The following is the assembly I have used in an attempt to print to console:

global _start

  addi   a0, x0, 1
  addi   a1, x0, 42
  addi   a7, x0, 63

  addi   a0, x0, 0
  addi   a7, x0, 93

  .byte 6  

I compiled with

riscv64-unknown-elf-as  -o example.o  example.S
riscv64-unknown-elf-ld  -o example  example.o

and run using spike and proxy kernel

spike pk example

No output is generated.

This works on https://www.kvakil.me/venus/ with

  addi   a0, x0, 1
  addi   a1, x0, 42

and prints 42.

Also, if I wanted to print the contents of num in the data segment, how would I go about it?

  • I have no output when run this program with qemu-riscv32 a.out.
    – Land
    Commented May 31 at 0:37
  • @Land the code above will work on venus--an instruction set primarily used for education purposes. It contains system calls for print and other memory management calls. If you go the qemu emulation way, you will have to check the specific system calls for your needs.
    – code4eva
    Commented May 31 at 11:06

2 Answers 2


I managed a solution from Peter Cordes' answer. I am posting the implementation here in case someone needs it and for my own reference.



  1. Given a signed number, get its absolute value, if the number is negative, make a note of it through a variable.
  2. Choose an end address position justified by the next point.
  3. Perform repeated division and store the reminder in the appropriate memory location.
  4. If the number is negative add '-' at the beginning.
  5. Get length by subtracting first address from the end. Then call appropriate system call.

System calls can be found here.

C code logically mirrors the assembly

#include <unistd.h>

void num_print(long num){
    unsigned int base = 10;
    int sign_bit = 0;

    char string[20];
    char* end = string + 19;
    char* p   = end;
    *p = '\n';
    if (num < 0){
        num = 0 - num;
        sign_bit = 1;

    do {
        *(--p) = (num % base) + '0';
        num /= base;
    } while (num);

    if (sign_bit)
        *(--p) = '-';
    size_t len = end - p;
    write(1, p, len + 1);

int main(){
    int arr[3] = {1234567, -1234567, 0};
    for (int i=0; i < 3; i++){
    return 0;

Risc-v Assembly

.global _start

    la           s1, arr          # s1: load arr address
    addi         s2, zero, 3      # s2: arr length

    addi         sp, sp, -8       # push 1 item to stack 
    sd           ra, 0(sp)        # save return address
    mv           s3, zero         # s3: i loop counter  
    j            compare_ipos

    slli         s4, s3, 3        # s4: i * 8
    add          s5, s1, s4       # s5: address of a[i]
    ld           a0, 0(s5)        # a0: arr[i]
    jal          ra, num_print    # call num_print
    addi         s3, s3, 1        # increment i

    blt          s3, s2, L1       # loop if i < 3
    j            exit
    addi         sp, sp, -40      # create stack space
    sd           s0, 32(sp)       # store frame pointer
    addi         s0, sp, 40       # new frame pointer
    addi         t0, zero, 0      # initialize sign_bit
    addi         t1, zero, 10     # divisor and new-line char
    addi         t2, s0, -16      # t2: string[n] 
    add          a1, zero, t2     # a1: string[0] currently string[n]
    addi         t3, zero, '\n'   # '\n' char
    sb           t3, 0(a1)        # store '\n'
    bge          a0, zero, PVE    # if num >= 0 go to L1 else get absolute
    xori         a0, a0, -1       # (num ^ -1)
    addi         a0, a0, 1        # num + 1
    addi         t0, zero, 1      # set sign-bit to 1

    remu         t3, a0, t1       # num % 10
    addi         t3, t3, 48       # convert to ascii
    addi         a1, a1, -1       # decrement start pointer
    sb           t3, 0(a1)        # store value
    divu         a0, a0, t1       # num /= 10
    blt          zero, a0, PVE    # if num > 0 loop

    beq          t0, zero, print  # if sign_bit = 0 go to print else, add '-' char
    addi         t3, zero, '-'    # ascii '-'
    addi         a1, a1, -1       # decrement start pointer
    sb           t3, 0(a1)        # store '-'

    sub          t4, t2, a1       # t4: len -- string[n] - string[0]
    addi         a2, t4, 1        # len + 1
    addi         a0, zero, 1      # file descriptor to write to
    addi         a7, zero, 64     #  pk SYS_write
    ecall                         # transfer control to os

    ld           s0, 32(sp)       # restore frame pointer
    addi         sp, sp, 40       # restore stack pointer

    ret                           # return from function        
    ld           ra, 0(sp)        # restore ra
    addi         sp, sp, 8        # pop stack

    addi         a0, zero, 0      # return value
    addi         a7, zero, 93     # syscall exit code

  .dword  12345670, -12345670, 0
  • Get the number's number of digits -- length. Necessary to figure out the memory offset. - not really, you can just start storing at the end of the buffer, as shown in How do I print an integer in Assembly Level Programming without printf from the c library?. When you're done, you have a pointer to the start of the number, wherever that is, which you can pass to `write(fd, buf, len). You can calculate the length by subtracting end-start. Commented Apr 12, 2021 at 1:10
  • It's very wasteful to do the division twice; if you needed the digit-string to start at a specific position in memory (i.e. you weren't just going to pass a pointer to a write system call), copy them after you generate either backwards or right-justified to the end of a buffer. Commented Apr 12, 2021 at 1:10
  • If you're going to actually branch on num < 0, negate it with 0 - num, i.e. sub t0, zero, t0. You only need that branchless abs implementation if you're going to avoid branching, e.g. with signbit = num<0, e.g. slt. Or better with sra t2, t0, 31 to get a 0 / non-zero result (which you also want as the mask for the xor/sub 2's complement identity abs trick). Commented Apr 12, 2021 at 1:13
  • It's weird that you use s0..2 as temporary registers. Those ABI names correspond to the calling convention: s registers are "saved", i.e. you should save/restore them if you modify them at all, and t registers are temporaries that your caller doesn't care if you modify. (You exit with a system call because _start isn't a function, but you're not gaining anything from using call-preserved registers here since you don't make any calls yourself.) Commented Apr 12, 2021 at 1:18
  • Your C uses printf("%s") but your asm uses write(1, buf, len). That's weird; your asm wastes a couple instructions 0-terminating the string. Hopefully you're not actually writing the '\0' byte as part of the length, so the kernel doesn't care if it's there or not. So you should just remove sb t6, 0(t5) # store null to address. (Also, it's ASCII NUL, not null, and there was no reason to copy a zero to t6, you could have done sb zero, 0(t5). You sometimes use zero and sometimes x0. Those are the same register in RISC-V; use the same name for consistency. Commented Apr 12, 2021 at 1:23

System calls depend on the environment. "Toy" systems like Venus or RARS have their own set of toy system calls that do things like print an integer.

In a real-world system like GNU/Linux, true system calls that you can access with ecall can only copy bytes to a file descriptor. If you want to output text, you need to create text in memory in user-space and pass a pointer to a write system call.

Spike + pk is apparently more like Linux, with a POSIX write(2) system call, not like those toy system-call environments where you could pass an integer directly to a print-int ecall. https://www.reddit.com/r/RISCV/comments/dagvzr/where_do_i_find_the_list_of_stdio_system_etc/ has some examples and links. Notably https://github.com/riscv/riscv-pk/blob/master/pk/syscall.h where we find #define SYS_write 64 as the call number (goes in a7) for a write system call.

A write system-call takes args: write(int fd, const void *buf, size_t count).

Formatting a binary integer into an ASCII string is something that library functions like printf will do. Toy systems don't have a library, so they just put a few useful functions as system calls. And if you want control over stuff like leading zeros or padding to a fixed width, you have to write it yourself. But on a system like Spike-pk, you only have simple Unix-like system calls and (perhaps?) no library at all, so you have to always do it yourself.

With just Linux / Unix / Spike-pk system-calls, you'll want to do repeated division by 10 to get the decimal digits of a binary integer. like in How do I print an integer in Assembly Level Programming without printf from the c library? which shows C and x86-64 assembly for Linux:

char *itoa_end(unsigned long val, char *p_end) {
  const unsigned base = 10;
  char *p = p_end;
  do {
    *--p = (val % base) + '0';
    val /= base;
  } while(val);                  // runs at least once to print '0' for val=0.

  // write(1, p,  p_end-p);
  return p;  // let the caller know where the leading digit is

Translate to RISC-V assembly (or compile with gcc or clang, e.g. via https://godbolt.org/). Reserving a small buffer on the stack is convenient.

Also, if I wanted to print the contents of num in the data segment, how would I go about it?

lw the number into a register, then do the same thing as above.

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