This is basically a (partial) reimplementation of tracer by Dennis Yurichev for linux OS, implemented using Intel PIN.
The tool can perform simple debugging tasks, such as log/modify register/memory values at runtime.
Currently, it only supports x86-64 ELF binaries.
Run build.sh, it will download PIN 3.19 and compile the pintool.
--callgraph <outfile.dot>: dump the (partial) callgraph in outfile.dot.
--symbs <regex>: print all symbols loaded by the traced program that matches the regex. The regex has this shape: <module_name>#<symbol_name>.
Ex: print all symbols defined in the traced program:
$ pincher --symbs "dummy#.*" -- /path/to/dummy
...
<symbol> [Address] 0x55aef06cd67c ( dummy+0x67c ) [SymbolName] bar
...
Ex: print all symbols in libc (loaded by dummy):
$ pincher --symbs "libc.*#.*" -- /path/to/dummy
...
<symbol> [Address] 0x7fb5ec041bb0 ( libc.so.6+0x43bb0 ) [SymbolName] srand
...
--bpf <address/regex>,<opt>,<key>:<value>,...: log that the function at address (or the function that matches the regex) is called. Other optional arguments are passed in the form of <opt> or <key>:<value>. Notice that the regex has the shape <module_name>#<symbol_name>.
The optional arguments are:
module:<module_name>: if you specify the address (and not the regex),<module_name>is the name of the module that will be used as a base for the address (e.g.,--bpf "0xaa,libc.so.8"triggers the breakpoint atLIBC_BASE+0xaa). If omitted, the base of the main module will be used.args:<nargs>: tell the tool how many arguments the function has. If set, the tool will log also the arguments.dump_args:<size>: if the arguments are pointers, dump<size>bytes of memory starting from the address pointed by the argument.skip: skip the execution of the function (jump to return address).rt:<value>: force the function to return<value>.bt: dump callstack (up to 30 elements).
Ex: log all calls to strcmp:
$ pincher --bpf "strcmp,args:2" -- /path/to/dummy bla
<bpf beg> strcmp@plt @ dummy+0x5b0 ( 0x7fffeb6c6e40 "bla", 0x55d823cd77fc "ciao" ) [ called from dummy!main+0x4b @ dummy+0x72e ]
<bpf end> strcmp@plt -> 0xffffffff
Ex: dump write arguments:
$ pincher --bpf "write,args:3,dump_args:32" -- /path/to/dummy bla
...
<bpf beg> write @ libc.so.6+0x110140 ( 0x1, 0x5650223d8260 "I'm in foo!", 0x1d ) [ called from libc.so.6!_IO_file_write+0x28 @ libc.so.6+0x8b1b8 ]
dumping arg 1
0x00005650223d8260: 49 27 6d 20 69 6e 20 66 6f 6f 21 0a 49 27 6d 20 "I'm in foo!.I'm "
0x00005650223d8270: 69 6e 20 62 61 72 21 0a 61 3a 20 33 0a 00 00 00 "in bar!.a: 3...."
...
<bpf end> write -> 0x1d
Ex: dump write backtrace:
$ pincher --bpf "write,args:3,bt" -- /home/luca/Documents/code/c/dummy/dummy bla
...
<bpf beg> write @ libc.so.6+0x110140 ( 0x1, 0x55b978779260 "I'm in foo!", 0xc ) [ called from libc.so.6!_IO_file_write+0x28 @ libc.so.6+0x8b1b8 ]
CALLSTACK
>>> libc.so.6+0x8b1b8 ( _IO_file_write+0x28 )
>>> libc.so.6+0x8cf4d ( _IO_do_write+0xad )
>>> libc.so.6+0x8d3fe ( __overflow+0xfffffffffffff56e [ tailjmp? ] )
>>> libc.so.6+0x80b5d ( puts@plt+0x296ddd45960d [ tailjmp? ] )
>>> dummy+0x687 ( bar+0xb )
>>> dummy+0x6bb ( main+0x28 )
>>> libc.so.6+0x21b95 ( __libc_start_main+0xe5 )
<bpf end> write -> 0xc
...
--bpx <address>,<opt>,...: log the state of the machine just before the execution of the the instruction at address.
As for bpf, it is possible to specify other optional arguments:
module:<module_name>: as before, this is the name of the module whose base is used to calculate the virtual address. If omitted, the base of the main module is used.set(<reg_name>, <reg_value>): set<reg_name>to<reg_value>just before the execution of the instruction.<reg_value>can be expressed in decimal, hexadecimal and floating point.dump(<reg_name>, <size>): dump the value of<reg_name>and, if it points some mapped memory, dump also<size>bytes starting from the first address pointed by the register.
Ex:
$ pincher --bpx "0x710" -- /path/to/dummy
...
<bpx beg> dummy+0x710 ( dummy!main+0x2d )
rax: 0x0000000000000002 rbx: 0x0000000000000000 rcx: 0x00000000fbad2a84
rdx: 0x00007f98e531a8c0 rsi: 0x000055e39d097260 rdi: 0x0000000000000001
rsp: 0x00007ffc7a54b220 rbp: 0x00007ffc7a54b240 rip: 0x000055e39c025710
<bpx end>
...
Ex:
$ pincher --bpx "0x710,set(rdx,0xabadcafe),set(xmm0,16.1)" "0x713,dump(xmm0,1)" -- /path/to/dummy
...
<bpx beg> dummy+0x710 ( dummy!main+0x2d )
rax: 0x0000000000000002 rbx: 0x0000000000000000 rcx: 0x00000000fbad2a84
rdx: 0x00007f44e2ca88c0 rsi: 0x000055cd3ac8d260 rdi: 0x0000000000000001
rsp: 0x00007ffeafe20780 rbp: 0x00007ffeafe207a0 rip: 0x000055cd3a0c0710
SET rdx <- 0xabadcafe
SET xmm0 <- 16.1
<bpx end>
<bpx beg> dummy+0x713 ( dummy!main+0x30 )
rax: 0x0000000000000002 rbx: 0x0000000000000000 rcx: 0x00000000fbad2a84
rdx: 0x00000000abadcafe rsi: 0x000055cd3ac8d260 rdi: 0x0000000000000001
rsp: 0x00007ffeafe20780 rbp: 0x00007ffeafe207a0 rip: 0x000055cd3a0c0713
xmm0: 0x403019999999999a
<bpx end>
...
We can use pincher to change the result of every arithmetic operation performed by libreoffice calc in a cell.
For example, using LibreOffice 6.0.7.3 00m0(Build:3) on ubuntu 18.04, we can execute:
$ pincher --bpx "0x6ed92e,module:libsclo.so,dump(xmm2,1),set(xmm2,1337.0)" -- /usr/lib/libreoffice/program/soffice.bin --calc
after some time, libreoffice calc will start. If we try to perform an arithmetic operation in a cell, we will obtain always 1337 as result.
