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I've been trying to understand how my assembly code is being loaded in RAM,so I ran this code on a x86_64 cpu:

section .text
global main
main:
    push 50
    push 64
    push 0x10
    mov eax, 60
    syscall

after looking at how the first 4 lines are loaded in RAM using gdb I got the result:

0x401000 <main>:    0x406a326a  0x3cb8106a

since my CPU is little endian, it's natural for the lines to be flipped(hence why line 2 comes before line 1) so from that push would be 0x6a and mov would be 0xb8(not sure).

My question is, why are they bundled up into 32 bit words? I thought the output would be something like:

0x3cb8106a 0x406a326a   

as it would make sense in a 64 bit little endian machine.

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    You asked GDB to display memory contents in (little-endian) 32-bit chunks. That is all. push imm8 is a 2-byte instruction; mov eax, imm32 is a 5-byte instruction. x86 machine code uses variable-length instructions from 1 to 15 bytes with no alignment or bundling Mar 11 '20 at 5:03
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    It does do that, with your choice of output format. The default is 32-bit chunks which GDB calls "words". Intel manuals call that size "double word" or dword, but it has nothing to do with how the CPU would decode. Use help x. Or use disas /r to disassemble and show machine code. (You probably also want set disassembly-flavor intel - GNU .intel_syntax noprefix is different from NASM, but closer than AT&T syntax.) Mar 11 '20 at 5:06
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    Yes, GDB has its own names for widths. Outside of GDB, most 64-bit ISAs (like MIPS64, or AArch64) define a "word" as 32 bits, and 64 bits as a double-word. But x86-64 evolved out of a 16-bit ISA, not 32, so on x86-64 a "word" = 16 bit, a dword = 32-bit, and a qword = 64-bit. Again, that's unrelated to GDB's size options. But your idea that a "64-bit ISA" should mean word = 64-bit is totally wrong even outside of GDB not caring about the ISA's sizes. See What's the size of a QWORD on a 64-bit machine? Mar 11 '20 at 5:11
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    Yeah, a disassembly that includes machine-code hexdump shows you that most clearly. The hardware only cares about cache line (64-byte) boundaries as far as fetching instructions. Or maybe some effect from 16-byte aligned fetch blocks. x86 is not a "word-oriented" ISA; at the other end of the spectrum MIPS for example is very strongly word-oriented, with fixed-width 32-bit aligned instruction words that (originally) barely needed decoding and could just be used directly as internal control signals. related: Instruction Lengths Mar 11 '20 at 5:36
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    For that level of detail, read Agner Fog's microarch pdf - it's very good, and aimed at software people that want to know how hardware runs their code. Also realworldtech.com/sandy-bridge explains fetch from L1i cache to feed pre-decode and decode stages on Sandybridge-family CPUs. But logically all of this is giving the illusion of fetching / decoding / executing single instructions one at a time. Out-of-order exec always preserves that illusion for a single thread. Mar 11 '20 at 5:50

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