The True Story of Hello World
(or at least a good part of it)
Most of our computer science students have been through the famous "Hello World" program at least once. When compared to a typical application program —almost always featuring a web-aware graphical user interface, "Hello World" turns into an very uninteresting fragment of code. Nevertheless, many computer science students still didn’t get the real story behind it. The goal of this exercise is to cast some light in the subject by snooping in the "Hello World" life-cycle.
The source code
Let’s begin with Hello World’s source code:
1. | #include <stdio.h> |
Line 1 instructs the compiler to include the declarations needed to invoke the printf C library (libc) function.
Line 3 declares function main, which is believed to be our program entry point (it is not, as we will see later). It is declared as a function that takes no parameter (we disregard command line arguments in this program) and returns an integer to the parent process — the shell, in our case. By the way, the shell dictates a convention by which a child process must return an 8-bit number representing it status: 0 for normal termination, 0 <n < 128 for process detected abnormal termination, and n > 128 for signal induced termination.
Line 4 through 8 comprise the definition of function main, which invokes the printf C library function to output the "Hello World!n" string and returns 0 to the parent process.
Simple, very simple!
Compilation
Now let’s take a look at the compilation process for "Hello World". For the upcoming discussion, we’ll take the widely-used GNU compiler (gcc) and its associated tools (binutils). We can compile the program as follows:
# gcc -Os -c hello.c
This produces the object file hello.o. More specifically,
# file hello.o
hello.o: ELF 32-bit LSB relocatable, Intel 80386, version 1 (SYSV), not stripped
tells us hello.o is a relocatable object file, compiled for the IA-32 architecture (I used a standard PC for this study), stored in the Executable and Linking Format (ELF), that contains a symbol table (not stripped).
By the way,
# objdump -hrt hello.o
hello.o: file format elf32-i386
Sections:
Idx Name Size VMA LMA File off Algn
0 .text 00000011 00000000 00000000 00000034 2**2
CONTENTS, ALLOC, LOAD, RELOC, READONLY, CODE
1 .data 00000000 00000000 00000000 00000048 2**2
CONTENTS, ALLOC, LOAD, DATA
2 .bss 00000000 00000000 00000000 00000048 2**2
ALLOC
3 .rodata.str1.1 0000000d 00000000 00000000 00000048 2**0
CONTENTS, ALLOC, LOAD, READONLY, DATA
4 .comment 00000033 00000000 00000000 00000055 2**0
CONTENTS, READONLY
SYMBOL TABLE:
00000000 l df *ABS* 00000000 hello.c
00000000 l d .text 00000000
00000000 l d .data 00000000
00000000 l d .bss 00000000
00000000 l d .rodata.str1.1 00000000
00000000 l d .comment 00000000
00000000 g F .text 00000011 main
00000000 *UND* 00000000 puts
RELOCATION RECORDS FOR [.text]:
OFFSET TYPE VALUE
00000004 R_386_32 .rodata.str1.1
00000009 R_386_PC32 puts
tells us hello.o has 5 sections:
- .text: that’s "Hello World" compiled program, i.e. IA-32 opcodes corresponding to the program. This will be used by the program loader to initialize the process’ code segment.
- .data: "Hello World" has neither initialized global variables nor initialized static local variables, so this section is empty. Otherwise, it would contain the variable initial values to be loaded into the data segment.
- .bss: "Hello World" also doesn’t have any non-initialized variable, either global or local, so this section is also empty. Otherwise, it would indicate how many bytes must be allocated and zeroed in the data segment in addition to section .data.
- .rodata: this segment contains the "Hello World!n" string, which is tagged read-only. Most operating systems do not support a read-only data segment for processes (running programs), so the contents of .rodata go either to the process’ code segment (because it’s read-only), or to the data segment (because it’s data). Since the compiler doesn’t know the policy adopted by your OS, it creates this extra ELF section.
- .comment: this segment contains 33 bytes of comments which cannot be tracked back to our program, since we didn’t write any comment. We’ll soon see where it comes from.
It also shows us a symbol table with symbol main bound to address 00000000 and symbol puts undefined. Moreover, the relocation table tells us how to relocate the references to external sections made in section .text. The first relocatable symbol corresponds to the "Hello World!n" string contained in section .rodata. The second relocatable symbol, puts, designates a libc function which was generated as a result of invoking printf. To better understand the contents of hello.o, let’s take a look at the assembly code:
1. | # gcc -Os -S hello.c -o –
|
From the assembly code, it becomes clear where the ELF section flags come from. For instance, section .text is to be 32-bit aligned (line 7). It also reveals where the .comment section comes from (line 20). Since printf was called to print a single string, and we requested our nice compiler to optimize the generated code (-Os), puts was generated instead. Unfortunately, we’ll see later that our libc implementation will render the compiler effort useless.
And what about the assembly code produced? No surprises here: a simple call to function puts with the string addressed by .LC0 as argument.
Linking
Now let’s take a look at the process of transforming hello.o into an executable. One might think the following command would do:
# ld -o hello hello.o -lc
ld: warning: cannot find entry symbol _start; defaulting to 08048184
But what’s that warning? Try running it!
Yes, it doesn’t work. So let’s go back to that warning: it tells the linker couldn’t find our program’s entry point _start. But wasn’t it main our entry point? To be short here, main is the start point of a C program from the programmer’s perspective. In fact, before calling main, a process has already executed a bulk of code to "clean up the room for execution". We usually get this surrounding code transparently from the compiler/OS provider.
So let’s try this:
# ld -static -o hello -L`gcc -print-file-name=` /usr/lib/crt1.o /usr/lib/crti.o hello.o /usr/lib/crtn.o -lc -lgcc
Now we should have a real executable. Static linking was used for two reasons: first, I don’t want to go into the discussion of how dynamic libraries work here; second, I’d like to show you how much unnecessary code comes into "Hello World" due to the way libraries (libc and libgcc) are implemented. Try the following:
# find hello.c hello.o hello -printf "%ft%sn"
hello.c 84
hello.o 788
hello 445506
You can also try "nm hello" or "objdump -d hello" to get an idea of what got linked into the executable.
For information about dynamic linking, please refer to Program Library HOWTO.
Loading and running
In a POSIX OS, loading a program for execution is accomplished by having the father process to invoke the fork system call to replicates itself and having the just-created child process to invoke the execve system call to load and start the desired program. This procedure is carried out, for instance, by the shell whenever you type an external command. You can confirm this with truss or strace:
# strace -i hello > /dev/null
[????????] execve("./hello", ["hello"], [/* 46 vars */]) = 0
…
[08053d44] write(1, "Hello World!n", 13) = 13
…
[0804e7ad] _exit(0) = ?
Besides the execve system call, the output shows the call to write that results from puts, and the call to exit with the argument returned by function main (0).
To understand the details behind the loading procedure carried out by execve, let’s take a look at our ELF executable:
# readelf -l hello
Elf file type is EXEC (Executable file)
Entry point 0x80480e0
There are 3 program headers, starting at offset 52
Program Headers:
Type Offset VirtAddr PhysAddr FileSiz MemSiz Flg Align
LOAD 0x000000 0x08048000 0x08048000 0x55dac 0x55dac RE 0x1000
LOAD 0x055dc0 0x0809edc0 0x0809edc0 0x01df4 0x03240 RW 0x1000
NOTE 0x000094 0x08048094 0x08048094 0x00020 0x00020 R 0x4
Section to Segment mapping:
Segment Sections…
00 .init .text .fini .rodata __libc_atexit __libc_subfreeres .note.ABI-tag
01 .data .eh_frame .got .bss
02 .note.ABI-tag
The output shows the overall structure of hello. The first program header corresponds to the process’ code segment, which will be loaded from file at offset 0x000000 into a memory region that will be mapped into the process’ address space at address 0x08048000. The code segment will be 0x55dac bytes large and must be page-aligned (0x1000). This segment will comprise the .text and .rodata ELF segments discussed earlier, plus additional segments generated during the linking procedure. As expected, it’s flagged read-only (R) and executable (X), but not writable (W).
The second program header corresponds to the process’ data segment. Loading this segment follows the same steps mentioned above. However, note that the segment size is 0x01df4 on file and 0x03240 in memory. This is due to the .bss section, which is to be zeroed and therefore doesn’t need to be present in the file. The data segment will also be page-aligned (0x1000) and will contain the .data and .bss ELF segments. It will be flagged readable and writable (RW). The third program header results from the linking procedure and is irrelevant for this discussion.
If you have a proc file system, you can check this, as long as you get "Hello World" to run long enough (hint: gdb), with the following command:
# cat /proc/`ps -C hello -o pid=`/maps
08048000-0809e000 r-xp 00000000 03:06 479202 …/hello
0809e000-080a1000 rw-p 00055000 03:06 479202 …/hello
080a1000-080a3000 rwxp 00000000 00:00 0
bffff000-c0000000 rwxp 00000000 00:00 0
The first mapped region is the process’ code segment, the second and third build up the data segment (data + bss + heap), and the fourth, which has no correspondent in the ELF file, is the stack. Additional information about the running hello process can be obtained with GNU time, ps, and /proc/pid/stat.
Terminating
When "Hello World" executes the return statement in main function, it passes a parameter to the surrounding functions discussed in section linking. One of these functions invokes the exit system call passing by the return argument. The exit system call hands over that value to the parent process, which is currently blocked on the wait system call. Moreover, it conducts a clean process termination, with resources being returned to the system. This procedure can be partially traced with the following:
# strace -e trace=process -f sh -c "hello; echo $?" > /dev/null
execve("/bin/sh", ["sh", "-c", "hello; echo 0"], [/* 46 vars */]) = 0
fork() = 8321
[pid 8320] wait4(-1, <unfinished …>
[pid 8321] execve("./hello", ["hello"], [/* 46 vars */]) = 0
[pid 8321] _exit(0) = ?
<… wait4 resumed> [WIFEXITED(s) && WEXITSTATUS(s) == 0], 0, NULL) = 8321
— SIGCHLD (Child exited) —
wait4(-1, 0xbffff06c, WNOHANG, NULL) = -1 ECHILD (No child processes)
_exit(0)
Closing
The intention of this exercise is to call attention of new computer science students to the fact that a Java applet doesn’t get run by magic: there’s a lot of system software behind even the simplest program. If consider it useful and have any suggestion to improve it, please e-mail me.
FAQ
This section is dedicated to student’s frequently asked questions.
- What is "libgcc"? Why is included in linkage?
Internal compiler libs, such as libgcc, are used to implement language constructs not directly implemented by the target architecture. For instance, the module operator in C ("%") might not be mappable to a single assembly instruction on the target architecture. Instead of having the compiler to generate in-line code, a function call might be preferable (specially for memory limited machines such as microcontrollers). Many other primitives, including division, multiplication, string manipulation (e.g. memory copy) are typically implemented on such libraries.
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