i wasn't first

F

congratulations michel 👑

Nice

🍕

I mean.. there is the 6502 and z80, how about some 6800 too?

In MIPS... there's a jump and link(jal), which also saves the current pc+4 to a register 31(or $ra)... and it's responsibility of the subprogram to take care of it(pushing to the stack if it needs to call another function and popping it back). By convention, registers 4-7(or $v0 to $v3, inclusive) are used for arguments, registers 8-15(or $t0-$t7) are used for temporaries and may be modified by inner functions calls, while registers 16-23($s0-$s7) are to be preserved at the return(if you really need to use them, you should push their values... and pop them back when you are done) Finally registers 2 and 3(or $v0 and $v1) are the convention for the return.

I took a course in IBM 360 (370?) assembly in 1982 and my second favorite instruction was BAL - branch and link. My favorite was ZAP - zero and add packed (packed decimal), because, well, ZAP.

@@matheusjahnke8643 That convention is the o32 ABI, there's also the n32/64 ABI which defines a slightly different usage for the registers: Arguments are now from $4-$11 ($a0-$a7) Temporaries are from $12-$15 ($t4-$t7) The callee saved registers are the same, $16-$23 ($s0-$s7), plus the others ($gp, $sp, $fp) And the return registers are also the same $2 and $3 ($v0 and $v1)

The Arm calling convention expects the callee to preserve registers r4 to r12. Complier people know this so they would do this extra work (pushing and poping the registers in the callee if it requires extra registers). R0 is usually used as return value. Actually the first few registers as passing parameters

The Journey is Hard Than it seems. Hardness builds a man .

Assembly is very similar to basic in terms of program flow

Assembly is very easy if you start thinking about it in terms of physical circuits and the mosfet transistors and all their electric fields and depletion regions. Basically remember that it's all physics in the end, and assembly occupies some intermediate step.

It’s a lot easier to comprehend when you learn with computer architecture and organization. It’s why a lot of colleges combine the two classes together nowadays it’s usually called “Computer organization and Assembly” or something along those lines.

@@fackyoutube8452 very true, I remember going through the whole organization of basic 8086 arch and the registers and their uses etc and then it made much more sense what each instruction is doing and where its storing stuff and how its storing and updating etc

The same is true for any language that compiles into some intermediate form, like JVM bytecode, BTW.

I learned a lot of assembly by doing exactly this but then going in, cleaning it up, adding comments, and gutting half of it because gcc generates some really inefficient assembly. Seriously, I've seen gcc do this: mov %eax %ebx mov %ebx %eax multiple times. Still haven't figured out what possible purpose that could have.

@@nightfox6738 This is why I never trusted compilers. I've seen them do amazing things but also really dumb things. But that's a new low lol

Calling conventions is something that you have to have in mind when you are calling a function from a different programming language. It is quite fascinating to delve into. Another term worth looking into is ABI or Application Binary Interface

If the language is higher level, there's likely a calling convention layered on top of the architecture's convention, especially if it's a multiplatform higher level language.

When you see "WINAPI" when you program in windows it's macro alias for "__stdcall" calling convention. Same as "CALLBACK" or "APIENTRY".

teehee ty

@@LowLevelTV bro I love you 💋💋💋

Call stack has a limited size on most platforms. On Linux the default is 8 MB. So if a program uses more than that then a stack overflow error will occur.

8 MB is actually very generous, using more than that is quite difficult.

I remember the 6502 architecture had a hardware stack of 255 bytes. I dimly recall you had to push/pop two numbers. Exceeding this stack caused a Stack Overflow fatal error. Not sure how newer architectures do it, I imagine there is a stack in RAM which could be any size or location. Don’t forget that the operating system also uses the stack.

@@darylcheshire1618on Monday modern systems every thread has its own call stack. They're randomly placed in memory to avoid hackers from accessing them.

@@darylcheshire1618 Modern systems typically use the upper portion of heap memory, if your stack gets two big it can start to clobber the heap but this doesn't usually happen except with a botched recursion or the like

same, from ben eater's videos iirc

Write your tests, kids!

pre and post increments should be considered harmful

what confuses me most is the presence of a second semicolon right past the only one required, to my knowledge. what is its point ?

an empty string is not empty, it's an array of char that ends with /0, the char that mean string ending, so "abc" length is in fact 4, ('a', 'b', 'c', '/0'). After the call it says "The string is __ bytes long", bytes not characters.

@@MT-cf2ms that's true. but calling the function `strlen` and giving it different semantics than the C library's strlen function (which returns 0 for an empty string) is cursed behavior. calling it something like `bytelen` would be a bit more acceptable. Or changing that text and fixing the bug would have worked too.

I learned about stack smashing a few weeks ago. It feels so crazy that I actually understand this stuff now.

Return value optimization. This is why you shouldn't be afraid to return structs.

Instead of returning structs most functions i seen require to pass explicitly a pointer to a struct that needs to be filled with information.

@@SirusStarTVwhich functions? If you’re referring to libc ones, it might be because they were written before the optimisation discussed above was implemented. Just speculation

MYNAMEEHJEGF

And this is not the code report

my name, will never be Jeff either

Pfp says PP, but Names PK??

my name's not shane kid

It adjusts the stack after popping of the return address into IP in 80x86 systems. Also, whether the value passed back is in the register or on the stack can be language and compiler dependent even on 80x86 systems.

As Alex said. When the calling code needs to get more parameters to a function than the CPU can hold in its registers, one strategy is to put them onto the stack before calling (another one is to put them somewhere in memory and have a pointer to that address in a register). So the stack would hold the parameters, then the return address, then the function's local variables. When returning, those extra parameters need to be removed from the stack, too. The calling code can do that manually (it put them there, so it knows how much to remove) or the function can use a RET that can do that and let the CPU do that for free.

That depends on the calling conventions. Some architectures have a “frame pointer” in addition to the stack pointer; IIRC the frame pointer would save the value of the stack pointer just after a jump to subroutine. Then no matter how much data the function pushed onto the stack all the CPU has to do on a return is copy the frame pointer back to the stack pointer to get back to where the return address is on the stack.

@@trevinbeattie4888 EBP register in x86

We did something similar to that at Uni. We were given C code and had to turn it into MIPS (the assembly language Playstation 1 was written in). For small programs it's okay, but for a real-life application written in a high-level language like JS or Python, it would take weeks, months or even years I imagine... Our C was really simple, for example, figuring out if a number is a leap year. Assembly is fun, you can just "go to" whichever line you like lol. I found it really enjoyable but I think C runs almost as fast, so cost-to-benefit ratio-wise, it isn't worth coding in assembly. Check out Rollercoaster Tycoon from 1999, as it's coded entirely in assembly which is pretty cool :)

@@FreeWithinMe I've learned assembly but I barely understand C, and often with C, I have to figure out how to get the toolchain working with makefiles etc... it's a huge pain. I'm not sure which route to take since most people learn C before asm and I ended up doing the opposite

@@YarisTex actually, its not really about speed, even tho that may be somewhat faster (I am not sure that its even faster lol). Its about saving bytes, since `xor eax, eax` takes less bytes to encode than `mov eax, 0`. And even that is not the reason why compilers at `-O3` optimization leves use it (since at maximum speed level, the compiler kinda disregards the size of your code), its about register renaming. The `eax` 32 bit register is actually a couple of dozens of registers which get assigned as the "current eax register" dynamically at runtime to go around false-register-dependencies in your code and this increases the speed of execution DRASTICALLY. So the `mov eax, 0` instruction itself has the same speed, but the next couple of instructions will sometimes run a little slower because it uses the "wrong" register.

What was the game, out of curiosity?

I've found most asm languages easy to learn once you've learned any one of them. While they have different instructions etc, they broadly work in a similar fashion.

@@jemmerl Don't know if KZbin is glitching right now but my reply seems to be gone. I am talking about Maniaplanet, the platform for the Trackmania 2 games.

Can confirm, about a year ago I was trying to make a genesis game. But I couldn't get the sound to work

u must be a genius

Turing Complete is also a good game to learn that kind of stuff

lmao

I built a toy compiler for university. The bugs that you can be FUN: like where I was indexing the stack upside down because I forgot what direction the stack was growing 😂

Doing that you would understand and gain more skills even in interpreted languages like python.

There's a very valid reason why we develop high level abstraction on top of low level architecture like x86 and ARM - to solve more complex problems that will take forever to accomplish using assembly

I totally agree. I used to be a teaching assistant in my old uni and we had a class where we covered assembly. It was so much fun. It was so annoying that the Uni did more advanced architecture classes for final year undergrads only after I left 😢

@@anirudhkumar9139 i'm more interested in the system behind all these abstractions than programming anything useful with them 😄because i feel stupid trying to use them, like what are they even do behind the scene!? if i don't understand it i can't properly utilize them.

Direct access to memory is fun, you can invent drawing algorithms yourself instead of relying on others. Of course it's easier to use those shape and lines drawing functions but you would forever be speculating on how they work (if you're curious).

I learned mostly from Chibiakumas

I learned about computers from Ben Eater and redstone

I love his breadboard computer series. It taught me so much about computer architecture.

I learned 6502 Assembly first, haha. Took me about a year to "get it" but now I can learn basically any assembly language no problem.

​@@williamdrum9899my first processor was the 6502. I quickly learnt to program it in hex without op codes as the computers I generally used had no assembler nor disassembler. The 6502 has some interesting quirks. Its little endianness speeds up processing of calculated addressing: it adds the offset to the LSB whilst the MSB is loading, and only needs the extra cycle to increment the MSB if a page boundary is crossed. Due to synchronous memory accessing whilst the 6502 is deciding and incrementing the MSB if necessary, it loads the byte at the address found so far. If the MSB needed changing it throws this away and loads the correct byte. It is this synchronous memory access that allows a read to be a cycle shorter if a page boundary is not crossed, but to prevent memory being splatted over a write always waits until the correct address is confirmed before writing. The incorrect address is the same offset in the previous page of memory. Normally this may not be a problem, but if that page contains memory mapped IO a side effect can be to trigger hardware that relies on just a memory access (the Apple ][ had some such memory locations). A write does a read before the write so writing to such memory locations results in a double access. The bug in the JMP (I) instruction is due to the LSB being incremented but no check being made for overflow to 0 from 0xFF. For a JSR it also stores the return address as the last byte of the instruction, so that when a RTS is executed, after loading the return address it needs to increment it for the next instruction. This is something to do with the "pipelining" the 6502 does as part of its synchronous memory access whereby it is finishing off the previous instruction when it loads the next instruction.

Which book you are referring to?

It's a bit different, in that there are fewer registers and more specialized commands. Also there are much fewer limitations on addressing modes (you can use register offsets for indexing unlike MIPS)

@@ayoubedd The only assembly code ive learned is LC-3 (stupid oldschool). I cant remeber the exact order i do remember we moved the program counter, as well as the local vars for the function directly into our registers (of which we only had 7). Its good to review.

I believe the 6502 would use JSR, jump to subroutine, and push the PC onto the stack. RTS, return from subroutine, would grab whatever 2 values were on the stack and jump to that address.

It's mostly the same except most CISC computers use the top of the stack to store the return address

The languages I can think of return multiple values as a tuple.

@@Beliar_83 A tuple doesn't fit in a register.

​@@gideonz74b Ah, I am sorry, I was thinking in high level languages. While I don't know for sure what it actually is in terms of assembly, I guess they probable return something similar to what they return for a class. Likely an address that points to the tuple data.

@@Beliar_83 The whole point of this video is how the return statement in a higher language actually works under the hood. So, any other higher level (compiled) language would need to have a pattern to translate tuples to. A pointer to an object is highly inefficient, as it would require memory allocation. Therefore, I mentioned that I imagined that the compiler reserves some room on the stack to place the return tuple into, but this stack space must belong to the caller, obviously. It is possible, because the compiler knows the return type compile time, and it is the same for all paths exiting the function. The return type is defined in the signature of the function.

It's used to retrieve function parameters and local variables.

The frame pointer is used to save the value of the stack pointer at the time of the jump to subroutine; i.e. it points to the return address on the stack. This way no matter how much extra data is pushed onto the stack the CPU knows exactly where to pop back to on return, _and_ the function can use it as a base reference for any call parameters passed to the function (which would have been pushed to the stack before the JSR.)

The reality is that often in Assembly you're free to implement these conventions however you like. Some architectures like x86 have a "call" instruction that makes you jump to a particular address and also puts the return address on the stack, but really you could just jump and store the return address in a register instead. The reason to have conventions, however, is that if your program is calling a C function it is often expected to follow the "C convention" (in the early days a "Pascal convention" was common on Apple Computers). And some architectures like MIPS just declare what the convention for programmers are, but it isn't really enforced. Some instructions may assume that certain values are stored in certain places though. But Assembly is absolute freedom.. make as big of a mess as you like!

The declared function will store the return in RAX but then the caller will just ignore it :)

I think Chibiakumas is a good resource (look it up on youtube.) The CPU in general terms operates a lot like a BASIC interpreter from the 80s. Now, there are some more complex things going on in modern CPUs, but in general your assembly code is executed from the start to the finish, from the top of your source code document going down, one line at a time. Chibiakumas' videos are more in the context of retro game consoles than computers, which do have a few differences to be aware of. For example, on a Game Boy or Sega Genesis, your "main()" isn't going to return since there's nothing to return to. Trying to return from main on one of those systems is more than likely going to crash, as you're just taking whatever junk is on top of the stack and blindly GOTOing it.

That's right. RAM is finite, and every time you recurse you use more.

@@williamdrum9899 why have RAM if you don't use all of it lmao

@@sentjojo It's ok to use all of it, but not more than you have

Yup! The way the stack frame is constructed is the reason local variable scope exists. Thanks for watching!

Update: HOLY SHIT I WAS RIGHT LET’S GOOOOOOOO

It's unfortunately also the reason why buffer overrun attacks exist. If an array stored on the stack is indexed out of bounds, a hacker can overwrite the return address with the address of any function he wants and "return" to it, even if the program hasn't been there before.