1997 by Greg Hankins, (c) 1998-2005 by David S. Lawyer mailto:[email protected]
Please freely copy and distribute (sell or give away) this document in any format. Send any corrections and comments to the document maintainer. You may create a derivative work and distribute it provided that you:
If you're considering making a derived work other than a translation, it's requested that you discuss your plans with the current maintainer.
While I haven't intentionally tried to mislead you, there are likely a number of errors in this document. Please let me know about them. Since this is free documentation, it should be obvious that I cannot be held legally responsible for any errors.
Any brand names (starts with a capital letter such as MS Windows) should be assumed to be a trademark). Such trademarks belong to their respective owners.
Most of the original Serial-HOWTO was written by Greg Hankins. mailto:[email protected] He also rewrote many contributions by others in order to maintain continuity in the writing style and flow. He wrote: ``Thanks to everyone who has contributed or commented, the list of people has gotten too long to list (somewhere over one hundred). Special thanks to Ted Ts'o for answering questions about the serial drivers.'' Approximately half of v2.00 was from Greg Hankins HOWTO and the other half were additions by David Lawyer. Ted Ts'o has continued to be helpful. In Jan. 2006 "Charles Brockman" reviewed it for typos which resulted in many typos being fixed.
New versions will be issued perhaps every year or two. They will be available to browse and/or download at LDP mirror sites see: http://www.tldp.org/mirrors.html. Various formats are available. If you only want to quickly check the date of the latest version look at http://www.tldp.org/HOWTO/Serial-HOWTO.html and compare it to this version: v2.27 February 2011 .
For a full revision history going back to the time I started maintaining this HOWTO, see the source file (in linuxdoc format): (cvs) Serial-HOWTO.sgml
Modems, Text-Terminals, some printers, and other peripherals often used the serial port. Get these HOWTOs from the nearest mirror site as explained above.
Modem-HOWTO
is about installing and configuring modemsPrinting-HOWTO
has info for serial printers using old
lpr commandLPRng-HOWTO
(not a LDP HOWTO, may come with software)
has info for serial printing for "Next Generation" lprSerial-Programming-HOWTO
helps you write
C programs that read and write to the serial port
and/or check/set its state. A version written by Vern Hoxie but not
submitted to LDP is at
Internet section.Text-Terminal-HOWTO
is about how they work, how to install
configure, and repair them. It includes a section on "Make a
Terminal the Console" which is useful for using a remote terminal to
control a server (via the serial port).Remote-Serial-Console-HOWTO
is about making a
text-terminal be the console so it can display boot-time messages, etc. Please send me any suggestions, correction or additional
material. Tell me what you don't understand, or what could be
clearer. You can reach me via email at
mailto:[email protected]
.
The conventional serial port (not the newer USB port, or Firewire port) is a very old I/O (Input/Output) port. Until around 2006, most new desktop PC's had one, and old PC's from the 1990's sometimes had 2 of them. Most laptops gave up them before the desktops did. Macs (Apple Computer) after mid-1998 only had the USB port. However, it's possible, to put a conventional serial port device on the USB bus which is on all modern PCs.
Each serial port has a "file" associated with it in the /dev directory. It isn't really a file but it seems like one. For example, /dev/ttyS0. Other serial ports are /dev/ttyS1, /dev/ttyS2, etc. But ports on the USB bus, multiport cards, etc. have different names.
The common specification for the conventional serial port is RS-232 (or RS-232). So it's often called a "RS-232 serial port". The connector(s) for the serial port are often seen as one or two 9-pin connectors (in some cases 25-pin) on the back of a PC. But the serial port is more than just connectors. It includes the associated electronics which must produce signals conforming to the RS-232 specification. See Voltage Waveshapes. One pin is used to send out data bytes and another to receive data bytes. Another pin is a common signal ground. The other "useful" pins are used mainly for signalling purposes with a steady negative voltage meaning "off" and a steady positive voltage meaning "on".
The UART (Universal Asynchronous Receiver-Transmitter) chip does most of the work. Today, the functionality of this chip is usually built into another chip. See What Are UARTs? These have improved over time and old models (prior to say 1994) are usually very obsolete.
The serial port was originally designed for connecting external modems to a PC but it's used to connect many other devices also such as mice, text-terminals, some printers, etc. to a computer. You just plug these devices into the serial port using the correct cable. Many internal modem cards have a built-in serial port so when you install one inside your PC it's as if you just installed another serial port in your PC.
This repeats more detailed information found elsewhere. If your computer can't seem to find your serial port and you already know something about hardware resources (addresses like 3F8 and IRQs like 5) then try this: First, get into the BIOS (often called "setup") when the computer is powered on by pressing certain keys. To find out what keys to press, watch the screen as your PC starts up. If the words that flash by on the screen too fast to read, freeze them by holding down the "pause" and "shift" keys at the same time. Then when read, hit any key to resume (cease pausing) and hold down the key(s) required to enter the BIOS setup. You may have to try this again since there may be more than one screen which you can freeze with the "pause" key. Also, look for messages about the serial ports on these frozen screens.
Once in the BIOS menus, try to find menus dealing with the serial port. They could be shown in a menu dealing with Resources, Plug-and-Play, Peripherals, Ports, etc. Some old BIOSs setups (before 1995 ?) didn't deal with the serial ports. Make sure the ports you need are not disabled and note how they are configured (like 3F8 IRQ 4). You may need to change the configuration to prevent conflicts. There could be a shortage of IRQs if the BIOS has reserved some IRQs that it didn't need to reserve.
For serial ports to be found, either the kernel must have been compiled with serial support, or serial support must be provided by a module. To check this look in the file /boot/config-2.6... and search for SERIAL. =m means it's a module and you may check to see the modules that are being used by typing: lsmod.
Below is an introduction to the topic, but for a more advanced treatment of it see FIFOs.
Transmitting is sending bytes out of the serial port away from the computer (output). Once you understand transmitting, receiving (input) is easy to understand since it's similar. The first explanation given here will be grossly oversimplified. Then more detail will be added in later explanations. When the computer wants to send a byte out the serial port (to the external cable) the CPU sends the byte on the bus inside the computer to the I/O (Input Output) address of the serial port. I/O is often written as just IO. The serial port takes the byte, and sends it out one bit at a time (a serial bit-stream) on the transmit pin of the serial cable connector. For what a bit (and byte) look like electrically see Voltage Waveshapes.
Here's a replay of the above in a little more detail (but still very incomplete). Most of the work at the serial port is done by the UART chip (or the like). To transmit a byte, the serial device driver program (running on the CPU) sends a byte to the serial port"s I/O address. This byte gets into a 1-byte "transmit shift register" in the serial port. From this shift register bits are taken from the byte one-by-one and sent out bit-by-bit on the serial line. Then when the last bit has been sent and the shift register needs another byte to send, it could just ask the CPU to send it another byte. Thus would be simple but it would likely introduce delays since the CPU might not be able to get the byte immediately. After all, the CPU is usually doing other things besides just handling the serial port.
A way to eliminate such delays is to arrange things so that the CPU gets the byte before the shift register needs it and stores it in a serial port buffer (in hardware). Then when the shift register has sent out its byte and needs a new byte immediately, the serial port hardware just transfers the next byte from its own buffer to the shift register. No need to call the CPU to fetch a new byte.
The size of this serial port buffer was originally only one byte, but today it is usually 16 bytes (more in higher priced serial ports). Now there is still the problem of keeping this buffer sufficiently supplied with bytes so that when the shift register needs a byte to transmit it will always find one there (unless there are no more bytes to send). This is done by contacting the CPU using an interrupt.
First we'll explain the case of the old fashioned one-byte buffer, since 16-byte buffers work similarly (but are more complex). When the shift register grabs the byte out of the buffer and the buffer needs another byte, it sends an interrupt to the CPU by putting a voltage on a dedicated wire on the computer bus. Unless the CPU is doing something very important, the interrupt forces it to stop what it was doing and start running a program which will supply another byte to the port's buffer. The purpose of this buffer is to keep an extra byte (waiting to be sent) queued in hardware so that there will be no gaps in the transmission of bytes out the serial port cable.
Once the CPU gets the interrupt, it will know who sent the interrupt since there is a dedicated interrupt wire for each serial port (unless interrupts are shared). Then the CPU will start running the serial device driver which checks registers at I/0 addresses to find out what has happened. It finds out that the serial's transmit buffer is empty and waiting for another byte. So if there are more bytes to send, it sends the next byte to the serial port's I/0 address. This next byte should arrive when the previous byte is still in the transmit shift register and is still being transmitted bit-by-bit.
In review, when a byte has been fully transmitted out the transmit wire of the serial port and the shift register is now empty the following 3 things happen in rapid succession:
Thus we say that the serial port is interrupt driven. Each time the serial port issues an interrupt, the CPU sends it another byte. Once a byte has been sent to the transmit buffer by the CPU, then the CPU is free to pursue some other activities until it gets the next interrupt. The serial port transmits bits at a fixed rate which is selected by the user (or an application program). It's sometimes called the baud rate. The serial port also adds extra bits to each byte (start, stop and perhaps parity bits) so there are often 10 bits sent per byte. At a rate (also called speed) of 19,200 bits per second (bps), there are thus 1,920 bytes/sec (and also 1,920 interrupts/sec).
Doing all this is a lot of work for the CPU. This is true for many reasons. First, just sending one 8-bit byte at a time over a 32-bit data bus (or even 64-bit) is not a very efficient use of bus width. Also, there is a lot of overhead in handing each interrupt. When the interrupt is received, the device driver only knows that something caused an interrupt at the serial port but doesn't know that it's because a character has been sent. The device driver has to make various checks to find out what happened. The same interrupt could mean that a character was received, one of the control lines changed state, etc.
A major improvement has been the enlargement of the buffer size of the serial port from 1-byte to 16-bytes. This means that when the CPU gets an interrupt it gives the serial port up to 16 new bytes to transmit. This is fewer interrupts to service but data must still be transferred one byte at a time over a wide bus. The 16-byte buffer is actually a FIFO (First In First Out) queue and is often called a FIFO. See FIFOs for details about the FIFO along with a repeat of some of the above info.
Receiving bytes by a serial port is similar to sending them only it's in the opposite direction. It's also interrupt driven. For the obsolete type of serial port with 1-byte buffers, when a byte is fully received from the external cable it goes into the 1-byte receive buffer. Then the port gives the CPU an interrupt to tell it to pick up that byte so that the serial port will have room for storing the next byte which is currently being received. For newer serial ports with 16-byte buffers, this interrupt (to fetch the bytes) may be sent after 14 bytes are in the receive buffer. The CPU then stops what it was doing, runs the interrupt service routine, and picks up 14 to 16 bytes from the port. For an interrupt sent when the 14th byte has been received, there could be 16 bytes to get if 2 more bytes have arrived since the interrupt. But if 3 more bytes should arrive (instead of 2), then the 16-byte buffer will overrun. It also may pick up less than 14 bytes by setting it up that way or due to timeouts. See FIFOs for more details.
We've talked about small 16-byte serial port hardware buffers but there are also much larger buffers in main memory. When the CPU takes some bytes out of the receive buffer of the hardware, it puts them into a much larger (say 8k-byte) receive buffer in main memory. Then a program that is getting bytes from the serial port takes the bytes it's receiving out of that large buffer (using a "read" statement in the program).
A similar situation exists for bytes that are to be transmitted. When the CPU needs to fetch some bytes to be transmitted it takes them out of a large (8k-byte) transmit buffer in main memory and puts them into the small 16-byte transmit buffer in the hardware. And when a program wants to send bytes out the serial port, it writes them to this large transmit buffer.
Both of these buffers are managed by the serial driver. But the driver does more than just dealing with these buffers. It also does limited filtering (minor modifications) of data passing thru these buffers and listens for control certain characters. All this is configurable using the Stty program.
You don't have to understand the basics to use the serial port But understanding it may help to determine what is wrong if you run into problems. This section not only presents new topics but also repeats some of what was said in the previous section How the Hardware Transfers Bytes but in greater detail.
The UART serial port (or just "serial port for short" is an I/O (Input/Output) device.
An I/O device is just a way to get data into and out of a computer. There are many types of I/O devices such as the older serial ports and parallel ports, network cards, universal serial buses (USB), and firewire etc. Most pre-2007 PC's have a serial port or two (on older PC's). Each has a 9-pin connector (sometimes 25-pin) on the back of the computer. Computer programs can send data (bytes) to the transmit pin (output) and receive bytes from the receive pin (input). The other pins are for control purposes and ground.
The serial port is much more than just a connector. It converts the data from parallel to serial and changes the electrical representation of the data. Inside the computer, data bits flow in parallel (using many wires at the same time). Serial flow is a stream of bits over a single wire (such as on the transmit or receive pin of the serial connector). For the serial port to create such a flow, it must convert data from parallel (inside the computer) to serial on the transmit pin (and conversely).
Most of the electronics of the serial port is found in a computer chip (or a part of a chip) known as a UART. For more details on UARTs see the section What Are UARTS? But you may want to finish this section first so that you will hopefully understand how the UART fits into the overall scheme of things.
Old PC's used 25 pin connectors but only about 9 pins were actually used so later on most connectors were only 9-pin. Each of the 9 pins usually connects to a wire. Besides the two wires used for transmitting and receiving data, another pin (wire) is signal ground. The voltage on any wire is measured with respect to this ground. Thus the minimum number of wires to use for 2-way transmission of data is 3. Except that it has been known to work with no signal ground wire but with degraded performance and sometimes with errors.
There are still more wires which are for control purposes (signalling) only and not for sending bytes. All of these signals could have been shared on a single wire, but instead, there is a separate dedicated wire for every type of signal. Some (or all) of these control wires are called "modem control lines". Modem control wires are either in the asserted state (on) of +5 volts or in the negated state (off) of -5 volts. One of these wires is to signal the computer to stop sending bytes out the serial port cable. Conversely, another wire signals the device attached to the serial port to stop sending bytes to the computer. If the attached device is a modem, other wires may tell the modem to hang up the telephone line or tell the computer that a connection has been made or that the telephone line is ringing (someone is attempting to call in). See section Pinout and Signals for more details.
The serial port (not the USB) is usually a RS-232-C, EIA-232-D, or EIA-232-E. These three are almost the same thing. The original RS (Recommended Standard) prefix officially became EIA (Electronics Industries Association) and later EIA/TIA after EIA merged with TIA (Telecommunications Industries Association). The EIA-232 spec provides also for synchronous (sync) communication but the hardware to support sync is almost always missing on PC's. The RS designation is was intended to become obsolete but is still widely used and will be used in this howto for RS-232. Other documents may use the full EIA/TIA designation, or just EIA or TIA. For info on other (non-RS-232) serial ports see the section Other Serial Devices (not async RS-232)
Since the computer needs to communicate with each serial port, the operating system must know that each serial port exists and where it is (its I/O address). It also needs to know which wire (IRQ number) the serial port must use to request service from the computer's CPU. It requests service by sending an interrupt voltage on this wire. Thus every serial port device must store in its non-volatile memory both its I/O address and its Interrupt ReQuest number: IRQ. See Interrupts. The PCI bus has its own system of interrupts. But since the PCI-aware BIOS sets up these PCI interrupts to map to IRQs, it seemingly behaves just as described above. Except that sharing of PCI interrupts is allowed (2 or more devices may use the same IRQ number).
I/O addresses are not the same as memory addresses. When an I/O addresses is put onto the computer's address bus, another wire is energized. This both tells main memory to ignore the address and tells all devices which have I/O addresses (such as the serial port) to listen to the address sent on the bus to see if it matches the device's. If the address matches, then the I/O device reads the data on the data bus.
The I/O address of a certain device (such as ttyS2) will actually be a range of addresses. The lower address in this range is the base address. "address" usually means just the "base address".
The serial ports are named ttyS0, ttyS1, etc. (and usually correspond respectively to COM1, COM2, etc. in DOS/Windows). The /dev directory has a special file for each port. Type "ls /dev/ttyS*" to see them. Just because there may be (for example) a ttyS3 file, doesn't necessarily mean that there exists a physical serial port there.
Which one of these names (ttyS0, ttyS1, etc.) refers to which
physical serial port is determined as follows. The serial driver
(software) maintains a table showing which I/O address corresponds to
which ttyS. This mapping of names (such as ttyS1) to I/O addresses
(and IRQ's) may be both set and viewed by the "setserial" command.
See
What is Setserial. This does
not
set the I/O address and IRQ in the hardware itself (which is
set by jumpers or by plug-and-play software). Thus which physical port
corresponds to say ttyS1 depends both on what the serial driver thinks
(per setserial) and what is set in the hardware. If a mistake has
been made, the physical port may not correspond to any name (such as
ttyS2) and thus it can't be used. See
Serial Port Devices /dev/ttyS2, etc. for more details.
When the serial port receives a number of bytes (may be set to 1, 4, 8, or 14) into its FIFO buffer, it signals the CPU to fetch them by sending an electrical signal known as an interrupt on a certain wire normally used only by that port. Thus the FIFO waits until it has received a number of bytes and then issues an interrupt.
However, this interrupt will also be sent if there is an unexpected delay while waiting for the next byte to arrive (known as a timeout). Thus if the bytes are being received slowly (such as from someone typing on a terminal keyboard) there may be an interrupt issued for every byte received. For some UART chips the rule is like this: If 4 bytes in a row could have been received in an interval of time, but none of these 4 show up, then the port gives up waiting for more bytes and issues an interrupt to fetch the bytes currently in the FIFO. Of course, if the FIFO is empty, no interrupt will be issued.
Each interrupt conductor (inside the computer) has a number (IRQ) and the serial port must know which conductor to use to signal on. For example, ttyS0 normally uses IRQ number 4 known as IRQ4 (or IRQ 4). A list of them and more will be found in "man setserial" (search for "Configuring Serial Ports"). Interrupts are issued whenever the serial port needs to get the CPU's attention. It's important to do this in a timely manner since the buffer inside the serial port can hold only 16 incoming bytes. If the CPU fails to remove such received bytes promptly, then there will not be any space left for any more incoming bytes and the small buffer may overflow (overrun) resulting in a loss of data bytes.
There is no Flow Control to prevent this.
Interrupts are also issued when the serial port has just sent out all of its bytes from its small transmit FIFO buffer out the external cable. It then has space for 16 more outgoing bytes. The interrupt is to notify the CPU of that fact so that it may put more bytes in the small transmit buffer to be transmitted. Also, when a modem control line changes state, an interrupt is issued.
The buffers mentioned above are all hardware buffers. The serial port also has large buffers in main memory. This will be explained later
Interrupts convey a lot of information but only indirectly. The interrupt itself just tells a chip called the interrupt controller that a certain serial port needs attention. The interrupt controller then signals the CPU. The CPU then runs a special program to service the serial port. That program is called an interrupt service routine (part of the serial driver software). It tries to find out what has happened at the serial port and then deals with the problem such a transferring bytes from (or to) the serial port's hardware buffer. This program can easily find out what has happened since the serial port has registers at IO addresses known to the serial driver software. These registers contain status information about the serial port. The software reads these registers and by inspecting the contents, finds out what has happened and takes appropriate action.
Data (bytes representing letters, pictures, etc.) flows into and out of your serial port. Flow rates (such as 56k (56000) bits/sec) are (incorrectly) called "speed". But almost everyone says "speed" instead of "flow rate".
It's important to understand that the average speed is often less than the specified speed. Waits (or idle time) result in a lower average speed. These waits may include long waits of perhaps a second due to Flow Control. At the other extreme there may be very short waits (idle time) of several micro-seconds between bytes. If the device on the serial port (such as a modem) can't accept the full serial port speed, then the average speed must be reduced.
Flow control means the ability to slow down the flow of bytes in a wire. For serial ports this means the ability to stop and then restart the flow without any loss of bytes. Flow control is needed for modems and other hardware to allow a jump in instantaneous flow rates.
For example, consider the case where you connect a 33.6k external modem via a short cable to your serial port. The modem sends and receives bytes over the phone line at 33.6k bits per second (bps). Assume it's not doing any data compression or error correction. You have set the serial port speed to 115,200 bits/sec (bps), and you are sending data from your computer to the phone line. Then the flow from the your computer to your modem over the short cable is at 115.2k bps. However the flow from your modem out the phone line is only 33.6k bps. Since a faster flow (115.2k) is going into your modem than is coming out of it, the modem is storing the excess flow (115.2k -33.6k = 81.6k bps) in one of its buffers. This buffer would soon overrun (run out of free storage space) unless the high 115.2k flow is stopped.
But now flow control comes to the rescue. When the modem's buffer is almost full, the modem sends a stop signal to the serial port. The serial port passes on the stop signal on to the device driver and the 115.2k bps flow is halted. Then the modem continues to send out data at 33.6k bps drawing on the data it previous accumulated in its buffer. Since nothing is coming into this buffer, the number of bytes in it starts to drop. When almost no bytes are left in the buffer, the modem sends a start signal to the serial port and the 115.2k flow from the computer to the modem resumes. In effect, flow control creates an average flow rate in the short cable (in this case 33.6k) which is significantly less than the "on" flow rate of 115.2k bps. This is "start-stop" flow control.
In the above simple example it was assumed that the modem did no data compression. This could happen when the modem is sending a file which is already compressed and can't be compressed further. Now let's consider the opposite extreme where the modem is compressing the data with a high compression ratio. In such a case the modem might need an input flow rate of say 115.2k bps to provide an output (to the phone line) of 33.6k bps (compressed data). This compression ratio is 3.43 (115.2/33.6). In this case the modem is able to compress the 115.2 bps PC-to-modem flow and send the same data (in compressed form) out the phone line at 33.6bps. There's no need for flow control here so long as the compression ratio remains higher than 3.43. But the compression ratio varies from second to second and if it should drop below 3.43, flow control will be needed
In the above example, the modem was an external modem. But the same situation exists (as of early 2003) for most internal modems. There is still a speed limit on the PC-to-modem speed even though this flow doesn't take place over an external cable. This makes the internal modems compatible with the external modems.
In the above example of flow control, the flow was from the computer to a modem. But there is also flow control which is used for the opposite direction of flow: from a modem (or other device) to a computer. Each direction of flow involves 3 buffers: 1. in the modem 2. in the UART chip (called FIFOs) and 3. in main memory managed by the serial driver. Flow control protects all buffers (except the FIFOs) from overflowing.
Under Linux, the small UART FIFO buffers are not protected by flow control but instead rely on a fast response to the interrupts they issue. Some UART chips can be set to do hardware flow control to protect their FIFOs but Linux (as of early 2003) doesn't seem to support it. FIFO stand for "First In, First Out" which is the way it handles bytes in a queue. All the 3 buffers use the FIFO rule but only the one in the UART is named "FIFO". This is the essence of flow control but there are still some more details.
Understanding flow-control theory can be of practical use. The symptom of no flow control is that chunks of data missing from files sent without the benefit of flow control. When overflow happens, often hundreds or even thousands of bytes get lost, and all in contiguous chunks.
If feasible, it's best to use "hardware" flow control that uses two dedicated "modem control" wires to send the "stop" and "start" signals. Hardware flow control at the serial port works like this: The two pins, RTS (Request to send) and CTS (Clear to send) are used. When the computer is ready to receive data it asserts RTS by putting a positive voltage on the RTS pin (meaning "Request To Send to me"). When the computer is not able to receive any more bytes, it negates RTS by putting a negative voltage on the pin saying: "stop sending to me". The RTS pin is connected by the serial cable to another pin on the modem, printer, terminal, etc. This other pin's only function is to receive this signal.
For the case of a modem, this "other" pin will be the modem's RTS pin. But for a printer, another PC, or a non-modem device, it's usually a CTS pin so a "crossover" or "null modem" cable is required. This cable connects the CTS pin at one end with the RTS pin at the other end (two wires since each end of the cable has a CTS pin). For a modem, a straight-thru cable is used.
For the opposite direction of flow a similar scheme is used. For a modem, the CTS pin is used to send the flow control signal to the CTS pin on the PC. For a non-modem, the RTS pin sends the signal. Thus modems and non-modems have the roles of their RTS and CTS pins interchanged. Some non-modems such as dumb terminals may use other pins for flow control such as the DTR pin instead of RTS.
Software flow control uses the main receive and transmit data wires to send the start and stop signals. It uses the ASCII control characters DC1 (start) and DC3 (stop) for this purpose. They are just inserted into the regular stream of data. Software flow control is not only slower in reacting but also does not allow the sending of binary data unless special precautions are taken. Since binary data will likely contain DC1 and DC3 characters, special means must be taken to distinguish between a DC3 that means a flow control stop and a DC3 that is part of the binary code. Likewise for DC1.
It's been mentioned that there are 3 buffers for each direction of flow (3 pairs altogether): 16-byte FIFO buffers (in the UART), a pair of larger buffers inside a device connected to the serial port (such as a modem), and a pair of buffers (say 8k) in main memory. When an application program sends bytes to the serial port they first get stashed in the transmit serial port buffer in main memory. The other member of this pair consists of a receive buffer for the opposite direction of byte-flow. Here's an example diagram for the case of browsing the Internet with a browser. Transmit data flow is left to right while receive flow is right to left. There is a separate buffer for each direction of flow.
application 8k-byte 16-byte 1k-byte tele- BROWSER ------- MEMORY -------- FIFO --------- MODEM -------- phone program buffer buffer buffer line
For the transmit case, the serial device driver takes out say 15 bytes from this transmit buffer (in main memory), one byte at a time and puts them into the 16-byte transmit buffer in the serial UART for transmission. Once in that transmit buffer, there is no way to stop them from being transmitted. They are then transmitted to the modem or (other device connected to the serial port) which also has a fair sized (say 1k) buffer. When the device driver (on orders from flow control sent from the modem) stops the flow of outgoing bytes from the computer, what it actually stops is the flow of outgoing bytes from the large transmit buffer in main memory. Even after this has happened and the flow to the modem has stopped, an application program may keep sending bytes to the 8k transmit buffer until it becomes full. At the same time, the bytes stored in the FIFO continue to be sent out. Bytes stored in the modem will continue to be sent out the phone line unless the modem has gotten a modem-to-modem flow control stop from the modem at the other end of the phone line.
When the memory buffer gets full, the application program can't send any more bytes to it (a "write" statement in a C-program blocks) and the application program temporarily stops running and waits until some buffer space becomes available. Thus a flow control "stop" is ultimately able to stop the program that is sending the bytes. Even though this program stops, the computer does not necessarily stop computing since it may switch to running other processes while it's waiting at a flow control stop.
The above was a little oversimplified in three ways. First, some UARTs can do automatic hardware flow control which can stop the transmission out of the FIFO buffers if needed (not yet supported by Linux). Second, while an application process is waiting to write to the transmit buffer, it could possibly perform other tasks. Third, the serial driver (located between the memory buffer and the FIFO) has it's own small buffer (in main memory) used to process characters.
For many situations, there is a transmit path involving several links, each with its own flow control. For example, I type at a text-terminal connected to a PC and the PC (under my control) dials out to another computer using a modem. Today, a "text-terminal" is likely to be just another PC emulating a text-terminal. The main (server) PC, in addition to serving my text-terminal, could also have someone else sitting at it doing something else. Note that calling this PC a "server" is not technically correct but it does serve the terminal.
The text-terminal uses a command-line interface with no graphical display. Every letter I type at the text-terminal goes over the serial cable to my main PC and then over the phone line to the computer that I've dialed out to. To dial out, I've used the communication software: "minicom" which runs on my PC.
This sounds like a simple data path. I hit a key and the byte that key generates flows over just two cables (besides the keyboard cable): 1. the cable from my text-terminal to my PC and 2. the telephone line cable to some other computer. Of course, the telephone cable is actually a number of telephone system cables and includes switches and electronics so that a single physical cable can transmit many phone calls. But I can think of it like one cable (or one link).
Now, let's count the number and type of electronic devices each keystroke-byte has to pass thru. The terminal-to-PC cable has a serial port at each end. The telephone cable has both a serial port and a modem at each end. This adds up to 4 serial ports and 2 modems. Since each serial port has 2 buffers, and each modem one buffer, that adds up to 10 buffers. And that's just for one direction of flow. Each byte also must pass thru the minicom software as well.
While there's just 2 cables in the above scenario, if external modems were used there would be an additional cable between each modem and it's serial port. This makes 4 cables in all. Even with internal modems it's like there is a "virtual cable" between the modem and its serial port. On all these 4 links (or cables), flow control takes place.
Now lets consider an example of the operation of flow control. Consider the flow of bytes from the remote computer at the other end of the phone line to the screen on the text-terminal that I'm sitting at. A real text-terminal has a limit to the speed at which bytes can be displayed on its screen and issues a flow control "stop" from time to time to slow down the flow. This "stop" propagates in a direction opposite to the flow of bytes it controls. What happens when such a "stop" is issued? Let's consider a case where the "stop" waits long enough before canceling it with a "start", so that it gets thru to the remote computer at the other end of the phone line. When it gets there it will stop the program at the remote computer which is sending out the bytes.
Let's trace out the flow of this "stop" (which may be "hardware" on some links and "software" on others). First, suppose I'm "capturing" a long file from the remote computer which is being sent simultaneously to both my text-terminal and to a file on my hard-disk. The bytes are coming in faster than the terminal can handle them so it sends a "stop" out its serial port to a serial port on my PC. The device driver detects it and stops sending bytes from the 8k PC serial buffer (in main memory) to the terminal. But minicom still keeps sending out bytes for the terminal into this 8k buffer.
When this 8k transmit buffer (on the first serial port) is full, minicom must stop writing to it. Minicom stops and waits. But this also causes minicom to stop reading from the 8k receive buffer on the 2nd serial port connected to the modem. Flow from the modem continues until this 8k buffer too fills up and sends a different "stop" to the modem. Now the modem's buffer ceases to send to the serial port and also fills up. The modem (assuming error correction is enabled) sends a "stop signal" to the other modem at the remote computer. This modem stops sending bytes out of its buffer and when its buffer gets full, another stop signal is sent to the serial port of the remote computer. At the remote computer, the 8-k (or whatever) buffer fills up and the program at the remote computer can't write to it anymore and thus temporarily halts.
Thus a stop signal from a text terminal has halted a program on a remote computer computer. What a long sequence of events! Note that the stop signal passed thru 4 serial ports, 2 modems, and one application program (minicom). Each serial port has 2 buffers (in one direction of flow): the 8k one and the hardware 16-byte one. The application program may have a buffer in its C_code. This adds up to 11 different buffers the data is passing thru. Note that the small serial hardware buffers do not participate directly in flow control. Also note that the two buffers associated with the text-terminal's serial port are going to be dumping their contents to the screen during this flow control halt. This leaves 9 other buffers that may be getting filled up during the flow control halt.
If the terminal speed limitation is the bottleneck in the flow from the remote computer to the terminal, then its flow control "stop" is actually stopping the program that is sending from the remote computer as explained above. But you may ask: How can a "stop" last so long that 9 buffers (some of them large) all get filled up? It seldom happens, but it can actually happen this way if all the buffers were near their upper limits when the terminal sent out the "stop".
But if you were to run a simulation on this you would discover that it's usually more complicated than this. At an instant of time some links are flowing and others are stopped (due to flow control). A "stop" from the terminal seldom propagates back to the remote computer neatly as described above. It may take a few "stops" from the terminal to result in one "stop" at the remote computer, etc. To understand what is going on you really need to observe a simulation which can be done for a simple case with coins on a table. Use only a few buffers and set the upper level for each buffer at only a few coins.
Does one really need to understand all this? Well, understanding this explained to me why capturing text from a remote computer was loosing text. The situation was exactly the above example but modem-to-modem flow control was disabled. Chunks of captured text that were supposed to also get to my hard-disk never got there because of an overflow at my modem buffer due to flow control "stops" from the terminal. Even though the remote computer had a flow path to the hard-disk without bottlenecks, the same flow also went to a terminal which issued flow control "stops" with disastrous results for the branch of the flow going to a file on the hard-disk. The flow to the hard-disk passed thru my modem and since the overflow happened at the modem, bytes intended for the hard-disk were lost.
The device driver for the serial port is the software that
operates the serial port. It is now provided as a serial module.
From kernel 2.2 on, this module will normally get loaded automatically
if it's needed. In earlier kernels, you had to have kerneld
running in order to do auto-load modules on demand. Otherwise the
serial module needed to be explicitly listed in /etc/modules. Before
modules became popular with Linux, the serial driver was usually built
into the kernel (and sometimes still is). If it's built-in don't let
the serial module load or else you will have two serial drivers
running at the same time. With 2 drivers there are all sorts of
errors including a possible "I/O error" when attempting to open a
serial port. Use "lsmod" to see if the module is loaded.
When the serial module is loaded it displays a message on the screen
about the existing serial ports (often showing a wrong IRQ). But once
the module is used by setserial
to tell the device driver the
(hopefully) correct IRQ then you should see a second display similar
to the first but with the correct IRQ, etc. See
Serial Module
See
What is Setserial for more info on
setserial
.
The serial port is today (2011) sort of obsolete on PCs (and often called a "legacy" device) but it is still in use on some older computers and is used in imbedded systems, for communication with routers and point-of-sale equipment, etc. The serial port is slow and after about 2005 most new PC's no longer had them. Most laptops and Macs discontinued them even earlier. During the era when some new PC's came with serial ports and others didn't, the PC's that didn't have serial ports were euphemistically called "legacy-free". However, while PC's today no longer have serial ports, some do have them built into a "legacy" modem (which plugs into a telephone line). Such a serial port only works with the modem and can't be used for any other device. The reason they have such a "built in" serial port is that analog modems are designed to only work thru a serial port.
The physical serial port on the back of a PC (including the chip its connected to inside the PC), must pass data between the computer and an external cable. Thus it has two interfaces: the serial-port-to cable and the serial-port-to-computer-bus. Both of these interfaces are slow. First we'll consider the interface via external cable to the outside world.
The conventional RS-232 serial port is inherently low speed and is severely limited in distance. Ads often read "high speed" but it can only work at "high speed" over very short distances such as to a modem located right next to the computer. Compared to a network card, even this "high speed" is actually low speed. All of the RS-232 serial cable wires use a common ground return wire so that twisted-pair technology (needed for high speeds) can't be used without additional hardware. More modern interfaces for serial ports exist but they are not standard on PC's like the RS-232 is. See Successors to RS-232. Some multiport serial cards support them.
It is somewhat tragic that the RS-232 standard from 1969 did not use twisted pair technology which could operate about a hundred times faster. Twisted pairs have been used in telephone cables since the late 1800's. In 1888 (over 120 years ago) the "Cable Conference" reported its support of twisted-pair (for telephone systems) and pointed out its advantages. But over 80 years after this approval by the "Cable Conference", RS-232 failed to utilize it. Since RS-232 was originally designed for connecting a terminal to a low speed modem located nearby, the need for high speed and longer distance transmission was apparently not recognized. The result was that since the serial port couldn't handle high speeds, new types of serial interfaces were devised that could: Ethernet, USB, Firewire, etc. The final outcome was the demise of the serial port which due to it's ancient technology became obsolete for high speed uses.
The serial port communicates with the computer via the PCI bus, the LPC bus, X-bus, or ISA bus. The PCI bus is now 32 or 64 bits wide, but the serial port only sends a byte at a time (8 bits wide) which is a waste of PCI bus bandwidth. Not so for the LPC bus which has only a 4-bit wide bus and thus provides an efficient interface. The ISA bus is usually 16-bits wide and the efficiency is intermediate as compared to efficient LPC and inefficient PCI.
Multiport serial cards install in slots in a PC on the ISA or PCI bus. They are also called "... adapters" or "... boards". Each such card provides you with many serial ports. Today they are commonly used for the control of external devices (including automation for both industry and the home). They can connect to computer servers for the purpose of monitoring/controlling the server from a remote location. They were once mainly used for connecting up many dumb terminals and/or modems to serial ports. Today, use of dumb terminals has declined, and several modems (or digital modems) can now be built into an internal card. So multiport serial cards are not as significant as they once were.
Each multiport card has a number of external connecters (DB-25 or RJ45) so that one may connect up a number of devices (modems, terminals, etc.). Each such physical device would then be connected to its own serial port. Since the space on the external-facing part of the card is limited there is often not enough room for all the serial port connectors. To solve this problem, the connectors may be on the ends of cables which come out (externally) from the card (octopus cable). Or they may be on an external box (possibly rack mountable) which is connected by a cable to a multiport card.
Dumb multiport cards are not too much different than ordinary serial ports. They are interrupt driven and the CPU of the computer does most all the work servicing them. They usually have a system of sharing a single interrupt for all the ports. This doesn't decrease the load on the CPU since the single interrupt will be sent to the CPU each time any one port needs servicing. Such devices usually require special drivers that you must either compile into the kernel or use as a module.
Smart boards may use ordinary UARTs but handle most interrupts from the UARTs internally within the board. This frees the CPU from the burden of handling all these interrupts. The board may save up bytes in its large internal FIFOs and transfer perhaps 1k bytes at a time to the serial buffer in main memory. It may use the full bus width of 32 bits for making data transfers to main memory (instead of transferring only 8-bit bytes like dumb serial cards do). Not all "smart" boards are equally efficient. Many boards today are Plug-and-Play.
For a multiport board to work, a special driver for it must be used. This driver may either be built into the kernel source code or supplied as a module. For the 2.6 kernels on, most drivers are supplied both ways: as a module or it can be built into the kernel. Take care not to both build support into the kernel and force the module to load for a certain serial card. For older kernels, there were often no modules for dumb serial multiport boards so support was built into the kernel.
A pre-compiled kernel may not have a driver for your multiport card built in. So then you must either compile the kernel yourself and build in the right driver, or insure that the module is available and loads. Of course if the driver doesn't come both ways (as a compile-time option and as a module) you have no such choice.
If you want to see what has already been compiled into an existing working kernel, go the the /boot directory (or wherever the compiled kernel(s) reside) and look in the config... file.
In the 2.6 kernel there are many options to select from in the configuration file for compiling. Adding support for certain multiport cards is listed under the headings "Character devices" or "Serial drivers". Old multiport cards had support as part of the serial driver and are found under "Serial Drivers". More advanced cards have their own driver found under "Character devices"
For compiling kernel 2.6 you should select "CONFIG_SERIAL_8250_EXTENDED". (or just "CONFIG_SERIAL_EXTENDED" for 2.4). Then you will be asked more questions about your serial ports with more options to select. If the resulting configuration is not quite right, then you may need to edit the kernel configuration file manually.
A pre-compiled kernel may come with a pre-compiled module for the
board so that you don't need to recompile the kernel. This module
must be loaded in order to use it and if there is installation
software for the driver, it should also set up Linux to load the
module (probably at boottime). Some of the modules to load at
boottime are listed in /etc/modules or /etc/modules.conf
Also certain parameters may need to be passed
to the driver via entries in these files or via lilo's "append"
command or via grub's "kernel" command. For kernel 2.6 (and 2.4) the
(unloaded) modules should be found in
/lib/modules/.../kernel/drivers/char.
The board's manufacturer should have info on their website. Unfortunately, info for old boards is sometimes not there but might be found somewhere else on the Internet (including discussion groups). You might also want to look at the kernel documentation in /usr/share/doc/linux-doc... (formerly kernel-doc in pre 2.6 kernels). For configuring the kernel or modules prior to compiling see: Configure.help and search for "serial", etc. There are also kernel documentation files for certain boards including computone, hayes-esp, moxa-smartio, riscom8, specialix, stallion, and sx (specialix).
The serial ports your multiport board uses depends on what kind of
board you have. Some have their own device names like /dev/ttyE27
(Stallion) or /dev/ttyD2 (Digiboard), etc. For various other brands,
see see devices.txt in the kernel documentation. Some use the
standard names like /dev/ttyS14 and may be found in configuration
files that used as arguments to setserial
. Such files may be
included in a setserial or serial package.
An installation script may do this for you. But if not, here's some examples of how to create a device name in the /dev directory. If you use udev, MAKEDEV will not create devices in the device directory since this directory is only in memory and will be lost when you turn off the computer. Instead it will create the device indev/.static/dev directory.
For the names and numbers of other types of serial ports other
than ttyS.. See devices.txt in the kernel documentation. Either use
the mknod
command, or the MAKEDEV
script. Typing "man
makedev" may show instructions on using it.
Using the MAKEDEV
script, you would first become the superuser
(root) and type (for example) either:
linux# MAKEDEV ttyS17
Or if the above doesn't work cd to /dev before giving the above command>. Substitute whatever your port is for ttyS17.
Using mknod
is a more complicated option since you need to know
the major and minor device numbers. These numbers are in the
"devices" file in the kernel documentation. For ttyS serial ports the
minor number is: 64 + port number (=81 for the example below). Note
the "major" number is always 4 for ttyS devices (and 5 for the
obsolete cua devices). So, if you wanted to create a device for
ttyS17
using mknod
, you would type:
linux# mknod -m 666 /dev/ttyS17 c 4 81
In olden days, PCs came with a serial card installed. Later on, the serial function was put on the hard-drive interface card. In the 1990s and early 2000s one or two serial ports were usually built into the motherboard (on-board). Most of them (as of 2002) use a 16550 but some use 16650 (32-byte FIFOs). But one may still buy the individual PC serial cards if they need more serial ports. They can be used to connect external serial devices (modems, serial mice, etc...). Only a tiny percentage of retail computer stores carry such cards. But one can purchase them on the Internet. Before getting one for the PCI bus, make sure Linux supports it.
Here's a list of a few popular brands:
Note: due to address conflicts, you may not be able to use /dev/ttyS3 with a IBM8514 video card (and some others) simultaneously. See Avoiding IO Address Conflicts with Certain Video Boards
They are also called "serial adapters". Each port has its own
address. They often have a special method of sharing interrupts which
requires that you compile support for them into the kernel.
* => The file that ran setserial in Debian shows some details of
configuring
# => See note below for this board
In general, Linux will support any serial board which uses a 8250, 16450, 16550, 16550A, 16650, 16650V2, 16654, 16750, 16850, 16950, and 16954. UART. See the latest man page for "setserial" for a more complete list.
Notes:
AST Fourport: You might need to specify skip_test
in rc.serial
.
BB-1004 and BB-1008 do not support DCD and RI lines, and thus are not usable for dialin modems. They will work fine for all other purposes.
Digi PC/8 Interrupt Status Register is at 0x140.
SIIG IO1812 manual for the listing for COM5-COM8 is wrong. They should be COM5=0x250, COM6=0x258, COM7=0x260, and COM8=0x268.
Make sure that a Linux-compatible driver is available and read the information that comes with it. These boards use special devices (in the /dev directory), and not the standard ttyS ones. This information varies depending on your hardware. If you have updated info which should be shown here please email it to me.
Names of Linux driver modules are *.ko (*.o prior to kernel 2.6) but these may not work for all models shown. See Modules (mostly for smart boards) The needed module may have been supplied with your Linux distribution. Also, parameters (such as the io and irq often need to be given to the module so you need to find instructions on this (possibly in the source code tree).
There are many different brands, each of which often offers many different cards. No attempt is currently being made to list all the cards here (and many listed are obsolete and have bad internet links to them which need to be fixed). But all major brands and websites should be shown here so it something is missing let me know. Go to the webpage shown for more information. These websites often also have info (ads) on related hardware such as modem pools, remote access servers (RASs), and terminal servers. Where there is no webpage, the cards are likely obsolete. If you would like to put together a better list, let me know.
http://www.perle.com
http://www.comtrol.com
ftp://tsx-11.mit.edu/pub/linux/packages/comtrol
http://www.connecttech.com/
http://www.cyclades.com/products/svrbas/zseries.php
ftp://ftp.cyclades.com/pub/cyclades
and included in Linux
kernel since version 1.1.75: cyclades.o
mailto:[email protected]
ftp://ftp.cendio.se/pub/pccom8
http://www.dgii.com
ftp://ftp.dgii.com/drivers/linux
and
included in Linux kernel since version 2.0. epca.o
[email protected]
http://www.equinox.com
ftp://ftp.equinox.com/library/sst
http://www.gtek.com
ftp://ftp.gtek.com/pub
http://www.nyx.net/~arobinso
http://www.nyx.net/~arobinso
http://www.maxpeed.com
ftp://maxpeed.com/pub/ss
http://www.moxa.com
http://www.moxa.com/support/download/download.php3>
ftp://ftp.moxa.com/drivers/linux
(also from Taiwan at www.moxa.com.tw/...) where ... is the same as
above)
http://www.sdlcomm.com
ftp://ftp.sdlcomm.com/pub/drivers
[email protected]
or
http://www.stallion.com
ftp://ftp.stallion.com/drivers/ata5/Linux
and
included in linux kernel since 1.3.27. Moved: it's now at ?.
A review of Comtrol, Cyclades, Digi, and Stallion products was printed in the June 1995 issue of the Linux Journal. The article is available at Review: Intelligent Multiport Serial Boards Besides the listing of various brands of multiports found above in this HOWTO there is Gary's Encyclopedia - Serial Cards. It's not as complete, but may have some different links.
The following brands that formerly made boards for with Linux support don't mention any Linux support as of 1 Jan. 2000. Let me know if this changes.
A computer that has many serial ports (with many serial cables connected to it) is often called a server. Of course, most servers serve other functions besides just serving serial ports, and many do not serve serial ports at all (although they likely have a serial port on them). For example, a "serial server" may have serial cables, each of which runs to a different (non-serial) server. The serial server (perhaps called a "console server") controls, via a console, all the other servers. The console may be physically located remote from the serial server, communicating with the server over a network.
There are two basic types of serial servers. One type is just an ordinary computer (perhaps rack mounted) that uses multiport cards on a PCI bus (or the like). The other type is a proprietary server that is a dedicated computer that serves a special purpose. Servers of both types may be called: serial servers, console servers, print servers, or terminal servers. They are not the same.
The terminal server was originally designed to provide many serial ports, each connected to a dumb text-terminal. Today, a terminal server often connects to graphic terminals over a fast network and doesn't use serial ports since they are too slow. One network cable takes the place of many serial cables and each graphic terminal uses far more bandwidth than the text-terminals did. However, graphic terminals may be run in text mode to reduce the bandwidth required. A more detailed discussion of terminal servers (serial port) is in Text-Terminal-HOWTO. For networked terminal servers (not serial port) see Linux Terminal Server Project (LTSP)
(To-do: Discuss other types of serial servers, but the author knows little about them.)
In most cases configuring is automatically taken care of and you have nothing to do. Linux should detect your serial ports, and load driver modules if needed. Then the driver should insure that IRQ and address space resources have been allocated. Finally, the application program which uses the serial port should set the port speed, etc.
For any of this to work, serial support must either be compiled into the kernel (by you or by whoever compiled your kernel) or provided by modules that are loaded into the kernel when you start to use the serial port. In most cases, if it hasn't been compiled into the kernel, a module(s) will do the job and Linux should hopefully automatically find and load the correct modules.
But if you have more than 4 (or perhaps 2) serial ports, then the kernel must be told this as it doesn't seem to do it automatically. See Number of Serial Ports Supported, Kernel Configuration and. Serial Modules.
Once the proper support is in your kernel and modules, then The rest of the configuring of the serial port should happen automatically. This is done by the serial driver software often with help from your application software. But sometimes it doesn't get configured right and then you need to do it yourself. Or perhaps you need to configure it in a special way, etc. This HOWTO only covers configuration of the serial port itself and not the configuring of any devices attached to the port (such as a modem or printer).
Resource allocation (locating the hardware or low-level configuring) is assigning each port an IO address, IRQ, and name (such as ttyS2). This IO-IRQ pair must be set in both the hardware and become known to the serial driver. We might just call this "io-irq" configuring for short. The "setserial" program is sometimes used to tell the driver io-irq info that an administrator has put in a configuration file or given as parameters to the setserial command. PnP methods, jumpers, etc, are used to set the IO and IRQ in the hardware. Details will be supplied later. If you need to configure but don't understand certain details it's easy to get into trouble. See Locating the Serial Port: IO address IRQs What is Setserial
The second part (high-level configuring) is assigning it a speed (such
as 115.2k bits/sec), selecting flow control, etc. This is often
initiated by communication programs such as wvdial, PPP, minicom,
picocom or by getty (which you may run on the port so that others may
log into your computer from an old-fashioned dumb terminal connected
to the port). However you will need to tell these programs what speed
you want, etc. by using a menu or a configuration file. This
high-level configuring may also be done manually with the stty
program. stty
is also useful to view the current status if
you're having problems. See the section
Stty
If you need to find a serial port it often helps if you know what bus it's on. If the serial port is on a card, you may know what bus the card inserts into such as a PCI slot. But if the serial port is built into the motherboard it may not be clear what bus it's on. For old motherboards that have ISA bus slots, it's likely on the ISA bus and may not even be Plug-and-Play. But even if all your slots are PCI, the serial port is likely to be on either an ISA bus or LPC bus (also called a "LPC interface"). LPC is common on laptop computers. Type "lspci" to see if it shows "LPC". Unfortunately, the LPC bus has no standard Plug-and-Play method for low-level configuring devices on it. But according to the specs, the BIOS is supposed to do such configuring (using ACPI ??). To see if you have a LPC bus, type "lspci" and look for a LPC bridge or the like.
For a serial port to work properly it first must be given both an IO address and an IRQ. For old hardware (of mid 1990s), jumpers on a card or a saved BIOS setting does it. For newer hardware the BIOS or Linux must set them at boot-time, and the new hardware doesn't remember how it was set once it's powered down. Enabling the hardware (by using software) gives it both an IRQ and an IO address. Without an IO address, it can't be used. Without an IRQ it will need to use inefficient polling methods for which one must set the IRQ to 0 in the serial driver. Using digital signals sent to the hardware by the BIOS or Linux, it all should get configured automatically (provided the BIOS has not been previously set up to disable it). So you only need to read this if you're having problems or if you want to understand how it works.
The driver must of course know both the IO address and IRQ so that it can talk to the serial port chip. Modern serial port drivers (kernel 2.4) try to determine this by PnP methods so one doesn't normally need to tell the driver (by using "setserial"). A driver may also set an IO address or IRQ in the hardware. But unfortunately, there is some PCI serial port hardware that the driver doesn't recognize so you might need to enable the port yourself. See PCI: Enabling a disabled port
For the old ISA bus, the driver also probes likely serial port addresses to see if there are any serial ports there. This works for the case of jumpers and sometimes works for a ISA PnP port when the driver doesn't do ISA PnP (prior to kernel 2.4).
Locating the serial port by giving it an IRQ and IO address is low-level configuring. It's often automatically done by the serial driver but sometimes you have to do it yourself. What follows repeats what was said above but in more detail.
The low-level configuring consists of assigning an IO address, IRQ, and names (such as ttyS2) . This IO-IRQ pair must be set in both the hardware and told to the serial driver. And the driver needs to call this pair a name (such as ttyS2). We could call this "io-irq" configuring for short. The modern way to do this is for the driver to use PnP methods to detect/set the IO/IRQ and then remember what it did. An easy way for a driver to do this is for the driver to ask the kernel to enable the device and then the kernel tells the driver what IO/IRQ it has used. The old way is using the "setserial" program to tell the driver. For jumpers, there is no PnP but the driver might detect the port if the jumpers are set to the usual IO/IRQ. If you need to configure but don't understand certain details it's easy to get into trouble.
When Linux starts, an effort is made to detect and configure (low-level) the serial ports. Exactly what happens depends on your BIOS, hardware, Linux distribution, kernel version, etc. If the serial ports work OK, there may be no need for you to do any more low-level configuring.
If you're having problems with the serial ports, then you may need to do low-level configuring. If you have kernel 2.2 or lower, then you need to do it if you:
Starting with kernel 2.2 you may be able to use more than 2 serial ports without doing any low-level configuring by sharing interrupts. All PCI ports should support this but for ISA it only works for some hardware. It may be just as easy to give each port a unique interrupt if they are available. See Interrupt sharing and Kernels 2.2+
The low-level configuring (setting the IRQ and IO address) seems to cause people more trouble than the high-level stuff, although for many it's fully automatic and there is no configuring to be done. Until the port is enabled and the serial driver knows the correct IRQ and IO address, the port will not usually not work at all.
A port may be disabled, either by the BIOS or by failure of Linux to find and enable the port. For modern ports (provided the BIOS hasn't disabled them) manual PnP tools such as lspci should be able to find them. Applications, and utilities such as "setserial" and "scanport" (Debian only ??) only probe IO addresses, don't use PnP tools, and thus can't detect disabled ports.
Even if an ISA port can be found by the probing done by the serial driver it may work extremely slow if the IRQ is wrong. See Extremely Slow: Text appears on the screen slowly after long delays. PCI ports are less likely to get the IRQ wrong.
IO address, IRQs, etc. are called "resources" and we are thus configuring certain resources. But there are many other types of "resources" so the term has many other meanings. In summary, the low-level configuring consists of enabling the device, giving it a name (ttyS2 for example) and putting two values (an IRQ number and IO address) into two places:
setserial
")You may watch the start-up (= boot-time) messages. They are usually correct. But if you're having problems, your serial port may not show up at all or if you do see a message from "setserial" it may not show the true configuration of the hardware (and it is not necessarily supposed to). See I/O Address & IRQ: Boot-time messages.
If you have kernel 2.4 or better, then there should be support for PnP for both the PCI and ISA buses (either built-in or by modules). Some PCI serial ports can be automatically detected and low-level configured by the serial driver. Others may not be.
While kernel 2.2 supported PCI in general, it had no support for PCI serial ports (although some people got them working anyway). Starting with kernel 2.4, the serial driver will read the id number digitally stored in the serial hardware to determine how to support it (if it knows how). It should assign an I/O address to it, determine its IRQ, etc. So you don't need to use "setserial" for it.
There is a possible problem if you don't use the device filesystem.
The driver may assign the port to say tt/ttyS4 per a boot-time
message (use dmesg
to see it). But if you don't have a "file"
/dev/ttyS4 then the port will not work. So you will then need to
create it, using
cd /dev; ./MAKEDEV ttyS4
PCI ports are not well standardized. Some use main memory for communication with the PC. Some require special enabling of the IRQ. The output of "lspci -vv" can help determine if one can be supported. If you see a 4-digit IO port, the port might work by just telling "setserial" the IO port and the IRQ. For example, if lspci shows IRQ 10, I/O at 0xecb8 and you decide to name it ttyS2 then the command is:
setserial /dev/ttyS2 irq 10 port 0xecb8 autoconfig
Note that the boot-time message "Probing PCI hardware" means reading the PnP configuration registers in the PCI devices which detects info about all PCI cards and on-board PCI devices. This is different than the probing of IO addresses by the serial driver which means reading certain IO addresses to see if what's read looks like there's a serial port at that address.
Here are some common mistakes people make:
There are really two answers to the question "What is my IO and IRQ?" 1. What the device driver thinks has been set (This is what setserial usually sets and shows.). 2. What is actually set in the hardware. Both 1. and 2. above should be the same. If they're not it spells trouble since the driver has incorrect info on the physical serial port. In some cases the hardware is disabled so it has no IO address or IRQ.
If the driver has the wrong IO address it will try to send data to a non-existing serial port --or even worse, to some other device. If it has the wrong IRQ the driver will not get interrupt service requests from the serial port, resulting in a very slow or no response. See Extremely Slow: Text appears on the screen slowly after long delays. If it has the wrong model of UART there is also apt to be trouble. To determine if both IO-IRQ pairs are identical you must find out how they are set in both the driver and the hardware.
What the driver thinks is not necessarily how the hardware is actually set. If everything works OK then what the driver thinks is likely correct (set in the hardware) and you don't need to investigate (unless you're curious or want to become a guru). Ways to determine what the driver thinks include: boot-time messages I/O Address & IRQ: Boot-time messages, the /proc directory "files" The /proc directory and setserial, and the "setserial" command.
In many cases your ports will automatically get low-level configured at boot-time (but not always correctly). To see what is happening, look at the start-up messages on the screen. Don't neglect to check the messages from the BIOS before Linux is loaded (no examples shown here). These BIOS messages may be frozen by pressing the Pause key (while holding down shift). It's often tricky to freeze them and you may need to hit Ctrl-Alt-Del while Linux is booting to start rebooting and try again. What these messages display may change as booting progresses and it's often tricky to freeze it at exactly the right words.
Use Shift-PageUp to scroll back to the messages after they have
flashed by. Shift-PageDown will scroll in the opposite direction.
The dmesg
command (or looking at logs in /var/log) will show only
the first of these two messages. Here's an example of the start-up
messages (as of 2004, almost the same as for 1999). Note that in
older versions ttyS1 was displayed in these messages as ttyS01, etc.
At first you see what was detected (but the irq is only a wild guess):
Serial driver version 4.27 with no serial options enabled
ttyS0 at 0x03f8 (irq = 4) is a 16550A
ttyS1 at 0x02f8 (irq = 3) is a 16550A
ttyS2 at 0x03e8 (irq = 4) is a 16550A
ttyS4 at port 0xeff0 (irq = 10) is a 16550A
Note that ttyS0-ttyS2 were detected by probing the standard addresses while ttyS4 is a PCI port detected by probing the PCI configuration. Later setserial shows you what was saved in a configuration file (which you may edit), but it's not necessarily correct either:
Loading the saved-state of the serial devices...
/dev/ttyS1 at 0x02f8 (irq = 3) is a 16550A
/dev/ttyS2 at 0x03e8 (irq = 5) is a 16550A
Note that the configuration file only had ttyS1-2 in it so that ttyS0 and ttyS4 were not affected by it. There is also a slight discrepancy: The first message shows ttyS2 at irq=4 while the second shows it at irq=5. In most cases the second message is the correct one. But if you're having trouble, it may be misleading. Before reading the explanation of all of this complexity in the rest of this section, you might just try using your serial port and see if it works OK. If so it may not be essential to read further.
The second message is from the setserial
program being run at
boot-time from a script in the /etc directory tree. It shows what the
device driver thinks is the correct configuration. But this too could
be wrong. For example, the irq could actually be set to irq=8 in the
hardware (both messages wrong). The irq=5 could be there because the
configuration file is incorrect.
With old jumper-set serial ports Linux sometimes gets IRQs wrong because it doesn't by default probe for IRQs. It just assumes the "standard" ones (first message) or accepts what is in a configuration file (second message). Neither of these is necessarily correct. If the serial driver has the wrong IRQ, the serial port is very slow or doesn't seem to work at all.
The first message is a result of Linux probing the ISA serial port
addresses but it doesn't probe for IRQs. If a port shows up here it
exists but the IRQ may be wrong. Linux doesn't check IRQs because
doing so is not foolproof. It just assumes the IRQs are as shown
because they are the "standard" values. You may check them manually
with setserial
using the autoconfig
and auto_irq
options but this isn't guaranteed to be correct either.
The data shown by the BIOS messages (which you see at first before Linux is booted) are what is initially set in the hardware. If your serial port is Plug-and-Play (PnP) then it's possible that "isapnp" or "setpci" will run and change these settings. Look for messages about this after Linux starts. The last serial port message shown in the example above should agree with the BIOS messages (as possibly modified by isapnp or setpci). If they don't agree then you either need to change the setting in the port hardware or use setserial to tell the driver what is actually set in the hardware.
Also, if you have Plug-and-Play (PnP) serial ports, they can only be found by PnP software unless the IRQ and IO has been set inside the hardware by Plug-and-Play software. Prior to kernel 2.4 this was a common reason why the start-up messages did not show a serial port that physically exists. A PnP BIOS may automatically low-level configure them. PnP configuring will be explained later.
Type "setserial -g /dev/ttyS*". There are some other ways to find this info by looking at "files" in the /proc directory. Be warned that there is no guarantee that the same is set in the hardware.
/proc/ioports
will show the IO addresses that the drivers are using.
/proc/interrupts
shows the IRQs that are used by drivers of
currently running processes (that have devices open). It shows how
many interrupts have actually be issued.
/proc/tty/driver/serial
shows much of the above, plus the
number of bytes that have been received and sent (even if the device
is not now open).
Note that for the IO addresses and IRQ assignments, you are only seeing what the driver thinks and not necessarily what is actually set in the hardware. The data on the actual number of interrupts issued and bytes processed is real however. If you see a large number of interrupts and/or bytes then it probably means that the device is (or was) working. But the interrupts might be from another device. If there are no bytes received (rx:0) but bytes were transmitted (tx:3749 for example), then only one direction of flow is working (or being utilized).
Sometimes a showing of just a few interrupts doesn't mean that the interrupt is actually being physically generated by any serial port. Thus if you see almost no interrupts for a port that you're trying to use, that interrupt might not be set in the hardware. To view /proc/interrupts to check on a program that you're currently running (such as "minicom") you need to keep the program running while you view it.
If it's PCI or ISA PnP then what's set in the hardware has been done by PnP methods. Even if nothing has been set or the port disabled, PnP ports may still be found by using "lspci -v" or "isapnp --dumpregs". Ports disabled by jumpers (or hardware failures) are completely lost. See ISA PnP ports, PCI: What IOs and IRQs have been set?, PCI: Enabling a disabled port
PnP ports don't store their configuration in the hardware when the power is turned off. This is in contrast to Jumpers (non-PnP) which remain the same with the power off. That's why a PnP port is more likely to be found in a disabled state than an old non-PnP one.
For PCI, the BIOS almost always sets the IRQ and may set the IO address as well. To see how it's set use "lspci -vv" (best) or look in /proc/bus/pci (or for kernels <2.2 /proc/pci). The modem's serial port is often called a "Communication controller". Look for this. If lspci shows "I/O ports at ... [disabled]" then the serial port is disabled and the hardware has no IO address so it's lost and can't be used. See PCI: Enabling a disabled port for how to enable it.
If more than one IO address is shown, the first one is more likely to be it. You can't change the IRQ (at least not with "setpci") This is because if one writes an IRQ it it's hardware register no action is taken on it. It's the BIOS that should actually set up the IRQs and then write the correct value to this register for lspci to view. If you must, change the IO address with "setpci" by changing the BASE_ADDRESS_0 or the like.
If the port communicates via an IO address then "lspci -vv" should show "Control: I/O+ ..." with + meaning that the IO address is enabled. If it shows "I/O-" (and "I/O ports at ... [disabled]") then you may need to use the setpci command to enable it. For example "setpci -d 151f:000 command=101". 151f is the vendor id, and 000 is the device id both obtained from "lspci -n -v" or from /proc/bus/pci or from "scanpci -v". The "command=101" means that 101 is put into the command register which is the same as the "Control" register displayed by "lspci". The 101h sets two bits: the 1 sets I/O to + and the 100 part keeps SERR# set to +. In this case only the SERR# bit of the Control register was initially observed to be + when the lspci command was run. So we kept it enabled to + by setting bit 8 (where bit 0 is I/O) to 1 by the first 1 in 101. Some serial cards don't use SERR# so if you see SERR#- then there's no need to enable it so then use: command=1. Then you'll need to set up "setserial" to tell the driver the IO and IRQ.
Bit 8 is actually the 9th bit since we started counting bits from 0. Don't be alarmed that lspci shows a lot of - signs showing that the card doesn't have many features available (or enabled). Serial ports are relatively slow and don't need these features.
Another way to enable it is to let the BIOS do it by telling the BIOS that you don't have a plug-and-play operating system. Then the BIOS should enable it when you start your PC. If you have MS Windows9x on the same PC then doing this might cause problems with Windows (see Plug-and-Play-HOWTO).
For an ISA Plug-and-Play (PnP) port one may try the pnpdump
program (part of isapnptools
). If you use the --dumpregs option
then it should tell you the actual IO address and IRQ set in the port.
It should also find an ISA PnP port that is disabled. The address it
"trys" is not the device's IO address, but a special address used for
communicating with PnP cards.
Perhaps the BIOS messages will tell you some info before Linux starts booting. Use the shift-PageUp key to step back thru the boot-time messages and look at the very first ones which are from the BIOS. This is how it was before Linux started. Setserial can't change it but isapnp or setpci can. Starting with kernel 2.4, the serial driver can make such changes for many (but not all) serial ports.
Using "scanport" (Debian only ??) will probe all I/O ports and will indicate what it thinks may be serial port. After this you could try probing with setserial using the "autoconfig" option. You'll need to guess the addresses to probe at (using clues from "scanport"). See What is Setserial.
For a port set with jumpers, the IO ports and IRQs are set per the jumpers. If the port is not Plug-and-Play (PnP) but has been setup by using a DOS program, then it's set at whatever the person who ran that program set it to.
For PnP ports, checking on how it's configured under DOS/Windows may (or may not) imply how it's under Linux. MS Windows stores its configuration info in its Registry which is not used by Linux so they are not necessarily configured the same. If you let a PnP BIOS automatically do the configuring when you start Linux (and have told the BIOS that you don't have a PnP operating system when starting Linux) then Linux should use whatever configuration is in the BIOS's non-volatile memory. Windows also makes use of the same non-volatile memory but doesn't necessarily configure it that way.
If you have Plug-and-Play ports then either a PnP BIOS or a serial driver may configure all your devices for you so then you may not need to choose any IRQs. PnP software determines what it thinks is best and assigns them (but it's not always best). But if you directly use isapnp (ISA bus) or jumpers then you have to choose. If you already know what IRQ you want to use you could skip this section except that you may want to know that IRQ 0 has a special use (see the following paragraph).
While IRQ 0 is actually the timer (in hardware) it has a special meaning for setting a serial port with setserial. It tells the driver that there is no interrupt for the port and the driver then will use polling methods. Such polling puts more load on the CPU but can be tried if there is an interrupt conflict or mis-set interrupt. The advantage of assigning IRQ 0 is that you don't need to know what interrupt is set in the hardware. It should be used only as a temporary expedient until you are able to find a real interrupt to use.
Sharing of IRQs is where two devices use the same IRQ. As a general rule, this wasn't allowed for the ISA bus. The PCI bus may share IRQs but one can't share the same IRQ between the ISA and the PCI bus. Most multi-port boards may share IRQs. Sharing is not as efficient since every time a shared interrupt is given a check must be made to determine where it came from. Thus if it's feasible, it's nicer to allocate every device its own interrupt.
Prior to kernel 2.2, serial IRQs could not be shared with each other except for most multiport boards. Starting with kernel 2.2 serial IRQs may be sometimes shared between serial ports. In order for sharing to work in 2.2 the kernel must have been compiled with CONFIG_SERIAL_SHARE_IRQ, and the serial port hardware must support sharing (so that if two serial cards put different voltages on the same interrupt wire, only the voltage that means "this is an interrupt" will prevail). Since the PCI bus specs permit sharing, any PCI card should allow sharing.
The serial hardware often has only a limited number of IRQs. Also
you don't want IRQ conflicts. So there may not be much of a choice.
Your PC may normally come with ttyS0
and ttyS2
at IRQ 4, and
ttyS1
and ttyS3
at IRQ 3. Looking at
/proc/interrupts
will show which IRQs are being used by
programs currently running. You likely don't want to use one of
these. Before IRQ 5 was used for sound cards, it was often used for a
serial port.
Here is how Greg (original author of Serial-HOWTO) set his up in /etc/rc.d/rc.serial. rc.serial is a file (shell script) which runs at start-up (it may have a different name or location). For versions of "setserial" after 2.15 it's not always done this way anymore but this example does show the choice of IRQs.
/sbin/setserial /dev/ttyS0 irq 3 # my serial mouse
/sbin/setserial /dev/ttyS1 irq 4 # my Wyse dumb terminal
/sbin/setserial /dev/ttyS2 irq 5 # my Zoom modem
/sbin/setserial /dev/ttyS3 irq 9 # my USR modem
Standard IRQ assignments:
IRQ 0 Timer channel 0 (May mean "no interrupt". See below.) IRQ 1 Keyboard IRQ 2 Cascade for controller 2 IRQ 3 Serial port 2 IRQ 4 Serial port 1 IRQ 5 Parallel port 2, Sound card IRQ 6 Floppy diskette IRQ 7 Parallel port 1 IRQ 8 Real-time clock IRQ 9 Redirected to IRQ2 IRQ 10 not assigned IRQ 11 not assigned IRQ 12 not assigned IRQ 13 Math co-processor IRQ 14 Hard disk controller 1 IRQ 15 Hard disk controller 2
There is really no Right Thing to do when choosing interrupts. Try to find one that isn't being used by the motherboard, or any other boards. 2, 3, 4, 5, 7, 10, 11, 12 or 15 are possible choices. Note that IRQ 2 is the same as IRQ 9. You can call it either 2 or 9, the serial driver is very understanding. If you have a very old serial board it may not be able to use IRQs 8 and above.
Make sure you don't use IRQs 1, 6, 8, 13 or 14! These are used by
your motherboard. You will make her very unhappy by taking her IRQs.
When you are done you might want to double-check
/proc/interrupts
when programs that use interrupts are being
run and make sure there are no conflicts.
Here's a problem with some old serial cards. The IO address of
the IBM 8514 video board (and others like it) is allegedly 0x?2e8
where ? is 2, 4, 8, or 9. This may conflict with the IO address of
ttyS3
at 0x02e8. Your may think that this shouldn't happen since
the addresses are different in the high order digit (the leading 0 in
02e8). You're right, but a poorly designed serial port may ignore the
high order digit and respond to any address that ends in 2e8. That is
bad news if you try to use ttyS3
(ISA bus) at this IO address.
For the ISA bus you should try to use the default addresses shown below. PCI cards use different addresses so as not to conflict with ISA addresses. The addresses shown below represent the first address of an 8-byte range. For example 3f8 is really the range 3f8-3ff. Each serial device (as well as other types of devices that use IO addresses) needs its own unique address range. There should be no overlaps (conflicts). Here are the default addresses for commonly used serial ports on the ISA bus:
ttyS0 address 0x3f8
ttyS1 address 0x2f8
ttyS2 address 0x3e8
ttyS3 address 0x2e8
Suppose there is an address conflict (as reported by setserial -g
/dev/ttyS*
) between a real serial port and another port which
does not physically exist (and shows UART: unknown). Such a conflict
shouldn't cause problems but it sometimes does in older kernels. To
avoid this problem don't permit such address conflicts or delete
/dev/ttySx if it doesn't physically exist.
After it's set in the hardware don't forget to insure that it also
gets set in the driver by using setserial
. For non-PnP serial
ports they are either set in hardware by jumpers or by running a DOS
program ("jumperless") to set them (it may disable PnP). The rest of
this subsection is only for PnP serial ports. Here's a list of the
possible methods of configuring PnP serial ports:
isapnp
for a PnP serial port (non-PCI)The IO address and IRQ must be set (by PnP) in their registers each time the system is powered on since PnP hardware doesn't remember how it was set when the power is shut off. A simple way to do this is to let a PnP BIOS know that you don't have a PnP OS and the BIOS will automatically do this each time you start. This might cause problems in Windows (which is a PnP OS) if you start Windows with the BIOS thinking that Windows is not a PnP OS. See Plug-and-Play-HOWTO.
Plug-and-Play (PnP) was designed to automate this io-irq configuring, but for Linux it initially made life much more complicated. In modern Linux (2.4 kernels --partially in 2.2 kernels), each device driver has to do its own PnP (using supplied software which it may utilize). There is unfortunately no centralized planning for assigning IO addresses and IRQs as there is in MS Windows. But it usually works out OK in Linux anyway.
While the explanation of how to use setpci or isapnp for io-irq configuring should come with such software, this is not the case if you want to let a PnP BIOS do such configuring. Not all PnP BIOS can do this. The BIOS usually has a CMOS menu for setting up the first two serial ports. This menu may be hard to find. For an "Award" BIOS it was found under "chipset features setup" There is often little to choose from. For ISA serial ports, the first two ports normally get set at the standard IO addresses and IRQs. See More on Serial Port Names
Whether you like it or not, when you start up a PC, a PnP BIOS starts to do PnP (io-irq) configuring of hardware devices. It may do the job partially and turn the rest over to a PnP OS (which Linux is in some sense) or if thinks you don't have a PnP OS it may fully configure all the PnP devices but not configure the device drivers.
If you tell the BIOS that you don't have a PnP OS, then the PnP BIOS should do the configuring of all PnP serial ports --not just the first two. An indirect way to control what the BIOS does (if you have Windows 9x on the same PC) is to "force" a configuration under Windows. See Plug-and-Play-HOWTO and search for "forced". It's easier to use the CMOS BIOS menu which may override what you "forced" under Windows. There could be a BIOS option that can set or disable this "override" capability.
If you add a new PnP device, the BIOS should PnP configure it. It could even change the io-irq of existing devices if required to avoid any conflicts. For this purpose, it keeps a list of non-PnP devices provided that you have told the BIOS how these non-PnP devices are io-irq configured. One way to tell the BIOS this is by running a program called ICU under DOS/Windows.
But how do you find out what the BIOS has done so that you set up the device drivers with this info? The BIOS itself may provide some info, either in its setup menus of via messages on the screen when you turn on your computer. See What is set in my serial port hardware?. Other ways of finding out is to use lspci for the PCI bus or isapnp --dumpregs for the ISA bus. The cryptic results it shows you may not be clear to a novice.
Once you've set the IRQ and IO address in the hardware (or arranged for it to be done by PnP) you also need to insure that the "setserial" command is run each time you start Linux. See the subsection Boot-time Configuration
See the section Stty. The "stty" command sets many things such as flow control, speed, and parity. The only one discussed in this section is flow control.
Configuring Flow Control: Hardware Flow Control is Usually Best See Flow Control for an explanation of it. It's usually better to use hardware flow control rather than software flow control using Xon/Xoff. To use full hardware flow control you must normally have two dedicated wires for it in the cable between the serial port and the device. If the device is on a card or the motherboard, then it should always be possible to use hardware flow control.
Many applications (and the getty program) give you an option regarding flow control and will set it as you specify or it might enable hardware flow control by default if you don't set it. It must be set both in the serial driver and in the hardware connected to the serial port. How it's set into this hardware is hardware dependent. Sometimes there is a certain "init string" you send to the hardware device via the serial port from your PC. For a modem, the communication program should set it in both places.
If a program you use doesn't set flow control in the serial driver,
then you may do it yourself using the stty
command. Since the
driver doesn't remember the setting after you stop Linux, you could
put the stty command in a file that runs at start-up or when you login
(such as /etc/profile for the bash shell). Here's what you would add
for hardware flow control for port ttyS2:
stty -F /dev/ttyS2 crtscts
or for old stty versions < 1.17:
stty crtscts < /dev/ttyS2
crtscts
stands for a Control setting to use the RTS and CTS pins of
the serial port for hardware flow control. Note that RTS+CTS almost
spells: crtscts
and the initial "c" means "control".
Common serial port names are /dev/ttyS0, /dev/ttyS1, etc. Then around the year 2000 came the USB bus with names like /dev/ttyUSB0 and /dev/ttyACM1 (for the ACM modem on the USB bus). Multiport serial card used somewhat differnt names (depending on the brand) such as /dev/ttyE5.
Since DOS provided for 4 serial ports on the old ISA bus: COM1-COM4, or ttyS0-ttyS3 in Linux, most serial ports on the newer PCI bus used higher numbers such as ttyS4 or ttyS14 (prior to kernel 2.6.13). But since most PCs only came with one or two serial ports, ttyS0 and possibly ttyS1 (for the second port) the PCI bus can now use ttyS2 (kernel 2.6.15 on). All this permits one to have both ISA serial ports and PCI serial ports on the same PC with no name conflicts. 0-1 (or 0-3) are reserved for the old ISA bus (or the newer LPC bus) and 2-upward (or 4-upward or 14-upward) are used for PCI, where older schemes are shown in parentheses . It's not required to be this way but it often is.
If you're using udev (which puts only the device you have on your
computer into the /dev directory at boottime) then there's an easy way
to change the device names by editing files in /etc/udev/. For
example, to change the name of what the kernel detects as ttyS3 to
what you want to name it: ttyS14, add a line similar to this to
/etc/udev/udev.rules
BUS=="pci" KERNEL=="ttyS3",
NAME="ttyS14"
On-board serial ports on motherboards which have both PCI and ISA slots are likely to still be ISA ports. Even for all-PCI-slot motherboards, the serial ports are often not PCI. Instead, they are either ISA, on an internal ISA bus or on a LPC bus which is intended for slow legacy I/O devices: serial/parallel ports and floppy drives.
Devices in Linux have major and minor numbers. The serial port ttySx (x=0,1,2, etc.) is major number 4. You can see this (and the minor numbers too) by typing: "ls -l ttyS*" in the /dev directory. To find the device names for various devices, see the "devices" file in the kernel documentation.
There formerly was a "cua" name for each serial port and it behaved just a little differently. For example, ttyS2 would correspond to cua2. It was mainly used for modems. The cua major number was 5 and minor numbers started at 64. You may still have the cua devices in your /dev directory but they are now deprecated. For details see Modem-HOWTO, section: cua Device Obsolete.
For creating the old devices in the device directory see:
Creating Devices In the /dev directory
Dos/Windows use the COM name while the messages from the serial driver use ttyS00, ttyS01, etc. Older serial drivers (2001 ?) used just tty00, tty01, etc.
The tables below shows some examples of serial device names. The IO addresses are the default addresses for the old ISA bus (not for the newer PCI and USB buses).
dos common IO USB-BUS ( ACM => acm modem )
name name major minor address || common name common name
COM1 /dev/ttyS0 4, 64; 3F8 || /dev/ttyUSB0 | /dev/ttyACM0
COM2 /dev/ttyS1 4, 65; 2F8 || /dev/ttyUSB1 | /dev/ttyACM1
COM3 /dev/ttyS2 4, 66; 3E8 || /dev/ttyUSB2 | /dev/ttyACM2
COM4 /dev/ttyS3 4, 67; 2E8 || /dev/ttyUSB3 | /dev/ttyACM3
- /dev/ttyS4 4, 68; various
For more info see the usb subdirectory in the kernel documentation directory for files: usb-serial, acm, etc.
On some installations, two extra devices will be created,
/dev/modem
for your modem and /dev/mouse
for a
mouse. Both of these are symbolic links to the appropriate
device in /dev
.
Historical note: Formerly (in the 1990s) the use of
/dev/modem
(as a link to the modem's serial port) was
discouraged since lock files might not realize that it was really say
/dev/ttyS2
. The newer lock file system doesn't fall into
this trap so it's now OK to use such links.
Inspecting the connectors may give some clues but is often not definitive. The serial connectors on the back side of a PC are usually DB connectors with male pins. 9-pin is the most common but some are 25-pin (especially older PCs like 486s). There may be one 9-pin (perhaps ttyS0 ??) and one 25-pin (perhaps ttyS1 ??). For two 9-pin ones the top one might be ttyS0.
If you only have one serial port connector on the back of your PC, this may be easy. If you also have an internal modem, a program like wvdial may be able to tell you what port it's on (unless it's a PnP that hasn't been enabled yet). A report from setserial (at boot-time or run by you from the command line) should help you identify the non-modem ports.
If you have two serial ports it may be more difficult. You could have only one serial connector but actually have 2 ports, one of which isn't used (but it's still there electronically). First check manuals (if any) for your computer. Look at the connectors for meaningful labels. You might even want to take off the PC's cover and see if there are any meaningful labels on the card where the internal ribbon serial cables plug in. Labels (if any) are likely to say something like "serial 1", "serial 2" or A, B. Which com port it actually is will depend on jumper or PnP settings (sometimes shown in a BIOS setup menu). But 1 or A are more likely to be ttyS0 with 2 or B ttyS1.
Labels are not apt to be definitive so here's another method. If the serial ports have been configured correctly per setserial, then you may send some bytes out a port and try to detect which connector (if any) they are coming out of. One way to send such a signal is to copy a long text file to the port using a command like: cp my_file_name /dev/ttyS1. A voltmeter connected to the DTR pin (see Serial-HOWTO for Pinout) will display a positive voltage as soon as you give the copy command.
The transmit pin should go from several volts negative to a voltage
fluctuating around zero after you start sending the bytes. If it doesn't
(but the DTR went positive) then you've got the right port but it's
blocked from sending. This may be due to a wrong IRQ, -clocal being
set, etc. The command "stty -F /dev/ttyS1 -a
" should show
clocal (and not -clocal). If not, change it to clocal.
Another test is to jumper the transmit and receive pins (pins 2 and 3 of either the 25-pin or 9-pin connector) of a test serial port. Then send something to each port (from the PCs keyboard) and see if it gets sent back. If it does it's likely the port with the jumper on it. Then remove the jumper and verify that nothing gets sent back. Note that if "echo" is set (per stty) then a jumper creates an infinite loop. Bytes that pass thru the jumper go into the port and come right back out of the other pin back to the jumper. Then they go back in and out again and again. Whatever you send to the port repeats itself forever (until you interrupt it by removing the jumper, etc.). This may be a good way to test it as the repeating test messages halt when the jumper is removed.
As a jumper you could use a mini (or micro) jumper cable (sold in some electronic parts stores) with mini alligator clips. A small scrap of paper may be used to prevent the mini clips from making electrical contact where it shouldn't. Metal paper clips can sometimes be bent to use as jumpers. Whatever you use as a jumper take care not to bend or excessively scratch the pins. To receive something from a port, you can go to a virtual terminal (for example Alt-F2 and login) and type something like "cp /dev/ttyS2 /dev/tty". Then at another virtual terminal you may send something to ttyS2 (or whatever) by "echo test_message > /dev/ttyS2". Then go back to the receive virtual terminal and look for the test_message. See Serial Electrical Test Equipment for more info.
Another way to try to identify a serial port is to connect some physical serial device to it and see if it works. But a problem here is that it might not work because it's not configured right. A serial mouse might get detected at boot-time if connected.
You may put a device, such as a serial mouse (use 1200 baud), on a port and then use minicom or picocom to communicate with that port. Then by clicking on the mouse, or otherwise sending characters with the device, see if they get displayed. It not you may have told picocom the wrong port (such as ttyS0 instead of ttyS1) so try again.
If the software shows that you have more serial ports than you have connectors for (including an internal modem which counts as a serial port) then you may have a serial port that has no connector. Some motherboards come with a serial port with no cable or external serial DB connector. Someone may build a PC from this and decide not to use this serial port. There may be a "serial" connector and label on the motherboard but no ribbon cable connects to its pins. To use this port you must get a ribbon cable and connector. I've seen different wiring arrangements for such ribbon cables so beware.
If you don't use devfs (which automatically creates such devices) and
don't have a device "file" that you need, you will have to create it.
Use the mknod
command or with the MAKEDEV shell script.
Example, suppose you needed to create ttyS0
:
linux# mknod -m 666 /dev/ttyS0 c 4 64
The MAKEDEV script is easier to use.
See the man page for it. For example, if you needed to make the
device for ttyS0
you would just type:
linux# MAKEDEV ttyS0
If the above command doesn't work (and you are the root user), look for the MAKEDEV script in the /dev directory and run it.
This handles the devices creation and should set the correct permissions. For making multiport devices see Making multiport devices in the /dev directory.
Most info on getty has been moved to Modem-HOWTO with a little info on the use of getty with directly connected terminals now found in Text-Terminal-HOWTO.
A few Linux programs (and one "file") will monitor various modem control lines and indicate if they are positive (1 or green) or negative (0 or red).
irqtune
will give serial port interrupts higher
priority to improve performance.hdparm
for hard-disk tuning may help some more.This part is in 3 HOWTOs: Modem, Serial, and Text-Terminal. There are some minor differences, depending on which HOWTO it appears in.
If you have a Laptop (PCMCIA) don't use setserial
until you
read
Laptops: PCMCIA.
setserial
is a program used for the user to communicate with
the serial device driver. You normally never need to use it, provided
that you only use the one or two serial ports that come as standard
equipment with a PC. Even in other cases, most extra serial ports
should be auto-detected by modern kernels. Except you'll need to use
setserial if you have an old ISA serial port set by jumpers on the
physical hardware or if your kernel (such as 2.2 or older) doesn't
both detect and set your add-on PCI serial ports.
setserial
allows you (or a shell script) to talk to the serial
software. But there's also another program, tt/stty/, that also deals
with the serial port and is used for setting the port speed, etc.
setserial
deals with the lower-level configuring of the serial
port, such as dealing with IRQs (such as 5), port addresses (such as
3f8), and the like. A major problem with it is that it can't
set or configure the serial port hardware: It can't set the IRQ or
port addresses into the hardware. Furthermore, when it seemingly
reports the configuration of the hardware, it's sometimes wrong since
it doesn't actually probe the hardware unless you specifically tell it
to. Even then, it doesn't do the modern type of bus probing and some
hardware may never be found by it. Still, what it shows is right most
all the time but if you're having trouble getting a serial port to
work, then there's a fair chance it's wrong.
In olden days, when the IRQ and port address was set by jumpers on the
serial card, one would use setserial
to tell the driver how these
jumpers were set. Today, when plug-and-play methods detect how the
jumperless serial port is set, setserial
is not really needed
anymore unless you're having problems or using old hardware.
Furthermore, if the configuration file used by setserial
is
wrong, then there's trouble. In this case, if you use setserial
to try to find out how the port is configured, it may just repeat the
incorrect information in the configuration file.
setserial
can sometimes be of help to find a serial port. But
it's only of use if you know the port address and use the right
options. For modern ports, there's usually better ways to look for
them by plug-and-play methods.
Thus the name setserial
is somewhat of a misnomer since it
doesn't set the I/O address nor IRQ in the hardware, it just "sets"
them in the driver software. And the driver naively believes that
what setserial
tells it, even if it conflicts with what the driver
has found by using plug-and-play methods. Too bad that it fails to
at least issue a warning message for such a conflict. Since the
device driver is considered to be part of the kernel, the word
"kernel" is often used in other documentation with no mention made of
any "serial driver".
Some distributions (and versions) set things up so that setserial
is run at boot-time by an initialization shell script (in the
/etc directory tree). But the configuration file which this script
uses may be either in the /etc tree or the /var tree. In some cases,
if you want setserial
to run at boot-time, you may have to take
some action. setserial
will not work without either serial
support built into the kernel or loaded as a module. The module may
get loaded automatically if you (or a script) attempt to use
setserial
.
While setserial
can be made to probe the hardware IO port
addresses to try to determine the UART type and IRQ, this has
severe limitations. See
Probing. It
can't set the IRQ or the port address in the hardware of PnP or PCI
serial ports (but the plug-and-play features of the serial driver may
do this). It also can't directly read the PnP data stored in
configuration registers in the hardware. But since the device driver
can read these registers and setserial tells you what the device
driver thinks, it might be correct. Or it could be telling you what
setserial
had previously (and perhaps erroneously) told the
driver. There's no way to know for sure without doing some other
checks.
The serial driver (for Linux Kernel 2.4+) looks for a few "standard"
legacy serial ports, for PnP ports on the ISA bus, and for all
supported port hardware on the PCI bus. If it finds your ports
correctly, then there's no need to use setserial
. The driver
doesn't probe for the IRQs of old ISA serial ports set with jumpers on
the card and may get these wrong.
Besides the man page for setserial
, check out info in
/usr/doc/setserial.../
or /usr/share/doc/setserial
.
This should tell you how setserial is handled for your distribution of
Linux. While setserial
behaves the same in all distributions,
the scripts for running it, how to configure such scripts (including
automatic configuration), and the names and locations of the script
files, etc., are all distribution-dependent.
If a serial module gets unloaded, the changes previously made by
setserial
will be forgotten by the driver. But while the driver
forgets it, a script provided by the distribution may save it in a
file somewhere so that it can the restored if the module is reloaded.
There once was a problem with slow serial printers (especially the old ones of the 1980s). The printing program would close the serial port at the "end" of printing well before all the characters from the large serial buffer (in main memory) were sent to the printer. The result was a truncated print job that didn't print the last paragraph or last page, etc.
But the newer lprng print program (and possibly other printing
programs) keeps the port open until printing is finished so "problem
solved", even if you're using an antique printer. Setserial can
modify the time that the port will keep operating after it's closed
(in order to output any characters still in its buffer in main RAM).
This is done by the "closing_wait" option per the setserial
man
page. For "bad" software that closes the port too soon, it might also
be needed at speeds above 1200 if there are a lot of "flow control"
waits.
setserial
commandRemember, that setserial
can't set any I/O addresses or IRQs
in the hardware. That's done either by plug-and-play software (run by
the driver) or by jumpers for legacy serial ports. Even if you give
an I/O address or IRQ to the driver via setserial
it will not set
such values and assumes that they have already been set. If you give
it wrong values, the serial port will not work right (if at all).
For legacy ports, if you know the I/O address but don't know the IRQ you may command setserial to attempt to determine the IRQ.
You can see a list of possible commands by just typing setserial
with no arguments. This fails to show you the one-letter options such
as -v for verbose which you should normally use when troubleshooting.
Note that setserial calls an IO address a "port". If you type:
setserial -g /dev/ttyS*
You'll see some info about how the device driver is configured for
your ports. In many cases you'll see some ports displayed with what
appears at first glance to be erroneous IRQs and addresses. But if
you also see: "UART: unknown"
just ignore the entire line
since no serial port exists at that address.
If you add -a to the option -g you will see more info although few
people need to deal with (or understand) this additional info since
the default settings you see usually work fine. In normal cases the
hardware is set up the same way as "setserial" reports. But if you are
having problems there is a good chance that setserial
has it wrong.
In fact, you can run "setserial" and assign a purely fictitious I/O
port address, any IRQ, and whatever uart type you would like to have.
Then the next time you type "setserial ..." it will display these
bogus values you've supplied to the driver. They will also be officially
registered with the kernel as displayed (at the top of the screen) by
the "scanport" command (Debian). Of course the serial
port driver will not work correctly (if at all) if you attempt to use
such a port. Thus, when giving parameters to setserial
, "anything
goes". Well almost. If you assign one port a base address that is
already assigned (such as 3e8) it may not accept it. But if you use
3e9 it will accept it. Unfortunately 3e9 is actually assigned since it
is within the range starting at base address 3e8. Thus the moral of
the story is to make sure your data is correct before assigning
resources with setserial.
While assignments made by setserial are lost when the PC is powered
off, a configuration file may restore them when the PC is started
up again. In newer versions, what you change by setserial might get
automatically saved to a configuration file. When setserial
runs
it uses the info from the configuration file.
Where this configuration file resides depends on your distribution. Look at the start-up scripts somewhere in the /etc/ tree (such as /etc/init.d/ or /etc/rc.d/) and read the startup script for "serial" or "setserial" or the like. It should show where the configuration file(s) reside. In Debian there are 4 options for use of this configuration file:
setserial
reports when the system is first
shutdown and put it in the configuration file. After that, don't ever
make any changes to the configuration file, even if someone has made
changes by running the setserial
command on the command line and
then shuts down the system. ("autosave-once" option)setserial
detects to the
configuration file. ("autosave" option)In olden days (perhaps before 2000), there wasn't any configuration
file and the configuration was manually set (hard coded) inside the
shell script that ran setserial
. See
Edit a script (prior to version 2.15).
You probe for a port with setserial
only when you suspect that
it has been enabled (by PnP methods, the BIOS, jumpers, etc.).
Otherwise setserial
probing will never find it since its address
doesn't exist. A problem is where the software looks for a port at
specified I/O addresses. Prior to probing with "setserial", one may
run the "scanport" (Debian) command to check all possible ports in one
scan. It makes crude guesses as to what is on some ports but doesn't
determine the IRQ. It's a fast first start. It may hang your PC but
so far it's worked fine for me. Note that non-Debian distributions
don't seem to supply "scanport". Is there another scan program?
With appropriate options, setserial
can probe (at a given I/O
address) for a serial port but you must guess the I/O address. If you
ask it to probe for /dev/ttyS2 for example, it will only probe at the
address it thinks ttyS2 is at (2F8). If you tell setserial that ttyS2
is at a different address, then it will probe at that address, etc.
See
Probing
The purpose of such probing is to see if there is a uart there, and if
so, what its IRQ is. Use setserial
mainly as a last resort as
there are faster ways to attempt it such as wvdialconf to detect
modems, looking at very early boot-time messages, or using pnpdump
--dumpregs
, or lspci -vv. But if you want to detect hardware
with setserial
use for example :
setserial
/dev/ttyS2 -v autoconfig
If the resulting message shows a uart type such as 16550A, then you're
OK. If instead it shows "unknown
" for the uart type, then there
is supposedly no serial port at all at that I/O address. Some cheap
serial ports don't identify themselves correctly so if you see
"unknown
" you still might have a serial port there.
Besides auto-probing for a uart type, setserial can auto-probe for
IRQ's but this doesn't always work right either. In one case it first
gave the wrong irq but when the command was repeated it found the
correct irq. In versions of setserial >= 2.15, the results of your
last probe test could be automatically saved and put into a
distribution-specific configuration file such as
/etc/serial.conf
or /etc/sysconfig/serial
or
/var/lib/setserial/autoserial.conf
for Debian. This will be
used next time you start Linux.
It may be that two serial ports both have the same IO address set in
the hardware. Of course this is not normally permitted for the ISA
bus but it sometimes happens anyway. Probing detects one serial port
when actually there are two. However if they have different IRQs,
then the probe for IRQs may show IRQ = 0. For me, it only did this if
I first used setserial
to give the IRQ a fictitious value.
While setserial
may run via an initialization script,
something akin to setserial
also runs earlier when the serial
module is loaded (or when the kernel starts the built-in serial driver
if it was compiled into the kernel). Thus when you watch the start-up
messages on the screen it may look like it ran twice, and in fact it
has.
If the first message is for a legacy port, the IRQs shown may be wrong since it didn't probe for IRQs. If there is a second report of serial ports, it may the result of a script such as /etc/init.d/setserial. It usually does no probing and thus could be wrong about how the hardware is actually set. It only shows configuration data that got saved in a configuration files. The old method, prior to setserial 2.15, was to manually write such data directly into the script.
When the kernel loads the serial module (or if the "module equivalent"
is built into the kernel) then all supported PnP ports are detected.
For legacy (non-PnP) ports, only ttyS{0-3}
are auto-detected
and the driver is set to use only IRQs 4 and 3 (regardless of what
IRQs are actually set in the hardware). No probing is done for IRQs
but it's possible to do this manually. You see this as a boot-time
message just as if setserial
had been run.
To correct possible errors in IRQs (or for other
reasons) there may be a script file somewhere that runs
setserial
. Unfortunately, if this file has some IRQs wrong, the
kernel will still have incorrect info about the IRQs. This file is
usually part of the initialization done at boot-time. Whether it
runs or not depends on how you (and/or your distribution) have set
things up. It may also depends on the runlevel.
Before modifying a configuration file, you can test out a "proposed"
setserial
command by just typing it on the command line. In some
cases the results of this use of setserial
will automatically get
saved somewhere such as /etc/serial.conf (or autoserial.conf or
serial) when you shutdown. So if it worked OK (and solved your
problem) then there's no need to modify any configuration file. See
Configuration method using /etc/serial.conf, etc..
This is how it was done prior to setserial
2.15 (1999)
The objective was to modify (or create) a script file in the /etc
tree that runs setserial at boot-time. Most distributions provided
such a file (but it may not have initially resided in the /etc tree).
So prior to version 2.15 (1999) it was simpler. All you did was edit a script. There was no /etc/serial.conf file (or the like) to configure setserial. Thus you needed to find the file that runs "setserial" at boot time and edit it. If it didn't exist, you needed to create one (or place the commands in a file that ran early at boot-time). If such a file was currently being used it's likely was somewhere in the /etc directory-tree. But Redhat <6.0 has supplied it in /usr/doc/setserial/ but you need to move it to the /etc tree before using it.
The script /etc/rc.d/rc.serial
was commonly used in the past.
The Debian distribution used /etc/rc.boot/0setserial
.
Another file once used was /etc/rc.d/rc.local
but it's may
not have run early enough. It was reported that other processes may
try to open the serial port before rc.local ran resulting in serial
communication failure. Later on it most likely was found in
/etc/init.d/ but wasn't normally intended to be edited.
If such a file was supplied, it likely contained a number of
commented-out examples. By uncommenting some of these and/or
modifying them, you could set things up correctly. It was important
use a valid path for setserial
, and a valid
device name. You could do a test by executing this file manually
(just type its name as the super-user) to see if it works right.
Testing like this was a lot faster than doing repeated reboots to get
it right.
For versions >= 2.15 (provided your distribution implemented the change, Redhat didn't at first) it may be more tricky to do since the file that runs setserial on startup, /etc/init.d/setserial or the like was not intended to be edited by the user. See Configuration method using /etc/serial.conf, etc..
An example line in such a script was:
/sbin/setserial /dev/ttyS3 irq 5 uart 16550A skip_test
or, if you wanted setserial to automatically determine the uart and the IRQ for ttyS3 you would have used something like this:
/sbin/setserial /dev/ttyS3 auto_irq skip_test autoconfig
This was done for every serial port you wanted to auto configure, using a device name that really does exist on your machine. In some cases it didn't work right due to the hardware.
Prior to setserial version 2.15 (1999), the way to configure
setserial was to manually edit the shell-script that ran setserial at
boot-time. See
Edit a script (before version 2.15). This was simple, but the simple and clear method has
been changed to something that is unnecessarily complex. Today the
script and configuration file are two different files instead of one.
This shell-script is not edited but gets its data from a configuration
file such as /etc/serial.conf
(or
/var/lib/setserial/autoserial.conf
).
Furthermore you may not even need to edit serial.conf (or the like) because using the "setserial" command on the command line may automatically cause serial.conf to be edited appropriately. This was done so that you may not need to edit any file in order to set up (or change) what setserial does each time that Linux is booted.
What often happens is this: When you shut down your PC the script
that ran "setserial" at boot-time is run again, but this time it only
does what the part for the "stop" case says to do: It uses
"setserial" to find out what the current state of "setserial" is, and
it puts that info into the serial configuration file such as
serial.conf
. Thus when you run "setserial" to change
the serial.conf file, it doesn't get changed immediately but only when
and if you shut down normally.
Now you can perhaps guess what problems might occur. Suppose you don't shut down normally (someone turns the power off, etc.) and the changes don't get saved. Suppose you experiment with "setserial" and forget to run it a final time to restore the original state (or make a mistake in restoring the original state). Then your "experimental" settings are saved. And worst of all, unless you know which options were set in the configuration file, you don't know what will happen. One option in Debian (and likely other distributions) is known as "AUTOSAVE-ONCE" which saves changes only for the first time you make them with the setserial command.
If the option "###AUTOSAVE###" is set and you manually edit serial.conf, then your editing is destroyed when you shut down because it gets changed back to the state of setserial at shutdown. There is a way to disable the changing of serial.conf at shutdown and that is to remove "###AUTOSAVE###" or the like from first line of serial.conf. In the Debian distribution, the removal of "###AUTOSAVE###" from the first line was once automatically done after the first time you shutdown just after installation. To retain this effect the "AUTOSAVE-ONCE" option was created which only does a save when time the system is shut down for the first time (just after you install or update the setserial program).
The file most commonly used to run setserial at boot-time (in conformance with the configuration file) is now /etc/init.d/setserial (Debian) or /etc/init.d/serial (Redhat), or etc., but it should not normally be edited. For 2.15, Redhat 6.0 just had a file /usr/doc/setserial-2.15/rc.serial which you have to move to /etc/init.d/ if you want setserial to run at boot-time.
To disable a port, use setserial
to set it to "uart none". This
will not be saved. The format of /etc/serial.conf appears to be just
like that of the parameters placed after "setserial" on the command
line with one line for each port. If you don't use autosave, you may
edit /etc/serial.conf manually.
In order to force the current settings set by setserial to be saved to
the configuration file (serial.conf) without shutting down, do what
normally happens when you shutdown: Run the shell-script
/etc/init.d/{set}serial stop
. The "stop" command will save
the current configuration but the serial ports still keep working OK.
In some cases you may wind up with both the old and new configuration methods installed but hopefully only one of them runs at boot-time. Debian labeled obsolete files with "...pre-2.15".
By default, both ttyS0 and ttyS2 will share IRQ 4, while ttyS1 and ttyS3 share IRQ 3. But while sharing serial interrupts (using them in running programs) is OK for the PCI bus, it's not permitted for the ISA bus unless you: 1. have kernel 2.2 or better, and 2. you've compiled in support for this, and 3. your serial hardware supports it. See
Interrupt sharing and Kernels 2.2+
If you only have two serial ports, ttyS0 and ttyS1, you're still OK since IRQ sharing conflicts don't exist for non-existent devices.
If you add a legacy internal modem (without plug-and-play) and retain ttyS0 and ttyS1, then you should attempt to find an unused IRQ and set it in your serial port (or modem card) and then use setserial to assign it to your device driver. If IRQ 5 is not being used for a sound card, this could be used for a modem.
If you have a Laptop, read PCMCIA-HOWTO for info on the serial configuration. For serial ports on the motherboard, setserial is used just like it is for a desktop. But for PCMCIA cards (such as a modem) it's a different story. The configuring of the PCMCIA system should automatically run setserial so you shouldn't need to run it. If you do run it (by a script file or by /etc/serial.conf) it might be different and cause trouble. The autosave feature for serial.conf shouldn't save anything for PCMCIA cards (but Debian did until 2.15-7). Of course, it's always OK to use setserial to find out how the driver is configured for PCMCIA cards.
stty
does much of the configuration of the serial port but
since application programs (and the getty program) often handle this,
you may not need to use it much. It's handy if you're having problems
or want to see how the port is set up. Try typing ``stty -a'' at your
terminal/console to see how it's now set. Also try typing it without
the -a (all) for a short listing which shows how it's set different
than "normal" which is how it's set using the command "stty
sane"
. Don't try to learn all the setting unless you want to
become a serial historian since many of the settings are only for slow
antique dumb terminals of the 1970's. Most of the defaults should
work OK.
stty
is documented in the man pages with a more detailed account
in the info pages. Type "man stty"
or "info stty"
.
Many of the stty options start with an "o" (output) or an "i" (input).
For example: onlcr
. Output is the flow of bytes out of the
computer while input is the flow of bytes into the computer. The
"point of view" is the computer, not the serial port or the device
connected to the serial port. For example, received input data comes
in on a cable and goes to the serial port chip. This chip, after
converting the bits from the serial to parallel representation, then
sends it (via a program read) to the large serial port buffer in main
computer memory. Thus the chip has both input and output but since
it's input data to the computer, its output is considered to be input.
The situation is similar for output flowing thru this chip. The
"input" and "output" refer to the direction of flow with respect to the
computer and not the serial port hardware (the chip).
Whereas setserial
only deals with actual serial ports, stty is
used both for serial ports and for virtual terminals such as the standard
Linux text interface on a PC monitor. For the PC monitor, many of the
stty settings are meaningless. Changing the baud rate, etc. doesn't
appear to actually do anything.
Here are some of the items stty configures: speed (bits/sec), parity,
bits/byte, # of stop bits, strip 8th bit?, modem control signals, flow
control, break signal, end-of-line markers, change case, padding, beep
if buffer overrun?, echo what you type to the screen, allow background
tasks to write to terminal?, define special (control) characters (such
as what key to press for interrupt). See the stty
man or info
page for more details. Also see the man page: termios
which
covers the same options set by stty but (as of mid 1999) covers
features which the stty man page fails to mention.
With some implementations of getty (getty_ps package), the commands that one would normally give to stty are typed into a getty configuration file: /etc/gettydefs. Even without this configuration file, the getty command line may be sufficient to set things up so that you don't need stty.
One may write C programs which change the stty configuration, etc. Looking at some of the documentation for this may help one better understand the use of the stty command (and its many possible arguments). Serial-Programming-HOWTO may be useful but it's outdated. The manual page: termios contains a description of the C-language structure (of type termios) which stores the stty configuration in computer memory. Many of the flag names in this C-structure are almost the same (and do the same thing) as the arguments to the stty command.
To set hardware flow control use "crtscts". For software flow control there are 3 settings: ixon, ixoff, and ixany.
ixany: Mainly for terminals. Hitting any key will restart the flow after a flow-control stop. If you stop scrolling with the "stop scroll" key (or the like) then hitting any key will resume scrolling. It's seldom needed since hitting the "scroll lock" key again will do the same thing.
ixon: Enables the port to listen for Xoff and to stop transmitting when it gets an Xoff. Likewise, it will resume transmitting if it gets an Xon.
ixoff: enables the port to send the Xoff signal out the transmit line when its buffers in main memory are nearly full. It protects the device where the port is located from being overrun.
For a slow dumb terminal (or other slow device) connected to a fast PC, it's unlikely that the PC's port will be overrun. So you seldom actually need to enable ixoff. But it's often enabled "just in case".
How do you use stty to view or set a terminal other than the
terminal you are currently using? It's usually impossible to do it if
the foreign terminal is in use and has a shell running on it. In
other cases for dealing with say ttyS2 while typing at another
terminal (such as tty1) use stty -F /dev/ttyS2 ...
(or
--file instead of F). If ... is -a it displays all the stty settings
(-a means all).
But if the foreign terminal (ttyS2 in this example) has a shell running on it, then what you see will likely be deceptive and trying to set it will not work. This problem exists for virtual terminals also such as dealing with tty3 from tty1, etc. See Two interfaces at a terminal to understand it.
When using a shell (such as bash) with command-line-editing enabled there are two different terminal interfaces (what you see when you type stty -a). When you type in modern shells at the command line you have a temporary "raw" interface (or raw mode) where each character is read by the command-line-editor as you type it. Once you hit the <return> key, the command-line-editor is exited and the terminal interface is changed to the nominal "cooked" interface (cooked mode) for the terminal. This cooked mode lasts until the next prompt is sent to the terminal (which is only a small fraction of a second). Note that one never gets to type any command in this cooked mode but what was typed in raw mode on the command line gets read by the shell while in cooked mode.
When a prompt is sent to the terminal, the terminal goes from "cooked" to "raw" mode (just like it does when you start an editor such as vim. The prompt signals starting the command-line editor. The settings for the "raw" mode are based only on the basic stty settings taken from the "cooked" mode. Raw mode keeps these setting but changes several other settings in order to change the mode to "raw". It is not at all based on the settings used in the previous "raw" mode. Thus if one uses stty to change settings for the raw mode, such settings will be permanently lost as soon as one hits the <return> key at the terminal that has supposedly been "set".
Now when one types stty to look at the terminal interface, one may either get a view of the cooked mode or the raw mode. You need to figure out which one you're looking at. It you use stty from a foreign terminal (other than the terminal you are currently typing at) then you will see the raw mode settings. Any changes made will only be made to the raw mode and will be lost when someone presses <return> at the foreign terminal you tried to "set". But if you type a stty command to view/change the configuration of the terminal you are using, and then hit <return> it's a different story. The <return> puts the terminal in cooked mode. Your changes are saved and will still be there when the terminal goes back into raw mode (unless of course it's a setting not allowed in raw mode).
This situation can create problems. For example, suppose you corrupt your terminal interface. To restore it you go to another terminal and "stty -F dev/ttyS1 sane" (or the like). It will not work! Of course you can try to type "stty sane ..." at the terminal that is corrupted but you can't see what you typed. All the above not only applies to dumb terminals but to virtual terminals used on a PC Monitor as well as to the terminal windows in X. In other words, it applies to almost everyone who uses Linux.
Luckily, when you start up Linux, any file that runs stty at boot-time will likely deal with a terminal (or serial port with no terminal) that has no shell running on it so there's no problem for this special case.
Should you need to have stty
set up the serial interface each
time the computer starts up then you need to put the stty
command
in a file that will be executed each time the computer is started up
(Linux boots). It should be run before the serial port is used
(including running getty on the port). There are many possible places
to put it. If it gets put in more than one place and you only know
about (or remember) one of those places, then a conflict is likely.
So make sure to document what you do.
One place to put it would be in the same file that runs setserial when the system is booted. The location is distribution and version dependent. It would seem best to put it after the setserial command so that the low level stuff is done first. If you have directories in the /etc tree where every file in them is executed at boot-time (System V Init) then you could create a file named "stty" for this purpose.
Prior to about 2000 you needed to use the redirection operator "<" if you wanted to use stty on a foreign terminal. For example to use stty on ttyS2 sitting at tty1 you would type: stty .... < /dev/ttyS2. After 2000 (provided your version of setserial is >= 1.17 and stty >= 2.0) a better method was created using the -F option: stty -F /dev/ttyS2. This will work when the old redirection method fails.
The old redirection example above makes ttyS2 the standard input to stty. This gives the stty program a link to the "file" ttyS2 so that it may "read" it. But instead of reading the bytes sent to ttyS2 as one might expect, it uses the link to find the configuration settings of the port so that it may read or change them. In olden days, some people tried to use ``stty ... > /dev/ttyS2'' to set the terminal. This didn't work. Instead, it takes the message normal displayed by the stty command for the terminal you are on (say tty1) and sends this message to ttyS2. But it doesn't change any settings for ttyS2.
Here's a problem with the old redirection operator (which doesn't happen if you use the newer -F option instead). Sometimes when trying to use stty, the command hangs and nothing happens (you don't get a prompt for a next command even after hitting <return>). This is likely due to the port being stuck because it's waiting for one of the modem control lines to be asserted. For example, unless you've set "clocal" to ignore modem control lines, then if no CD signal is asserted the port will not open and stty will not work for it (unless you use the newer -F option). A similar situation seems to exist for hardware flow control. If the cable for the port doesn't even have a conductor for the pin that needs to be asserted then there is no easy way to stop the hang.
One way to try to get out of the above hang is to use the newer -F option and set "clocal" and/or "crtscts" as needed. If you don't have the -F option then you may try to run some program (such as minicom) on the port that will force it to operate even if the control lines say not to. Then hopefully this program might set the port so it doesn't need the control signal in the future in order to open: clocal or -crtscts. To use "minicom" to do this you likely will have to reconfigure minicom and then exit it and restart it. Instead of all this bother, it may be simpler to just reboot the PC or via using a virtual terminal kill the process using "top" (or "ps" to get the process number and then "kill" to kill that process.
The obsolete redirection method (which still works in later versions) is to type ``stty ... < /dev/ttyS2''. If the new method using -F works but the obsolete one hangs, it implies that the port is hung due to a modem control line not being asserted. Thus the obsolete redirection method might still useful for troubleshooting.
isapnp
is a program to configure Plug-and-Play (PnP) devices
on the ISA bus including internal modems. It comes in a package
called "isapnptools" and includes another program, "pnpdump" which
finds all your ISA PnP devices and shows you options for configuring
them in a format which may be added to the PnP configuration file:
/etc/isapnp.conf. The isapnp command may be put into a startup file
so that it runs each time you start the computer and thus will
configure ISA PnP devices. It is able to do this even if your BIOS
doesn't support PnP. See Plug-and-Play-HOWTO.
This is where you run a serial cable (crossover type = null-modem type) between the serial ports of two PCs. Then how do you use this line? One way is for one PC to run login on the serial line and for the other PC to run say minicom or picocom to emulate a terminal. See Text-Terminal-HOWTO. There is no network protocol used in this case and no error detection.
The other method is to run a network protocol on the line. For example, to use PPP in combination with TCP/IP see Serial Laplink HOWTO. Although this HOWTO doesn't mention the old program "slattach" (serial line attach) it can put the serial line into a networking mode using the protocol you select. Protocols for slattach include PPP or SLIP (an older protocol widely used prior to PPP).
The Debian package, net-tools, contains slattach. SLIP is provided as a kernel module or can be built into the kernel (2.2, 2.4, or 2.6).
ser2net is a Linux program which will connect a network to the serial port. For example, someone connects to your PC via an ethernet port or fast modem using say telnet. Then (without ser2net) they could remotely login to your PC and then run programs on your PC that utilize a serial port on the PC. However, it might be better if they didn't need to login and use your software, but instead could immediately connect to the serial port. ser2net running on your PC can make this happen.
It could be like a bridge between the ethernet cable and the serial cable. The ethernet cable would have TCP/IP protocol on it but the serial port would just have the raw data taken out of the TCP/IP packets. Optionally, you could use TCP/IP packets on the serial line too. Since an ethernet port has high bandwidth, it could communicate with several serial ports at the same time and also have data flowing elsewhere as well.
To set up ser2net, you must specify which network ports (on the ethernet) will connect to which serial ports. Then when network packets arrive at your PC over ethernet which are addressed to a network port you've tied to a serial port, the data in those packets flows to the serial port. And conversely. Of course the network doesn't have to be ethernet. It could be a cable modem or DSL line, etc.
By "speed" we really mean the "data flow rate" but almost everybody incorrectly calls it speed. The speed is measured in bits/sec (or baud). Speed is set using the "stty" command or by a program which uses the serial port. See Stty
The top speed of 115.2k has been standard since the mid 1990's. But by the year 2000, most new serial ports supported higher speeds of 230.4k and 460.8k. Some also support 921.6k. Unfortunately Linux seldom uses these speeds due to lack of drivers. Thus such ports behave just like 115.2k ports unless the higher speeds are enabled by special software. To get these speeds you need to compile the kernel with special patches or use modules until support is built into the kernel's serial driver.
Unfortunately serial port manufacturers never got together on a standard way to support high speeds, so the serial driver needs to support a variety of hardware. Once high speed is enabled, a standard way to choose it is to set baud_base to the highest speed with setserial (unless the serial driver does this for you). The software will then use a divisor of 1 to set the highest speed. All this will hopefully be supported by the Linux kernel sometime in 2003.
A driver for the w83627hf chip (used on many motherboards such as the Tyan S2460) is at https://www.muru.com/linux/w83627hf/
A non-standard way that some manufacturers have implemented high speed is to use a very large number for the divisor to get the high speed. This number isn't really a divisor at all since it doesn't divide anything. It's just serves as a code number to tell the hardware what speed to use. In such cases you need to compile the kernel with special patches.
One patch to support this second type of high-speed hardware is called shsmod (Super High Speed Mode). There are both Windows and Linux versions of this patch. See http://www.devdrv.com/shsmod/. There is also a module for the VIA VT82C686 chip http://www.kati.fi/viahss/. Using it may result in buffer overflow.
For internal modems, only a minority of them advertise that they support speeds of over 115.2k for their built-in serial ports. Does shsmod support these ??
Speed is set by having the serial port's clock change frequency. But this change happens not by actually changing the frequency of the oscillator driving the clock but by "dividing" the clock's frequency. For example, to divide by two, just ignore every other clock tick. This cuts the speed in half. Dividing by 3 makes the clock run at 1/3 frequency, etc. So to slow the clock down (meaning set speed), we just send the clock a divisor. It's sent by the serial driver to a register in the port. Thus speed is set by a divisor.
If the clock runs at a top speed of 115,000 bps (common), then here are the divisors for various speeds (assuming a maximum speed of 115,200): 1 (115.2k), 2 (57.6k), 3 (38.4k), 6 (19.2k), 12 (9.6k), 24 (4.8k), 48 (2.4k), 96 (1.2k), etc. The serial driver sets the speed in the hardware by sending the hardware only a "divisor" (a positive integer). This "divisor" divides the "maximum speed" of the hardware resulting in a slower speed (except a divisor of 1 obviously tells the hardware to run at maximum speed).
There are exceptions to the above since for certain serial port hardware, speeds above 115.2k are set by using a very high divisor. Keep that exception in mind as you read the rest of this section. Normally, if you specify a speed of 115.2k (in your communication program or by stty) then the serial driver sets the port hardware to divisor 1 which sets the highest speed.
Besides using a very high divisor to set high speed, the conventional way to do it is as follows: If you happen to have hardware with a maximum speed of say 230.4k (and the 230.4k speed has been enabled in the hardware), then specifying 115.2k will result in divisor 1. For some hardware this will actually give you 230.4k. This is double the speed that you set. In fact, for any speed you set, the actual speed will be double. If you had hardware that could run at 460.8k then the actual speed would be quadruple what you set. All the above assumes that you don't use "setserial" to modify things.
To correct this accounting (but not always fix the problem) you may use "setserial" to change the baud_base to the actual maximal speed of your port such as 230.4k. Then if you set the speed (by your application or by stty) to 230.4k, a divisor of 1 will be used and you'll get the same speed as you set.
If you have very old software which will not allow you to tell it such a high speed (but your hardware has it enabled) then you might want to look into using the "spd_cust" parameter. This allows you to tell the application that the speed is 38,400 but the actual speed for this case is determined by the value of "divisor" which has also been set in setserial. I think it best to try to avoid using this kludge.
There are some brands of UARTs that uses a very high divisor to set high speeds. There isn't any satisfactory way to use "setserial" (say set "divisor 32770") to get such a speed since then setserial would then think that the speed is very low and disable the FIFO in the UART.
Note that the baud_base setting is usually much lower than the frequency of the crystal oscillator since the crystal frequency of say 1.8432 MHz is divided by 16 in the hardware to get the actual top speed of 115.2k. The reason the crystal frequency needs to be higher is so that this high crystal speed can generate clock ticks to take a number of samples of each bit to determine if it's a 1 or a 0.
Actually, the 1.8432 MHz "crystal frequency" may be obtained from a 18.432 MHz crystal oscillator by dividing by 10 before being fed to the UART. Other schemes are also possible as long as the UART performs properly.
If you are seeing slow throughput and serial port overruns on a
system with (E)IDE disk drives, you can get hdparm
. This
is a utility that can modify (E)IDE parameters, including unmasking
other IRQs during a disk IRQ. This will improve responsiveness
and will help eliminate overruns. Be sure to read the man page very
carefully, since some drive/controller combinations don't like this
and may corrupt the filesystem.
Also have a look at a utility called irqtune
that will change
the IRQ priority of a device, for example the serial port that your
modem is on. This may improve the serial throughput on your system.
The irqtune
FAQ is at
http://www.best.com/~cae/irqtune
When you are using a serial port, you may want to prevent others from using it at the same time. However there may be cases where you do want others to use it, such as sending you an important message if you are using a text-terminal.
There are various ways of preventing others (or other processes) from using your serial port when you are using it (locking). This should all happen automatically but it's important to know about this if it gives you trouble. If a program is abnormally exited or the PC is abruptly turned off (by pulling the plug, etc.) your serial port might wind up locked. Even if the lock remains, it's usually automatically removed when you want to use the serial port again. But in rare cases it isn't. That's when you need to understand what happened.
One way to implement locking is to design the kernel to handle it but Linux thus far has shunned this solution (with an exception involving the cua device which is now obsolete). Two solutions used by Linux is to:
If you use the new device-filesystem (devfs) then see the next
section. A lock-file is simply a file created to mean that a
particular device is in use. They are kept in /var/lock
.
Formerly they were in /usr/spool/uucp
. Linux lock-files are
usually named LCK..
name, where name may be a device
name, a process id number, a device's major and minor numbers, or a
UUCP site name. Most processes (an exception is getty) create these
locks so that they can have exclusive access to devices. For instance
if you dial out on your modem, some lockfiles will appear to tell
other processes that someone else is using the modem. In older
versions (in the 1990s) there was usually only one lockfile per
process. Lock files contain the PID of the process that has locked
the device. Note that if a process insists on using a device that is
locked, it may ignore the lockfile and use the device anyway. This is
useful in sending a message to a text-terminal, etc.
When a program wants to use a serial port but finds it locked with lock-files it should check to see if the lock-file's PID is still in use. If it's not it means that the lock is stale and it's OK to go ahead and use the port anyway (after removing the stale lock-files). Unfortunately, there may be some programs that don't do this and give up by telling you that a device is already in use when it really isn't.
If the lockfile only uses device names, the following problem could arise: If the same device has two different names then two different processes could each use a different name for the same device. This results in lockfiles with different names that actually are the same device. Formerly each physical serial port was known by two different device names: ttyS0 and cua0. To solve this lockfile alias problem, 3 methods have been used. It may be overkill since any one of these methods would have fixed the problem.
Using alternate names such as /dev/modem for /dev/ttyS2 may cause problems if one program opens /dev/ttyS2 while another program opens /dev/modem. This problem was supposedly fixed around 2000, but is still present in 2005. For dumb terminals, lockfiles are not used since this would not permit someone else to send a message to your terminal using the write or talk program.
In order to use a device, you (or the program you run if you have "set user id") needs to have permission to read and write the device "file" in the /dev directory. So a logical way to prevent others from using a device is to make yourself the temporary owner of the device and set permissions so that no one else can use it. A program may do this for you. A similar method can be used with the group of the device file.
While lock files prevent other process from using the device, changing device file owners/permissions restricts other users (or the group) from using it. One case is where the group is permitted to write to the port, but not to read from it. Writing to the port might just mean a message sent to a text-terminal while reading means destructive reading. The original process that needs to read the data may find data missing if another process has already read that data. Thus a read can do more harm that a write since a read causes loss of data while a write only adds extra data. That's a reason to allow writes but not reads. This is exactly the opposite of the case for ordinary files where you allow others to read the file but not write (modify) it. Use of a port normally requires both read and write permissions.
A program that changes the device file attributes should undo these changes when it exits. But if the exit is abnormal, then a device file may be left in such a condition that it gives the error "permission denied" when one attempts to use it again.
Here is a list of some communication software you can choose from, available via FTP, if they didn't come with your Linux distribution.
ecu
- a communications programgkermit
Tiny GPLed kermit run only from the command line.
Can't connect to another computergtkterm
- a simple gtk terminal, X-basedminicom
- telix-like communications programpicocom
- like a small minicom but no automatic phone dialingpppd
- establishes a ppp connection on the serial lineseyon
- X based communication programxc
- xcomm communication package
term
and SLiRP
offer TCP/IP functionality using a
shell account.
screen
is another multi-session program. This one behaves
like the virtual consoles.
callback
is where you dial out to a remote modem and then
that modem hangs up and calls you back (to save on phone bills).
mgetty+fax
handles FAX stuff, and provides an alternate
ps_getty
.
ZyXEL
is a control program for ZyXEL U-1496 modems. It
handles dialin, dialout, dial back security, FAXing, and voice
mailbox functions.
ftp://metalab.unc.edu/pub/Linux/system/network/serial
. For use of kermit with modems see the Modem-HOWTO. One can run
zmodem within the kermit program. To do this (for ttyS3), add the
following to your .kermrc
file:
define rz !rz < /dev/ttyS3 > /dev/ttyS3
define sz !sz \%0 > /dev/ttyS3 < /dev/ttyS3
Be sure to put in the correct port your modem is on. Then, to use it,
just type rz
or sz <filename>
at the kermit
prompt.
Often the serial driver is provided as a module(s) such as generic_serial.ko. Drivers for USB serial ports and multiport cards are often provided as modules. Linux should automatically load any needed module, so in most cases you have nothing to do.
But sometimes you need to configure Linux to load certain modules or gives parameters to the module or to the kernel.
Such parameters may be supplied to certain modules on the command line for the kernel or in /etc/modules, /etc/modules.conf or /etc/modprobe.conf. Since kernel 2.2 you don't edit the modprobe.conf file but use the program update-modules to change it. The info that is used to update modules.conf is put in /etc/modutils/.
The Debian/GNU Linux has a file named /etc/modutils/setserial which runs the serial script in /etc/init.d/ every time the serial module is loaded or unloaded. When the serial module is unloaded this script will save the state of the module in /var/run/setserial.conf. Then if the module loads again this saved state is restored. When the serial module first loads at boot-time, there's nothing in /var/run/setserial.conf so the state is obtained from /etc/serial.conf. So there are two files that save the state. Other distributions may do something similar.
Serial modules are found in subdirectories of
/lib/modules/.../kernel/drivers/
. For multiport cards, look
in the serial
subdirectory and/or char
. For USB serial,
look in the usb/serial
subdirectory. The module,
parport_serial is for PCI cards that contain both serial and parallel
ports.
As a last resort, one may modify the serial driver by editing the source code. Much of the serial driver is found in the file serial.c. For info regarding writing of programs for the serial port see Serial-Programming-HOWTO. It was revised in 1999 by Vern Hoxie but that revision is not at LDP.
If you have more than 4 (or possibly 2) serial ports, then you must insure that the kernel knows this. It can be done by configuring the kernel when compiling or by a parameter given to the kernel when it starts (boot-prompt or kernel command line).
The kernel configuration parameters: CONFIG_SERIAL_8250_RUNTIME_UARTS=4 and CONFIG_SERIAL_8250_NR_UARTS=4 set the maximum number of ordinary serial ports (UARTs) equal to 4. If you have more than 4 ordinary serial ports, then you need to change the 4 to whatever. But you may override this via the kernel command line for example: nr_uarts=16 (if serial support built into the kernel) or 8250.nr_uarts=16 (if serial support is via a module). The boot loader such as lilo or grub can be told to do this.
See the kernel documentation in: Documentation/serial-console.txt. Kernel 2.4+ has better documentation. See also "Serial Console" in Text-Terminal-HOWTO.
For a text terminal, the RS-232 speeds are fast enough but the usable cable length is often too short. Balanced technology could fix this. The common method of obtaining balanced communication with a text terminal is to install 2 line drivers in the serial line to convert unbalanced to balanced (and conversely). They are a specialty item and are expensive if purchased new.
Normally flow control and/or application programs stop the flow of bytes when its needed. But sometimes they don't. The problem is that output to the serial port first passes thru the large serial buffer in the PC's main memory. So if you want to abort printing, whatever is in this buffer should be removed. When you tell an application program to stop printing, it may not empty this buffer so printing continues until it's empty. In addition, your printer has it's own buffer which needs to be cleared. So telling the PC to stop printing may not work due to these two buffers that continue to supply bytes for the printer. It's a problem with printer software not knowing about the serial port and that modem control lines need to be dropped to stop the printer.
One way to insure that printing stops is to just turn off the printer. With newer serial drivers, this works OK. The buffers are cleared and printing doesn't resume. With older serial drivers, the PC's serial buffer didn't clear and it would sometimes continue to print when the printer was turned back on. To avoid this, you must wait a time specified by setserial's closing_wait before turning the printer back on again. You may also need to remove the print job from the print queue so it won't try to resume.
The IO address of the IBM 8514 video board (and others) is
allegedly 0x?2e8 where ? is 2, 4, 8, or 9. This may conflict (but
shouldn't if the serial port is well designed) with the IO address of
ttyS3
at 0x02e8 if the serial port ignores the leading 0 hex
digit when it decodes the address (many do). That is bad news if you
try to use ttyS3
at this IO address. Another story is that Linux
will not detect your internal modem on ttyS3
but that you can use
setserial
to put ttyS3
at this address and the modem
will work fine.
The address of ttyS2 is 3e8-3ef while hard drive ide2 uses 3ee which is in this range. So when booting Linux you may see a report of this conflict. Most people don't use ide2 (the 3rd hard drive cable) and may ignore this conflict message. You may have 2 hard drives on ide0 and two more on ide1 so most people don't need ide2.
This has a race condition between an interrupt and a status register of the UART. An interrupt is issued when the UART transmitter finishes the transmission of a byte and the UART transmit buffer becomes empty (waiting for the next byte). But a status register of the UART doesn't get updated fast enough to reflect this. As a result, the interrupt service routine rapidly checks and determines (erroneously) that nothing has happened. Thus no byte is sent to the port to be transmitted and the UART transmitter waits in vain for a byte that never arrives. If the interrupt service routine had waited just a bit longer before checking the status register, then it would have been updated to reflect the true state and all would be OK.
There is a proposal to fix this by patching the serial driver. But Should linux be patched to accommodate defective hardware, especially if this patch may impair performance of good hardware?
See Modem-HOWTO for troubleshooting related to modems or getty for modems. For a Text-Terminal much of the info here will be of value as well as the troubleshooting info in Text-Terminal-HOWTO.
While a multimeter (used as a voltmeter) may be all that you need for just a few serial ports, simple special test equipment has been made for testing serial port lines. Some are called "breakout ... " where breakout means to break out conductors from a cable. These gadgets have a couple of connectors which connect to serial port connectors (either at the ends of serial cables or at the back of a PC). Some have test points for connecting a voltmeter. Others have LED lamps which light when certain modem control lines are asserted (turned on). The color of the light may indicate the polarity of the signal (positive or negative voltage). Still others have jumpers so that you can connect any wire to any wire. Some have switches.
Radio Shack sells (in 2002) a "RS-232 Troubleshooter" (formerly called "RS-232 Line Tester") Cat. #276-1401. It checks TD, RD, CD, RTS, CTS, DTR, and DSR. A green light means on (+12 v) while red means off (-12 v). They also sell a "RS-232 Serial Jumper Box" Cat. #276-1403. This permits connecting the pins anyway you choose. Both these items are under the heading of "Peripheral hookup helpers". Unfortunately, they are not listed in the index to the printed catalog. They are on the same page as the D type connecters so look in the index under "Connectors, Computer, D-Sub". A store chain named "Active Components" may have them.
Any voltmeter or multimeter, even the cheapest that sells for about $10, should work fine. Trying to use other methods for checking voltage is tricky. Don't use a LED unless it has a series resistor to reduce the voltage across the LED. A 470 ohm resistor is used for a 20 ma LED (but not all LED's are 20 ma). The LED will only light for a certain polarity so you may test for + or - voltages. Does anyone make such a gadget for automotive circuit testing?? Logic probes may be damaged if you try to use them since the TTL voltages for which they are designed are only 5 volts. Trying to use a 12 V incandescent light bulb is not a good idea. It won't show polarity and due to limited output current of the UART it probably will not even light up.
To measure voltage on a female connector you may plug in a bent paper clip into the desired opening. The paper clip's diameter should be no larger than the pins so that it doesn't damage the contact. Clip an alligator clip (or the like) to the paper clip to connect up. Take care not to touch two pins at the same time with any metal object.
As a last resort, if you have no test equipment and are willing to risk getting shocked (or even electrocuted) you can always taste the voltage. Before touching one of the test leads with your tongue, test them to make sure that there is no high voltage on them. Touch both leads (at the same time) to one hand to see if they shock you. Then if no shock, wet the skin contact points by licking and repeat. If this test gives you a shock, you certainly don't want to use your tongue.
For the test for 12 V, Lick a finger and hold one test lead in it. Put the other test lead on your tongue. If the lead on your tongue is positive, there will be a noticeable taste. You might try this with flashlight batteries first so you will know what taste to expect.
A few Linux programs will monitor the modem control lines and indicate if they are positive (1) or negative (0). See section Serial Monitoring/Diagnostics
There are 3 possibilities:
First check BIOS messages at boot-time (and possibly the BIOS menu for the serial port). Then for the PCI bus type lspci -v. If this shows something like "LPC Bridge" then your port is likely on the LPC bus which is not well supported by Linux yet (but the BIOS might find it) ?? If it's an ISA bus PnP serial port, try "pnpdump --dumpregs" and/or see Plug-and-Play-HOWTO. If the port happens to be enabled then the following two paragraphs may help find the IO port:
This is mainly for legacy non-PCI ports and ISA ports that are not Plug-and-Play.
Using "scanport" (Debian only ??) will scan all enabled bus ports and may discover an unknown port that could be a serial port (but it doesn't probe the port). It could hang your PC. If you suspect that your port may be at a certain address, you may try manually probing with setserial, but it's a slow tedious task if you have several addresses to probe. See Probing.
If your PC has a BIOS that handles ISA (and likely PCI too) then if you find a IRQ conflict, it might be due to a shortage of free IRQs. The BIOS often maintains a list of reserved IRQs, reserved for legacy ISA cards. If too many are reserved, the BIOS may not be able to find a free IRQ and will erroneously assign an IRQ to the serial port that creates a conflict. So check to see if all the reserved IRQs are really needed and if not, unreserve an IRQ that the serial port can use. For more details, see Plug-and-Play-HOWTO.
It's likely mis-set/conflicting interrupts. Here are some of the symptoms which will happen the first time you try to use a modem, terminal, or serial printer. In some cases you type something but nothing appears on the screen until many seconds later. Only the last character typed may show up. It may be just an invisible <return> character so all you notice is that the cursor jumps down one line. In other cases where a lot of data should appear on the screen, only a batch of about 16 characters appear. Then there is a long wait of many seconds for the next batch of characters. You might also get "input overrun" error messages (or find them in logs).
For more details on the symptoms and why this happens see Interrupt Problem Details and/or Interrupt Conflicts and/or Mis-set Interrupts. If it involves Plug-and-Play devices, see also the Plug-and-Play-HOWTO.
As a quick check to see if it really is an interrupt problem, set the IRQ to 0 with "setserial". This will tell the driver to use polling instead of interrupts. If this seems to fix the "slow" problem then you had an interrupt problem. You should still try to solve the problem since polling uses excessive computer resources.
Checking to find the interrupt conflict may not be easy since Linux supposedly doesn't permit any interrupt conflicts and will send you a /dev/ttyS?: Device or resource busy error message if it thinks you are attempting to create a conflict. But a real conflict can be created if "setserial" has told the kernel incorrect info. The kernel has been lied to and thus doesn't think there is any conflict. Thus using "setserial" will not reveal the conflict (nor will looking at /proc/interrupts which bases its info on "setserial"). You still need to know what "setserial" thinks so that you can pinpoint where it's wrong and change it when you determine what's really set in the hardware.
What you need to do is to check how the hardware is set by checking jumpers or using PnP software to check how the hardware is actually set. For PnP run either "pnpdump --dumpregs" (if ISA bus) or run "lspci" (if PCI bus). Compare this to how Linux (e.g. "setserial") thinks the hardware is set.
An obvious reason is that the baud rate is set too slow. It's claimed that this once happened by trying to set the baud rate to a speed higher than the hardware can support (such as 230400).
Another reason may be that whatever is on the serial port (such as a modem, terminal, printer) doesn't work as fast as you thought it did.
Another possible reason is that you have an obsolete serial port: UART 8250, 16450 or early 16550 (or the serial driver thinks you do). See
What Are UARTS? Use "setserial -g /dev/ttyS*". If it shows anything less than a 16550A, this may be your problem. If you think that "setserial" has it wrong check it out. See What is Setserial for more info. If you really do have an obsolete serial port, lying about it to setserial will only make things worse.
For non-PnP ports, Linux does not do any IRQ detection on startup. When the serial module loads it only does serial device detection. Thus, disregard what it says about the IRQ, because it's just assuming the standard IRQs. This is done, because IRQ detection is unreliable, and can be fooled. But if and when setserial runs from a start-up script, it changes the IRQ's and displays the new (and hopefully correct) state on on the startup screen. If the wrong IRQ is not corrected by a later display on the screen, then you've got a problem.
So, even though I have my ttyS2
set at IRQ 5, I still see
ttyS02 at 0x03e8 (irq = 4) is a 16550A
at first when Linux boots. (Older kernels may show "ttyS02" as
"tty02" which is the same as ttyS2). You may need to use
setserial
to tell Linux the IRQ you are using.
See /dev/tty? Device or resource busy
Check the file permissions on this port with "ls -l /dev/ttyS?"_ If you own the ttyS? then you need read and write permissions: crw with the c (Character device) in col. 1. It you don't own it then it will work for you if it shows rw- in cols. 8 & 9 which means that everyone has read and write permission on it. Use "chmod" to change permissions. There are more complicated (and secure) ways to get access like belonging to a "group" that has group permission. Some programs change the permissions when they run but restore them when the program exists normally. But if someone pulls the plug on your PC it's an abnormal exit and correct permissions may not be restored.
Unless stty is set for clocal, the CD pin may need to be asserted in order to open a serial port. If the physical port is not connected to anything, or if it's connected to something that is not powered on (such an external modem) then there will be no voltage on CD from that device. Thus the "cannot open" message. Either set clocal or connect the serial port connector to something and power it on.
Even if a device is powered on and connected to a port, it may sometimes prevent opening the port. An example of this is where the device has negated CD and the CD pin on your PC is negated (negative voltage).
This means that an operation requested by setserial, stty, etc. couldn't be done because the kernel doesn't support doing it. Formerly this was often due to the "serial" module not being loaded. But with the advent of PnP, it may likely mean that there is no modem (or other serial device) at the address where the driver (and setserial) thinks it is. If there is no modem there, commands (for operations) sent to that address obviously don't get done. See What is set in my serial port hardware?
If the "serial" module wasn't loaded but "lsmod" shows you it's now loaded it might be the case that it's loaded now but wasn't loaded when you got the error message. In many cases the module will automatically loaded when needed (if it can be found). To force loading of the "serial" module it may be listed in the file: /etc/modules.conf or /etc/modules. The actual module should reside in: /lib/modules/.../misc/serial.o.
Sometimes when it can't create a lockfile you get the erroneous message: "... Device or resource busy" instead of the one above. When a port is "opened" by a program a lockfile is created in /var/lock/. Wrong permissions for the lock directory will not allow a lockfile to be created there. Use "ls -ld /var/lock" to see if the permissions are OK. Giving rwx permissions for the root owner and the group should work, provided that the users that need to dialout belong to that group. Others should have r-x permission. Even with this scheme, there may be a security risk. Use "chmod" to change permissions and "chgrp" to change groups. Of course, if there is no "lock" directory no lockfile can be created there. For more info on lockfiles see What Are Lock Files
This means that someone else (or some other process) is supposedly using the serial port. There are various ways to try to find out what process is "using" it. One way is to look at the contents of the lockfile (/var/lock/LCK...). It should be the process id. If the process id is say 100 type "ps 100" to find out what it is. Then if the process is no longer needed, it may be gracefully killed by "kill 100". If it refuses to be killed use "kill -9 100" to force it to be killed, but then the lockfile will not be removed and you'll need to delete it manually. Of course if there is no such process as 100 then you may just remove the lockfile but in most cases the lockfile should have been automatically removed if it contained a stale process id (such as 100).
This means that the device you are trying to access (or use) is supposedly busy (in use) or that a resource it needs (such as an IRQ) is supposedly being used by another device and can't be shared. This message is easy to understand if it only means that the device is busy (in use). But it sometimes means that a needed resource is already in use (busy). What makes it even more confusing is that in some cases neither the device nor the resources that it needs are actually "busy".
In olden days, if a PC was shutdown by just turning off the power, a bogus lockfile might remain and then later on one would get this bogus message and not be able to use the serial port. Software today is supposed to automatically remove such bogus lockfiles, but as of 2006 there is still a problem with the "wvdial" dialer program related to lockfiles. If wvdial can't create a lockfile because it doesn't have write permission in the /var/lock/ directory, you will see this erroneous message. See Cannot create lockfile. Sorry
The following example is where interrupts can't be shared (at least
one of the interrupts is on the ISA bus). The ``resource busy'' part
often means (example for ttyS2
) ``You can't use ttyS2
since
another device is using ttyS2's interrupt.'' The potential interrupt
conflict is inferred from what "setserial" thinks. A more accurate
error message would be ``Can't use ttyS2
since the setserial data
(and kernel data) indicates that another device is using ttyS2
's
interrupt''. If two devices use the same IRQ and you start up only
one of the devices, everything is OK because there is no conflict yet.
But when you next try to start the second device (without quitting the
first device) you get a "... busy" error message. This is because the
kernel only keeps track of what IRQs are actually in use and actual
conflicts don't happen unless the devices are in use (open). The
situation for I/O address (such as 0x3f8) conflict is similar.
This error is sometimes due to having two serial drivers: one a module and the other compiled into the kernel. Both drivers try to grab the same resources and one driver finds them "busy".
There are two possible cases when you see this message:
ttyS2
can't be
used is that setserial erroneously predicts a conflict.What you need to do is to find the interrupt setserial thinks
ttyS2
is using. Look at /proc/tty/driver/serial. You should
also be able to find it with the "setserial" command for ttyS2
.
Bug in old versions: Prior to 2001 there was a bug which wouldn't let you see it with "setserial". Trying to see it would give the same "... busy" error message.
To try to resolve this problem reboot or: exit or gracefully kill all likely conflicting processes. If you reboot: 1. Watch the boot-time messages for the serial ports. 2. Hope that the file that runs "setserial" at boot-time doesn't (by itself) create the same conflict again.
If you think you know what IRQ say ttyS2
is using then you may
look at /proc/interrupts to find what else (besides another serial
port) is currently using this IRQ. You might also want to double
check that any suspicious IRQs shown here (and by "setserial") are
correct (the same as set in the hardware). A way to test whether or
not it's a potential interrupt conflict is to set the IRQ to 0
(polling) using "setserial". Then if the busy message goes away, it
was likely a potential interrupt conflict. It's not a good idea to
leave it permanently set at 0 since it will put more load on the CPU.
This means that communication with the serial port isn't working right. It could mean that there isn't any serial port at the IO address that setserial thinks your port is at. It could also be an interrupt conflict (or an IO address conflict). It also may mean that the serial port is in use (busy or opened) and thus the attempt to get/set parameters by setserial or stty failed. It will also happen if you make a typo in the serial port name such as typing "ttys" instead of "ttyS".
LSR is the name of a hardware register. It usually means that there is no serial port at the address where the driver thinks your serial port is located. You need to find your serial port and possibly configure it. See Locating the Serial Port: IO address IRQs and/or What is Setserial
This is an overrun of the hardware FIFO buffer and you can't increase its size. Bug note (reported in 2002): Due to a bug in some kernel 2.4 versions, the port number may be missing and you will only see "ttyS" (no port number). But if devfs notation such as "tts/2" was being used, there was no bug. See Higher Serial Thruput.
There could be some other program running on the port. Use "top" (provided you've set it to display the port number) or type "ps -alxw". Look at the results to see if the port is being used by another program. Be on the lookout for the gpm mouse program which often runs on a serial port.
These are some of the programs you might want to use in troubleshooting:
Perhaps a baud mismatch. If one port sends at twice the speed that the other port is set to receive, then every two characters sent will be received as one character. Each bit of this received character will be a sample of two bits of what is sent and will be wrong. Also, only half the characters sent seem to get received. For flow in the reverse direction, it's just the opposite. Twice as many characters get received than were sent. A worse mismatch will produce even worse results.
A speed mismatch is not likely to happen with a modem since the modem autodetects the speed. One cause of a mismatch may be due to serial port hardware that has been set to run at very fast speeds. It may actually operate at a speed say 8 times that of which you (or an application) set it via software. See Very High Speeds
While the section Troubleshooting lists problems by symptom, this section explains what will happen if interrupts are set incorrectly. This section helps you understand what caused the symptom, what other symptoms might be due to the same problem, and what to do about it.
The "setserial" program will show you how serial driver thinks the interrupts are set. If the serial driver (and setserial) has it right then everything regarding interrupts should be OK. Of course a /dev/ttyS must exist for the device and Plug-and-Play (or jumpers) must have set an address and IRQ in the hardware. Linux will not knowingly permit an interrupt conflict and you will get a "Device or resource busy" error message if you attempt to do something that would create a conflict.
Since the kernel tries to avoid interrupt conflicts and gives you the "resource busy" message if you try to create a conflict, how can interrupt conflicts happen? Easy. "setserial" may have it wrong and erroneously predicts no conflict when there will actually be a real conflict based on what is set in the hardware. When this happens there will be no "... busy" message but a conflict will physically happen. Performance is likely to be extremely slow. Both devices will send identical interrupt signals on the same wire and the CPU will erroneously think that the interrupts only come from one device. This will be explained in detail in the following sections.
Linux doesn't complain when you assign two devices the same IRQ provided that neither device is in use. As each device starts up (initializes), it asks Linux for permission to use its hardware interrupt. Linux keeps track of which interrupt is assigned to whom, and if your interrupt is already in use, you'll see this "... busy" error message. Thus if two devices use the same IRQ and you start up only one of the devices, everything is OK. But when you next try to start the second device (without quitting the first device) you get "... busy" error message.
The symptoms depend on whether or not you have a modern serial port with FIFO buffers or an obsolete serial port without FIFO buffers. It's important to understand the symptoms for the obsolete ones also since sometimes modern ports seem to behave that way.
For the obsolete serial ports, only one character gets thru every several seconds. This is so slow that it seems almost like nothing is working (especially if the character that gets thru is invisible (such a space or newline). For the modern ports with FIFO buffers you will likely see bursts of up to 16 characters every several seconds.
If you have a modem on the port and dial a number, it seemingly may not connect since the CONNECT message may not make it thru. But after a long wait it may finally connect and you may see part of a login message (or the like). The response from your side of the connection may be so delayed that the other side gives up and disconnects you, resulting in a NO CARRIER message.
If you use minicom, a common test to see if things are working is to type the simplest "AT" command and see if the modem responds. Typing just at<enter> should normally (if interrupts are OK) result in an immediate "OK" response from the modem. With bad interrupts you type at<enter> and may see nothing. But then after 10 seconds or so you see the cursor drop down one line. What is going on is that the FIFO is behaving like it can only hold one byte. The "at" you typed caused it to overrun and both letters were lost. But the final <enter> eventually got thru and you "see" this invisible character by noticing that the cursor jumped down one line. If you were to type a single letter and then wait about 10 seconds, you should see it echo back to the screen. This is fine if your typing speed is less that one word per minute :-)
If you don't understand what an interrupt does see Interrupts. If a serial port has one IRQ set in the hardware but a different one set in the device driver, the device driver will not catch any interrupts sent by the serial port. Since the serial port uses interrupts to call its driver to service the port (fetching bytes from its 16-byte receive buffer or putting another 16-bytes in its transmit buffer) one might expect that the serial port would not work at all.
But it still may work anyway --sort of. Why? Well, besides the interrupt method of servicing the port there's an undocumented slow polling method that doesn't need interrupts. The way it works is that every so often the device driver checks the serial port to see if it needs anything such as if it has some bytes that need fetching from its receive buffer. If interrupts don't work, the serial driver falls back to this polling method. But this polling method was not intended to be used a substitute for interrupts. It's so slow that it's not practical to use and may cause buffer overruns. Its purpose may have been to get things going again if just one interrupt is lost or fails to do the right thing. It's also useful in showing you that interrupts have failed. Don't confuse this slow polling method with the fast polling method that operates on ports that have their IRQs set to 0.
For the 16-byte transmit buffer, 16 bytes will be transmitted and then it will wait until the next polling takes place (several seconds later) before the next 16 bytes are sent out. Thus transmission is very slow and in small chunks. Receiving is slow too since bytes that are received by the receive buffer are likely to remain there for several seconds until it is polled.
This explains why it takes so long before you see what you typed. When you type say AT to a modem, the AT goes out the serial port to the modem. The modem then echos the AT back thru the serial port to the screen. Thus the AT characters have to pass twice thru the serial port. Normally this happens so fast that AT seems to appear on the screen at the same time you hit the keys on the keyboard. With slow polling delays at the serial port, you don't see what you typed until perhaps 15 seconds later. Even then, you don't often see all you typed but only the first several characters.
What about overruns of the 16-byte receive buffer? This will happen with an external modem since the modem just sends to the serial port at high speed which is likely to overrun the 16-byte buffer. But for an internal modem, the serial port is on the same card and it's likely to check that this 16-byte receive buffer has room for more bytes before putting received bytes into it. In this case there will be no overrun of this receive buffer, but text will just appear on your screen in 16-byte chunks spaced at intervals of several seconds.
Even with an external modem you might not get overruns. If just a few characters (under 16) are sent you don't get overruns since the buffer likely has room for them. But attempts to send a larger number of bytes from your modem to your screen may result in overruns. However, more than 16 (with no gaps) can get thru without overruns if the timing is right. For example, suppose a burst of 32 bytes is sent into the port from the external cable. The polling might just happen after the first 16 bytes came in so it would pick up these 16 bytes OK. Then there would be space for the next 16 bytes so that entire 32 bytes gets thru OK. While this scenario is not very likely, similar cases where 17 to 31 bytes make thru are more likely. But it's even more likely that only an occasional 16-byte chunk will get thru with possible loss of data.
If you have an obsolete serial port with only a 1-byte buffer (or it's been incorrectly set to work like a 1-byte buffer) then the situation will be much worse than described above and only one character will occasionally make it thru the port. Every character received causes an overrun (and is lost) except for the last character received. This character is likely to be just a line-feed since this is often the last character to be transmitted in a burst of characters sent to your screen. Thus you may type AT<return> to the modem but never see AT on the screen. All you see several seconds later is that the cursor drops down one line (a line feed). This has happened to me with a 16-byte FIFO buffer that was behaving like a 1-byte buffer.
When a communication program starts up, it expects interrupts to be working. It's not geared to using this slow polling-like mode of operation. Thus all sorts of mistakes may be made such as setting up the serial port and/or modem incorrectly. It may fail to realize when a connection has been made. If a script is being used for login, it may fail (caused by timeout) due to the polling delays.
When two devices have the same IRQ number it's called sharing interrupts. Under some conditions this sharing works out OK. Starting with kernel version 2.2, ISA serial ports may, if the hardware is designed for this, share interrupts with other serial ports. Devices on the PCI bus may share the same IRQ interrupt with other devices on the PCI bus (provided the software supports this). In other cases where there is potential for conflict, there should be no problem if no two devices with the same IRQ are ever "in use" at the same time. More precisely, "in use" really means "open" (in programmer jargon). In cases other than the exceptions mentioned above (unless special software and hardware permit sharing), sharing is not allowed and conflicts arise if sharing is attempted.
Even if two processes with conflicting IRQs run at the same time, one of the devices will likely have its interrupts caught by its device driver and may work OK. The other device will not have its interrupts caught by the correct driver and will likely behave just like a process with mis-set interrupts. See Mis-set Interrupts for more details.
If you are getting a very slow response as described above, then one test is to change the IRQ to 0 (uses fast polling instead of interrupts) and see if the problem goes away. Note that the polling due to IRQ=0 is orders of magnitude faster than the slow "polling" due to bad interrupts. If IRQ=0 seems to fix the problem, then there was likely something wrong with the interrupts. Using IRQ=0 is very resource intensive and is only a temporary fix. You should try to find the cause of the interrupt problem and not permanently use IRQ=0.
Check /proc/interrupts to see if the IRQ is currently in use by another process. If it's in use by another serial port you could try "top" (type f and then enable the TTY display) or "ps -e" to find out which serial ports are in use. If you suspect that setserial has a wrong IRQ then see What is the current IO address and IRQ of my Serial Port ?
UARTs (Universal Asynchronous Receiver Transmitter) are serial chips on your PC motherboard (or on an internal modem card). The UART function may also be done on a chip that does other things as well. On older computers like many 486's, the chips were on the disk IO controller card. Still older computer have dedicated serial boards.
When PCs all had parallel bus architecture, the UART's purpose was to convert bytes from the PC's parallel bus to a serial bit-stream. The cable going out of the serial port is serial and has only one wire for each direction of flow. The serial port sends out a stream of bits, one bit at a time. Conversely, the bit stream that enters the serial port via the external cable was converted to parallel bytes that the computer can understand. UARTs deal with data in byte sized pieces, which is conveniently also the size of ASCII characters.
Say you have a terminal hooked up to a serial port on your PC. When you type a character, the terminal gives that character to its transmitter (also a UART). The transmitter sends that byte out onto the serial line, one bit at a time, at a specific rate. On the PC end, the receiving UART takes all the bits and reconstruct the byte (parallel on older PCs) and puts it in a buffer. For newer PCs that might have a PCI-e serial port, the UART doesn't need to convert parallel-to-serial since the PCI-e "bus" is already a serial line. But the PCI-e line carries an encoded signal which must be decoded and then greatly slowed down to the speed of the RS-232 serial line.
Along with converting between serial and parallel, the UART does some other things as a byproduct (side effect) of its primary task. The voltage used to represent bits is also converted (changed). Extra bits (called start and stop bits) are added to each byte before it is transmitted. See the Serial-HOWTO section Voltage Waveshapes for details. Also, while the flow rate (in bytes/sec) on the parallel bus inside the computer is very high, the flow rate out the UART on the serial port side of it is much lower. The UART has a fixed set of rates (speeds) which it can use at its serial port interface.
There are two basic types of UARTs: dumb UARTS and FIFO UARTS. Dumb UARTs are the 8250, 16450, early 16550, and early 16650. They are obsolete but if you understand how they work it's easy to understand how the modern ones work with FIFO UARTS ( late 16550, 16550A, and higher numbers). Note that the driver for all of them is still labeled a "8250" driver in Linux where you may see it in compile options if you compile your own kernel, etc.
There is some confusion regarding 16550. Early models had a bug and worked properly only as 16450's (no FIFO). Later models with the bug fixed were named 16550A but many manufacturers did not accept the name change and continued calling it a 16550. Most all 16550's in use today are like 16550A's. Linux will report it as being a 16550A even though your hardware manual (or a label note) says it's a 16550. A similar situation exists for the 16650 (only it's worse since the manufacturer allegedly didn't admit anything was wrong). Linux will report a late 16650 as being a 16650V2. If it reports it as 16650 it is bad news and only is used as if it had a one-byte buffer.
To understand the differences between dumb and FIFO (First In, First Out queue discipline) first let's examine what happens when a UART has sent or received a byte. The UART itself can't do anything with the data passing thru it, it just receives and sends it. For the obsolete dumb UARTS, the CPU gets an interrupt from the serial device every time a byte has been sent or received. The CPU then moves the received byte out of the UART's buffer and into memory somewhere, or gives the UART another byte to send. The obsolete 8250 and 16450 UARTs only have a 1 byte buffer. That means, that every time 1 byte is sent or received, the CPU is interrupted. At low transfer rates, this is OK. But, at high transfer rates, the CPU gets so busy dealing with the UART, that is doesn't have time to adequately tend to other tasks. In some cases, the CPU does not get around to servicing the interrupt in time, and the byte is overwritten, because they are coming in so fast. This is called an "overrun" or "overflow".
FIFO UARTs help solve this problem. The 16550A (or 16550) FIFO chip comes with 16 byte FIFO buffers. This means that it can receive up to 14 bytes (or send 16 bytes) before it has to interrupt the CPU. Not only can it wait for more bytes, but the CPU then can transfer all (14 to 16) bytes at a time. This is a significant advantage over the obsolete UARTs, which only had 1 byte buffers. The CPU receives less interrupts, and is free to do other things. Data is rarely lost. Note that the interrupt threshold of FIFO buffers (trigger level) may be set at less than 14. 1, 4 and 8 are other possible choices. As of late 2000 there was no way the Linux user could set these directly (setserial can't do it). While many PC's only have a 16550 with 16-byte buffers, better UARTS have even larger buffers.
Note that the interrupt is issued slightly before the buffer gets full (at say a "trigger level" of 14 bytes for a 16-byte buffer). This allows room for a couple more bytes to be received before the interrupt service routine is able to actually fetch all these bytes. The trigger level may be set to various permitted values by kernel software. A trigger level of 1 will be almost like an obsolete UART (except that it still has room for 15 more bytes after it issues the interrupt).
Now consider the case where you're on the Internet. It's just sent you a short webpage of text. All of this came in thru the serial port. If you had a 16-byte buffer on the serial port which held back characters until it had 14 of them, some of the last several characters on the screen might be missing as the FIFO buffer waited to get the 14th character. But the 14th character doesn't arrive since you've been sent the entire page (over the phone line) and there are no more characters to send to you. It could be that these last characters are part of the HTML formatting, etc. and are not characters to display on the screen but you don't want to lose format either.
There is a "timeout" to prevent the above problem. The "timeout" works like this for the receive UART buffer: If characters arrive one after another, then an interrupt is issued only when say the 14th character reaches the buffer. But if a character arrives and the next character doesn't arrive soon thereafter, then an interrupt is issued anyway. This results in fetching all of the characters in the FIFO buffer, even if only a few (or only one) are present. There is also "timeout" for the transmit buffer as well.
You may wonder why the FIFO buffers are not larger. After all, memory is cheap and it wouldn't cost much more to use buffers in the kilo-byte range. The reason is flow control. Flow control stops the flow of data (bytes) on serial line when necessary. If a stop signal is sent to serial port, then the stop request is handled by software (even if the flow control is "hardware"). The serial port hardware knows nothing about flow control.
If the serial port buffer contains 64 bytes ready to send when it receives a flow control signal to stop sending, it will send out the 64 bytes anyway in violation of the stop request. There is no stopping it since it doesn't know about flow control. If the buffer was large, then many more bytes would be sent in violation of flow control's request to stop.
Here's a list of some UARTs. TL is Trigger Level
For V.90 56k modems, it may be a several percent faster with a 16650 (especially if you are downloading large uncompressed files). The main advantage of the 16650 is its larger buffer size as the extra speed isn't needed unless the modem compression ratio is high. Some 56k internal modems may come with a 16650 ??
Non-UART, and intelligent multiport boards use DSP chips to do additional buffering and control, thus relieving the CPU even more. For example, the Cyclades Cyclom, and Stallion EasyIO boards use a Cirrus Logic CD1400 RISC UART, and many boards use 80186 CPUs or even special RISC CPUs, to handle the serial IO.
Many 486 PCs (old) and all Pentiums (or the like) should have at least 16550As (usually called just 16550's) with FIFOs. Some better motherboards today (2000) even have 16650s. For replacing obsolete UARTs with newer ones in pre 1990 hardware see the Appendix: Obsolete ...
The pin numbers are often engraved in the plastic of the connector but you may need a magnifying glass to read them. Note DCD is sometimes labeled CD. The numbering of the pins on a female connector is read from right to left, starting with 1 in the upper right corner (instead of 1 in the upper left corner for the male connector as shown below). --> direction is out of PC.
___________ ________________________________________
\1 2 3 4 5/ Looking at pins \1 2 3 4 5 6 7 8 9 10 11 12 13/
\6 7 8 9/ on male connector \14 15 16 17 18 19 20 21 22 23 24 25/
------ -----------------------------------
Pin # Pin # Acronym Full-Name Direction What-it-May-Do/Mean
9-pin 25-pin
3 2 TxD Transmit Data --> Transmits bytes out of PC
2 3 RxD Receive Data <-- Receives bytes into PC
7 4 RTS Request To Send --> RTS/CTS flow control
8 5 CTS Clear To Send <-- RTS/CTS flow control
6 6 DSR Data Set Ready <-- I'm ready to communicate
4 20 DTR Data Terminal Ready--> I'm ready to communicate
1 8 DCD Data Carrier Detect<-- Modem connected to another
9 22 RI Ring Indicator <-- Telephone line ringing
5 7 SG Signal Ground
9-Pin DB9 Connector 25-Pin DB-25 Connector
1 DCD Carrier Detect 1 Chassis Ground
2 RxD Receive Data 2 TxD Transmit Data
3 TxD Transmit Data 3 RxD Receive Data
4 DTR Data Terminal Ready 4 RTS Request To Send
5 SG Signal Ground 5 CTS Clear To Send
6 DSR Data Set Ready 6 DSR Data Set Ready
7 RTS Request To Send 7 SG Signal Ground
8 CTS Clear To Send 8 DCD Carrier Detect
9 RI Ring Indicator 20 DTR Data Terminal Ready
22 RI Ring Indicator
Only 3 of the 9 pins have a fixed assignment: transmit, receive and signal ground. This is fixed by the hardware and you can't change it. But the other signal lines are controlled by software and may do (and mean) almost anything at all. However they can only be in one of two states: asserted (+12 volts) or negated (-12 volts). Asserted is "on" and negated is "off". For example, Linux software may command that DTR be negated and the hardware only carries out this command and puts -12 volts on the DTR pin. A modem (or other device) that receives this DTR signal may do various things. If a modem has been configured a certain way it will hang up the telephone line when DTR is negated. In other cases it may ignore this signal or do something else when DTR is negated (turned off).
It's like this for all the 6 signal lines. The hardware only sends and receives the signals, but what action (if any) they perform is up to the Linux software and the configuration/design of devices that you connect to the serial port. However, most pins have certain functions which they normally perform but this may vary with the operating system and the device driver configuration. Under Linux, one may modify the source code to make these signal lines behave differently (some people have).
A cable from a serial port always connects to another serial port. An external modem or other device that connects to the serial port has a serial port built into it. For modems, the cable is always straight thru: pin 2 goes to pin 2, etc. The modem is said to be DCE (Data Communications Equipment) and the computer is said to be DTE (Data Terminal Equipment). Thus for connecting DTE-to-DCE you use straight-thru cable. For connecting DTE-to-DTE you must use a null-modem cable (also called a crossover cable). There are many ways to wire such cable (see examples in Text-Terminal-HOWTO subsection: "Direct Cable Connection")
There are good reasons why it works this way. One reason is that the signals are unidirectional. If pin 2 sends a signal out of it (but is unable to receive any signal) then obviously you can't connect it to pin 2 of the same type of device. If you did, they would both send out signals on the same wire to each other but neither would be able to receive any signal. There are two ways to deal with this situation. One way is to have a two different types of equipment where pin 2 of the first type sends the signal to pin 2 of the second type (which receives the signal). That's the way it's done when you connect a PC (DTE) to a modem (DCE). There's a second way to do this without having two different types of equipment: Connect pin sending pin 2 to a receiving pin 3 on same type of equipment. That's the way it's done when you connect 2 PCs together or a PC to a terminal (DTE-to-DTE). The cable used for this is called a null-modem cable since it connects two PCs without use of a modem. A null-modem cable may also be called a cross-over cable since the wires between pins 2 and 3 cross over each other (if you draw them on a sheet of paper). The above example is for a 25 pin connector but for a 9-pin connector the pin numbers 2 and 3 are just the opposite.
The serial pin designations were originally intended for connecting a dumb terminal to a modem. The terminal was DTE (Data Terminal Equipment) and the modem was DCE (Data Communication Equipment). Today the PC is usually used as DTE instead of a terminal (but real terminals may still be used this way). The names of the pins are the same on both DTE and DCE. The words: "receive" and "transmit" are from the "point of view" of the PC (DTE). The transmit pin from the PC transmits to the "transmit" pin of the modem (but actually the modem is receiving the data from this pin so from the point of view of the modem it would be a receive pin).
The serial port was originally intended to be used for connecting DTE to DCE which makes cabling simple: just use a straight-thru cable. Thus when one connects a modem one seldom needs to worry about which pin is which. But people wanted to connect DTE to DTE (for example a computer to a terminal) and various ways were found to do this by fabricating various types of special null-modem cables. In this case what pin connects to what pin becomes significant.
This is "hardware" flow control. Flow control was previously
explained in the
Flow Control
subsection but the pins and voltage signals were not. Linux only
supports RTS/CTS flow control at present (but a special driver may
exist for a specific application which supports DTR/DSR flow control).
Only RTS/CTS flow control will be discussed since DTR/DSR flow control
works the same way. To get RTS/CTS flow control one needs to either
select hardware flow control in an application program or use the
command:
stty -F /dev/ttyS2 crtscts (or the like). This enables RTS/CTS
hardware flow control in the Linux device driver.
Then when a DTE (such as a PC) wants to stop the flow into it, it negates RTS. Negated "Request To Send" (-12 volts) means "request NOT to send to me" (stop sending). When the PC is ready for more bytes it asserts RTS (+12 volts) and the flow of bytes to it resumes. Flow control signals are always sent in a direction opposite to the flow of bytes that is being controlled. DCE equipment (modems) works the same way but sends the stop signal out the CTS pin. Thus it's RTS/CTS flow control using 2 lines.
On what pins is this stop signal received? That depends on whether we have a DCE-DTE connection or a DTE-DTE connection. For DCE-DTE it's a straight-thru connection so obviously the signal is received on a pin with the same name as the pin it's sent out from. It's RTS-->RTS (PC to modem) and CTS<--CTS (modem to PC). For DTE-to-DTE the connection is also easy to figure out. The RTS pin always sends and the CTS pin always receives. Assume that we connect two PCs (PC1 and PC2) together via their serial ports. Then it's RTS(PC1)-->CTS(PC2) and CTS(PC1)<--RTS(PC2). In other words RTS and CTS cross over. Such a cable (with other signals crossed over as well) is called a "null modem" cable. See Cabling Between Serial Ports
What is sometimes confusing is that there is the original use of RTS where it means about the opposite of the previous explanation above. This original meaning is: I Request To Send to you. This request was intended to be sent from a terminal (or computer) to a modem which, if it decided to grant the request, would send back an asserted CTS from its CTS pin to the CTS pin of the computer: You are Cleared To Send to me. Note that in contrast to the modern RTS/CTS bi-directional flow control, this only protects the flow in one direction: from the computer (or terminal) to the modem. This original use appears to be little used today on modern equipment (including modems).
Just like RTS and CTS, these pins are paired. For DTE-to-DTE connections they are likely to cross over. There are two ways to use these pins. One way is to use them as a substitute for RTS/CTS flow control. The DTR pin is just like the RTS pin while the DSR pin behaves like the CTS pin. Although Linux doesn't support DTR/DSR flow control, it can be obtained by connecting the RTS/CTS pins at the PC to the DSR/DTR pins at the device that uses DTR/DSR flow control. DTR flow control is the same as DTR/DSR flow control but it's only one-way and only uses the DTR pin at the device. Many text terminals and some printers use DTR/DSR (or just DTR) flow control. In the future, Linux may support DTR/DSR flow control. The software has already been written but it's not clear when (or if) it will incorporated into the serial driver.
The normal use of DTR and DSR (not for flow control) is as follows: A device asserting DTR says that its powered on and ready to operate. For a modem, the meaning of a DTR signal from the PC depends on how the modem is configured. Negating DTR is sometimes called "hanging up" but it doesn't always do this. One way to "hang up" (negate DTR) is to set the baud rate to 0 using the command "stty 0". Trying to do this from a "foreign" terminal may not work due to the two-interface problem. See Two interfaces at a terminal. For internal modem-serial_ports it worked OK with a port using minicom but didn't work if the port was using wvdial. Why?
If "stty -clocal" (or getty is used with the "local" flag negated) then a serial port can't open until DCD gets an assert (+12 volts) signal.
At the RS-232 serial port, voltages are bipolar (positive or negative with respect to ground) and should be about 12 volts in magnitude (some are 5 or 10 volts). For the transmit and receive pins +12 volts is a 0-bit (sometimes called "space") and -12 volts is a 1-bit (sometimes called "mark"). This is known as inverted logic since normally a 0-bit is both false and negative while a one is normally both true and positive. Although the receive and transmit pins are inverted logic, other pins (modem control lines) are normal logic with a positive voltage being true (or "on" or "asserted") and a negative voltage being false (or "off" or "negated"). Zero voltage has no meaning (except it usually means that the unit is powered off).
A range of voltages is allowed. The specs say the magnitude of a transmitted signal should be between 5 and 15 volts but must never exceed 25 V. Any voltage received under 3 V is undefined (but some devices will accept a lower voltage as valid). One sometimes sees erroneous claims that the voltage is commonly 5 volts (or even 3 volts) but it's usually 11-12 volts. If you are using a EIA-422 (RS-422) port on a Mac computer as an RS-232 (requires a special cable) or EIA-423 (RS-423) then the voltage will actually be only 5 V. The discussion here assumes 12 V.
Note that normal computer logic normally is just a few volts (5 volts was once the standard) so that if you try to use test equipment designed for testing 3-5 volt computer logic (TTL) on the 12 volts of a serial port, it may damage the test equipment.
The transmit pin (TxD) is held at -12 V (mark) at idle when nothing is being sent. To start a byte it jumps to +12 V (space) for the start bit and remains at +12 V for the duration (period) of the start bit. Next comes the low-order bit of the data byte. If it's a 0-bit nothing changes and the line remains at +12 V for another bit-period. If it's a 1-bit the voltage jumps from +12 to -12 V. After that comes the next bit (-12 V if a 1 or +12 V if a 0), etc., etc. After the last data bit, a parity bit may be sent and then a -12 V (mark) stop bit. Then the line remains at -12 V (idle) until the next start bit. Note that there is no return to 0 volts and thus there is no simple way (except by a synchronizing signal) to tell where one bit ends and the next one begins for the case where 2 consecutive bits are the same polarity (both zero or both one).
A 2nd stop bit would also be -12 V, just the same as the first stop bit. Since there is no signal to mark the boundaries between these bits, the only effect of the 2nd stop bit is that the line must remain at -12 V idle twice as long. The receiver has no way of detecting the difference between a 2nd stop bit and a longer idle time between bytes. Thus communications works OK if one end uses one stop bit and the other end uses 2 stop bits, but using only one stop bit is obviously faster. In rare cases 1 1/2 stop bits are used. This means that the line is kept at -12 V for 1 1/2 time periods (like a stop bit 50% wider than normal).
Characters are normally transmitted with either 7 or 8 bits of data. An additional parity bit may (or may not) be appended to this resulting in a byte length of 7, 8 or 9 bits. Some terminal emulators and older terminals do not allow 9 bits. Some prohibit 9 bits if 2 stop bits are used (since this would make the total number of bits too large: 12 bits total after adding the start bit).
The parity may be set to odd, even or none (mark and space parity may be options on some terminals or other serial devices). With odd parity, the parity bit is selected so that the number of 1-bits in a byte, including the parity bit, is odd. If a such a byte gets corrupted by a bit being flipped, the result is an illegal byte of even parity. This error will be detected and if it's an incoming byte to the terminal an error-character symbol will appear on the screen. Even parity works in a similar manner with all legal bytes (including the parity bit) having an even number of 1-bits. During set-up, the number of bits per character usually means only the number of data bits per byte (7 for true ASCII and 8 for various ISO character sets).
A "mark" is a 1-bit (or logic 1) and a "space" is a 0-bit (or logic
0). For mark parity, the parity bit is always a one-bit. For space
parity it's always a zero-bit. Mark or space parity (also known as
"sticky parity") only wastes bandwidth and should be avoided if
feasible. The stty
command can't set sticky parity but it's
supported by serial hardware and can be dealt with by programming in
C. "No parity" means that no parity bit is added. For terminals
that don't permit 9 bit bytes, "no parity" must be selected when using
8 bit character sets since there is no room for a parity bit.
In serial transmission of bytes via RS-232 ports, the low-order bit is always sent first (the bit-order). Serial ports on PC's use asynchronous communication where there is a start bit and a stop bit to mark the beginning and end of a byte. This is called framing and the framed byte is sometimes called a frame. As a result a total of 9, 10, or 11 bits are sent per byte with 10 being the most common. 8-N-1 means 8 data bits, No parity, 1 stop bit. This adds up to 10 bits total when one counts the start bit. One stop bit is almost universally used. At 110 bits/sec (and sometimes at 300 bits/sec) 2 stop bits were once used but today the 2nd stop bit is used only in very unusual situations (or by mistake since it still works OK that way but wastes bandwidth).
Don't confuse this type of framing with the framing used for a packet of bytes on a network. The serial port just frames every byte. For a network, many bytes are framed into a packet (sometimes called a frame). For a network frame, instead of a start bit, there is a sequence of bytes called a header. On a network that uses serial ports (with modems), a report of a frame error usually refers to a multi-byte frame and not the serial port frame of a single byte.
The RS-232 serial port as implemented on PC is asynchronous which in effect means that there is no "clock" signal sent with "ticks" to mark when each bit is sent.. There are only two states of the transmit (or receive) wire: mark (-12 V) or space (+12 V). There is no state of 0 V. Thus a sequence of 1-bits is transmitted by just a steady -12 V with no markers of any kind between bits. For the receiver to detect individual bits it must always have a clock signal which is in synchronization with the transmitter clock. Such a clock would generate a "tick" in synchronization with each transmitted (or received) bit.
For asynchronous transmission, synchronization is achieved by framing each byte with a start bit and a stop bit (done by hardware). The receiver listens on the negative line for a positive start bit and when it detects one it starts its clock ticking. It uses this clock tick to time the reading of the next 7, 8 or 9 bits. (It actually is a little more complex than this since several samples of a bit are normally taken and this requires additional timing ticks.) Then the stop bit is read, the clock stops and the receiver waits for the next start bit. Thus async is actually synchronized during the reception of a single byte but there is no synchronization between one byte and the next byte.
A number of EIA (or RS) standards have been established for higher speeds and longer distances using twisted-pair (balanced) technology. Balanced transmission make possible higher speeds, and can be a thousand times faster than unbalanced RS-232. For a given speed, the distance (maximum cable length) may be many times longer with twisted pair. But PC's, prior to about 2004??, kept being made with the quasi-obsolete RS-232 since it works OK with modems and mice since the cable length is short.
High speed serial ports (over 460.8 kbps) will often support both RS-232 and EIA-485/EIA-422 (RS-485/RS-422) modes . (Note that for non-RS-232 I've used the "EIA" designation instead of the more commonly used "RS" but they both mean the same thing.) At such high speeds RS-232 is not of much use (except for a very short cable).
EIA-423 is just like the unbalanced RS-232 except that the voltage is only 5 volts. Since this falls within RS-232 specs it can be connected to a RS-232 port. Its specs call for somewhat higher speeds than the RS-232 (but this may be of little help on a long run where it's the unbalance that causes interference). Since EIA-423 is not much of an improvement over RS-232, it is seldom used except on old Mac computers.
EIA-422 is twisted pair (known as "balanced" or "differential) and is (per specs) exactly 100 times as fast as EIA-423 (which in turn is somewhat faster than RS-232). Apple's Mac computer used it prior to mid-1998 with its RS-232/EIA-422 port. The Mac used a small round "mini-DIN-8" connector and named these serial ports as "modem port", "printer port", and/or "GeoPort".
Mac also provided conventional RS-232 but at only at 5 volts (which is still legal RS-232). To make it work like at RS-232 one must use a special cable which (signal) grounds RxD+ (one side of a balanced pair) and use RxD- as the receive pin. While TxD- is used as the transmit pin, for some reason TxD+ should not be grounded. See Macintosh Communications FAQ. However, due to the fact that Macs (and upgrades for them) cost more than PC's, they are not widely as host computers for Linux.
This is like EIA-422 (balanced = differential). It is half-duplex. It's not just point-to-point but is like ethernet or the USB since all devices (nodes) on it share the same "bus". It may be used for a multidrop LAN (up to 32 nodes or more). Unfortunately, Linux currently doesn't support this and you can only use it under Linux only for point-to-point where it behaves like RS-232. So read further only if you are curious about how its features would work if only Linux supported them.
Since many nodes share the same twisted pair, there's a need to use the electrical tri-state mode. Thus, besides the 0 and 1 binary states, there is also an open circuit state to permit other nodes to use the twisted pair line. Instead of a transmitter keeping a 1-state voltage on the line during line idle, the line is open circuited and all nodes just listen (receive mode).
The most common architecture is master/slave. The master polls the slaves to see if they have anything to send. A slave can only transmit just after it's been polled. But EIA-485 is just an electrical specification and doesn't specify any protocol for the master/slave interaction. In fact, it doesn't even specify that there must be a master and slaves. So various protocols have been used. Based on a discussion of 485 on the linux-serial mailing list in March 2003, it seems likely that none of these master/slave protocols are currently supported by Linux.
There is an alternative implementation where two pair of wires are used for sending data. One pair is only for the Master to send to the Slaves. Since no one transmits on this line except the master, there is no need for it to be tri-state. Thus the Master may just be RS-232 but the slaves must still be EIA-485. See http://www.hw.cz/english/docs/rs485/rs485.html for more details.
EIA-530-A (balanced but can also be used unbalanced) at 2Mbits/s (balanced) was intended to be a replacement for RS-232 but few have been installed. It uses the same 25-pin connector as RS-232.
The High Speed Serial Interface ( HSSI = EIA-612/613) uses a 50-pin connector and goes up to about 50 Mbits/s but the distance is limited to only several meters. For Linux there are PCI cards supporting HSSI. The companies that sell the cards often provide (or point you to) a Linux driver. A howto or the like is needed for this topic.
The Universal Serial Bus (USB) is being built into PCI chips. Newer PC's have them. It was originally 12 Mbps but is now 480 Mbps over a twisted pair with a 4-pin connector (2 wires are power supply). It also is limited to short distances of at most 5 meters (depends on configuration). Linux supports the bus, although not all devices that can plug into the bus are supported.
It is synchronous and transmits in special packets like a network. Just like a network, it can have several devices physically attached to it, including serial ports. Each device on it gets a time-slice of exclusive use for a short time. A device can also be guaranteed the use of the bus at fixed intervals. One device can monopolize it if no other device wants to use it. It's not simple to describe in detail.
For serial ports on the USB bus, there are numerous configuration options to use when compiling the kernel. They all start with: CONFIG_USB_SERIAL. Each one is usually for a certain brand/model of serial port, although generic is also an option. See the Configuration Help file in the kernel documentation.
For documentation, see the USB directory in /usr/share/doc/kernel ... and look at the file: usb-serial.txt. The modules that support usb serial devices are found in the modules tree: kernel/drivers/usb/serial. It would be nice to have a HOWTO on the USB. See also http://www.linux-usb.org and/or http://www.qbik.ch/usb/.
Firewire (IEEE 1394) is something like the USB only faster (800 Mbps is planned). The protocol on the bus is claimed to be more efficient than USB's. It uses two twisted pair for data plus two power conductors (6 conductors in all). A variants uses only 4 conductors. You may compile firewire support into the Linux kernel. Like USB, it's also limited to short distances.
Sound cards often have a 15-pin game port connector used for MIDI. They are for connecting a musical keyboard to a PC so that you can create musical recordings. You could also connect a MIDI sound system. The MIDI standard uses 31250 baud (1M/32) which is not available on an ordinary serial port. Some MIDI devices are designed so that they can be connected directly to an ordinary serial port.
Besides the 15-pin connector, a 5-pin DIN connector is also a MIDI standard but the flow of sound is only one way thru it so for bidirectional sound you need 2 of them. Breakout cables often have a 15-pin connector on one end and 2 or more 5-pin connectors on the other end. The /dev/midi00 is for MIDI.
Beside the asynchronous RS-232 (and others) there are a number of synchronous serial port standards. In fact RS-232 includes synchronous specifications but they aren't normally implemented for serial ports on PC's. But first we'll explain what a synchronous means.
Asynchronous (async) means "not synchronous". In practice, an async signal is what the async serial port sends and receives which is a stream of bytes with each byte framed by a start and stop bit. Synchronous (sync) is most everything else. But this doesn't explain the basic concepts.
In theory, synchronous means that bytes are sent out at a constant rate one after another in step with a clock signal tick. There is often a separate wire or channel for sending the clock signal. The clock signal might also be embedded in the transmitted bytes. Asynchronous bytes may be sent out erratically with various time intervals between bytes (like someone typing characters at a keyboard).
When a file is being sent thru the async serial port, the flow of bytes will likely be at the speed of the port (say 115.2k) which is a constant rate. This flow may frequently start and stop due to flow control. Is this sync or async? Ignoring the flow control stops, it might seem like sync since it's a steady flow. But it's not because there is no clock signal and the bytes could have been sent erratically since they are framed by start/stop bits.
Another case is where data bytes (without any start-stop bits) are put into packets with possible erratic spacing between one packet and the next. This is called sync since the bytes within each packet are transmitted synchronously.
Did you ever wonder what all the unused pins are for on a 25-pin connector for the serial port? Most of them are for use in synchronous communication which is seldom implemented in chips for PC's. There are pins for sync timing signals as well as for a sync reverse channel. The RS-232 spec provides for both sync and async but PC's use a UART (Universal Asynchronous Receiver/Transmitter) chip such as a 16450, 16550A, or 16650 and can't deal with sync. For sync one needs a USRT chip or the equivalent where the "S" stands for Synchronous. A USART chip supports both synchronous and asynchronous. Since sync is a niche market, a sync serial port is likely to be quite expensive.
SCC stands for "Serial Communication Controller" or "Serial Controller Chip". It's likely old terminology and since it doesn't say "sync" or "async" it might support both.
Besides the sync part of the RS-232, there are various other EIA synchronous standards. For RS-232, 3 pins of the connector are reserved for clock (or timing) signals. Sometimes it's a modem's task to generate some timing signals making it impossible to use synchronous communications without a synchronous modem (or without a device called a "synchronous modem eliminator" which provides the timing signals).
Although few serial ports are sync, synchronous communication does often take place over telephone lines using modems which use V.42 error correction. This strips off the start/stop bits and puts the data bytes in packets resulting in synchronous operation over the phone line.
Notes re books:
If it's not available in your Linux distribution try:
Serial Software for Linux software for the serial ports
including getty and port monitors.
Serial Communications for communication programs.
irqtune
will give serial port interrupts higher
priority to improve performance. Using hdparm
for hard-disk tuning
may help some more.
modemstat
and statserial
show the current state of
various modem control lines. See
Serial Monitoring/Diagnostics
setserial
and stty
The Linux serial mailing list. To join, send email to
[email protected]
, with ``subscribe
linux-serial
'' in the message body. If you send ``help
'' in
the message body, you get a help message. The server also serves
many other Linux lists. Send the ``lists
'' command for a list
of mailing lists.
http://www.cyclades.com
.
Many 486 PCs (old) and all Pentiums (or the like) should have modern 16550As (usually called just 16550's) with FIFOs. If you have something really old (pre 1990), the chip may unplug so that you may be able to upgrade by finding a plug-in 16550A chip and replacing your old existing 16450 UART. If the functionality has been built into another type of chip, you are out of luck. If the UART is socketed, then upgrading would be easy if you could find a replacement. The new and old are pin-to-pin compatible. It may be more feasible to just buy a new serial card on the Internet (few retail stores stock them as of 2000) or find a used one.
Modern kernels should not allow the opening of ports with the same IO address. But one may probe for ports even though they are not open. If two ports have the same IO address then old fashioned probing by sending commands to the address will erroneously indicate only one port. But modem device detection at boot-time should discover both ports and report the conflict. In olden days, all sorts of errors were reported/observed for devices illegally attempting to use the same IO address. See Probing.
In the past, to get a certain serial port supported, one might need to modify the C source code, perhaps by adding a #define to it. Today, the use of parameters for modules or the kernel, or the use of configuration options should handle all cases (except possible for antique hardware ??).
For a modem to transmit at nearly 56k requires that it be a special digital modem and have a digital connection to a digital phone line (such as a T1 line). Modems used with serial cards (the modems may either be on the serial card or on another card) normally have no such digital connection so they can't be used at the 56k speed, and thus are obsolete unless one doesn't need to send at 56k. In other words they are obsolete for ISP servers but might be OK for small business or home use.
A partial exception to the above are modem banks that connect to multiport serial cards where the modem bank can access multiplexed digital phone lines. Thus one could use a multiport serial card with a few 56k digital modems for sending at 56k. For both analog and digital modems there is one modem on each serial port so there needs to be an external cable (modem bank to multiport) for each modem. This can lead to a large number of cables. So it's less clutter (and cheaper) to use internal modems without a multiport card. This makes even this "exception" obsolete for high volume work. It's somewhat analogous to the lower cost of an internal modem for a desktop PC as compared to the higher cost (and more cabling) for an external modem. See Modem-HOWTO: Modem Pools, Digital Modems.
The abandoned device-filesystem (devfs) has the /dev directory with subdirectories. As of late 2001, there were problems with lockfiles. For example, the lockfile mechanism considered dev/usb/tts/0 and /dev/tts/0 to be the same device with name "0". Ditto for all other devices that had the same "leaf" name. Also, if some applications use the old name for a device and other applications use the devfs name for the same device, then the lockfiles will have different names. But the serial driver should know they are the same.
Kernel 2.4 introduced the now obsolete optional "device file system" (devfs) with a whole new set of names for everything. Some people used it but the majority probably didn't. But in 2003-4, it was claimed that devfs had unsolvable problems and starting with kernel 2.6.12 it was replaced with "udev" (kernels prior to 2.6.12 also could use udev but with some problems). Although udev doesn't provide all the functionality of devfs, it does handle hot plugging. Also, the use of udev isn't required to run Linux so some people don't use it. But many distributions install it by default.
Devfs was a good idea and was claimed to be more efficient than udev. But unfortunately, the author of devfs didn't maintain it for long and it allegedly became not too well maintained. So for better or worse we now have udev instead although the debate of devfs vs. udev still continues. For a detailed description of devfs see: http://www.atnf.csiro.au/~rgooch/linux/docs/devfs.html Also see the kernel documentation tree: filesystems/devfs.
The names of devices for the devfs can be used in udev, but usually are not and may not be simple to activate. Here's the devfs names for serial devices: ttyS1 becomes tts/1, ttyUSB1 becomes /usb/tts/1, and ttyACM1 is /usb/acm/1. Note that the number 1 above is just an example. It could be replaced by 0, 2, 3, 4, etc. Some more examples of udev names: ttyS2 becomes tts/2 (Serial port), tty3 becomes vc/3 (Virtual Console), ptyp1 becomes pty/m1 (PTY master), ttyp2 becomes pty/s2 (PTY slave). "tts" looks like a directory which contains devices "files": 0, 1, 2, etc. All of these new names were put in the /dev directory although optionally one may put them elsewhere.
For devfs, device names in the /dev directory are created automatically by the corresponding driver. Thus, if serial support comes from a module and that module isn't loaded yet, there will not be any serial devices in the /dev directory. This can be confusing: you physically have serial ports but don't see them in the /dev directory. However, if a device name is requested (attempt to open it) by a communication program and the serial module isn't loaded, the kernel is supposed to try to find a driver for it and create a name for it in the /dev directory.
This works OK if it finds a driver. But suppose there is no driver found for it. For example, if you try to use "setserial" to configure a port that the driver failed to detect, it claims there is no such port. How does one create a devfs port in this case?
For multiport devices for example, /dev/ttyF9 becomes /dev/ttf/9, or in a later version /dev/tts/F9. Substitute for F (or f) whatever letter(s) your multiport board uses for this purpose. A multiport driver is supposed to create a devfs name similar to the above and put it into the /dev directory
END OF Serial-HOWTO