247 lines
16 KiB
Markdown
247 lines
16 KiB
Markdown
# Assembly
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Assembly (also ASM) is, for any given hardware computing platform ([ISA](isa.md), basically a [CPU](cpu.md) architecture), the lowest level [programming language](programming_language.md) that expresses typically a linear, unstructured sequence of CPU instructions -- it maps (mostly) 1:1 to [machine code](machine_code.md) (the actual [binary](binary.md) CPU instructions) and basically only differs from the actual machine code by utilizing a more human readable form (it gives human friendly nicknames, or mnemonics, to different combinations of 1s and 0s). Assembly is converted by [assembler](assembler.md) into the the machine code. Assembly is similar to [bytecode](bytecode.md), but bytecode is meant to be [interpreted](interpreter.md) or used as an intermediate representation in [compilers](compiler.md) while assembly represents actual native code run by hardware. In ancient times when there were no higher level languages (like [C](c.md) or [Fortran](fortran.md)) assembly was used to write computer programs -- nowadays most programmers no longer write in assembly (majority of zoomer "[coders](coding.md)" probably never even touch anything close to it) because it's hard (takes a long time) and not [portable](portability.md), however programs written in assemCbly are known to be extremely fast as the programmer has absolute control over every single instruction.
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**Assembly is NOT a single language**, it differs for every architecture, i.e. every model of CPU has potentially different architecture, understands a different machine code and hence has a different assembly (though there are some standardized families of assembly like x86 that work on wide range of CPUs); therefore **assembly is not [portable](portability.md)** (i.e. the program won't generally work on a different type of CPU or under a different [OS](os.md))! And even the same kind of assembly language may have several different [syntax](syntax.md) formats which may differ in comment style, order of writing arguments and even instruction abbreviations (e.g. x86 can be written in [Intel](intel.md) and [AT&T](at_and_t.md) syntax). For the reason of non-portability (and also for the fact that "assembly is hard") you shouldn't write your programs directly in assembly but rather in a bit higher level language such as [C](c.md) (which can be compiled to any CPU's assembly). However you should know at least the very basics of programming in assembly as a good programmer will come in contact with it sometimes, for example during hardcore [optimization](optimization.md) (many languages offer an option to embed inline assembly in specific places), debugging, reverse engineering, when writing a C compiler for a completely new platform or even when designing one's own new platform. **You should write at least one program in assembly** -- it gives you a great insight into how a computer actually works and you'll get a better idea of how your high level programs translate to machine code (which may help you write better [optimized](optimization.md) code) and WHY your high level language looks the way it does.
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The most common assembly languages you'll encounter nowadays are **[x86](x86.md)** (used by most desktop [CPUs](cpu.md)) and **[ARM](arm.md)** (used by most mobile CPUs) -- both are used by [proprietary](proprietary.md) hardware and though an assembly language itself cannot (as of yet) be [copyrighted](copyright.md), the associated architectures may be "protected" (restricted) e.g. by [patents](patent.md). **[RISC-V](risc_v.md)** on the other hand is an "[open](open.md)" alternative, though not yet so wide spread. Other assembly languages include e.g. [AVR](avr.md) (8bit CPUs used e.g. by some [Arduinos](arduino.md)) and [PowerPC](ppc.md).
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To be precise, a typical assembly language is actually more than a set of nicknames for machine code instructions, it may offer helpers such as [macros](macro.md) (something aking the C preprocessor), pseudoinstructions (commands that look like instructions but actually translate to e.g. multiple instructions), [comments](comment.md), directives, named labels for jumps (as writing literal jump addresses would be extremely tedious) etc.
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Assembly is extremely low level, so you get no handholding or much programming "safety" (apart from e.g. CPU operation modes), you have to do everything yourself -- you'll be dealing with things such as function [call conventions](call_convention.md), [interrupts](interrupt.md), [syscalls](syscall.md) and their conventions, how many CPU cycles different instructions take, memory segments, [endianness](endianness.md), raw addresses/[goto](goto.md) jumps, [call frames](call_frame.md) etc.
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Note that just replacing assembly mnemonics with binary machine code instructions is not yet enough to make an executable program! More things have to be done such as [linking](linking.md) [libraries](library.md) and converting the result to some [executable format](executable_format.md) such as [elf](elf.md) which contains things like header with metainformation about the program etc.
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## Typical Assembly Language
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Assembly languages are usually unstructured, i.e. there are no control structures such as `if` or `while` statements: these have to be manually implemented using labels and jump ([goto](goto.md)) instructions. There may exist macros that mimic control structures. The typical look of an assembly program is however still a single column of instructions with arguments, one per line, each representing one machine instruction.
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The working of the language reflects the actual [hardware](hardware.md) architecture -- most architectures are based on [registers](register.md) so usually there is a small number (something like 16) of registers which may be called something like R0 to R15, or A, B, C etc. Sometimes registers may even be subdivided (e.g. in x86 there is an *eax* 32bit register and half of it can be used as the *ax* 16bit register). These registers are the fastest available memory (faster than the main RAM memory) and are used to perform calculations. Some registers are general purpose and some are special: typically there will be e.g. the FLAGS register which holds various 1bit results of performed operations (e.g. [overflow](overflow.md), zero result etc.). Some instructions may only work with some registers (e.g. there may be kind of a "[pointer](pointer.md)" register used to hold addresses along with instructions that work with this register, which is meant to implement [arrays](array.md)). Values can be moved between registers and the main memory (with instructions called something like *move*, *load* or *store*).
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Writing instructions works similarly to how you call a [function](function.md) in high level language: you write its name and then its [arguments](argument.md), but in assembly things are more complicated because an instruction may for example only allow certain kinds of arguments -- it may e.g. allow a register and immediate constant (kind of a number literal/constant), but not e.g. two registers. You have to read the documentation for each instruction. While in high level language you may write general [expressions](expression.md) as arguments (like `myFunc(x + 2 * y,myFunc2())`), here you can only pass specific values.
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There are also no complex [data types](data_type.md), assembly only works with numbers of different size, e.g. 16 bit integer, 32 bit integer etc. Strings are just sequences of numbers representing [ASCII](ascii.md) values, it is up to you whether you implement null terminated strings or Pascal style strings. [Pointers](pointer.md) are just numbers representing addresses. It is up to you whether you interpret a number as signed or unsigned (some instructions treat numbers as unsigned, some as signed).
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Instructions are typically written as three-letter abbreviations and follow some unwritten naming conventions so that different assembly languages at least look similar. Common instructions found in most assembly languages are for example:
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- **MOV** (move): move a number between registers and/or main memory (RAM).
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- **JMP** (jump): unconditional jump to far away instruction.
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- **BEQ** (branch if equal): jump if result of previous comparison was equality.
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- **ADD** (add): add two numbers.
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- **NOP** (no operation): do nothing (used e.g. for delays or as placeholders).
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- **CMP** (compare): compare two numbers and set relevant flags (typically for a subsequent conditional jump).
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## How To
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On [Unices](unix.md) the [objdump](objdump.md) utility from GNU binutils can be used to **disassemble** compiled programs, i.e view the instructions of the program in assembly (other tools like ndisasm can also be used). Use it e.g. as:
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```
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objdump -d my_compiled_program
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```
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Let's now write a simple Unix program in [x86](x86.md) assembly (AT&T syntax). Write the following source code into a file named e.g. `program.s`:
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```
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.global _start # include the symbol in object file
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str:
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.ascii "it works\n" # the string data
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.text
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_start: # execution starts here
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mov $5, %rbx # store loop counter in rbx
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.loop:
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# make a Linux "write" syscall:
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# args to syscall will be passed in regs.
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mov $1, %rax # says syscalls type (1 = write)
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mov $1, %rdi # says file to write to (1 = stdout)
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mov $str, %rsi # says the address of the string to write
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mov $9, %rdx # says how many bytes to write
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syscall # makes the syscall
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sub $1, %rbx # decrement loop counter
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cmp $0, %rbx # compare it to 0
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jne .loop # if not equal, jump to start of the loop
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# make an "exit" syscall to properly terminate:
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mov $60, %rax # says syscall type (60 = exit)
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mov $0, %rdi # says return value (0 = success)
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syscall # makes the syscall
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```
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The program just writes out `it works` five times: it uses a simple loop and a [Unix](unix.md) [system call](syscall.md) for writing a string to standard output (i.e. it won't work on [Windows](windows.md) and similar shit).
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Now assembly source code can be manually assembled into executable by running assemblers like `as` or `nasm` to obtain the intermediate [object file](obj.md) and then [linking](linking.md) it with `ld`, but to assemble the above written code simply we may just use the `gcc` compiler which does everything for us:
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```
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gcc -nostdlib -no-pie -o program program.s
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```
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Now we can run the program with
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```
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./program
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```
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And we should see
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```
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it works
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it works
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it works
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it works
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it works
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```
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As an exercise you can objdump the final executable and see that the output basically matches the original source code. Furthermore try to disassemble some primitive C programs and see how a compiler e.g. makes if statements or functions into assembly.
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## Example
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Let's take the following [C](c.md) code:
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```
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#include <stdio.h>
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char incrementDigit(char d)
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{
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return // remember this is basically an if statement
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d >= '0' && d < '9' ?
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d + 1 :
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'?';
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}
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int main(void)
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{
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char c = getchar();
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putchar(incrementDigit(c));
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return 0;
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}
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```
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We will now compile it to different assembly languages (you can do this e.g. with `gcc -S my_program.c`). This assembly will be pretty long as it will contain [boilerplate](boilerplate.md) and implementations of `getchar` and `putchar` from standard library, but we'll only be looking at the assembly corresponding to the above written code. Also note that the generated assembly will probably differ between compilers, their versions, flags such as [optimization](optimization.md) level etc. The code will be manually commented.
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{ I used this online tool: https://godbolt.org. ~drummyfish }
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The [x86](x86.md) assembly may look like this:
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```
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incrementDigit:
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pushq %rbp # save base pointer
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movq %rsp, %rbp # move base pointer to stack top
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movl %edi, %eax # move argument to eax
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movb %al, -4(%rbp) # and move it to local var.
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cmpb $47, -4(%rbp) # compare it to '0'
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jle .L2 # if <=, jump to .L2
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cmpb $56, -4(%rbp) # else compare to '9'
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jg .L2 # if >, jump to .L4
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movzbl -4(%rbp), %eax # else get the argument
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addl $1, %eax # add 1 to it
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jmp .L4 # jump to .L4
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.L2:
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movl $63, %eax # move '?' to eax (return val.)
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.L4:
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popq %rbp # restore base pointer
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ret
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main:
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pushq %rbp # save base pointer
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movq %rsp, %rbp # move base pointer to stack top
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subq $16, %rsp # make space on stack
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call getchar # push ret. addr. and jump to func.
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movb %al, -1(%rbp) # store return val. to local var.
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movsbl -1(%rbp), %eax # move with sign extension
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movl %eax, %edi # arg. will be passed in edi
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call incrementDigit
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movsbl %al, %eax # sign extend return val.
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movl %eax, %edi # pass arg. in edi again
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call putchar
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movl $0, %eax # values are returned in eax
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leave
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ret
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```
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The [ARM](arm.md) assembly may look like this:
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```
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incrementDigit:
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sub sp, sp, #16 // make room on stack
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strb w0, [sp, 15] // load argument from w0 to local var.
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ldrb w0, [sp, 15] // load back to w0
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cmp w0, 47 // compare to '0'
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bls .L2 // branch to .L2 if <
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ldrb w0, [sp, 15] // load argument again to w0
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cmp w0, 56 // compare to '9'
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bhi .L2 // branch to .L2 if >=
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ldrb w0, [sp, 15] // load argument again to w0
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add w0, w0, 1 // add 1 to it
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and w0, w0, 255 // mask out lowest byte
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b .L3 // branch to .L3
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.L2:
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mov w0, 63 // set w0 (ret. value) to '?'
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.L3:
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add sp, sp, 16 // shift stack pointer back
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ret
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main:
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stp x29, x30, [sp, -32]! // shift stack and store x regs
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mov x29, sp
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bl getchar
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strb w0, [sp, 31] // store w0 (ret. val.) to local var.
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ldrb w0, [sp, 31] // load it back to w0
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bl incrementDigit
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and w0, w0, 255 // mask out lowest byte
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bl putchar
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mov w0, 0 // set ret. val. to 0
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ldp x29, x30, [sp], 32 // restore x regs
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ret
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```
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The [RISC-V](risc_v.md) assembly may look like this:
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```
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incrementDigit:
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addi sp,sp,-32 # shift stack (make room)
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sw s0,28(sp) # save frame pointer
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addi s0,sp,32 # shift frame pointer
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mv a5,a0 # get arg. from a0 to a5
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sb a5,-17(s0) # save to to local var.
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lbu a4,-17(s0) # get it to a4
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li a5,47 # load '0' to a4
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bleu a4,a5,.L2 # branch to .L2 if a4 <= a5
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lbu a4,-17(s0) # load arg. again
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li a5,56 # load '9' to a5
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bgtu a4,a5,.L2 # branch to .L2 if a4 > a5
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lbu a5,-17(s0) # load arg. again
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addi a5,a5,1 # add 1 to it
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andi a5,a5,0xff # mask out the lowest byte
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j .L3 # jump to .L3
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.L2:
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li a5,63 # load '?'
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.L3:
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mv a0,a5 # move result to ret. val.
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lw s0,28(sp) # restore frame pointer
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addi sp,sp,32 # pop stack
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jr ra # jump to addr in ra
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main:
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addi sp,sp,-32 # shift stack (make room)
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sw ra,28(sp) # store ret. addr on stack
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sw s0,24(sp) # store stack frame pointer on stack
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addi s0,sp,32 # shift frame pointer
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call getchar
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mv a5,a0 # copy return val. to a5
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sb a5,-17(s0) # move a5 to local var
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lbu a5,-17(s0) # load it again to a5
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mv a0,a5 # move it to a0 (func. arg.)
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call incrementDigit
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mv a5,a0 # copy return val. to a5
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mv a0,a5 # get it back to a0 (func. arg.)
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call putchar
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li a5,0 # load 0 to a5
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mv a0,a5 # move it to a0 (ret. val.)
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lw ra,28(sp) # restore return addr.
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lw s0,24(sp) # restore frame pointer
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addi sp,sp,32 # pop stack
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jr ra # jump to addr in ra
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``` |