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I am very new to C, it's my second high-level programming language after Java. I have gotten most of the basics down, but for whatever reason I am unable to write a single character to screen memory.

This program is compiled using Turbo C for DOS on an Am486-DX4-100 running at 120mhz. The graphics card is a very standard VLB Diamond Multimedia Stealth SE using a Trio32 chip.

For an OS I am running PC-DOS 2000 with an ISO codepage loaded. I am running in standard MDA/CGA/EGA/VGA style 80 column text mode with colour.

Here is the program as I have it written:

#include <stdio.h>

int main(void) {
    unsigned short int *Video = (unsigned short int *)0xB8000;
    *Video = 0x0402;
    getchar();
    return 0;
}

As I stated, I am very new to C, so I apologize if my error seems obvious, I was unable to find a solid source on how to do this that I could understand.

To my knowledge, in real mode on the x86 platform, the screen memory for text mode starts at 0xB8000. Each character is stored in two bytes, one for the character, and one for the background/foreground. The idea is to write the value 0x0402 (which should be a red smiling face) to 0xB8000. This should put it at the top left of the screen.

I have taken into account the possibility that the screen may be scrolling, and thus immediately removing my character upon execution in two ways. To resolve this issue, I have tried:

  • Repeatedly write this value using a loop
  • Write it a bit further down.

I can read and print the value I wrote to memory, so it's obviously still somewhere in memory, but for whatever reason I do not get anything onscreen. I'm obviously doing something wrong, however I do not know what could be the issue. If any other details are needed, please ask. Thank you for any possible help you can give.

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  • 13
    How does your C implementation map integers to pointers? Do you need to use some kind of far pointer keyword? Or does it run in big/huge unreal mode with 32-bit pointers?. If a C pointer is only 16 bits wide, then it's just an offset within a segment (ds by default most of the time), and converting 0xB8000 to a pointer will truncate to 16 bits and give you an offset of 0x8000 relative to ds. TL:DR real mode segmentation doesn't map cleanly to C pointers. Do NOT expect this to be easy, especially if you don't know both C and x86-16 asm. Dec 1, 2017 at 7:40
  • 1
    0xB8000 is 20 bits wide. (Each hex digit encodes four bits, and there are five of them.) The width of an unsigned short int is only 16 bits. The width of a near pointer in most bcc memory models (I think other than huge, but it’s been decades.) is also 16 bits. So, you caused an overflow and wrapped around. I suspect you ended up writing to address DS:8000 instead.
    – Davislor
    Dec 1, 2017 at 10:08
  • 9
    Also, is there a prof in India who assigns compilers from the mid-’90s running on a 16-bit OS to beginning CS students, or something? Is there some reason for that? Modern tools like Linux, clang and gcc are completely free.
    – Davislor
    Dec 1, 2017 at 10:12
  • 9
    You are welcome to check out retrocomputing.stackexchange.com
    – user11153
    Dec 1, 2017 at 14:00
  • 2
    @Davislor: Knowing a bit of asm is also really handy to work backward from bug symptoms to what might have caused it in C, so the understanding how stuff works part shouldn't be underestimated. Fun example of this: unaligned uint16_t* can segfault on x86, but x86 can do unaligned loads? Auto-vectorization breaks this "happens to work" code in an interesting way. Dec 2, 2017 at 4:24

3 Answers 3

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In real mode to address the first full 1MiB of memory a mechanism called 20-bit segment:offset addressing is used. 0xb8000 is a physical memory address. You need to use something called a far pointer that allows you to address memory with real mode segmentation. The different types of pointers are described in this Stackoverflow Answer

0xb8000 can be represented as a segment of 0xb800 and an offset of 0x0000. The calculation to get physical address is segment*16+offset. 0xb800*16+0x0000=0xb8000. With this in mind you can include dos.h and use the MK_FP C macro to initialize a far pointer to such an address given segment and offset.

From the documentation MK_FP is defined as:

MK_FP() Make a Far Pointer

#include   <dos.h>

void       far *MK_FP(seg,off);
unsigned   seg;                         Segment
unsigned   off;                         Offset

MK_FP() is a macro that makes a far pointer from its component segment 'seg' and offset 'off' parts.

Returns: A far pointer.

Your code could be written like this:

#include <stdio.h>
#include <dos.h>
int main(void) {
    unsigned short int far *Video = (unsigned short int far *)MK_FP(0xB800,0x0000);
    *Video = 0x0402;
    getchar();
    return 0;
}
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  • This works and through all these explanations I think I've understood the issue. It's nearly 3 AM where I live, and I will need time to understand this proper. Thanks for the help.
    – Ampera
    Dec 1, 2017 at 7:48
  • Does casting from a 32-bit integer to a far * not work? Like Stacker's answer which uses char far *Video = (char far *)0xb8000000; Dec 1, 2017 at 7:51
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    @Ampera There is a link to Starman's page in my answer regarding segment:offset addressing in general. You need a good foundation on how the segment:offset addressing works in 16-bit real mode.When you are actually awake I suggest reading over the Starman link . There is further information in another SO answer about the types of pointers that 16-bit Turbo-C supports Dec 1, 2017 at 7:51
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    @PeterCordes It is a trivial copy that is done (far<=>uint32_t). The uint32_t (and the far pointer) doesn't represent a linear address. It is a 32-bit value where the high 16 bits are the segment and lower 16-bits are the offset. No conversion is done. You can do pointer arithmetic on such a casted pointer as long as you don't carry into the upper 16-bits. Dec 1, 2017 at 8:06
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    @PeterCordes : turboCand many early compilers didn't have a stdint.h. There was a 3rd party header you could use. That being said the size of a pointer was dependent on memory model (Tiny, Small, Medium were 16-bit pointers). You couldn't just arbitrarily cast a far or huge pointer (which are always 32-bit) to a 16-bit pointer with those models. In compact and large model the default pointer type is far (and uintptr_t is size 4). Huge is size 4. You could cast a huge pointer to far but not vice versa unless the far pointer was normalized first. Dec 1, 2017 at 23:05
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The memory segment adress depends on the video mode used:

0xA0000 for EGA/VGA graphics modes (64 KB)
0xB0000 for monochrome text mode (32 KB)
0xB8000 for color text mode and CGA-compatible graphics modes (32 KB)

To directly access vram you need a 32 bit-pointer to hold segement and offset address otherwise you would mess up your heap. This usually leads to undefined behaviour.

char far *Video = (char far *)0xb8000000;

See also: What are near, far and huge pointers?

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  • This would be a better answer if you explained that 0xb8000000 is the seg:off representation of the OP's 0xB8000 linear address. i.e. the upper 16 bits are 0xB8000 >> 4, and the lower 16 bits are all zero (0 & 15). And your first sentence should say "linear address" not "segment address", because those aren't segment-register values, they're what you need to use segmentation to access. (Also, a VGAtext base pointer should maybe be declared as short or a struct, not char). Dec 2, 2017 at 3:07
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As @stacker pointed-out, in the 16-bit environment you need to assign the pointer carefully. AFAIK you need to put FAR keyword (my gosh, what a nostalgia).

Also make sure you don't compile in so-called "Huge" memory model. It's incompatible with far addressing, because every 32-bit pointer is automatically "normalized" to 20 bits. Try selecting "Large" memory model.

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    Wouldn't Huge be exactly what the OP needs to make the code in the question work unmodified? So all pointers can be treated as linear addresses into real-mode physical memory, and have the compiler "work around" segmentation for you by reloading segment registers whenever needed. (oops NVM, that's not how it works. They aren't linear addresses. stackoverflow.com/questions/47588486/…) Dec 1, 2017 at 8:08
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    Yep, I found the reference: "Under DOS/4GW, the first megabyte of physical memory is mapped as a shared linear address space. This allows your application to access video RAM using a near pointer set to the screen's linear address.". But again, then this is no longer x86 16bit programming.
    – jjmontes
    Dec 1, 2017 at 16:00
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    @MichaelKjörling: Twentieth-century compiler writers recognized the value in having a family of languages which were tweaked for various platforms, but shared a common base. I think the reason the authors of the C89 Standard only defined two kinds of C implementations (hosted and freestanding) was that not that they thought two was enough, but rather that they didn't think themselves capable of defining everything that would be needed to make implementations suitable for all of the purposes to which C was being put. The 8086 clearly had a natural way of reading a 32-bit value as pointer...
    – supercat
    Dec 1, 2017 at 22:16
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    @PeterCordes: The real value in C's support for weird platforms has never been its ability to make such platforms usable with a wide range of programs, but rather its ability to make such platforms usable with a wide range of programmers. If a platform has 12-bit char, for example, code written for octet-based storage shouldn't be expected to work with it, but telling a programmer "this platform is pretty normal except that it has 12-bit char, 24-bit big-endian int and pointers, and 48-bit big-endian long" should give that person enough info to write code for it...
    – supercat
    Dec 1, 2017 at 23:43
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    ...without having to learn a new instruction set, assembler format, etc. I find the notion the notion that programmers should strive to support every conforming implementation absurd, especially since the authors of the Standard acknowledge that an implementation could be simultaneously conforming but useless.
    – supercat
    Dec 1, 2017 at 23:45

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