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I've encoutered these to instructions IN & OUT while reading "Understanding Linux Kernel" book. I've looked up reference manual.

5.1.9 I/O Instructions

These instructions move data between the processor’s I/O ports and a register or memory.

IN    Read from a port
OUT   Write to a port
INS/INSB  Input string from port/Input byte string from port 
INS/INSW  Input string from port/Input word string from port 
INS/INSD  Input string from port/Input doubleword string from port
OUTS/OUTSB    Output string to port/Output byte string to port 
OUTS/OUTSW    Output string to port/Output word string to port 
OUTS/OUTSD    Output string to port/Output doubleword string to port

I didn't get few things:

  1. "processor’s I/O ports". What are they? Why would we want to read & write "strings" to & from these ports?
  2. I never encoutered a scenerio where I need to use these instructions. When would I be needing these?
  3. Give some practical examples.
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6 Answers 6

up vote 25 down vote accepted

You know how memory addressing works? The CPU puts the address of a byte of memory on the bus, then raises the READ signal, and some RAM chip hopefully returns the contents of memory at that address.

Both RAM and IO devices are connected to the same address, data and control lines. Every IO device is configured to respond to a certain combination of address lines (that's the IO address). There's a signal line called M/#IO. When you use the IN or OUT instructions, the M/#IO is not asserted, so both memory and IO devices know that the CPU talks to IO devices. For the rest of instructions, M/#IO is asserted so CPU talks to the RAM and IO devices do not interfere with the communication.

Under certain conditions the IO devices can drive the data lines and the RAM can read them at the same time. And vice versa. It's called DMA.

Traditionally, serial and printer ports, as well as keyboard, mouse, temperature sensors and so forth were I/O devices. Disks were sort of in between; data transfers would be initiated by I/O commands but the disk controller would usually direct-deposit its data in system memory.

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Start with something like this:


You are learning instructions for a very old technology chip/architecture. Back when everything but the processor core was off chip. See the address lines and the data lines and there is a RD read line and WR write line and IO/M line?

There were two types of instructions memory based and I/O based because there were addressable spaces, easily decoded by the IO/M IO or Memory.

Remember you had 74LSxx glue logic, lots of wires and lots of chips to connect a memory to the processor. And memory was just that memory, big expensive chips. If you had a peripheral that needed do do anything useful you also had control registers, the memory might be pixel data, but somewhere you needed to set the horizontal and vertical scan clocks limits, these might be individual 74LSxx latches, NOT memories, having I/O mapped I/O saved on both glue logic and just made a lot of sense from a programmer perspective it also avoided changing your segment registers to aim your 64K memory window around, etc. Memory address space was a sacred resource, esp when you wanted to limit your address decoding to a few bits because every few bits cost you a number of chips and wires.

Like big and little endian memory mapped I/O vs I/O mapped I/O was a religious war. And some of the responses you are going to see to your question are going to reflect the strong opinions that are still around today in the folks that lived it. The reality is that every chip on the market today has multiple busess for various things, you dont hang your real time clock off of the ddr memory bus with an address decoder. Some still even have completely separate instruction and data busses. In a sense Intel won the war for the concept of separate address spaces for different classes of things even though the term I/O port is evil and bad and should not be uttered for say 20-30 more years. You need folks my age that lived it to be retired or gone before the war is truly over. Even the term memory mapped I/O is a thing of the past.

That is really all it ever was, a single address decode bit on the outside of the intel chip that was controlled by the use of specific instructions. Use one set of instructions the bit was on use one set of instructions the bit was off. Want to see something interesting go look at the instruction set for the xmos xcore processors they have lots of things that are instructions instead of memory mapped registers, it takes this I/O mapped I/O thing to a whole new level.

Where it was used is as I described above, you would put things that made sense and you could afford to burn memory address space for like video pixels, network packet memory (maybe), sound card memory (well not that either but you could have), etc. And the control registers, address space relative to the data was very small, maybe only a few registers, were decoded and used in I/O space. the obvious ones are/were serial ports and parallel ports who had little if any storage, you might have had a small fifo on the serial port if anything.

Because address space was scarce it was not uncommon and is still seen today to have memory hidden behind two registers an address register and a data register, this memory is only available through these two registers, it is not memory mapped. so you write the offset into this hidden memory in the address register and you read or write the data register to access the content of the memory. Now because intel had the rep instruction and you could combine it with insb/w outsb/w the hardware decoder would (if you had nice/friendly hardware folks working with you) autoincrement the address whenever you did an I/O cycle. So you could write the starting address in the address register and do a rep outsw and without burning fetch and decode clock cycles in the processor and on the memory bus you could move data pretty fast into or out of the peripheral. This kind of thing is now considered a design flaw thanks to the modern super scalar processors with fetches based on branch prediction, your hardware can experience reads at any time that have nothing to do with executing code, as a result you should NEVER auto increment an address or clear bits in a status register or modify anything as a result of a read to an address.

The protection mechanisms built into the 386 and on to the present actually make it very easy to access I/O from user space. Depending on what you do for a living, what your company produces, etc. You can most definitely use the in and out family of instructions from user space (application programs in windows and linux, etc) or kernel/driver space, it is your choice. You can also do fun things like take advantage of the virtual machine and use I/O instructions to talk to drivers, but that would probably piss off folks in both the windows and linux worlds, that driver/app wouldnt make it very far. The other posters are correct in that you are likely never going to need to use these instructions unless you are writing drivers, and you are likely never going to write drivers for devices using I/O mapped I/O because you know...the drivers for those legacy devices have already been written. Modern designs most definitely have I/O but it is all memory mapped (from a programmers perspective) and uses memory instructions not I/O instructions. Now the others side if this is DOS is definitely not dead, depending on where you you may be building voting machines or gas pumps or cash registers or a long list of DOS based equipment. In fact if you work somewhere that builds PCs or PC based peripherals or motherboards, DOS based tools are still widely used for testing and for distributing BIOS updates and other similar things. I still run into situations where I have to take code from a current dos test program to write a linux driver. Just like not everyone that can throw or catch a football plays in the NFL, percentage wise very few do software work that involves this kind of stuff. So it is still safe to say these instructions you found are likely not going to be more to you than a history lesson.

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+1, thanks for a history lesson :) –  Nikolai N Fetissov Jul 11 '10 at 15:41
But if you tell the young people that nowadays, they'll never believe you... :-) –  Bob Jarvis Nov 19 '10 at 12:24

This are used for communicating with I/O resources (read devices) - parallel/serial ports, etc. It's Operating System business, not user applications. You will find this used (not directly, but through the macro/function wrappers) inside the OS device drivers. See mighty wikipedia.


Yes, back in DOS days you would talk directly to ports from your app. Not anymore.

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Why should a user application not access ports? And what is a "user application"? –  cdonner Jul 9 '10 at 19:31
A user-mode application is the kind that isn't allowed to screw around with I/O ports. –  John Saunders Jul 9 '10 at 19:35
These days, if your application is running under Windows, Linux or Mac OS X (that covers most of the popular OSes) then it no longer gets access to the I/O ports. I/O is done solely by drivers, usually running at kernel level in the OS. User-space IO is the rare exception. –  Carl Smotricz Jul 9 '10 at 19:36
Using the parallel port to talk to hardware is a great example of doing this in user space. As an electronics experimenter is was a great way to interface with other devices. –  Jay Jul 9 '10 at 19:41
@Jay yes, but that doesn't work any more. I wrote a Delphi program to communicate with a home-built device via the printer port back in 2001; but to get it to work, I had to link in a special driver that let me get at the port through the OS. –  Carl Smotricz Jul 9 '10 at 19:52

If you're not writing an operating system, then you will never use these instructions.

x86-based machines have two independent address spaces - the memory address space you're familiar with, and then the I/O address space. I/O port addresses are only 16 bits wide, and reference low-level registers and other low-level widgets that are part of an I/O device - something like a serial or parallel port, disk controller, etc.

There are no practical examples because these are only used by device drivers and operating systems.

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If you're writing drivers they can certainly be used. –  Jay Jul 9 '10 at 19:38
@Downvoter: so why don't you tell people what the problem is? –  John Saunders Jul 11 '10 at 4:49
@Downvoter: BTW, I answered before he said anything about Linux. –  John Saunders Jul 11 '10 at 5:05
if you are writing a non-test linux device driver, you should not use those instructions directly if possible, but instead c functions furnished by the linux kernel such as insb or outsb (clearly influenced by the x86 architecture) to make your code more architecture portable. Those functions however are implemented with assembly instructions for each architecture. –  Ciro Santilli 六四事件 法轮功 纳米比亚 威视 Jun 11 '13 at 12:54

At the hardware level, most microprocessors have little or no I/O capability built in. A few processors have one or more pins that may be turned on and off using special instructions, and/or one or more pins that may be tested using special branch instructions, but such features are rare. Instead, I/O is usually handled by wiring the system so that accesses to a range of memory addresses will trigger some effect, or by including "in" and "out" instructions which behave like memory load/store operations except that a special signal is output saying "This is an I/O operation instead of a memory operation." In the days of 16-bit processors, there used to be some real advantages to having specialized in/out instructions. Nowadays such advantages are largely moot since one could simply allocate a big chunk of one's address space to I/O and still have plenty left for memory.

Since a program could wreak considerable havoc on a system by inappropriately performing I/O instructions (e.g. such instructions could perform arbitrary disk accesses), all modern operating systems forbid the use of such instructions in user-level code. Some systems may allow such instructions to be virtualized; if user code tries to write to I/O ports 0x3D4 and 0x3D5, for example, an operating system might interpret that as an attempt to set some video-control control registers to move the blinking cursor. Each time the user program performed the OUT instruction, the operating system would take over, see what the user program was trying to do, and act appropriately.

In the vast majority of cases, even if the operating system would translate an IN or OUT instruction into something suitable, it would be more efficient to request the appropriate action from the operating system directly.

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CPU connected to some external controllers through io ports. on old x86 pc i work with floppy drive using I/O ports. if you know what commands accept device controller you can program it through it's ports.

In modern world you will never use ports instructions. Exception if you are (or will be) driver developer.

there is more detailed information about I/O ports http://webster.cs.ucr.edu/AoA/DOS/ch03/CH03-6.html#HEADING6-1

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