radare2/libr/core/cmd_print.c
2019-02-26 17:04:30 +01:00

6402 lines
177 KiB
C

/* radare - LGPL - Copyright 2009-2019 - pancake */
#include "r_asm.h"
#include "r_core.h"
#include "r_config.h"
#include "r_util.h"
#include "r_types.h"
#include <limits.h>
#define R_CORE_MAX_DISASM (1024 * 1024 * 8)
#define PF_USAGE_STR "pf[.k[.f[=v]]|[v]]|[n]|[0|cnt][fmt] [a0 a1 ...]"
static const char *help_msg_pa[] = {
"Usage: pa[edD]", "[asm|hex]", "print (dis)assembled",
"pa", " [assembly]", "print hexpairs of the given assembly expression",
"paD", " [hexpairs]", "print assembly expression from hexpairs and show hexpairs",
"pad", " [hexpairs]", "print assembly expression from hexpairs",
"pade", " [hexpairs]", "print ESIL expression from hexpairs",
"pae", " [assembly]", "print ESIL expression of the given assembly expression",
NULL
};
static const char *help_msg_pdf[] = {
"Usage: pdf[bf]", "", "disassemble function",
"pdf", "", "disassemble function",
"pdfs", "", "disassemble function summary",
NULL
};
static const char *help_msg_p6[] = {
"Usage: p6[de]", "[len]", "base64 decoding/encoding",
"p6d", "[len]", "decode base64",
"p6e", "[len]", "encode base64",
NULL
};
static const char *help_msg_pF[] = {
"Usage: pF[apd]", "[len]", "parse ASN1, PKCS, X509, DER",
"pFa", "[len]", "decode ASN1 from current block",
"pFaq", "[len]", "decode ASN1 from current block (quiet output)",
"pFo", "[len]", "decode ASN1 OID",
"pFp", "[len]", "decode PKCS7",
"pFx", "[len]", "Same with X509",
NULL
};
static const char* help_msg_pr[] = {
"Usage: pr[glx]", "[size]", "print N raw bytes",
"prc", "", "print bytes as colors in palette",
"prl", "", "print raw with lines offsets",
"prx", "", "printable chars with real offset (hyew)",
"prg", "[?]", "print raw GUNZIPped block",
"prz", "", "print raw zero terminated string",
NULL
};
static const char *help_msg_prg[] = {
"Usage: prg[io]", "", "print raw GUNZIPped block",
"prg", "", "print gunzipped data of current block",
"prgi", "", "show consumed bytes when inflating",
"prgo", "", "show output bytes after inflating",
NULL
};
static const char *help_msg_amper[] = {
"Usage:", "&[-|<cmd>]", "Manage tasks (WARNING: Experimental. Use with caution!)",
"&", " <cmd>", "run <cmd> in a new background task",
"&t", " <cmd>", "run <cmd> in a new transient background task (auto-delete when it is finished)",
"&", "", "list all tasks",
"&j", "", "list all tasks (in JSON)",
"&=", " 3", "show output of task 3",
"&b", " 3", "break task 3",
"&-", " 1", "delete task #1 or schedule for deletion when it is finished",
"&", "-*", "delete all done tasks",
"&?", "", "show this help",
"&&", " 3", "wait until task 3 is finished",
"&&", "", "wait until all tasks are finished",
NULL
};
static const char *help_msg_at[] = {
"Usage: [.][#]<cmd>[*] [`cmd`] [@ addr] [~grep] [|syscmd] [>[>]file]", "", "",
"0", "", "alias for 's 0'",
"0x", "addr", "alias for 's 0x..'",
"#", "cmd", "if # is a number repeat the command # times",
"/*", "", "start multiline comment",
"*/", "", "end multiline comment",
".", "cmd", "execute output of command as r2 script",
".:", "8080", "wait for commands on port 8080",
".!", "rabin2 -re $FILE", "run command output as r2 script",
"*", "", "output of command in r2 script format (CC*)",
"j", "", "output of command in JSON format (pdj)",
"~", "?", "count number of lines (like wc -l)",
"~", "??", "show internal grep help",
"~", "..", "internal less",
"~", "{}", "json indent",
"~", "{}..", "json indent and less",
"~", "word", "grep for lines matching word",
"~", "!word", "grep for lines NOT matching word",
"~", "word[2]", "grep 3rd column of lines matching word",
"~", "word:3[0]", "grep 1st column from the 4th line matching word",
"@", " 0x1024", "temporary seek to this address (sym.main+3)",
"@", " [addr]!blocksize", "temporary set a new blocksize",
"@..", "addr", "temporary partial address seek (see s..)",
"@!", "blocksize", "temporary change the block size (p8@3!3)",
"@(", "from to)", "temporary set from and to for commands supporting ranges",
"@a:", "arch[:bits]", "temporary set arch and bits",
"@b:", "bits", "temporary set asm.bits",
"@B:", "nth", "temporary seek to nth instruction in current bb (negative numbers too)",
"@e:", "k=v,k=v", "temporary change eval vars",
"@f:", "file", "temporary replace block with file contents",
"@F:", "flagspace", "temporary change flag space",
"@i:", "nth.op", "temporary seek to the Nth relative instruction",
"@k:", "k", "temporary seek at value of sdb key `k`",
"@o:", "fd", "temporary switch to another fd",
"@r:", "reg", "tmp seek to reg value (f.ex pd@r:PC)",
"@s:", "string", "same as above but from a string",
"@x:", "909192", "from hex pairs string",
"@@=", "1 2 3", "run the previous command at offsets 1, 2 and 3",
"@@", " hit*", "run the command on every flag matching 'hit*'",
"@@?", "[ktfb..]", "show help for the iterator operator",
"@@@", " [type]", "run a command on every [type] (see @@@? for help)",
">", "file", "pipe output of command to file",
">>", "file", "append to file",
"H>", "file", "pipe output of command to file in HTML",
"H>>", "file", "append to file with the output of command in HTML",
"`", "pdi~push:0[0]`", "replace output of command inside the line",
"|", "cmd", "pipe output to command (pd|less) (.dr*)",
NULL
};
static const char *help_msg_at_at[] = {
"@@", "", " # foreach iterator command:",
"x", " @@ sym.*", "run 'x' over all flags matching 'sym.' in current flagspace",
"x", " @@dbt[abs]", "run 'x' command on every backtrace address, bp or sp",
"x", " @@.file", "run 'x' over the offsets specified in the file (one offset per line)",
"x", " @@=off1 off2 ..", "manual list of offsets",
"x", " @@/x 9090", "temporary set cmd.hit to run a command on each search result",
"x", " @@k sdbquery", "run 'x' on all offsets returned by that sdbquery",
"x", " @@t", "run 'x' on all threads (see dp)",
"x", " @@b", "run 'x' on all basic blocks of current function (see afb)",
"x", " @@i", "run 'x' on all instructions of the current function (see pdr)",
"x", " @@iS", "run 'x' on all sections adjusting blocksize",
"x", " @@f", "run 'x' on all functions (see aflq)",
"x", " @@f:write", "run 'x' on all functions matching write in the name",
"x", " @@s:from to step", "run 'x' on all offsets from, to incrementing by step",
"x", " @@c:cmd", "the same as @@=`` without the backticks",
"x", " @@=`pdf~call[0]`", "run 'x' at every call offset of the current function",
// TODO: Add @@k sdb-query-expression-here
NULL
};
static const char *help_msg_at_at_at[] = {
"@@@", "", " # foreach offset+size iterator command:",
"x", " @@@i", "imports",
"x", " @@@s", "symbols",
"x", " @@@S", "sections",
"x", " @@@f", "flags",
"x", " @@@F", "functions",
"x", " @@@t", "threads",
"x", " @@@r", "regs",
// TODO: Add @@k sdb-query-expression-here
NULL
};
static const char *help_msg_p[] = {
"Usage:", "p[=68abcdDfiImrstuxz] [arg|len] [@addr]", "",
"p-", "[?][jh] [mode]", "bar|json|histogram blocks (mode: e?search.in)",
"p=", "[?][bep] [N] [L] [b]", "show entropy/printable chars/chars bars",
"p2", " [len]", "8x8 2bpp-tiles",
"p3", " [file]", "print stereogram (3D)",
"p6", "[de] [len]", "base64 decode/encode",
"p8", "[?][j] [len]", "8bit hexpair list of bytes",
"pa", "[edD] [arg]", "pa:assemble pa[dD]:disasm or pae: esil from hex",
"pA", "[n_ops]", "show n_ops address and type",
"p", "[b|B|xb] [len] ([S])", "bindump N bits skipping S bytes",
"pb", "[?] [n]", "bitstream of N bits",
"pB", "[?] [n]", "bitstream of N bytes",
"pc", "[?][p] [len]", "output C (or python) format",
"pC", "[aAcdDxw] [rows]", "print disassembly in columns (see hex.cols and pdi)",
"pd", "[?] [sz] [a] [b]", "disassemble N opcodes (pd) or N bytes (pD)",
"pf", "[?][.nam] [fmt]", "print formatted data (pf.name, pf.name $<expr>)",
"pF", "[?][apx]", "print asn1, pkcs7 or x509",
"pg", "[?][x y w h] [cmd]", "create new visual gadget or print it (see pg? for details)",
"ph", "[?][=|hash] ([len])", "calculate hash for a block",
"pj", "[?] [len]", "print as indented JSON",
"p", "[iI][df] [len]", "print N ops/bytes (f=func) (see pi? and pdi)",
"p", "[kK] [len]", "print key in randomart (K is for mosaic)",
"pm", "[?] [magic]", "print libmagic data (see pm? and /m?)",
"pq", "[?][iz] [len]", "print QR code with the first Nbytes",
"pr", "[?][glx] [len]", "print N raw bytes (in lines or hexblocks, 'g'unzip)",
"ps", "[?][pwz] [len]", "print pascal/wide/zero-terminated strings",
"pt", "[?][dn] [len]", "print different timestamps",
"pu", "[?][w] [len]", "print N url encoded bytes (w=wide)",
"pv", "[?][jh] [mode]", "show variable/pointer/value in memory",
"pwd", "", "display current working directory",
"px", "[?][owq] [len]", "hexdump of N bytes (o=octal, w=32bit, q=64bit)",
"pz", "[?] [len]", "print zoom view (see pz? for help)",
NULL
};
static const char *help_msg_pxd[] = {
"Usage:", "pxd[1248] ([len])", "show decimal byte/short/word/dword dumps",
"pxd", "", "show decimal hexdumps",
"pxd2", "", "show shorts hexdump",
"pxd4", "", "show dword hexdump (int)",
"pxd8", "", "show qword hexdump (int)",
NULL
};
static const char *help_msg_p_equal[] = {
"Usage:", "p=[=bep?][qj] [N] ([len]) ([offset]) ", "show entropy/printable chars/chars bars",
"e ", "zoom.in", "specify range for zoom",
"p=", "", "print bytes of current block in bars",
"p==", "[..]", "same subcommands as p=, using column bars instead of rows",
"p=", "2", "short (signed int16) bars, good for waves",
"p=", "b", "same as above",
"p=", "c", "print number of calls per block",
"p=", "d", "print min/max/number of unique bytes in block",
"p=", "e", "print entropy for each filesize/blocksize",
"p=", "F", "print number of 0xFF bytes for each filesize/blocksize",
"p=", "i", "print number of invalid instructions per block",
"p=", "j", "print number of jumps and conditional jumps in block",
"p=", "m", "print number of flags and marks in block",
"p=", "p", "print number of printable bytes for each filesize/blocksize",
"p=", "s", "print number of syscall and priviledged instructions",
"p=", "z", "print number of chars in strings in block",
"p=", "0", "print number of 0x00 bytes for each filesize/blocksize",
NULL
};
static const char *help_msg_pj[] = {
"Usage:", "pj[..] [size]", "",
"pj", "", "print current block as indented JSON",
"pj.", "", "print as indented JSON from 0 to the current offset",
"pj..", "", "print JSON path from 0 to the current offset",
NULL
};
static const char *help_msg_p_minus[] = {
"Usage:", "p-[hj] [nblocks] ", "bar|json|histogram blocks",
"p-", "", "show ascii-art bar of metadata in file boundaries",
"p-h", "", "show histogram analysis of metadata per block",
"p-j", "", "show json format",
NULL
};
static const char *help_msg_pc[] = {
"Usage:", "pc", " # Print in code",
"pc", "", "C",
"pc*", "", "print 'wx' r2 commands",
"pca", "", "GAS .byte blob",
"pcA", "", ".bytes with instructions in comments",
"pcd", "", "C dwords (8 byte)",
"pch", "", "C half-words (2 byte)",
"pcj", "", "json",
"pcJ", "", "javascript",
"pcp", "", "python",
"pcs", "", "string",
"pcS", "", "shellscript that reconstructs the bin",
"pcw", "", "C words (4 byte)",
NULL
};
static const char *help_msg_pd[] = {
"Usage:", "p[dD][ajbrfils] [sz] [arch] [bits]", " # Print Disassembly",
"NOTE: ", "len", "parameter can be negative",
"NOTE: ", "", "Pressing ENTER on empty command will repeat last print command in next page",
"pd", " N", "disassemble N instructions",
"pd", " -N", "disassemble N instructions backward",
"pd--", "[n]", "context disassembly of N instructions",
"pD", " N", "disassemble N bytes",
"pda", "", "disassemble all possible opcodes (byte per byte)",
"pdb", "", "disassemble basic block",
"pdc", "", "pseudo disassembler output in C-like syntax",
"pdC", "", "show comments found in N instructions",
"pdf", "", "disassemble function",
"pdi", "", "like 'pi', with offset and bytes",
"pdj", "", "disassemble to json",
"pdJ", "", "formatted disassembly like pd as json",
"pdk", "", "disassemble all methods of a class",
"pdl", "", "show instruction sizes",
"pdp", "", "disassemble by following pointers to read ropchains",
"pdr", "", "recursive disassemble across the function graph",
"pdr.", "", "recursive disassemble across the function graph (from current basic block)",
"pdR", "", "recursive disassemble block size bytes without analyzing functions",
"pds", "[?]", "disassemble summary (strings, calls, jumps, refs) (see pdsf and pdfs)",
"pdt", "", "disassemble the debugger traces (see atd)",
NULL
};
static const char *help_msg_pf[] = {
"pf:", PF_USAGE_STR, "",
"Commands:", "", "",
"pf", "?", "Show this help",
"pf", "??", "Format characters",
"pf", "???", "pf usage examples",
"pf", " fmt", "Show data using the given format-string. See 'pf\?\?' and 'pf\?\?\?'.",
"pf.", "fmt_name", "Show data using named format",
"pf.", "fmt_name.field_name", "Show specific data field using named format",
"pfj ", "fmt_name|fmt", "Show data using (named) format in JSON",
"pf* ", "fmt_name|fmt", "Show data using (named) format as r2 flag create commands",
"pfd.", "fmt_name", "Show data using named format as graphviz commands",
"pf.", "name [0|cnt]fmt", "Define a new named format",
"pf.", "", "List all format definitions",
"pf?", "fmt_name", "Show the definition of a named format",
"pfo", "", "List all format definition files (fdf)",
"pfo", " fdf_name", "Load a Format Definition File (fdf)",
"pfq", " fmt ...", "Quiet print format (do now show address)",
"pf.", "fmt_name.field_name=33", "Set new value for the specified field in named format",
"pfv.", "fmt_name[.field]", "Print value(s) only for named format. Useful for one-liners",
"pfs", "[.fmt_name| fmt]", "Print the size of (named) format in bytes",
NULL
};
static const char *help_detail_pf[] = {
"pf:", PF_USAGE_STR, "",
"Format:", "", "",
" ", "b", "byte (unsigned)",
" ", "B", "resolve enum bitfield (see t?)",
" ", "c", "char (signed byte)",
" ", "C", "byte in decimal",
" ", "d", "0xHEX value (4 bytes) (see 'i' and 'x')",
" ", "D", "disassemble one opcode",
" ", "e", "temporally swap endian",
" ", "E", "resolve enum name (see t?)",
" ", "f", "float value (4 bytes)",
" ", "F", "double value (8 bytes)",
" ", "i", "signed integer value (4 bytes) (see 'd' and 'x')",
" ", "n", "next char specifies size of signed value (1, 2, 4 or 8 byte(s))",
" ", "N", "next char specifies size of unsigned value (1, 2, 4 or 8 byte(s))",
" ", "o", "octal value (4 byte)",
" ", "p", "pointer reference (2, 4 or 8 bytes)",
" ", "q", "quadword (8 bytes)",
" ", "r", "CPU register `pf r (eax)plop`",
" ", "s", "32bit pointer to string (4 bytes)",
" ", "S", "64bit pointer to string (8 bytes)",
" ", "t", "UNIX timestamp (4 bytes)",
" ", "T", "show Ten first bytes of buffer",
" ", "u", "uleb128 (variable length)",
" ", "w", "word (2 bytes unsigned short in hex)",
" ", "x", "0xHEX value and flag (fd @ addr) (see 'd' and 'i')",
" ", "X", "show formatted hexpairs",
" ", "z", "null terminated string",
" ", "Z", "null terminated wide string",
" ", "?", "data structure `pf ? (struct_name)example_name`",
" ", "*", "next char is pointer (honors asm.bits)",
" ", "+", "toggle show flags for each offset",
" ", ":", "skip 4 bytes",
" ", ".", "skip 1 byte",
" ", ";", "rewind 4 bytes",
" ", ",", "rewind 1 byte",
NULL
};
static const char *help_detail2_pf[] = {
"pf:", PF_USAGE_STR, "",
"Examples:", "", "",
"pf", " 3xi foo bar", "3-array of struct, each with named fields: 'foo' as hex, and 'bar' as int",
"pf", " B (BitFldType)arg_name`", "bitfield type",
"pf", " E (EnumType)arg_name`", "enum type",
"pf.", "obj xxdz prev next size name", "Define the obj format as xxdz",
"pf", " obj=xxdz prev next size name", "Same as above",
"pf", " *z*i*w nb name blob", "Print the pointers with given labels",
"pf", " iwq foo bar troll", "Print the iwq format with foo, bar, troll as the respective names for the fields",
"pf", " 0iwq foo bar troll", "Same as above, but considered as a union (all fields at offset 0)",
"pf.", "plop ? (troll)mystruct", "Use structure troll previously defined",
"pfj.", "plop @ 0x14", "Apply format object at the given offset",
"pf", " 10xiz pointer length string", "Print a size 10 array of the xiz struct with its field names",
"pf", " 5sqw string quad word", "Print an array with sqw struct along with its field names",
"pf", " {integer}? (bifc)", "Print integer times the following format (bifc)",
"pf", " [4]w[7]i", "Print an array of 4 words and then an array of 7 integers",
"pf", " ic...?i foo bar \"(pf xw yo foo)troll\" yo", "Print nested anonymous structures",
"pf", " ;..x", "Print value located 6 bytes from current offset",
"pf", " [10]z[3]i[10]Zb", "Print an fixed size str, widechar, and var",
"pfj", " +F @ 0x14","Print the content at given offset with flag",
"pf", " n2", "print signed short (2 bytes) value. Use N insted of n for printing unsigned values",
"pf", " [2]? (plop)structname @ 0", "Prints an array of structs",
"pf", " eqew bigWord beef", "Swap endianess and print with given labels",
"pf", ".foo rr (eax)reg1 (eip)reg2", "Create object referencing to register values ",
"pf", " tt troll plop", "print time stamps with labels troll and plop",
NULL
};
static const char *help_msg_pi[] = {
"Usage:", "pi[bdefrj] [num]", "",
"pia", "", "print all possible opcodes (byte per byte)",
"pib", "", "print instructions of basic block",
"pid", "", "alias for pdi",
"pie", "", "print offset + esil expression",
"pif", "[?]", "print instructions of function",
"pij", "", "print N instructions in JSON",
"pir", "", "like 'pdr' but with 'pI' output",
NULL
};
static const char *help_msg_pif[] = {
"Usage:", "pif[cj]", "",
"pif?", "", "print this help message",
"pifc", "", "print all calls from this function",
"pifcj", "", "print all calls from this function in JSON format",
"pifj", "", "print instructions of function in JSON format",
};
static const char *help_msg_ps[] = {
"Usage:", "ps[zpw+] [N]", "Print String",
"ps", "", "print string",
"psb", "", "print strings in current block",
"psi", "", "print string inside curseek",
"psj", "", "print string in JSON format",
"psp", "", "print pascal string",
"pss", "", "print string in screen (wrap width)",
"psu", "", "print utf16 unicode (json)",
"psw", "", "print 16bit wide string",
"psW", "", "print 32bit wide string",
"psx", "", "show string with escaped chars",
"psz", "", "print zero-terminated string",
"ps+", "", "print libc++ std::string (same-endian, ascii, zero-terminated)",
NULL
};
static const char *help_msg_pt[] = {
"Usage: pt", "[dn]", "print timestamps",
"pt.", "", "print current time",
"pt", "", "print UNIX time (32 bit `cfg.bigendian`) Since January 1, 1970",
"ptd", "", "print DOS time (32 bit `cfg.bigendian`) Since January 1, 1980",
"pth", "", "print HFS time (32 bit `cfg.bigendian`) Since January 1, 1904",
"ptn", "", "print NTFS time (64 bit `cfg.bigendian`) Since January 1, 1601",
NULL
};
static const char *help_msg_pv[] = {
"Usage: pv[j][1,2,4,8,z]", "", "",
"pv", "", "print bytes based on asm.bits",
"pv1", "", "print 1 byte in memory",
"pv2", "", "print 2 bytes in memory",
"pv4", "", "print 4 bytes in memory",
"pv8", "", "print 8 bytes in memory",
"pvz", "", "print value as string (alias for ps)",
NULL
};
static const char *help_msg_px[] = {
"Usage:", "px[0afoswqWqQ][f]", " # Print heXadecimal",
"px", "", "show hexdump",
"px/", "", "same as x/ in gdb (help x)",
"px0", "", "8bit hexpair list of bytes until zero byte",
"pxa", "", "show annotated hexdump",
"pxA", "[?]", "show op analysis color map",
"pxb", "", "dump bits in hexdump form",
"pxc", "", "show hexdump with comments",
"pxd", "[?1248]", "signed integer dump (1 byte, 2 and 4)",
"pxe", "", "emoji hexdump! :)",
"pxf", "", "show hexdump of current function",
"pxh", "", "show hexadecimal half-words dump (16bit)",
"pxH", "", "same as above, but one per line",
"pxi", "", "HexII compact binary representation",
"pxl", "", "display N lines (rows) of hexdump",
"pxo", "", "show octal dump",
"pxq", "", "show hexadecimal quad-words dump (64bit)",
"pxQ", "[q]", "same as above, but one per line",
"pxr", "[j]", "show words with references to flags and code (q=quiet)",
"pxs", "", "show hexadecimal in sparse mode",
"pxt", "[*.] [origin]", "show delta pointer table in r2 commands",
"pxw", "", "show hexadecimal words dump (32bit)",
"pxW", "[q]", "same as above, but one per line (q=quiet)",
"pxx", "", "show N bytes of hex-less hexdump",
"pxX", "", "show N words of hex-less hexdump",
NULL
};
const char *help_msg_pz[] = {
"Usage: pz [len]", "", "print zoomed blocks (filesize/N)",
"e ", "zoom.maxsz", "max size of block",
"e ", "zoom.from", "start address",
"e ", "zoom.to", "end address",
"e ", "zoom.byte", "specify how to calculate each byte",
"pzp", "", "number of printable chars",
"pzf", "", "count of flags in block",
"pzs", "", "strings in range",
"pz0", "", "number of bytes with value '0'",
"pzF", "", "number of bytes with value 0xFF",
"pze", "", "calculate entropy and expand to 0-255 range",
"pzh", "", "head (first byte value); This is the default mode",
// "WARNING: On big files, use 'zoom.byte=h' or restrict ranges\n");
NULL
};
const char *help_msg_pxA[] = {
"Usage: pxA [len]", "", "show op analysis color map",
"$$", "", "int/swi/trap/new\n",
"+-*/", "", "math ops\n",
"->", "", "push\n",
"..", "", "nop\n",
"<-", "", "pop\n",
"<<>>", "", "shift ops\n",
"==", "", "cmp/test\n",
"XX", "", "invalid\n",
"_C", "", "call\n",
"_J", "", "jump\n",
"_R", "", "ret\n",
"cJ", "", "conditional jump\n",
"io", "", "in/out ops\n",
"mv", "", "move,lea,li\n",
"|&^", "", "bin ops\n",
NULL
};
static const ut32 colormap[256] = {
0x000000, 0x560000, 0x640000, 0x750000, 0x870000, 0x9b0000, 0xb00000, 0xc60000, 0xdd0000, 0xf50000, 0xff0f0f, 0xff2828, 0xff4343, 0xff5e5e, 0xff7979, 0xfe9595,
0x4c1600, 0x561900, 0x641e00, 0x752300, 0x872800, 0x9b2e00, 0xb03400, 0xc63b00, 0xdd4200, 0xf54900, 0xff570f, 0xff6928, 0xff7b43, 0xff8e5e, 0xffa179, 0xfeb595,
0x4c3900, 0x564000, 0x644b00, 0x755700, 0x876500, 0x9b7400, 0xb08400, 0xc69400, 0xdda600, 0xf5b800, 0xffc30f, 0xffc928, 0xffd043, 0xffd65e, 0xffdd79, 0xfee495,
0x4c4c00, 0x565600, 0x646400, 0x757500, 0x878700, 0x9b9b00, 0xb0b000, 0xc6c600, 0xdddd00, 0xf5f500, 0xffff0f, 0xffff28, 0xffff43, 0xffff5e, 0xffff79, 0xfffe95,
0x324c00, 0x395600, 0x426400, 0x4e7500, 0x5a8700, 0x679b00, 0x75b000, 0x84c600, 0x93dd00, 0xa3f500, 0xafff0f, 0xb7ff28, 0xc0ff43, 0xc9ff5e, 0xd2ff79, 0xdbfe95,
0x1f4c00, 0x235600, 0x296400, 0x307500, 0x388700, 0x409b00, 0x49b000, 0x52c600, 0x5cdd00, 0x66f500, 0x73ff0f, 0x82ff28, 0x91ff43, 0xa1ff5e, 0xb1ff79, 0xc1fe95,
0x004c00, 0x005600, 0x006400, 0x007500, 0x008700, 0x009b00, 0x00b000, 0x00c600, 0x00dd00, 0x00f500, 0x0fff0f, 0x28ff28, 0x43ff43, 0x5eff5e, 0x79ff79, 0x95fe95,
0x004c19, 0x00561c, 0x006421, 0x007527, 0x00872d, 0x009b33, 0x00b03a, 0x00c642, 0x00dd49, 0x00f551, 0x0fff5f, 0x28ff70, 0x43ff81, 0x5eff93, 0x79ffa6, 0x95feb8,
0x004c4c, 0x005656, 0x006464, 0x007575, 0x008787, 0x009b9b, 0x00b0b0, 0x00c6c6, 0x00dddd, 0x00f5f5, 0x0ffffe, 0x28fffe, 0x43fffe, 0x5efffe, 0x79ffff, 0x95fffe,
0x00394c, 0x004056, 0x004b64, 0x005775, 0x006587, 0x00749b, 0x0084b0, 0x0094c6, 0x00a6dd, 0x00b8f5, 0x0fc3ff, 0x28c9ff, 0x43d0ff, 0x5ed6ff, 0x79ddff, 0x95e4fe,
0x00264c, 0x002b56, 0x003264, 0x003a75, 0x004387, 0x004d9b, 0x0058b0, 0x0063c6, 0x006edd, 0x007af5, 0x0f87ff, 0x2893ff, 0x43a1ff, 0x5eaeff, 0x79bcff, 0x95cafe,
0x00134c, 0x001556, 0x001964, 0x001d75, 0x002187, 0x00269b, 0x002cb0, 0x0031c6, 0x0037dd, 0x003df5, 0x0f4bff, 0x285eff, 0x4372ff, 0x5e86ff, 0x799aff, 0x95b0fe,
0x19004c, 0x1c0056, 0x210064, 0x270075, 0x2d0087, 0x33009b, 0x3a00b0, 0x4200c6, 0x4900dd, 0x5100f5, 0x5f0fff, 0x7028ff, 0x8143ff, 0x935eff, 0xa679ff, 0xb895fe,
0x33004c, 0x390056, 0x420064, 0x4e0075, 0x5a0087, 0x67009b, 0x7500b0, 0x8400c6, 0x9300dd, 0xa300f5, 0xaf0fff, 0xb728ff, 0xc043ff, 0xc95eff, 0xd279ff, 0xdb95fe,
0x4c004c, 0x560056, 0x640064, 0x750075, 0x870087, 0x9b009b, 0xb000b0, 0xc600c6, 0xdd00dd, 0xf500f5, 0xfe0fff, 0xfe28ff, 0xfe43ff, 0xfe5eff, 0xfe79ff, 0xfe95fe,
0x4c0032, 0x560039, 0x640042, 0x75004e, 0x87005a, 0x9b0067, 0xb00075, 0xc60084, 0xdd0093, 0xf500a3, 0xff0faf, 0xff28b7, 0xff43c0, 0xff5ec9, 0xff79d2, 0xffffff,
};
static void cmd_print_init(RCore *core) {
DEFINE_CMD_DESCRIPTOR_SPECIAL (core, &, amper);
DEFINE_CMD_DESCRIPTOR_SPECIAL (core, @, at);
DEFINE_CMD_DESCRIPTOR_SPECIAL (core, @@, at_at);
DEFINE_CMD_DESCRIPTOR (core, p);
DEFINE_CMD_DESCRIPTOR_SPECIAL (core, p=, p_equal);
DEFINE_CMD_DESCRIPTOR_SPECIAL (core, p-, p_minus);
DEFINE_CMD_DESCRIPTOR (core, pc);
DEFINE_CMD_DESCRIPTOR (core, pd);
DEFINE_CMD_DESCRIPTOR_WITH_DETAIL2 (core, pf);
DEFINE_CMD_DESCRIPTOR (core, pi);
DEFINE_CMD_DESCRIPTOR (core, ps);
DEFINE_CMD_DESCRIPTOR (core, pt);
DEFINE_CMD_DESCRIPTOR (core, pv);
DEFINE_CMD_DESCRIPTOR (core, px);
DEFINE_CMD_DESCRIPTOR (core, pz);
}
// colordump
static void cmd_prc (RCore *core, const ut8* block, int len) {
const char *chars = " .,:;!O@#";
bool square = true; //false;
int i, j;
char ch, ch2, *color;
int cols = r_config_get_i (core->config, "hex.pcols") + core->print->cols; // * 3.5;
bool show_color = r_config_get_i (core->config, "scr.color");
bool show_flags = r_config_get_i (core->config, "asm.flags");
bool show_cursor = core->print->cur_enabled;
if (cols < 1) {
cols = 1;
}
cols /= 2;
for (i = 0; i < len; i += cols) {
r_print_addr (core->print, core->offset + i);
for (j = i; j < i + cols; j ++) {
if (j >= len) {
break;
}
if (show_color) {
char *str = r_str_newf ("rgb:fff rgb:%06x", colormap[block[j]]);
color = r_cons_pal_parse (str, NULL);
free (str);
if (show_cursor && core->print->cur == j) {
ch = '_';
} else {
ch = ' ';
}
} else {
color = strdup ("");
if (show_cursor && core->print->cur == j) {
ch = '_';
} else {
const int idx = ((float)block[j] / 255) * (strlen (chars) - 1);
ch = chars[idx];
}
}
if (square) {
if (show_flags) {
RFlagItem *fi = r_flag_get_i (core->flags, core->offset + j);
if (fi) {
ch = fi->name[0];
ch2 = fi->name[1];
} else {
ch2 = ch;
}
} else {
ch2 = ch;
}
r_cons_printf ("%s%c%c", color, ch, ch2);
} else {
r_cons_printf ("%s%c", color, ch);
}
free (color);
}
r_cons_printf (Color_RESET);
r_cons_newline ();
}
}
static void cmd_pCd(RCore *core, const char *input) {
int h, w = r_cons_get_size (&h);
int colwidth = r_config_get_i (core->config, "hex.cols") * 2.5;
if (colwidth < 1) {
colwidth = 16;
}
int i, columns = w / colwidth;
int rows = h - 2;
int obsz = core->blocksize;
int user_rows = r_num_math (core->num, input);
bool asm_minicols = r_config_get_i (core->config, "asm.minicols");
char *o_ao = strdup (r_config_get (core->config, "asm.offset"));
char *o_ab = strdup (r_config_get (core->config, "asm.bytes"));
if (asm_minicols) {
r_config_set (core->config, "asm.offset", "false");
// r_config_set (core->config, "asm.bytes", "false");
}
r_config_set (core->config, "asm.bytes", "false");
if (user_rows > 0) {
rows = user_rows + 1;
}
r_cons_push ();
RConsCanvas *c = r_cons_canvas_new (w, rows);
ut64 osek = core->offset;
c->color = r_config_get_i (core->config, "scr.color");
r_core_block_size (core, rows * 32);
for (i = 0; i < columns; i++) {
(void) r_cons_canvas_gotoxy (c, i * (w / columns), 0);
char *cmd = r_str_newf ("pid %d @i:%d", rows, rows * i);
char *dis = r_core_cmd_str (core, cmd);
r_cons_canvas_write (c, dis);
free (cmd);
free (dis);
}
r_core_block_size (core, obsz);
r_core_seek (core, osek, 1);
r_cons_pop ();
r_cons_canvas_print (c);
r_cons_canvas_free (c);
if (asm_minicols) {
r_config_set (core->config, "asm.offset", o_ao);
r_config_set (core->config, "asm.bytes", o_ab);
}
r_config_set (core->config, "asm.bytes", o_ab);
free (o_ao);
free (o_ab);
}
static void findMethodBounds(RList *methods, ut64 *min, ut64 *max) {
RBinSymbol *sym;
RListIter *iter;
ut64 at_min = UT64_MAX;
ut64 at_max = 0LL;
r_list_foreach (methods, iter, sym) {
if (sym->vaddr) {
if (sym->vaddr < at_min) {
at_min = sym->vaddr;
}
if (sym->vaddr + sym->size > at_max) {
at_max = sym->vaddr + sym->size;
}
}
}
*min = at_min;
*max = at_max;
}
static ut64 findClassBounds(RCore *core, const char *input, int *len) {
ut64 min = 0, max = 0;
RListIter *iter;
RBinClass *c;
RList *cs = r_bin_get_classes (core->bin);
if (input && *input) {
// resolve by name
r_list_foreach (cs, iter, c) {
if (!c || !c->name || !c->name[0]) {
continue;
}
findMethodBounds (c->methods, &min, &max);
if (len) {
*len = (max - min);
}
return min;
}
} else {
// resolve by core->offset
r_list_foreach (cs, iter, c) {
if (!c || !c->name || !c->name[0]) {
continue;
}
findMethodBounds (c->methods, &min, &max);
if (len) {
*len = (max - min);
}
return min;
}
}
return 0;
}
static void cmd_pCD(RCore *core, const char *input) {
int h, w = r_cons_get_size (&h);
int i;
int rows = h - 2;
int obsz = core->blocksize;
int user_rows = r_num_math (core->num, input);
bool asm_minicols = r_config_get_i (core->config, "asm.minicols");
char *o_ao = strdup (r_config_get (core->config, "asm.offset"));
char *o_ab = strdup (r_config_get (core->config, "asm.bytes"));
if (asm_minicols) {
r_config_set (core->config, "asm.offset", "false");
r_config_set (core->config, "asm.bytes", "false");
}
r_config_set (core->config, "asm.bytes", "false");
if (user_rows > 0) {
rows = user_rows + 1;
}
r_cons_push ();
RConsCanvas *c = r_cons_canvas_new (w, rows);
ut64 osek = core->offset;
c->color = r_config_get_i (core->config, "scr.color");
r_core_block_size (core, rows * 32);
char *cmd = NULL;
int columns = 2;
for (i = 0; i < columns; i++) {
switch (i) {
case 0:
(void) r_cons_canvas_gotoxy (c, 0, 0);
cmd = r_str_newf ("dr;?e;?e backtrace:;dbt");
break;
case 1:
(void) r_cons_canvas_gotoxy (c, 28, 0);
// cmd = r_str_newf ("pxw 128@r:SP;pd@r:PC");
cmd = r_str_newf ("pxq 128@r:SP;pd@ 0x%"PFMT64x, osek);
break;
}
char *dis = r_core_cmd_str (core, cmd);
r_cons_canvas_write (c, dis);
free (cmd);
free (dis);
}
r_core_block_size (core, obsz);
r_core_seek (core, osek, 1);
r_cons_pop ();
r_cons_canvas_print (c);
r_cons_canvas_free (c);
if (asm_minicols) {
r_config_set (core->config, "asm.offset", o_ao);
r_config_set (core->config, "asm.bytes", o_ab);
}
r_config_set (core->config, "asm.bytes", o_ab);
free (o_ao);
free (o_ab);
}
static void cmd_pCx(RCore *core, const char *input, const char *xcmd) {
int h, w = r_cons_get_size (&h);
int hex_cols = r_config_get_i (core->config, "hex.cols");
int colwidth = hex_cols * 5;
int i, columns = w / (colwidth * 0.9);
int rows = h - 2;
int user_rows = r_num_math (core->num, input);
r_config_set_i (core->config, "hex.cols", colwidth / 5);
if (user_rows > 0) {
rows = user_rows + 1;
}
RConsCanvas *c = r_cons_canvas_new (w, rows);
if (!c) {
eprintf ("Couldn't allocate a canvas with %d rows\n", rows);
goto err;
}
ut64 tsek = core->offset;
c->color = r_config_get_i (core->config, "scr.color");
int bsize = hex_cols * rows;
if (!strcmp (xcmd, "pxA")) {
bsize *= 12;
}
for (i = 0; i < columns; i++) {
(void) r_cons_canvas_gotoxy (c, i * (w / columns), 0);
char *cmd = r_str_newf ("%s %d @ %"PFMT64u, xcmd, bsize, tsek);
char *dis = r_core_cmd_str (core, cmd);
if (dis) {
r_cons_canvas_write (c, dis);
free (dis);
}
free (cmd);
tsek += bsize - 32;
}
r_cons_canvas_print (c);
r_cons_canvas_free (c);
err:
r_config_set_i (core->config, "hex.cols", hex_cols);
}
static char get_string_type(const ut8 *buf, ut64 len) {
ut64 needle = 0;
int rc, i;
char str_type = 0;
if (!buf) {
return '?';
}
while (needle < len) {
rc = r_utf8_decode (buf + needle, len - needle, NULL);
if (!rc) {
needle++;
continue;
}
if (needle + rc + 2 < len &&
buf[needle + rc + 0] == 0x00 &&
buf[needle + rc + 1] == 0x00 &&
buf[needle + rc + 2] == 0x00) {
str_type = 'w';
} else {
str_type = 'a';
}
for (rc = i = 0; needle < len; i += rc) {
RRune r;
if (str_type == 'w') {
if (needle + 1 < len) {
r = buf[needle + 1] << 8 | buf[needle];
rc = 2;
} else {
break;
}
} else {
rc = r_utf8_decode (buf + needle, len - needle, &r);
if (rc > 1) {
str_type = 'u';
}
}
/*Invalid sequence detected*/
if (!rc) {
needle++;
break;
}
needle += rc;
}
}
return str_type;
}
static void cmd_print_eq_dict(RCore *core, const ut8 *block, int bsz) {
int i;
int min = -1;
int max = 0;
int dict = 0;
int range = 0;
bool histogram[256] = {0};
for (i = 0; i < bsz; i++) {
histogram[block[i]] = true;
}
for (i = 0; i < 256; i++) {
if (histogram[i]) {
if (min == -1) {
min = i;
}
max = i;
dict++;
}
}
range = max - min;
r_cons_printf ("min: %d 0x%x\n", min, min);
r_cons_printf ("max: %d 0x%x\n", max, max);
r_cons_printf ("unique (count): %d 0x%x\n", dict, dict);
r_cons_printf ("range (max-min): %d 0x%x\n", range, range);
r_cons_printf ("size (of block): %d 0x%x\n", bsz, bsz);
}
R_API void r_core_set_asm_configs(RCore *core, char *arch, ut32 bits, int segoff) {
r_config_set (core->config, "asm.arch", arch);
r_config_set_i (core->config, "asm.bits", bits);
// XXX - this needs to be done here, because
// if arch == x86 and bits == 16, segoff automatically changes
r_config_set_i (core->config, "asm.segoff", segoff);
}
static void cmd_pDj(RCore *core, const char *arg) {
int bsize = r_num_math (core->num, arg);
if (bsize < 0) {
bsize = -bsize;
}
PJ *pj = pj_new ();
if (!pj) {
return;
}
pj_a (pj);
ut8 *buf = malloc (bsize);
if (buf) {
r_io_read_at (core->io, core->offset, buf, bsize);
r_core_print_disasm_json (core, core->offset, buf, bsize, 0, pj);
free (buf);
} else {
eprintf ("cannot allocate %d byte(s)\n", bsize);
}
pj_end (pj);
r_cons_printf ("%s", pj_string (pj));
pj_free (pj);
}
static void cmd_pdj(RCore *core, const char *arg, ut8* block) {
int nblines = r_num_math (core->num, arg);
PJ *pj = pj_new ();
if (!pj) {
return;
}
pj_a (pj);
r_core_print_disasm_json (core, core->offset, block, core->blocksize, nblines, pj);
pj_end (pj);
r_cons_printf ("%s\n", pj_string (pj));
pj_free (pj);
}
static void helpCmdTasks(RCore *core) {
// TODO: integrate with =h& and bg anal/string/searchs/..
r_core_cmd_help (core, help_msg_amper);
}
static void print_format_help_help_help_help(RCore *core) {
const char *help_msg[] = {
" STAHP IT!!!", "", "",
NULL
};
r_core_cmd_help (core, help_msg);
}
static void cmd_print_fromage(RCore *core, const char *input, const ut8* data, int size) {
switch (*input) {
case 'a':
{
asn1_setformat (input[1] != 'q');
RASN1Object *asn1 = r_asn1_create_object (data, size, data);
if (asn1) {
char *res = r_asn1_to_string (asn1, 0, NULL);
r_asn1_free_object (asn1);
if (res) {
r_cons_printf ("%s\n", res);
free (res);
}
} else {
eprintf ("Malformed object: did you supply enough data?\ntry to change the block size (see b?)\n");
}
}
break;
case 'x': // "pFx" x509
{
RX509Certificate* x509 = r_x509_parse_certificate (r_asn1_create_object (data, size, data));
if (x509) {
RStrBuf *sb = r_strbuf_new ("");
r_x509_certificate_dump (x509, NULL, sb);
char *res = r_strbuf_drain (sb);
if (res) {
r_cons_printf ("%s\n", res);
free (res);
}
r_x509_free_certificate (x509);
} else {
eprintf ("Malformed object: did you supply enough data?\ntry to change the block size (see b?)\n");
}
}
break;
case 'p': // "pFp"
{
RCMS *cms = r_pkcs7_parse_cms (data, size);
if (cms) {
char *res = r_pkcs7_cms_to_string (cms);
if (res) {
r_cons_printf ("%s\n", res);
free (res);
}
r_pkcs7_free_cms (cms);
} else {
eprintf ("Malformed object: did you supply enough data?\ntry to change the block size (see b?)\n");
}
}
break;
default:
case '?': // "pF?"
r_core_cmd_help (core, help_msg_pF);
break;
}
}
R_API void r_core_gadget_free (RCoreGadget *g) {
free (g->cmd);
free (g);
}
static const char *help_msg_pg[] = {
"Usage: pg[-]", "[asm|hex]", "print (dis)assembled",
"pg", " [x y w h cmd]", "add a new gadget",
"pg", "", "print them all",
"pg", "*", "print the gadgets as r2 commands",
"pg-", "*", "remove all the gadgets",
NULL
};
static void cmd_print_gadget(RCore *core, const char *_input) {
if (*_input == '?') { // "pg?"
r_core_cmd_help (core, help_msg_pg);
return;
}
if (*_input == '-') { // "pg-"
// TODO support selecting one
r_list_free (core->gadgets);
core->gadgets = r_list_newf ((RListFree)r_core_gadget_free);
} else if (*_input == '*') { // "pg*"
RCoreGadget *g;
RListIter *iter;
r_list_foreach (core->gadgets, iter, g) {
r_cons_printf ("\"pg %d %d %d %d %s\"\n", g->x, g->y, g->w, g->h, g->cmd);
}
} else if (*_input == 'b') { // "pgb"
eprintf ("TODO: Change gadget background color\n");
} else if (*_input == 'm') { // "pgm"
int nth = atoi (_input + 1);
RCoreGadget *g = r_list_get_n (core->gadgets, nth);
if (g) {
char *input = strdup (_input);
char *space = strchr (input, ' ');
if (space) {
space++;
} else {
space = "";
}
RList *args = r_str_split_list (space, " ");
char *x = r_list_pop_head (args);
char *y = r_list_pop_head (args);
char *w = r_list_pop_head (args);
char *h = r_list_pop_head (args);
if (x && y && w && h) {
g->x = r_num_math (core->num, x);
g->y = r_num_math (core->num, y);
g->w = r_num_math (core->num, w);
g->h = r_num_math (core->num, h);
}
r_list_free (args);
free (input);
}
} else if (*_input == ' ') { // "pg "
char *input = strdup (_input);
RList *args = r_str_split_list (input, " ");
char *x = r_list_pop_head (args);
char *y = r_list_pop_head (args);
char *w = r_list_pop_head (args);
char *h = r_list_pop_head (args);
if (x && y && w && h) {
int X = r_num_math (core->num, x);
int Y = r_num_math (core->num, y);
int W = r_num_math (core->num, w);
int H = r_num_math (core->num, h);
char *cmd = r_str_list_join (args, " ");
if (cmd) {
// eprintf ("%d %d %d %d (%s)\n", X, Y, W, H, cmd);
RCoreGadget *g = R_NEW0 (RCoreGadget);
g->x = X;
g->y = Y;
g->w = W;
g->h = H;
g->cmd = cmd;
r_list_append (core->gadgets, g);
}
}
r_list_free (args);
free (input);
} else if (!*_input) { // "pg"
RCoreGadget *g;
RListIter *iter;
r_list_foreach (core->gadgets, iter, g) {
char *res = r_core_cmd_str (core, g->cmd);
if (res) {
r_cons_strcat_at (res, g->x, g->y, g->w, g->h);
free (res);
}
}
} else {
r_core_cmd_help (core, help_msg_pg);
}
}
static void cmd_print_format(RCore *core, const char *_input, const ut8* block, int len) {
char *input = NULL;
int mode = R_PRINT_MUSTSEE;
switch (_input[1]) {
case '*': // "pf*"
_input++;
mode = R_PRINT_SEEFLAGS;
break;
case 'q': // "pfq"
_input++;
mode = R_PRINT_QUIET | R_PRINT_MUSTSEE;
break;
case 'd': // "pfd"
_input++;
mode = R_PRINT_DOT;
break;
case 'j': // "pfj"
_input++;
mode = R_PRINT_JSON;
break;
case 'v': // "pfv"
_input++;
mode = R_PRINT_VALUE | R_PRINT_MUSTSEE;
break;
case 's': { // "pfs"
const char *val = NULL;
_input += 2;
if (*_input == '.') {
_input++;
val = sdb_get (core->print->formats, _input, NULL);
if (val) {
r_cons_printf ("%d\n", r_print_format_struct_size (val, core->print, mode, 0));
} else {
eprintf ("Struct %s not defined\nUsage: pfs.struct_name | pfs format\n", _input);
}
} else if (*_input == ' ') {
while (*_input == ' ' && *_input != '\0') {
_input++;
}
if (*_input) {
r_cons_printf ("%d\n", r_print_format_struct_size (_input, core->print, mode, 0));
} else {
eprintf ("Struct %s not defined\nUsage: pfs.struct_name | pfs format\n", _input);
}
} else {
eprintf ("Usage: pfs.struct_name | pfs format\n");
}
return;
}
case '?': // "pf?"
_input += 2;
if (*_input) {
if (*_input == '?') {
_input++;
if (_input && *_input == '?') {
_input++;
if (_input && *_input == '?') {
print_format_help_help_help_help (core);
} else {
r_core_cmd_help (core, help_detail2_pf);
}
} else {
r_core_cmd_help (core, help_detail_pf);
}
} else {
SdbListIter *iter;
Sdb *sht = core->print->formats;
SdbKv *kv;
SdbList *sdbls = sdb_foreach_list (sht, false);
ls_foreach (sdbls, iter, kv) {
r_cons_println (sdbkv_value (kv));
}
}
} else {
r_core_cmd_help (core, help_msg_pf);
}
return;
case 'o': // "pfo"
if (_input[2] == '?') {
eprintf ("|Usage: pfo [format-file]\n"
" " R_JOIN_3_PATHS ("~", R2_HOME_SDB_FORMAT, "") "\n"
" " R_JOIN_3_PATHS ("%s", R2_SDB_FORMAT, "") "\n",
r_sys_prefix (NULL));
} else if (_input[2] == ' ') {
char *home, *path, tmp[512];
snprintf (tmp, sizeof (tmp),
R_JOIN_2_PATHS (R2_HOME_SDB_FORMAT, "%s"), _input + 3);
home = r_str_home (tmp);
snprintf (tmp, sizeof (tmp), R_JOIN_2_PATHS (R2_SDB_FORMAT, "%s"), _input + 3);
path = r_str_r2_prefix (tmp);
if (!r_core_cmd_file (core, home) && !r_core_cmd_file (core, path)) {
if (!r_core_cmd_file (core, _input + 3)) {
eprintf ("ecf: cannot open colorscheme profile (%s)\n", path);
}
}
free (home);
free (path);
} else {
RList *files;
RListIter *iter;
const char *fn;
char *home = r_str_home (R2_HOME_SDB_FORMAT R_SYS_DIR);
if (home) {
files = r_sys_dir (home);
r_list_foreach (files, iter, fn) {
if (*fn && *fn != '.') {
r_cons_println (fn);
}
}
r_list_free (files);
free (home);
}
char *path = r_str_r2_prefix (R2_SDB_FORMAT R_SYS_DIR);
if (path) {
files = r_sys_dir (path);
r_list_foreach (files, iter, fn) {
if (*fn && *fn != '.') {
r_cons_println (fn);
}
}
r_list_free (files);
free (path);
}
}
free (input);
return;
} // switch
input = strdup (_input);
/* syntax aliasing bridge for 'pf foo=xxd' -> 'pf.foo xxd' */
if (input[1] == ' ') {
char *eq = strchr (input + 2, '=');
if (eq) {
input[1] = '.';
*eq = ' ';
}
}
int listFormats = 0;
if (input[1] == '.') {
listFormats = 1;
}
if (!strcmp (input, "*") && mode == R_PRINT_SEEFLAGS) {
listFormats = 1;
}
core->print->reg = core->dbg->reg;
core->print->get_register = r_reg_get;
core->print->get_register_value = r_reg_get_value;
int o_blocksize = core->blocksize;
if (listFormats) {
core->print->num = core->num;
/* print all stored format */
if (!input[1] || !input[2]) {
SdbListIter *iter;
SdbKv *kv;
SdbList *sdbls = sdb_foreach_list (core->print->formats, true);
ls_foreach (sdbls, iter, kv) {
r_cons_printf ("pf.%s %s\n", sdbkv_key (kv), sdbkv_value (kv));
}
/* delete a format */
} else if (input[1] && input[2] == '-') {
if (input[3] == '*') {
sdb_free (core->print->formats);
core->print->formats = sdb_new0 ();
} else {
sdb_unset (core->print->formats, input + 3, 0);
}
} else {
char *name = strdup (input + (input[1]? 2: 1));
char *space = strchr (name, ' ');
char *eq = strchr (name, '=');
char *dot = strchr (name, '.');
if (eq && !dot) {
*eq = ' ';
space = eq;
eq = NULL;
}
/* store a new format */
if (space && (!eq || space < eq)) {
// char *fields = NULL;
*space++ = 0;
// fields = strchr (space, ' ');
if (strchr (name, '.')) {// || (fields != NULL && strchr(fields, '.') != NULL)) // if anon struct, then field can have '.'
eprintf ("Struct or fields name can not contain dot symbol (.)\n");
} else {
sdb_set (core->print->formats, name, space, 0);
}
free (name);
free (input);
return;
}
if (!strchr (name, '.') &&
!sdb_get (core->print->formats, name, NULL)) {
eprintf ("Cannot find '%s' format.\n", name);
free (name);
free (input);
return;
}
char *delim = strchr (name, '.');
if (delim) {
int len = delim - name;
if (len > 0) {
name[len] = '\0';
}
}
/* Load format from name into fmt to get the size */
/* This make sure the whole structure will be printed */
const char *fmt = NULL;
fmt = sdb_get (core->print->formats, name, NULL);
if (fmt) {
int size = r_print_format_struct_size (fmt, core->print, mode, 0) + 10;
if (size > core->blocksize) {
r_core_block_size (core, size);
}
}
/* display a format */
if (dot) {
*dot++ = 0;
eq = strchr (dot, '=');
if (eq) { // Write mode (pf.field=value)
*eq++ = 0;
mode = R_PRINT_MUSTSET;
r_print_format (core->print, core->offset,
core->block, core->blocksize, name, mode, eq, dot);
} else {
r_print_format (core->print, core->offset,
core->block, core->blocksize, name, mode, NULL, dot);
}
} else {
r_print_format (core->print, core->offset,
core->block, core->blocksize, name, mode, NULL, NULL);
}
free (name);
}
} else {
/* This make sure the structure will be printed entirely */
char *fmt = input + 1;
while (*fmt && IS_WHITECHAR (*fmt)) {
fmt++;
}
int struct_sz = r_print_format_struct_size (fmt, core->print, mode, 0) + 10;
int size = R_MAX (core->blocksize, struct_sz);
ut8 *buf = calloc (1, size);
if (!buf) {
eprintf ("cannot allocate %d byte(s)\n", size);
goto stage_left;
}
if ((struct_sz > core->blocksize) && !core->fixedblock) {
r_core_block_size (core, struct_sz);
}
memcpy (buf, core->block, core->blocksize);
/* check if fmt is '\d+ \d+<...>', common mistake due to usage string*/
bool syntax_ok = true;
char *args = strdup (fmt);
if (!args) {
r_cons_printf ("Error: Mem Allocation.");
free (args);
goto stage_left;
}
const char *arg1 = strtok (args, " ");
if (arg1 && r_str_isnumber (arg1)) {
syntax_ok = false;
r_cons_printf ("Usage: pf [0|cnt][format-string]\n");
}
free (args);
if (syntax_ok) {
r_print_format (core->print, core->offset,
buf, size, fmt, mode, NULL, NULL);
}
free (buf);
}
stage_left:
free (input);
r_core_block_size (core, o_blocksize);
}
// > pxa
/* In this function, most of the buffers have 4 times
* the required length. This is because we supports colours,
* that are 4 chars long. */
#define append(x, y) { strcat (x, y); x += strlen (y); }
static void annotated_hexdump(RCore *core, const char *str, int len) {
const int usecolor = r_config_get_i (core->config, "scr.color");
int nb_cols = r_config_get_i (core->config, "hex.cols");
core->print->use_comments = r_config_get_i (core->config, "hex.comments");
int flagsz = r_config_get_i (core->config, "hex.flagsz");
const ut8 *buf = core->block;
ut64 addr = core->offset;
int color_idx = 0;
char *bytes, *chars;
char *ebytes, *echars; // They'll walk over the vars above
ut64 fend = UT64_MAX;
char *comment;
int i, j, low, max, here, rows;
bool marks = false, setcolor = true, hascolor = false;
ut8 ch = 0;
char *colors[10] = {NULL};
for (i = 0; i < 10; i++) {
colors[i] = r_cons_rainbow_get (i, 10, false);
}
const int col = core->print->col;
RFlagItem *flag, *current_flag = NULL;
char **note;
int html = r_config_get_i (core->config, "scr.html");
int nb_cons_cols;
bool compact = false;
if (core->print) {
compact = core->print->flags & R_PRINT_FLAGS_COMPACT;
}
char *format = compact ? " %X %X" : " %X %X ";
int step = compact ? 4 : 5;
// Adjust the number of columns
if (nb_cols < 1) {
nb_cols = 16;
}
nb_cols -= (nb_cols % 2); // nb_cols should be even
nb_cons_cols = 12 + nb_cols * 2 + (nb_cols / 2);
nb_cons_cols += 17;
rows = len / nb_cols;
chars = calloc (nb_cols * 40, sizeof (char));
if (!chars) goto err_chars;
note = calloc (nb_cols, sizeof (char *));
if (!note) goto err_note;
bytes = calloc (nb_cons_cols * 40, sizeof (char));
if (!bytes) goto err_bytes;
#if 1
int addrpadlen = strlen (sdb_fmt ("%08"PFMT64x, addr)) - 8;
char addrpad[32];
if (addrpadlen > 0) {
memset (addrpad, ' ', addrpadlen);
addrpad[addrpadlen] = 0;
// Compute, then show the legend
strcpy (bytes, addrpad);
} else {
*addrpad = 0;
addrpadlen = 0;
}
strcpy (bytes + addrpadlen, "- offset - ");
#endif
j = strlen (bytes);
for (i = 0; i < nb_cols; i += 2) {
sprintf (bytes + j, format, (i & 0xf), (i + 1) & 0xf);
j += step;
}
j--;
strcpy (bytes + j, " ");
j += 2;
for (i = 0; i < nb_cols; i++) {
sprintf (bytes + j + i, "%0X", i % 17);
}
if (usecolor) {
r_cons_strcat (Color_GREEN);
r_cons_strcat (bytes);
r_cons_strcat (Color_RESET);
} else {
r_cons_strcat (bytes);
}
r_cons_newline ();
// hexdump
for (i = 0; i < rows; i++) {
bytes[0] = '\0';
chars[0] = '\0';
ebytes = bytes;
echars = chars;
hascolor = false;
// r_print_offset (core->print, addr + i, 0, 0, 0, 0, NULL);
if (usecolor) {
append (ebytes, core->cons->context->pal.offset);
}
ebytes += sprintf (ebytes, "0x%08"PFMT64x, addr);
if (usecolor) {
append (ebytes, Color_RESET);
}
append (ebytes, (col == 1)? " |": " ");
bool hadflag = false;
for (j = 0; j < nb_cols; j++) {
setcolor = true;
R_FREE (note[j]);
RAnalMetaItem *meta = r_meta_find_in (core->anal, addr + j,
R_META_TYPE_FORMAT, R_META_WHERE_HERE);
if (meta && meta->type == R_META_TYPE_FORMAT && meta->from == addr + j) {
r_cons_printf (".format %s ; size=", meta->str);
r_core_cmdf (core, "pfs %s", meta->str);
r_core_cmdf (core, "pf %s @ 0x%08"PFMT64x, meta->str, meta->from);
append (ebytes, Color_INVERT);
append (echars, Color_INVERT);
hadflag = true;
}
// collect comments
comment = r_meta_get_string (core->anal, R_META_TYPE_COMMENT, addr + j);
if (comment) {
comment = r_str_prefix (comment, ";");
note[j] = comment;
marks = true;
}
// collect flags
flag = r_flag_get_i (core->flags, addr + j);
if (flag) { // Beginning of a flag
if (flagsz) {
fend = addr + flagsz; // core->blocksize;
} else {
fend = addr + j + flag->size;
}
note[j] = r_str_prefix (strdup (flag->name), "/");
marks = true;
color_idx++;
color_idx %= 10;
current_flag = flag;
if (flag->offset == addr + j) {
append (ebytes, Color_INVERT);
append (echars, Color_INVERT);
hadflag = true;
}
} else {
// Are we past the current flag?
if (current_flag && addr + j > (current_flag->offset + current_flag->size)) {
setcolor = false;
current_flag = NULL;
}
// Turn colour off if we're at the end of the current flag
if (fend == UT64_MAX || fend <= addr + j) {
setcolor = false;
}
}
if (usecolor && !setcolor) {
const char *bytecolor = r_print_byte_color (core->print, ch);
if (bytecolor) {
append (ebytes, bytecolor);
append (echars, bytecolor);
hascolor = true;
}
}
if (setcolor && !hascolor) {
hascolor = true;
if (usecolor) {
if (current_flag && current_flag->color) {
char *ansicolor = r_cons_pal_parse (current_flag->color, NULL);
if (ansicolor) {
append (ebytes, ansicolor);
append (echars, ansicolor);
free (ansicolor);
}
} else { // Use "random" colours
append (ebytes, colors[color_idx]);
append (echars, colors[color_idx]);
}
} else {
if (html) {
append (ebytes, "[");
} else {
append (ebytes, Color_INVERT);
}
}
}
here = R_MIN ((i * nb_cols) + j, core->blocksize);
ch = buf[here];
if (core->print->ocur != -1) {
low = R_MIN (core->print->cur, core->print->ocur);
max = R_MAX (core->print->cur, core->print->ocur);
} else {
low = max = core->print->cur;
}
if (core->print->cur_enabled) {
if (low == max) {
if (low == here) {
if (html) {
append (ebytes, "[");
append (echars, "[");
} else {
append (echars, Color_INVERT);
append (ebytes, Color_INVERT);
}
}
} else {
if (here >= low && here < max) {
if (html) {
append (ebytes, "[");
append (echars, "[");
} else {
append (ebytes, Color_INVERT);
append (echars, Color_INVERT);
}
}
}
}
sprintf (ebytes, "%02x", ch);
// r_print_byte (core->print, "%02x ", j, ch);
ebytes += strlen (ebytes);
if (hadflag) {
append (ebytes, Color_INVERT_RESET);
append (echars, Color_INVERT_RESET);
hadflag = false;
}
sprintf (echars, "%c", IS_PRINTABLE (ch)? ch: '.');
echars++;
if (core->print->cur_enabled && max == here) {
if (!html) {
append (ebytes, Color_RESET);
append (echars, Color_RESET);
}
hascolor = false;
}
if (j < (nb_cols - 1) && (j % 2) && !compact) {
append (ebytes, " ");
}
if (fend != UT64_MAX && fend == addr + j + 1) {
if (!html) {
append (ebytes, Color_RESET);
append (echars, Color_RESET);
}
fend = UT64_MAX;
hascolor = false;
}
}
if (!html) {
append (ebytes, Color_RESET);
append (echars, Color_RESET);
}
append (ebytes, (col == 1)? "| ": (col == 2)? " |": " ");
if (col == 2) {
append (echars, "|");
}
if (marks) { // show comments and flags
int hasline = 0;
int out_sz = nb_cons_cols + 20;
char *out = calloc (out_sz, sizeof (char));
memset (out, ' ', nb_cons_cols - 1);
for (j = 0; j < nb_cols; j++) {
if (note[j]) {
int off = (j * 3) - (j / 2) + 13;
int notej_len = strlen (note[j]);
int sz = R_MIN (notej_len, nb_cons_cols - off);
if (compact) {
off -= (j/2);
} else {
if (j % 2) {
off--;
}
}
memcpy (out + off, note[j], sz);
if (sz < notej_len) {
out[off + sz - 2] = '.';
out[off + sz - 1] = '.';
}
hasline = (out[off] != ' ');
R_FREE (note[j]);
}
}
out[out_sz - 1] = 0;
if (hasline) {
r_cons_strcat (addrpad);
r_cons_strcat (out);
r_cons_newline ();
}
marks = false;
free (out);
}
r_cons_strcat (bytes);
r_cons_strcat (chars);
if (core->print->use_comments) {
for (j = 0; j < nb_cols; j++) {
const char *comment = core->print->get_comments (core->print->user, addr + j);
if (comment) {
r_cons_printf (" ; %s", comment);
}
}
}
r_cons_newline ();
addr += nb_cols;
}
free (bytes);
err_bytes:
free (note);
err_note:
free (chars);
err_chars:
for (i = 0; i < R_ARRAY_SIZE (colors); i++) {
free (colors[i]);
}
}
R_API void r_core_print_examine(RCore *core, const char *str) {
char cmd[128], *p;
ut64 addr = core->offset;
int size = (core->anal->bits / 4);
int count = atoi (str);
int i, n;
if (count < 1) {
count = 1;
}
// skipspaces
while (*str >= '0' && *str <= '9') {
str++;
}
// "px/" alone isn't a full command.
if (!str[0]) {
return;
}
#if 0
Size letters are b(byte), h (halfword), w (word), g (giant, 8 bytes).
#endif
switch (str[1]) {
case 'b': size = 1; break;
case 'h': size = 2; break;
case 'd': size = 4; break;
case 'w': size = 4; break;
case 'g': size = 8; break;
}
if ((p = strchr (str, ' '))) {
*p++ = 0;
addr = r_num_math (core->num, p);
}
switch (*str) {
case '?':
eprintf (
"Format is x/[num][format][size]\n"
"Num specifies the number of format elements to display\n"
"Format letters are o(octal), x(hex), d(decimal), u(unsigned decimal),\n"
" t(binary), f(float), a(address), i(instruction), c(char) and s(string),\n"
" T(OSType), A(floating point values in hex).\n"
"Size letters are b(byte), h(halfword), w(word), g(giant, 8 bytes).\n"
);
break;
case 's': // "x/s"
r_core_cmdf (core, "psb %d @ 0x%"PFMT64x, count * size, addr);
break;
case 'o': // "x/o"
r_core_cmdf (core, "pxo %d @ 0x%"PFMT64x, count * size, addr);
break;
case 'f':
case 'A': // XXX (float in hex wtf)
n = 3;
snprintf (cmd, sizeof (cmd), "pxo %d @ 0x%"PFMT64x,
count * size, addr);
strcpy (cmd, "pf ");
for (i = 0; i < count && n < sizeof (cmd); i++) {
cmd[n++] = 'f';
}
cmd[n] = 0;
r_core_cmd0 (core, cmd);
break;
case 'x':
switch (size) {
default:
case 1:
r_core_cmdf (core, "px %d @ 0x%"PFMT64x, count, addr);
break;
case 2:
r_core_cmdf (core, "px%c %d @ 0x%"PFMT64x,
'h', count * 2, addr);
break;
case 4:
r_core_cmdf (core, "px%c %d @ 0x%"PFMT64x,
'w', count * 4, addr);
break;
case 8:
r_core_cmdf (core, "px%c %d @ 0x%"PFMT64x,
'q', count * 8, addr);
break;
}
break;
case 'a':
case 'd':
r_core_cmdf (core, "pxw %d @ 0x%"PFMT64x, count * size, addr);
break;
case 'i':
r_core_cmdf (core, "pid %d @ 0x%"PFMT64x, count, addr);
break;
}
}
struct count_pz_t {
RSpace *flagspace;
ut64 addr;
ut64 size;
int *ret;
};
static bool count_pzs(RFlagItem *fi, void *u) {
struct count_pz_t *user = (struct count_pz_t *)u;
if (fi->space == user->flagspace &&
((user->addr <= fi->offset && fi->offset < user->addr + user->size) ||
(user->addr <= fi->offset + fi->size && fi->offset + fi->size < user->addr + user->size))) {
(*user->ret)++;
}
return true;
}
static bool count_pzf(RFlagItem *fi, void *u) {
struct count_pz_t *user = (struct count_pz_t *)u;
if (fi->offset <= user->addr && user->addr < fi->offset + fi->size) {
(*user->ret)++;
}
return true;
}
static int printzoomcallback(void *user, int mode, ut64 addr, ut8 *bufz, ut64 size) {
RCore *core = (RCore *) user;
int j, ret = 0;
struct count_pz_t u;
switch (mode) {
case '0': // "pz0"
for (j = 0; j < size; j++) {
if (bufz[j] == 0) {
ret++;
}
}
break;
case 'e': // "pze"
ret = (ut8) (r_hash_entropy_fraction (bufz, size) * 255);
break;
case 'f': // "pzf"
u.addr = addr;
u.ret = &ret;
r_flag_foreach (core->flags, count_pzf, &u);
break;
case 'F': // "pzF"
for (j = 0; j < size; j++) {
if (bufz[j] == 0xff) {
ret++;
}
}
break;
case 'p': // "pzp"
for (j = 0; j < size; j++) {
if (IS_PRINTABLE (bufz[j])) {
ret++;
}
}
break;
case 's': // "pzs"
u.flagspace = r_flag_space_get (core->flags, R_FLAGS_FS_STRINGS);
u.addr = addr;
u.size = size;
u.ret = &ret;
r_flag_foreach (core->flags, count_pzs, &u);
break;
case 'h': // "pzh" head
default:
ret = *bufz;
}
return ret;
}
R_API void r_core_print_cmp(RCore *core, ut64 from, ut64 to) {
long int delta = 0;
int col = core->cons->columns > 123;
ut8 *b = malloc (core->blocksize);
ut64 addr = core->offset;
memset (b, 0xff, core->blocksize);
delta = addr - from;
r_io_read_at (core->io, to + delta, b, core->blocksize);
r_print_hexdiff (core->print, core->offset, core->block,
to + delta, b, core->blocksize, col);
free (b);
}
static void cmd_print_pwn(const RCore *core) {
r_cons_printf ("easter egg license has expired\n");
}
static int cmd_print_pxA(RCore *core, int len, const char *data) {
RConsPrintablePalette *pal = &core->cons->context->pal;
int show_offset = true;
int cols = r_config_get_i (core->config, "hex.cols");
int show_color = r_config_get_i (core->config, "scr.color");
int onechar = r_config_get_i (core->config, "hex.onechar");
int bgcolor_in_heap = false;
bool show_cursor = core->print->cur_enabled;
char buf[2];
char *bgcolor, *fgcolor, *text;
ut64 i, c, oi;
RAnalOp op;
if (len < 0 || len > core->blocksize) {
eprintf ("Invalid length\n");
return 0;
}
if (onechar) {
cols *= 4;
} else {
cols *= 2;
}
if (show_offset) {
char offstr[128];
snprintf (offstr, sizeof (offstr),
"0x%08"PFMT64x " ", core->offset);
if (strlen (offstr) > 12) {
cols -= ((strlen (offstr) - 12) * 2);
}
}
for (oi = i = c = 0; i < len; c++) {
if (i && (cols != 0) && !(c % cols)) {
show_offset = true;
r_cons_printf (" %d\n", i - oi);
oi = i;
}
if (show_offset) {
r_cons_printf ("0x%08"PFMT64x " ", core->offset + i);
show_offset = false;
}
if (bgcolor_in_heap) {
free (bgcolor);
bgcolor_in_heap = false;
}
bgcolor = Color_BGBLACK;
fgcolor = Color_WHITE;
text = NULL;
if (r_anal_op (core->anal, &op, core->offset + i, core->block + i, len - i, R_ANAL_OP_MASK_BASIC) <= 0) {
op.type = 0;
bgcolor = Color_BGRED;
op.size = 1;
}
switch (op.type) {
case R_ANAL_OP_TYPE_LEA:
case R_ANAL_OP_TYPE_MOV:
case R_ANAL_OP_TYPE_CAST:
case R_ANAL_OP_TYPE_LENGTH:
case R_ANAL_OP_TYPE_CMOV:
text = "mv";
bgcolor = pal->mov;
fgcolor = Color_YELLOW;
break;
case R_ANAL_OP_TYPE_PUSH:
case R_ANAL_OP_TYPE_UPUSH:
bgcolor = pal->push;
fgcolor = Color_WHITE;
text = "->";
break;
case R_ANAL_OP_TYPE_IO:
bgcolor = pal->swi;
fgcolor = Color_WHITE;
text = "io";
break;
case R_ANAL_OP_TYPE_TRAP:
case R_ANAL_OP_TYPE_SWI:
case R_ANAL_OP_TYPE_NEW:
// bgcolor = Color_BGRED;
bgcolor = pal->trap; // r_cons_swap_ground (pal->trap);
fgcolor = Color_WHITE;
text = "$$";
break;
case R_ANAL_OP_TYPE_POP:
text = "<-";
bgcolor = r_cons_swap_ground (pal->pop);
bgcolor_in_heap = true;
fgcolor = Color_WHITE;
break;
case R_ANAL_OP_TYPE_NOP:
fgcolor = Color_WHITE;
bgcolor = r_cons_swap_ground (pal->nop);
bgcolor_in_heap = true;
text = "..";
break;
case R_ANAL_OP_TYPE_MUL:
fgcolor = Color_BLACK;
bgcolor = r_cons_swap_ground (pal->math);
bgcolor_in_heap = true;
text = "_*";
break;
case R_ANAL_OP_TYPE_DIV:
bgcolor = r_cons_swap_ground (pal->math);
bgcolor_in_heap = true;
fgcolor = Color_BLACK;
text = "_/";
break;
case R_ANAL_OP_TYPE_AND:
bgcolor = r_cons_swap_ground (pal->bin);
bgcolor_in_heap = true;
fgcolor = Color_BLACK;
text = "_&";
break;
case R_ANAL_OP_TYPE_XOR:
bgcolor = r_cons_swap_ground (pal->bin);
bgcolor_in_heap = true;
fgcolor = Color_BLACK;
text = "_^";
break;
case R_ANAL_OP_TYPE_OR:
bgcolor = r_cons_swap_ground (pal->bin);
bgcolor_in_heap = true;
fgcolor = Color_BLACK;
text = "_|";
break;
case R_ANAL_OP_TYPE_SHR:
bgcolor = r_cons_swap_ground (pal->bin);
bgcolor_in_heap = true;
fgcolor = Color_BLACK;
text = ">>";
break;
case R_ANAL_OP_TYPE_SHL:
bgcolor = r_cons_swap_ground (pal->bin);
bgcolor_in_heap = true;
fgcolor = Color_BLACK;
text = "<<";
break;
case R_ANAL_OP_TYPE_SUB:
bgcolor = r_cons_swap_ground (pal->math);
bgcolor_in_heap = true;
fgcolor = Color_WHITE;
text = "--";
break;
case R_ANAL_OP_TYPE_ADD:
bgcolor = r_cons_swap_ground (pal->math);
bgcolor_in_heap = true;
fgcolor = Color_WHITE;
text = "++";
break;
case R_ANAL_OP_TYPE_JMP:
case R_ANAL_OP_TYPE_UJMP:
case R_ANAL_OP_TYPE_IJMP:
case R_ANAL_OP_TYPE_RJMP:
case R_ANAL_OP_TYPE_IRJMP:
case R_ANAL_OP_TYPE_MJMP:
bgcolor = r_cons_swap_ground (pal->jmp);
bgcolor_in_heap = true;
fgcolor = Color_BLACK;
text = "_J";
break;
case R_ANAL_OP_TYPE_CJMP:
case R_ANAL_OP_TYPE_UCJMP:
bgcolor = r_cons_swap_ground (pal->cjmp);
bgcolor_in_heap = true;
fgcolor = Color_BLACK;
text = "cJ";
break;
case R_ANAL_OP_TYPE_CALL:
case R_ANAL_OP_TYPE_UCALL:
case R_ANAL_OP_TYPE_ICALL:
case R_ANAL_OP_TYPE_RCALL:
case R_ANAL_OP_TYPE_IRCALL:
case R_ANAL_OP_TYPE_UCCALL:
bgcolor = r_cons_swap_ground (pal->call);
bgcolor_in_heap = true;
fgcolor = Color_WHITE;
text = "_C";
break;
case R_ANAL_OP_TYPE_ACMP:
case R_ANAL_OP_TYPE_CMP:
bgcolor = r_cons_swap_ground (pal->cmp);
bgcolor_in_heap = true;
fgcolor = Color_BLACK;
text = "==";
break;
case R_ANAL_OP_TYPE_RET:
bgcolor = r_cons_swap_ground (pal->ret);
bgcolor_in_heap = true;
fgcolor = Color_WHITE;
text = "_R";
break;
case -1:
case R_ANAL_OP_TYPE_ILL:
case R_ANAL_OP_TYPE_UNK:
bgcolor = r_cons_swap_ground (pal->invalid);
bgcolor_in_heap = true;
fgcolor = Color_WHITE;
text = "XX";
break;
#if 0
default:
color = Color_BGCYAN;
fgcolor = Color_BLACK;
break;
#endif
}
int opsz = R_MAX (op.size, 1);
if (show_cursor) {
if (core->print->cur >= i && core->print->cur < i + opsz) {
r_cons_invert (1, 1);
}
}
if (onechar) {
if (text) {
if (text[0] == '_' || text[0] == '.') {
buf[0] = text[1];
} else {
buf[0] = text[0];
}
} else {
buf[0] = '.';
}
buf[1] = 0;
text = buf;
}
if (show_color) {
if (!text) {
text = " ";
}
r_cons_printf ("%s%s%s\x1b[0m", bgcolor, fgcolor, text);
} else {
if (text) {
r_cons_print (text);
} else {
r_cons_print (" ");
}
}
if (show_cursor) {
if (core->print->cur >= i && core->print->cur < i + opsz) {
r_cons_invert (0, 1);
}
}
i += opsz;
r_anal_op_fini (&op);
}
r_cons_printf (" %d\n", i - oi);
if (bgcolor_in_heap) {
free (bgcolor);
}
return true;
}
static void printraw(RCore *core, int len, int mode) {
int obsz = core->blocksize;
int restore_obsz = 0;
if (len != obsz) {
if (!r_core_block_size (core, len)) {
len = core->blocksize;
} else {
restore_obsz = 1;
}
}
r_print_raw (core->print, core->offset, core->block, len, mode);
if (restore_obsz) {
(void) r_core_block_size (core, obsz);
}
core->cons->newline = true;
}
static void _handle_call(RCore *core, char *line, char **str) {
if (!core || !core->assembler || !core->assembler->cur) {
*str = NULL;
return;
}
if (strstr (core->assembler->cur->arch, "x86")) {
*str = strstr (line, "call ");
} else if (strstr (core->assembler->cur->arch, "arm")) {
*str = strstr (line, " b ");
if (*str && strstr (*str, " 0x")) {
/*
* avoid treating branches to
* non-symbols as calls
*/
*str = NULL;
}
if (!*str) {
*str = strstr (line, "bl ");
}
if (!*str) {
*str = strstr (line, "bx ");
}
}
}
// TODO: this is just a PoC, the disasm loop should be rewritten
// TODO: this is based on string matching, it should be written upon RAnalOp to know
// when we have a call and such
static void disasm_strings(RCore *core, const char *input, RAnalFunction *fcn) {
const char *linecolor = NULL;
char *ox, *qo, *string = NULL;
char *line, *s, *str, *string2 = NULL;
int i, count, use_color = r_config_get_i (core->config, "scr.color");
bool show_comments = r_config_get_i (core->config, "asm.comments");
bool show_offset = r_config_get_i (core->config, "asm.offset");
bool asm_tabs = r_config_get_i (core->config, "asm.tabs");
bool asm_flags = r_config_get_i (core->config, "asm.flags");
bool asm_cmt_right = r_config_get_i (core->config, "asm.cmt.right");
bool asm_emu = r_config_get_i (core->config, "asm.emu");
bool emu_str = r_config_get_i (core->config, "emu.str");
r_config_set_i (core->config, "emu.str", true);
RConsPrintablePalette *pal = &core->cons->context->pal;
// force defaults
r_config_set_i (core->config, "asm.offset", true);
r_config_set_i (core->config, "scr.color", COLOR_MODE_DISABLED);
r_config_set_i (core->config, "asm.tabs", 0);
r_config_set_i (core->config, "asm.cmt.right", true);
r_cons_push();
line = NULL;
s = NULL;
if (!strncmp (input, "dsb", 3)) {
RAnalBlock *bb = r_anal_bb_from_offset (core->anal, core->offset);
if (bb) {
line = s = r_core_cmd_strf (core, "pD %i @ 0x%08"PFMT64x, bb->size, bb->addr);
}
} else if (!strncmp (input, "dsf", 3) || !strncmp (input, "dsr", 3)) {
RAnalFunction *fcn = r_anal_get_fcn_in (core->anal, core->offset, R_ANAL_FCN_TYPE_NULL);
if (fcn) {
line = s = r_core_cmd_str (core, "pdr");
} else {
eprintf ("Cannot find function.\n");
r_config_set_i (core->config, "scr.color", use_color);
r_config_set_i (core->config, "asm.cmt.right", asm_cmt_right);
goto restore_conf;
}
} else if (!strncmp (input, "ds ", 3)) {
line = s = r_core_cmd_strf (core, "pD %s", input + 3);
} else {
line = s = r_core_cmd_str (core, "pd");
}
r_cons_pop();
r_config_set_i (core->config, "scr.color", use_color);
r_config_set_i (core->config, "asm.cmt.right", asm_cmt_right);
count = r_str_split (s, '\n');
if (!line || !*line || count < 1) {
// R_FREE (s);
goto restore_conf;
}
for (i = 0; i < count; i++) {
ut64 addr = UT64_MAX;
ox = strstr (line, "0x");
qo = strstr (line, "\"");
R_FREE (string);
if (ox) {
addr = r_num_get (NULL, ox);
}
if (qo) {
char *qoe = strrchr (qo + 1, '"');
if (qoe) {
int raw_len = qoe - qo - 1;
int actual_len = 0;
char *ptr = qo + 1;
for(; ptr < qoe; ptr++) {
if (*ptr == '\\' && ptr + 1 < qoe) {
int i, body_len;
switch (*(ptr + 1)) {
case 'x':
body_len = 3;
break;
case 'u':
body_len = 5;
break;
case 'U':
body_len = 9;
break;
default:
body_len = 1;
}
for (i = 0; i < body_len && ptr < qoe; i++) {
ptr++;
}
}
actual_len++;
}
if (actual_len > 2) {
string = r_str_ndup (qo, raw_len + 2);
}
linecolor = R_CONS_COLOR (comment);
}
}
ox = strstr (line, "; 0x");
if (!ox) {
ox = strstr (line, "@ 0x");
}
if (ox) {
char *qoe = strchr (ox + 3, ' ');
if (!qoe) {
qoe = strchr (ox + 3, '\x1b');
}
int len = qoe? qoe - ox: strlen (ox + 3);
string2 = r_str_ndup (ox + 2, len - 1);
if (r_num_get (NULL, string2) < 0x100) {
R_FREE (string2);
}
}
if (asm_flags) {
str = strstr (line, ";-- ");
if (str) {
r_cons_printf ("%s\n", str);
}
}
#define USE_PREFIXES 1
#if USE_PREFIXES
// XXX leak
str = strstr (line, " obj.");
if (!str) {
str = strstr (line, " str.");
if (!str) {
str = strstr (line, " imp.");
if (!str) {
str = strstr (line, " fcn.");
if (!str) {
str = strstr (line, " sub.");
}
}
}
}
#else
if (strchr (line, ';')) {
const char *dot = r_str_rchr (line, NULL, '.');
if (dot) {
const char *o = r_str_rchr (line, dot, ' ');
if (o) {
str = (char*)o;
} else {
eprintf ("Warning: missing summary reference: %s\n", dot);
}
}
}
#endif
if (str) {
str = strdup (str);
char *qoe = NULL;
if (!qoe) {
qoe = strchr (str + 1, '\x1b');
}
if (!qoe) {
qoe = strchr (str + 1, ';');
}
if (!qoe) {
qoe = strchr (str + 1, ' ');
}
if (qoe) {
free (string2);
string2 = r_str_ndup (str + 1, qoe - str - 1);
} else {
free (string2);
string2 = strdup (str + 1);
}
if (string2) {
R_FREE (string);
string = string2;
string2 = NULL;
}
}
R_FREE (string2);
_handle_call (core, line, &str);
if (!str) {
str = strstr (line, "sym.");
if (!str) {
str = strstr (line, "fcn.");
}
}
if (str) {
str = strdup (str);
char *qoe = strstr (str, ";");
if (qoe) {
char* t = str;
str = r_str_ndup (str, qoe - str);
free (t);
}
}
if (str) {
string2 = strdup (str);
linecolor = R_CONS_COLOR (call);
}
if (!string && string2) {
string = string2;
string2 = NULL;
}
if (strstr (line, "XREF")) {
addr = UT64_MAX;
}
if (addr != UT64_MAX) {
const char *str = NULL;
if (show_comments) {
char *comment = r_core_anal_get_comments (core, addr);
if (comment) {
if (show_offset) {
r_cons_printf ("%s0x%08"PFMT64x" ", use_color? pal->offset: "", addr);
}
r_cons_printf ("%s%s\n", use_color? pal->comment: "", comment);
R_FREE (comment);
}
}
if (fcn) {
bool label = false;
/* show labels, basic blocks and (conditional) branches */
RAnalBlock *bb;
RListIter *iter;
r_list_foreach (fcn->bbs, iter, bb) {
if (addr == bb->jump) {
if (show_offset) {
r_cons_printf ("%s0x%08"PFMT64x ":\n", use_color? Color_YELLOW: "", addr);
}
label = true;
break;
}
}
if (!label && strstr (line, "->")) {
r_cons_printf ("%s0x%08"PFMT64x ":\n", use_color? Color_YELLOW: "", addr);
}
if (strstr (line, "=<")) {
r_list_foreach (fcn->bbs, iter, bb) {
if (addr >= bb->addr && addr < bb->addr + bb->size) {
const char *op;
if (use_color) {
op = (bb->fail == UT64_MAX)? Color_GREEN "jmp": "cjmp";
} else {
op = (bb->fail == UT64_MAX)? "jmp": "cjmp";
}
if (show_offset) {
r_cons_printf ("%s0x%08"PFMT64x" "Color_RESET, use_color? pal->offset: "", addr);
}
r_cons_printf ("%s 0x%08"PFMT64x "%s\n",
op, bb->jump, use_color? Color_RESET: "");
break;
}
}
}
}
if (string && *string) {
if (string && !strncmp (string, "0x", 2)) {
str = string;
}
if (string2 && !strncmp (string2, "0x", 2)) {
str = string2;
}
ut64 ptr = r_num_math (NULL, str);
RFlagItem *flag = NULL;
if (str) {
flag = r_flag_get_i2 (core->flags, ptr);
}
if (!flag) {
if (string && !strncmp (string, "0x", 2)) {
R_FREE (string);
}
if (string2 && !strncmp (string2, "0x", 2)) {
R_FREE (string2);
}
}
if (string && addr != UT64_MAX && addr != UT32_MAX) {
string = r_str_trim (string);
string2 = r_str_trim (string2);
//// TODO implememnt avoid duplicated strings
// eprintf ("---> %s\n", string);
if (use_color) {
if (show_offset) {
r_cons_printf ("%s0x%08"PFMT64x" "Color_RESET, use_color? pal->offset: "", addr);
}
r_cons_printf ("%s%s%s%s%s%s%s\n",
linecolor? linecolor: "",
string2? string2: "", string2? " ": "", string,
flag? " ": "", flag? flag->name: "", Color_RESET);
} else {
if (show_offset) {
r_cons_printf ("0x%08"PFMT64x" ", addr);
}
r_cons_printf ("%s%s%s%s%s\n",
string2? string2: "", string2? " ": "", string,
flag? " ": "", flag? flag->name: "");
}
}
}
}
line += strlen (line) + 1;
}
// r_cons_printf ("%s", s);
free (string2);
free (string);
free (s);
free (str);
restore_conf:
r_config_set_i (core->config, "asm.offset", show_offset);
r_config_set_i (core->config, "asm.tabs", asm_tabs);
r_config_set_i (core->config, "asm.emu", asm_emu);
r_config_set_i (core->config, "emu.str", emu_str);
}
static void algolist(int mode) {
int i;
for (i = 0; i < R_HASH_NBITS; i++) {
ut64 bits = 1ULL << i;
const char *name = r_hash_name (bits);
if (name && *name) {
if (mode) {
r_cons_println (name);
} else {
r_cons_printf ("%s ", name);
}
}
}
if (!mode) {
r_cons_newline ();
}
}
static bool cmd_print_ph(RCore *core, const char *input) {
char algo[128];
ut32 osize = 0, len = core->blocksize;
const char *ptr;
int pos = 0, handled_cmd = false;
if (!*input || *input == '?') {
algolist (1);
return true;
}
if (*input == '=') {
algolist (0);
return true;
}
input = r_str_trim_ro (input);
ptr = strchr (input, ' ');
sscanf (input, "%31s", algo);
if (ptr && ptr[1]) { // && r_num_is_valid_input (core->num, ptr + 1)) {
int nlen = r_num_math (core->num, ptr + 1);
if (nlen > 0) {
len = nlen;
}
osize = core->blocksize;
if (nlen > core->blocksize) {
r_core_block_size (core, nlen);
if (nlen != core->blocksize) {
eprintf ("Invalid block size\n");
r_core_block_size (core, osize);
return false;
}
r_core_block_read (core);
}
} else if (!ptr || !*(ptr + 1)) {
osize = len;
}
/* TODO: Simplify this spaguetti monster */
while (osize > 0 && hash_handlers[pos].name) {
if (!r_str_ccmp (hash_handlers[pos].name, input, ' ')) {
hash_handlers[pos].handler (core->block, len);
handled_cmd = true;
break;
}
pos++;
}
if (osize) {
r_core_block_size (core, osize);
}
return handled_cmd;
}
static void cmd_print_pv(RCore *core, const char *input, const ut8* block) {
const char *stack[] = {
"ret", "arg0", "arg1", "arg2", "arg3", "arg4", NULL
};
int i, n = core->assembler->bits / 8;
int type = 'v';
bool fixed_size = true;
switch (input[0]) {
case '1': // "pv1"
n = 1;
input++;
break;
case '2': // "pv2"
n = 2;
input++;
break;
case '4': // "pv4"
n = 4;
input++;
break;
case '8': // "pv8"
n = 8;
input++;
break;
default:
if (input[1] == 'j') {
input++;
}
fixed_size = false;
break;
}
// variables can be
switch (input[0]) {
case 'z': // "pvz"
type = 'z';
if (input[1]) {
input++;
} else {
r_core_cmdf (core, "ps");
break;
}
/* fallthrough */
case ' ': // "pv "
for (i = 0; stack[i]; i++) {
if (!strcmp (input + 1, stack[i])) {
if (type == 'z') {
r_core_cmdf (core, "ps @ [`drn sp`+%d]", n * i);
} else {
r_core_cmdf (core, "?v [`drn sp`+%d]", n * i);
}
}
}
break;
case 'j': { // "pvj"
char *str = r_str_trim (r_core_cmd_str (core, "ps @ [$$]"));
char *p = str;
if (p) {
while (*p) {
if (*p == '\\' && p[1] == 'x') {
memmove (p, p + 4, strlen (p + 4) + 1);
}
}
}
// r_num_get is gonna use a dangling pointer since the internal
// token that RNum holds ([$$]) has been already freed by r_core_cmd_str
// r_num_math reload a new token so the dangling pointer is gone
switch (n) {
case 1:
pj_fmt (r_cons_printf, "{'value':%i,'string':%s}\n",
r_read_ble8 (block), str);
break;
case 2:
pj_fmt (r_cons_printf, "{'value':%i,'string':%s}\n",
r_read_ble16 (block, core->print->big_endian), str);
break;
case 4:
pj_fmt (r_cons_printf, "{'value':%n,'string':%s}\n",
(ut64)r_read_ble32 (block, core->print->big_endian), str);
break;
case 8:
pj_fmt (r_cons_printf, "{'value':%n,'string':%s}\n",
r_read_ble64 (block, core->print->big_endian), str);
break;
default:
pj_fmt (r_cons_printf, "{'value':%n,'string':%s}\n",
r_read_ble64 (block, core->print->big_endian), str);
break;
}
free (str);
break;
}
case '?': // "pv?"
r_core_cmd_help (core, help_msg_pv);
break;
default:
{
ut64 v;
if (!fixed_size) {
n = 0;
}
switch (n) {
case 1:
v = r_read_ble8 (block);
r_cons_printf ("0x%02" PFMT64x "\n", v);
break;
case 2:
v = r_read_ble16 (block, core->print->big_endian);
r_cons_printf ("0x%04" PFMT64x "\n", v);
break;
case 4:
v = r_read_ble32 (block, core->print->big_endian);
r_cons_printf ("0x%08" PFMT64x "\n", v);
break;
case 8:
v = r_read_ble64 (block, core->print->big_endian);
r_cons_printf ("0x%016" PFMT64x "\n", v);
break;
default:
v = r_read_ble64 (block, core->print->big_endian);
switch (core->assembler->bits / 8) {
case 1: r_cons_printf ("0x%02" PFMT64x "\n", v & UT8_MAX); break;
case 2: r_cons_printf ("0x%04" PFMT64x "\n", v & UT16_MAX); break;
case 4: r_cons_printf ("0x%08" PFMT64x "\n", v & UT32_MAX); break;
case 8: r_cons_printf ("0x%016" PFMT64x "\n", v & UT64_MAX); break;
default: break;
}
break;
}
}
// r_core_cmd0 (core, "?v [$$]");
break;
}
}
static int cmd_print_blocks(RCore *core, const char *input) {
char mode = input[0];
if (mode == '?') {
r_core_cmd_help (core, help_msg_p_minus);
return 0;
}
if (mode && mode != ' ') {
input++;
}
int w = (input[0] == ' ')
? (int)r_num_math (core->num, input + 1)
: (int)(core->print->cols * 2.7);
if (w == 0) {
r_core_cmd_help (core, help_msg_p_minus);
return 0;
}
ut64 off = core->offset;
ut64 from = UT64_MAX;
ut64 to = 0;
RList *list = r_core_get_boundaries_prot (core, -1, NULL, "search");
if (!list) {
return 1;
}
RListIter *iter;
RIOMap *map;
r_list_foreach (list, iter, map) {
ut64 f = r_itv_begin (map->itv);
ut64 t = r_itv_end (map->itv);
if (f < from) {
from = f;
}
if (t > to) {
to = t;
}
}
ut64 piece = R_MAX ((to - from) / w, 1);
RCoreAnalStats *as = r_core_anal_get_stats (core, from, to, piece);
if (!as) {
return 0;
}
PJ *pj = pj_new ();
if (!pj) {
return 0;
}
switch (mode) {
case 'j': // "p-j"
pj_o (pj);
pj_kn (pj, "from", from);
pj_kn (pj, "to", to);
pj_ki (pj, "blocksize", piece);
pj_k (pj, "blocks");
pj_a (pj);
break;
case 'h': // "p-h"
r_cons_printf (".-------------.----------------------------.\n");
r_cons_printf ("| offset | flags funcs cmts syms str |\n");
r_cons_printf ("|-------------)----------------------------|\n");
break;
default:
r_cons_printf ("0x%"PFMT64x " [", from);
}
bool use_color = r_config_get_i (core->config, "scr.color");
int len = 0;
int i;
RCoreAnalStatsItem total = {0};
for (i = 0; i < ((to - from) / piece); i++) {
ut64 at = from + (piece * i);
ut64 ate = at + piece;
ut64 p = (at - from) / piece;
switch (mode) {
case 'j':
pj_o (pj);
if ((as->block[p].flags)
|| (as->block[p].functions)
|| (as->block[p].comments)
|| (as->block[p].symbols)
|| (as->block[p].perm)
|| (as->block[p].strings)) {
pj_kn (pj, "offset", at);
pj_kn (pj, "size", piece);
}
if (as->block[p].flags) {
pj_ki (pj, "flags", as->block[p].flags);
}
if (as->block[p].functions) {
pj_ki (pj, "functions", as->block[p].functions);
}
if (as->block[p].in_functions) {
pj_ki (pj, "in_functions", as->block[p].in_functions);
}
if (as->block[p].comments) {
pj_ki (pj, "comments", as->block[p].comments);
}
if (as->block[p].symbols) {
pj_ki (pj, "symbols", as->block[p].symbols);
}
if (as->block[p].strings) {
pj_ki (pj, "strings", as->block[p].strings);
}
if (as->block[p].perm) {
pj_ks (pj, "perm", r_str_rwx_i (as->block[p].perm));
}
pj_end (pj);
len++;
break;
case 'h':
total.flags += as->block[p].flags;
total.functions += as->block[p].functions;
total.comments += as->block[p].comments;
total.symbols += as->block[p].symbols;
total.strings += as->block[p].strings;
if ((as->block[p].flags)
|| (as->block[p].functions)
|| (as->block[p].comments)
|| (as->block[p].symbols)
|| (as->block[p].strings)) {
r_cons_printf ("| 0x%09"PFMT64x " | %4d %4d %4d %4d %4d |\n", at,
as->block[p].flags,
as->block[p].functions,
as->block[p].comments,
as->block[p].symbols,
as->block[p].strings);
}
break;
default:
if (off >= at && off < ate) {
r_cons_memcat ("^", 1);
} else {
RIOMap *s = r_io_map_get (core->io, at);
if (use_color) {
if (s) {
if (s->perm & R_PERM_X) {
r_cons_print (Color_BGBLUE);
} else {
r_cons_print (Color_BGGREEN);
}
} else {
r_cons_print (Color_BGRED);
}
}
if (as->block[p].strings > 0) {
r_cons_memcat ("z", 1);
} else if (as->block[p].symbols > 0) {
r_cons_memcat ("s", 1);
} else if (as->block[p].functions > 0) {
r_cons_memcat ("F", 1);
} else if (as->block[p].comments > 0) {
r_cons_memcat ("c", 1);
} else if (as->block[p].flags > 0) {
r_cons_memcat (".", 1);
} else if (as->block[p].in_functions > 0) {
r_cons_memcat ("f", 1);
} else {
r_cons_memcat ("_", 1);
}
}
break;
}
}
switch (mode) {
case 'j':
pj_end (pj);
pj_end (pj);
r_cons_println (pj_string (pj));
pj_free (pj);
break;
case 'h':
// r_cons_printf (" total | flags funcs cmts syms str |\n");
r_cons_printf ("|-------------)----------------------------|\n");
r_cons_printf ("| total | %4d %4d %4d %4d %4d |\n",
total.flags, total.functions, total.comments, total.symbols, total.strings);
r_cons_printf ("`-------------'----------------------------'\n");
break;
default:
if (use_color) {
r_cons_print (Color_RESET);
}
r_cons_printf ("] 0x%"PFMT64x "\n", to);
}
r_core_anal_stats_free (as);
return len;
}
static bool checkAnalType(RAnalOp *op, int t) {
if (t == 'c') {
switch (op->type) {
case R_ANAL_OP_TYPE_RCALL:
case R_ANAL_OP_TYPE_UCALL:
case R_ANAL_OP_TYPE_CALL:
return true;
}
} else if (t == 's') {
if (op->family == R_ANAL_OP_FAMILY_PRIV) {
return true;
}
switch (op->type) {
case R_ANAL_OP_TYPE_SWI:
return true;
}
} else if (t == 'i') {
switch (op->type) {
case R_ANAL_OP_TYPE_TRAP:
case R_ANAL_OP_TYPE_ILL:
return true;
}
} else if (t == 'j') {
switch (op->type) {
case R_ANAL_OP_TYPE_JMP:
//case R_ANAL_OP_TYPE_RJMP:
//case R_ANAL_OP_TYPE_UJMP:
case R_ANAL_OP_TYPE_CJMP:
return true;
}
}
return false;
}
static inline void matchBar(ut8 *ptr, int i) {
if (ptr[i] < 0xff) {
ptr[i]++;
}
}
static ut8 *analBars(RCore *core, int type, int nblocks, int blocksize, int skipblocks, ut64 from) {
ut8 *p;
int j, i = 0;
ut8 *ptr = calloc (1, nblocks);
if (!ptr) {
eprintf ("Error: failed to malloc memory");
return NULL;
}
p = malloc (blocksize);
if (!p) {
R_FREE (ptr);
eprintf ("Error: failed to malloc memory");
return NULL;
}
for (i = 0; i < nblocks; i++) {
if (r_cons_is_breaked ()) {
break;
}
ut64 off = from + (i + skipblocks) * blocksize;
for (j = 0; j < blocksize ; j++) {
RAnalOp *op = r_core_anal_op (core, off + j, R_ANAL_OP_MASK_BASIC);
if (op) {
if (op->size < 1) {
// do nothing
if (type == 'i') {
matchBar (ptr, i);
}
} else {
if (checkAnalType (op, type)) {
matchBar (ptr, i);
}
}
if (op->size > 0) {
j += op->size - 1;
}
r_anal_op_free (op);
} else {
if (type == 'i') {
matchBar (ptr, i);
}
}
}
}
free (p);
return ptr;
}
static void cmd_print_bars(RCore *core, const char *input) {
bool print_bars = false;
ut8 *ptr = NULL;
// p=e [nblocks] [totalsize] [skip]
int nblocks = -1;
ut64 totalsize = UT64_MAX;
int skipblocks = -1;
RIOMap* map;
RListIter *iter;
ut64 from = 0, to = 0;
RList *list = r_core_get_boundaries_prot (core, -1, NULL, "zoom");
if (!list) {
goto beach;
}
ut64 blocksize = 0;
int mode = 'b'; // e, p, b, ...
int submode = 0; // q, j, ...
if (input[0]) {
char *spc = strchr (input, ' ');
if (spc) {
nblocks = r_num_math (core->num, spc + 1);
if (nblocks < 1) {
goto beach;
}
spc = strchr (spc + 1, ' ');
if (spc) {
totalsize = r_num_math (core->num, spc + 1);
spc = strchr (spc + 1, ' ');
if (spc) {
skipblocks = r_num_math (core->num, spc + 1);
}
}
}
mode = input[1];
if (mode && mode != ' ' && input[2]) {
submode = input[2];
}
}
if (skipblocks < 0) {
skipblocks = 0;
}
if (totalsize == UT64_MAX) {
if (core->file && core->io) {
totalsize = r_io_fd_size (core->io, core->file->fd);
if ((st64) totalsize < 1) {
totalsize = UT64_MAX;
}
}
if (totalsize == UT64_MAX) {
eprintf ("Cannot determine file size\n");
goto beach;
}
}
blocksize = (blocksize > 0)? (totalsize / blocksize): (core->blocksize);
if (blocksize < 1) {
eprintf ("Invalid block size: %d\n", (int)blocksize);
goto beach;
}
RIOMap* map1 = r_list_first (list);
if (map1) {
from = map1->itv.addr;
r_list_foreach (list, iter, map) {
to = r_itv_end (map->itv);
}
totalsize = to - from;
} else {
from = core->offset;
}
if (nblocks < 1) {
nblocks = totalsize / blocksize;
} else {
blocksize = totalsize / nblocks;
if (blocksize < 1) {
eprintf ("Invalid block size: %d\n", (int)blocksize);
goto beach;
}
}
switch (mode) {
case '?': // bars
r_core_cmd_help (core, help_msg_p_equal);
break;
case '=': // "p=="
switch (submode) {
case '?':
r_core_cmd_help (core, help_msg_p_equal);
break;
case '0': // 0x00 bytes
case 'f': // 0xff bytes
case 'F': // 0xff bytes
case 'p': // printable chars
case 'z': // zero terminated strings
{
ut8 *p;
ut64 i, j, k;
ptr = calloc (1, nblocks);
if (!ptr) {
eprintf ("Error: failed to malloc memory");
goto beach;
}
p = calloc (1, blocksize);
if (!p) {
R_FREE (ptr);
eprintf ("Error: failed to malloc memory");
goto beach;
}
int len = 0;
for (i = 0; i < nblocks; i++) {
ut64 off = from + blocksize * (i + skipblocks);
r_io_read_at (core->io, off, p, blocksize);
for (j = k = 0; j < blocksize; j++) {
switch (submode) {
case '0':
if (!p[j]) {
k++;
}
break;
case 'f':
if (p[j] == 0xff) {
k++;
}
break;
case 'z':
if ((IS_PRINTABLE (p[j]))) {
if (j < blocksize && p[j + 1] == 0) {
k++;
j++;
}
if (len++ > 8) {
k++;
}
} else {
len = 0;
}
break;
case 'p':
if ((IS_PRINTABLE (p[j]))) {
k++;
}
break;
}
}
ptr[i] = 256 * k / blocksize;
}
r_print_columns (core->print, ptr, nblocks, 14);
free (p);
}
break;
case 'e': // "p=e"
{
ut8 *p;
int i = 0;
ptr = calloc (1, nblocks);
if (!ptr) {
eprintf ("Error: failed to malloc memory");
goto beach;
}
p = malloc (blocksize);
if (!p) {
R_FREE (ptr);
eprintf ("Error: failed to malloc memory");
goto beach;
}
for (i = 0; i < nblocks; i++) {
ut64 off = from + (blocksize * (i + skipblocks));
r_io_read_at (core->io, off, p, blocksize);
ptr[i] = (ut8) (255 * r_hash_entropy_fraction (p, blocksize));
}
free (p);
r_print_columns (core->print, ptr, nblocks, 14);
}
break;
default:
r_print_columns (core->print, core->block, core->blocksize, 14);
break;
}
break;
case '2': // "p=2"
{
short *word = (short*) core->block;
int i, words = core->blocksize / 2;
int step = r_num_math (core->num, input + 2);
ut64 oldword = 0;
for (i = 0; i<words; i++) {
ut64 word64 = word[i] + ST16_MAX;
r_cons_printf ("0x%08"PFMT64x" %8d ", core->offset + (i *2), word[i]);
r_print_progressbar (core->print, word64 * 100 / UT16_MAX, 60);
r_cons_printf (" %d", word64 - oldword);
oldword = word64;
r_cons_newline ();
i += step;
}
}
break;
case 'd': // "p=d"
ptr = NULL;
if (input[2]) {
ut64 bufsz = r_num_math (core->num, input + 3);
ut64 curbsz = core->blocksize;
if (bufsz < 1) {
bufsz = curbsz;
}
if (bufsz > core->blocksize) {
r_core_block_size (core, bufsz);
r_core_block_read (core);
}
cmd_print_eq_dict (core, core->block, bufsz);
if (bufsz != curbsz) {
r_core_block_size (core, curbsz);
}
} else {
cmd_print_eq_dict (core, core->block, core->blocksize);
}
break;
case 'j': // "p=j" cjmp and jmp
if ((ptr = analBars (core, 'j', nblocks, blocksize, skipblocks, from))) {
print_bars = true;
}
break;
case 'c': // "p=c" calls
if ((ptr = analBars (core, 'c', nblocks, blocksize, skipblocks, from))) {
print_bars = true;
}
break;
case 'i': // "p=i" invalid
if ((ptr = analBars (core, 'i', nblocks, blocksize, skipblocks, from))) {
print_bars = true;
}
break;
case 's': // "p=s" syscalls
if ((ptr = analBars (core, 's', nblocks, blocksize, skipblocks, from))) {
print_bars = true;
}
break;
case 'm':
{
ut8 *p;
int j, i = 0;
ptr = calloc (1, nblocks);
if (!ptr) {
eprintf ("Error: failed to malloc memory");
goto beach;
}
p = malloc (blocksize);
if (!p) {
R_FREE (ptr);
eprintf ("Error: failed to malloc memory");
goto beach;
}
for (i = 0; i < nblocks; i++) {
ut64 off = from + (blocksize * (i + skipblocks));
for (j = 0; j < blocksize; j++) {
if (r_flag_get_at (core->flags, off + j, false)) {
matchBar (ptr, i);
}
}
}
free (p);
print_bars = true;
}
break;
case 'e': // "p=e" entropy
{
ut8 *p;
int i = 0;
ptr = calloc (1, nblocks);
if (!ptr) {
eprintf ("Error: failed to malloc memory");
goto beach;
}
p = malloc (blocksize);
if (!p) {
R_FREE (ptr);
eprintf ("Error: failed to malloc memory");
goto beach;
}
for (i = 0; i < nblocks; i++) {
ut64 off = from + (blocksize * (i + skipblocks));
r_io_read_at (core->io, off, p, blocksize);
ptr[i] = (ut8) (255 * r_hash_entropy_fraction (p, blocksize));
}
free (p);
print_bars = true;
}
break;
case '0': // 0x00 bytes
case 'F': // 0xff bytes
case 'p': // printable chars
case 'z': // zero terminated strings
if (blocksize > 0) {
ut8 *p;
ut64 i, j, k;
ptr = calloc (1, nblocks);
if (!ptr) {
eprintf ("Error: failed to malloc memory");
goto beach;
}
p = calloc (1, blocksize);
if (!p) {
R_FREE (ptr);
eprintf ("Error: failed to malloc memory");
goto beach;
}
int len = 0;
for (i = 0; i < nblocks; i++) {
ut64 off = from + blocksize * (i + skipblocks);
r_io_read_at (core->io, off, p, blocksize);
for (j = k = 0; j < blocksize; j++) {
switch (mode) {
case '0':
if (!p[j]) {
k++;
}
break;
case 'f':
if (p[j] == 0xff) {
k++;
}
break;
case 'z':
if ((IS_PRINTABLE (p[j]))) {
if (p[j + 1] == 0) {
k++;
j++;
}
if (len++ > 8) {
k++;
}
} else {
len = 0;
}
break;
case 'p':
if ((IS_PRINTABLE (p[j]))) {
k++;
}
break;
}
}
ptr[i] = 256 * k / blocksize;
}
free (p);
print_bars = true;
} else {
eprintf ("Invalid blocksize\n");
}
break;
case 'b': // bytes
case '\0':
ptr = calloc (1, nblocks);
r_io_read_at (core->io, from, ptr, nblocks);
// TODO: support print_bars
r_print_fill (core->print, ptr, nblocks, from, blocksize);
R_FREE (ptr);
break;
}
if (print_bars) {
int i;
switch (submode) {
case 'j': {
PJ *pj = pj_new ();
if (!pj) {
return;
}
pj_o (pj);
pj_kn (pj, "blocksize", blocksize);
pj_kn (pj, "address", from);
pj_kn (pj, "size", totalsize);
pj_k (pj, "entropy");
pj_a (pj);
for (i = 0; i < nblocks; i++) {
ut8 ep = ptr[i];
ut64 off = blocksize * i;
off += from;
pj_o (pj);
pj_kn (pj, "addr", off);
pj_ki (pj, "value", ep);
pj_end (pj);
}
pj_end (pj);
pj_end (pj);
r_cons_println (pj_string (pj));
pj_free (pj);
} break;
case 'q':
for (i = 0; i < nblocks; i++) {
ut64 off = from + (blocksize * i);
if (core->print->cur_enabled) {
if (i == core->print->cur) {
r_cons_printf ("> ");
core->num->value = off;
} else {
r_cons_printf (" ");
}
}
r_cons_printf ("0x%08"PFMT64x " %d %d\n", off, i, ptr[i]);
}
break;
default:
core->print->num = core->num;
r_print_fill (core->print, ptr, nblocks, from, blocksize);
break;
}
}
beach:
r_list_free (list);
free (ptr);
}
static int bbcmp(RAnalBlock *a, RAnalBlock *b) {
return a->addr - b->addr;
}
/* TODO: integrate this into r_anal */
static void _pointer_table(RCore *core, ut64 origin, ut64 offset, const ut8 *buf, int len, int step, int mode) {
int i;
ut64 addr;
st32 *delta; // only for step == 4
if (step < 1) {
step = 4;
}
if (!r_io_is_valid_offset (core->io, origin, 0) ||
!r_io_is_valid_offset (core->io, offset, 0)) {
return;
}
if (origin != offset) {
switch (mode) {
case '*':
r_cons_printf ("CC-@ 0x%08"PFMT64x "\n", origin);
r_cons_printf ("CC switch table @ 0x%08"PFMT64x "\n", origin);
r_cons_printf ("axd 0x%"PFMT64x " 0x%08"PFMT64x "\n", origin, offset);
break;
case '.':
r_core_cmdf (core, "CC-@ 0x%08"PFMT64x "\n", origin);
r_core_cmdf (core, "CC switch table @ 0x%08"PFMT64x "\n", origin);
r_core_cmdf (core, "f switch.0x%08"PFMT64x"=0x%08"PFMT64x"\n", origin, origin);
r_core_cmdf (core, "f jmptbl.0x%08"PFMT64x"=0x%08"PFMT64x"\n", offset, offset); //origin, origin);
r_core_cmdf (core, "axd 0x%"PFMT64x " 0x%08"PFMT64x "\n", origin, offset);
break;
}
} else if (mode == '.') {
r_core_cmdf (core, "CC-@ 0x%08"PFMT64x "\n", origin);
r_core_cmdf (core, "CC switch basic block @ 0x%08"PFMT64x "\n", offset);
r_core_cmdf (core, "f switch.0x%08"PFMT64x"=0x%08"PFMT64x"\n", offset, offset); // basic block @ 0x%08"PFMT64x "\n", offset);
}
int n = 0;
for (i = 0; (i + sizeof (st32)) <= len; i += step, n++) {
delta = (st32 *) (buf + i);
addr = offset + *delta;
if (!r_io_is_valid_offset (core->io, addr, 0)) {
// Lets check for jmptbl with not relative addresses
// Like: jmp dword [eax*4 + jmptbl.0x5435345]
if (!r_io_is_valid_offset (core->io, *delta, 0)) {
break;
}
addr = *delta;
}
if (mode == '*') {
r_cons_printf ("af case.%d.0x%"PFMT64x " 0x%08"PFMT64x "\n", n, offset, addr);
r_cons_printf ("ax 0x%"PFMT64x " 0x%08"PFMT64x "\n", offset, addr);
r_cons_printf ("ax 0x%"PFMT64x " 0x%08"PFMT64x "\n", addr, offset); // wrong, but useful because forward xrefs dont work :?
r_cons_printf ("aho case 0x%"PFMT64x " 0x%08"PFMT64x " @ 0x%08"PFMT64x "\n", (ut64)i, addr, offset + i); // wrong, but useful because forward xrefs dont work :?
r_cons_printf ("ahs %d @ 0x%08"PFMT64x "\n", step, offset + i);
} else if (mode == '.') {
r_core_cmdf (core, "af case.%d.0x%"PFMT64x " @ 0x%08"PFMT64x "\n", n, offset, addr);
r_core_cmdf (core, "ax 0x%"PFMT64x " 0x%08"PFMT64x "\n", offset, addr);
r_core_cmdf (core, "ax 0x%"PFMT64x " 0x%08"PFMT64x "\n", addr, offset); // wrong, but useful because forward xrefs dont work :?
// r_core_cmdf (core, "CC+ case %d: 0x%08"PFMT64x " @ 0x%08"PFMT64x "\n", i / step, addr, origin);
r_core_cmdf (core, "CCu case %d: @ 0x%08"PFMT64x "\n", n, addr); //, origin);
r_core_cmdf (core, "aho case %d 0x%08"PFMT64x " @ 0x%08"PFMT64x "\n", n, addr, offset + i); // wrong, but useful because forward xrefs dont work :?
r_core_cmdf (core, "ahs %d @ 0x%08"PFMT64x "\n", step, offset + i);
} else {
r_cons_printf ("0x%08"PFMT64x " -> 0x%08"PFMT64x "\n", offset + i, addr);
}
}
}
// TODO: this function is a temporary fix. All analysis should be based on realsize. However, now for same architectures realisze is not used
static ut32 tmp_get_contsize(RAnalFunction *f) {
int size = r_anal_fcn_contsize (f);
size = (size > 0)? size: r_anal_fcn_size (f);
return (size < 0)? 0: size;
}
static void pr_bb(RCore *core, RAnalFunction *fcn, RAnalBlock *b, bool emu, ut64 saved_gp, ut8 *saved_arena, char p_type, bool fromHere) {
bool show_flags = r_config_get_i (core->config, "asm.flags");
const char *orig_bb_middle = r_config_get (core->config, "asm.bb.middle");
core->anal->gp = saved_gp;
if (fromHere) {
if (b->addr < core->offset) {
core->cons->null = true;
} else {
core->cons->null = false;
}
}
if (emu) {
if (b->parent_reg_arena) {
ut64 gp;
r_reg_arena_poke (core->anal->reg, b->parent_reg_arena);
R_FREE (b->parent_reg_arena);
gp = r_reg_getv (core->anal->reg, "gp");
if (gp) {
core->anal->gp = gp;
}
} else {
r_reg_arena_poke (core->anal->reg, saved_arena);
}
}
if (b->parent_stackptr != INT_MAX) {
core->anal->stackptr = b->parent_stackptr;
}
r_config_set_i (core->config, "asm.bb.middle", false);
p_type == 'D'
? r_core_cmdf (core, "pD %d @0x%"PFMT64x, b->size, b->addr)
: r_core_cmdf (core, "pI %d @0x%"PFMT64x, b->size, b->addr);
r_config_set (core->config, "asm.bb.middle", orig_bb_middle);
if (b->jump != UT64_MAX) {
if (b->jump > b->addr) {
RAnalBlock *jumpbb = r_anal_bb_get_jumpbb (fcn, b);
if (jumpbb) {
if (emu && core->anal->last_disasm_reg && !jumpbb->parent_reg_arena) {
jumpbb->parent_reg_arena = r_reg_arena_dup (core->anal->reg, core->anal->last_disasm_reg);
}
if (jumpbb->parent_stackptr == INT_MAX) {
jumpbb->parent_stackptr = core->anal->stackptr + b->stackptr;
}
}
}
if (p_type == 'D' && show_flags) {
r_cons_printf ("| ----------- true: 0x%08"PFMT64x, b->jump);
}
}
if (b->fail != UT64_MAX) {
if (b->fail > b->addr) {
RAnalBlock *failbb = r_anal_bb_get_failbb (fcn, b);
if (failbb) {
if (emu && core->anal->last_disasm_reg && !failbb->parent_reg_arena) {
failbb->parent_reg_arena = r_reg_arena_dup (core->anal->reg, core->anal->last_disasm_reg);
}
if (failbb->parent_stackptr == INT_MAX) {
failbb->parent_stackptr = core->anal->stackptr + b->stackptr;
}
}
}
if (p_type == 'D' && show_flags) {
r_cons_printf (" false: 0x%08"PFMT64x, b->fail);
}
}
if (p_type == 'D' && show_flags) {
r_cons_newline ();
}
}
#if 0
dsmap {
r_itv_t addr;
ut64 size;
ut8 *dis;
}
#endif
#define P(x) (core->cons && core->cons->context->pal.x)? core->cons->context->pal.x
#if 0
static void disasm_recursive_old(RCore *core, ut64 addr, char type_print) {
bool push[512];
int pushes = 0;
RAnalOp aop = {0};
int i, j, ret;
ut8 *buf = calloc (core->blocksize, 1); // begin of instruction
if (!buf) {
return;
}
ut8 *raw = calloc (core->blocksize, 1); // instruction coverage
if (!raw) {
free (buf);
return;
}
int count = 64;
int base = 0;
for (i = 0; count > 0 && i < core->blocksize; i++) {
r_anal_op_fini (&aop);
ret = r_anal_op (core->anal, &aop, addr + i, core->block + i , core->blocksize - i);
if (ret < 0 || aop.size < 1) {
continue;
}
buf[i] = 1;
for (j = i; j < i + aop.size; j++) {
raw[j] = 1;
}
// r_core_cmdf (core, "pd 1 @ 0x%08"PFMT64x, addr + i);
switch (aop.type) {
case R_ANAL_OP_TYPE_JMP:
r_core_cmdf (core, "pD %d @ 0x%08"PFMT64x, i + aop.size - base, addr + base);
i = aop.jump - addr - 1;
base = i + 1;
count--;
continue;
break;
#if 0
case R_ANAL_OP_TYPE_CJMP:
if (aop.jump > addr + i) {
if (pushes > 500) {
eprintf ("Too deep\n");
}
push[pushes++] = i + aop.size;
i = aop.jump - addr - 1;
continue;
}
break;
#endif
case R_ANAL_OP_TYPE_UCJMP:
break;
}
i += aop.size - 1;
}
#if 0
if (base < i) {
r_cons_printf ("base:\n");
r_core_cmdf (core, "pD %d @ 0x%08"PFMT64x, i - base, addr + base); //+ aop.size - base, addr + base);
r_cons_printf ("base:\n");
}
#endif
// unlikely
int p;
for (p = 0; p<pushes; p++) {
r_cons_printf ("PUSH 0x%08"PFMT64x"\n", addr + push[p]);
for (i = push[p]; i < core->blocksize; i++) {
if (buf[i]) {
break;
}
buf[i] = 1;
r_anal_op_fini (&aop);
ret = r_anal_op (core->anal, &aop, addr + i, core->block + i , core->blocksize - i);
if (ret < 0 || aop.size < 1) {
continue;
}
// r_core_cmdf (core, "pd 1 @ 0x%08"PFMT64x, addr + i);
switch (aop.type) {
case R_ANAL_OP_TYPE_JMP:
if (aop.jump > addr + i) {
r_core_cmdf (core, "pD %d @ 0x%08"PFMT64x, i + aop.size - base, addr + base);
i = aop.jump - addr - 1;
base = i + 1;
continue;
}
break;
#if 0
case R_ANAL_OP_TYPE_CJMP:
if (aop.jump > addr + i) {
if (pushes > 500) {
eprintf ("Too deep\n");
}
push[pushes++] = i + aop.size;
i = aop.jump - addr - 1;
continue;
}
break;
#endif
case R_ANAL_OP_TYPE_UCJMP:
break;
}
i += aop.size - 1;
}
}
#if 0
// linear disasm
for (i = 0; i< core->blocksize; i++) {
if (!buf[i]) {
continue;
}
r_core_cmdf (core, "pd 1 @ 0x%08"PFMT64x, addr + i);
r_anal_op_fini (&aop);
ret = r_anal_op (core->anal, &aop, addr + i, core->block + i , core->blocksize - i);
i += aop.size
}
#endif
}
#endif
static void disasm_until_ret(RCore *core, ut64 addr, char type_print) {
int p = 0;
ut8 *buf = calloc (core->blocksize, 1);
if (!buf) {
return;
}
(void)r_io_read_at (core->io, addr, buf, core->blocksize);
while (p + 4 < core->blocksize) {
RAnalOp *op = r_core_anal_op (core, addr + p, R_ANAL_OP_MASK_BASIC);
if (op) {
r_cons_printf ("0x%08"PFMT64x" %10s %s\n", addr + p, "", op->mnemonic);
if (op->type == R_ANAL_OP_TYPE_RET) {
break;
}
p += op->size;
} else {
eprintf ("[pdp] Cannot get op at 0x%08"PFMT64x"\n", addr + p);
r_anal_op_free (op);
break;
}
//r_io_read_at (core->io, n, rbuf, 512);
r_anal_op_free (op);
}
free (buf);
}
static void disasm_ropchain(RCore *core, ut64 addr, char type_print) {
int p = 0;
ut64 n = 0;
ut8 *buf = calloc (core->blocksize, 1);
(void)r_io_read_at (core->io, addr, buf, core->blocksize);
while (p + 4 < core->blocksize) {
if (core->assembler->bits == 64) {
n = r_read_ble64 (buf + p, core->print->big_endian);
} else {
n = r_read_ble32 (buf + p, core->print->big_endian);
}
r_cons_printf ("[0x%08"PFMT64x"] 0x%08"PFMT64x"\n", addr + p, n);
disasm_until_ret (core, n, type_print);
if (core->assembler->bits == 64) {
p += 8;
} else {
p += 4;
}
}
free (buf);
}
static void disasm_recursive(RCore *core, ut64 addr, int count, char type_print) {
RAnalOp aop = {0};
int ret;
ut8 buf[128];
PJ *pj = NULL;
if (type_print == 'j') {
pj = pj_new ();
if (!pj) {
return;
}
pj_a (pj);
}
while (count-- > 0) {
r_io_read_at (core->io, addr, buf, sizeof (buf));
r_anal_op_fini (&aop);
ret = r_anal_op (core->anal, &aop, addr, buf, sizeof (buf), R_ANAL_OP_MASK_BASIC);
if (ret < 0 || aop.size < 1) {
addr++;
continue;
}
// r_core_cmdf (core, "pD %d @ 0x%08"PFMT64x, aop.size, addr);
if (type_print == 'j') {
r_core_print_disasm_json (core, addr, buf, sizeof (buf), 1, pj);
} else {
r_core_cmdf (core, "pd 1 @ 0x%08"PFMT64x, addr);
}
switch (aop.type) {
case R_ANAL_OP_TYPE_JMP:
addr = aop.jump;
continue;
break;
case R_ANAL_OP_TYPE_UCJMP:
break;
case R_ANAL_OP_TYPE_RET:
count = 0; // stop disassembling when hitting RET
break;
}
addr += aop.size;
}
if (type_print == 'j') {
pj_end (pj);
r_cons_printf ("%s\n", pj_string (pj));
pj_free (pj);
}
}
#if 0
static void _disasm_recursive(RCore *core, ut64 addr, char type_print) {
bool show_flags = r_config_get_i (core->config, "asm.flags");
bool show_bytes = r_config_get_i (core->config, "asm.bytes");
bool show_offset = r_config_get_i (core->config, "asm.offset");
bool show_imtrim = r_config_get_i (core->config, "asm.imm.trim");
Sdb *db = sdb_new0 ();
RAsmOp asmop = {0};
RAnalOp aop = {0};
int i, ret;
ut8 *buf = core->block;
int loop, len = core->blocksize;
for (loop = 0; loop < 2 ; loop ++) {
for (i = 0; i < len; i+= aop.size) {
r_anal_op_fini (&aop);
r_asm_set_pc (core->assembler, addr + i);
//if (i + 8 >= len) {
// eprintf ("WARNING: block size is too small\n");
// TODO: reimplement using dynamic memory accesses, not just the block
// break;
//}
ret = r_asm_disassemble (core->assembler, &asmop, buf + i, len - i);
if (ret < 0) {
asmop.size = 1;
continue;
}
ret = r_anal_op (core->anal, &aop, addr + i, buf + i , len - i);
if (ret < 0) {
aop.size = 1;
continue;
}
if (loop > 0) {
if (show_flags) {
const char *x = sdb_const_get (db, sdb_fmt ("label.0x%"PFMT64x, addr + i), NULL);
if (x) {
r_cons_printf ("%s:\n", x);
}
}
char *asm_str = asmop.buf_asm;
char *color_reg = P(reg): Color_YELLOW;
char *color_num = P(num): Color_CYAN;
asm_str = r_print_colorize_opcode (core->print, asm_str, color_reg, color_num, false);
if (show_imtrim) {
r_parse_immtrim (asm_str);
}
if (show_offset) {
r_print_offset (core->print, addr + i, 0, 0, 0, 0, NULL);
}
if (show_bytes) {
char *hexstr = r_print_hexpair (core->print, asmop.buf_hex, -1);
const char *pad = r_str_pad (' ', 20 - strlen (asmop.buf_hex));
r_cons_printf (" %s%s %s\n", pad, hexstr, asm_str);
free (hexstr);
} else {
r_cons_printf (" %s\n", asm_str);
}
}
switch (aop.type) {
case R_ANAL_OP_TYPE_JMP:
break;
case R_ANAL_OP_TYPE_CALL:
case R_ANAL_OP_TYPE_CJMP:
sdb_set (db, sdb_fmt ("label.0x%"PFMT64x, aop.jump),
sdb_fmt ("from.0x%"PFMT64x, addr + i), 0);
break;
}
if (aop.size < 1) {
aop.size = 1;
}
}
}
r_anal_op_fini (&aop);
sdb_free (db);
}
#endif
static void func_walk_blocks(RCore *core, RAnalFunction *f, char input, char type_print, bool fromHere) {
RListIter *iter;
RAnalBlock *b = NULL;
RAnalFunction *tmp_func;
RListIter *locs_it = NULL;
const char *orig_bb_middle = r_config_get (core->config, "asm.bb.middle");
r_config_set_i (core->config, "asm.bb.middle", false);
PJ *pj = NULL;
if (f->fcn_locs) {
locs_it = f->fcn_locs->head;
}
// XXX: hack must be reviewed/fixed in code analysis
if (!b) {
if (r_list_length (f->bbs) >= 1) {
ut32 fcn_size = r_anal_fcn_realsize (f);
b = r_list_get_top (f->bbs);
if (b->size > fcn_size) {
b->size = fcn_size;
}
}
}
r_list_sort (f->bbs, (RListComparator) bbcmp);
if (input == 'j' && b) {
pj = pj_new ();
if (!pj) {
return;
}
pj_a (pj);
for (; locs_it && (tmp_func = locs_it->data); locs_it = locs_it->n) {
if (r_cons_is_breaked ()) {
break;
}
if (fromHere) {
if (b->addr < core->offset) {
core->cons->null = true;
} else {
core->cons->null = false;
}
}
if (tmp_func->addr > f->addr) {
break;
}
r_list_foreach (tmp_func->bbs, iter, b) {
// const char *cmd = (type_print == 'D')? "pDj": "pIj";
// r_core_cmdf (core, "%s %d @ 0x%"PFMT64x, cmd, b->size, b->addr);
ut8 *buf = malloc (b->size);
if (buf) {
r_io_read_at (core->io, b->addr, buf, b->size);
r_core_print_disasm_json (core, b->addr, buf, b->size, 0, pj);
free (buf);
} else {
eprintf ("cannot allocate %d byte(s)\n", b->size);
}
}
}
r_list_foreach (f->bbs, iter, b) {
if (fromHere) {
if (b->addr < core->offset) {
core->cons->null = true;
} else {
core->cons->null = false;
}
}
#if 0
r_core_print_disasm_json (core, core->offset, buf, bsize, 0);
const char *cmd = (type_print == 'D')? "pDj": "pIj";
r_core_cmdf (core, "%s %d @ 0x%"PFMT64x, cmd, b->size, b->addr);
#endif
ut8 *buf = malloc (b->size);
if (buf) {
r_io_read_at (core->io, b->addr, buf, b->size);
r_core_print_disasm_json (core, b->addr, buf, b->size, 0, pj);
free (buf);
} else {
eprintf ("cannot allocate %d byte(s)\n", b->size);
}
}
for (; locs_it && (tmp_func = locs_it->data); locs_it = locs_it->n) {
if (r_cons_is_breaked ()) {
break;
}
r_list_foreach (tmp_func->bbs, iter, b) {
if (fromHere) {
if (b->addr < core->offset) {
core->cons->null = true;
} else {
core->cons->null = false;
}
}
#if 0
const char *cmd = (type_print == 'D')? "pDj": "pIj";
r_core_cmdf (core, "%s %d @0x%"PFMT64x, cmd, b->size, b->addr);
#endif
ut8 *buf = malloc (b->size);
if (buf) {
r_io_read_at (core->io, b->addr, buf, b->size);
r_core_print_disasm_json (core, b->addr, buf, b->size, 0, pj);
free (buf);
} else {
eprintf ("cannot allocate %d byte(s)\n", b->size);
}
}
}
pj_end (pj);
r_cons_printf ("%s", pj_string (pj));
pj_free (pj);
} else {
bool asm_lines = r_config_get_i (core->config, "asm.lines.bb");
bool emu = r_config_get_i (core->config, "asm.emu");
ut64 saved_gp = 0;
ut8 *saved_arena = NULL;
int saved_stackptr = core->anal->stackptr;
if (emu) {
saved_gp = core->anal->gp;
saved_arena = r_reg_arena_peek (core->anal->reg);
}
r_config_set_i (core->config, "asm.lines.bb", 0);
for (; locs_it && (tmp_func = locs_it->data); locs_it = locs_it->n) {
if (tmp_func->addr >= f->addr) {
break;
}
r_list_foreach (tmp_func->bbs, iter, b) {
pr_bb (core, tmp_func, b, emu, saved_gp, saved_arena, type_print, fromHere);
}
}
r_list_foreach (f->bbs, iter, b) {
pr_bb (core, f, b, emu, saved_gp, saved_arena, type_print, fromHere);
}
for (; locs_it && (tmp_func = locs_it->data); locs_it = locs_it->n) {
if (r_cons_is_breaked ()) {
break;
}
// this should be more advanced
r_list_foreach (tmp_func->bbs, iter, b) {
pr_bb (core, tmp_func, b, emu, saved_gp, saved_arena, type_print, fromHere);
}
}
if (emu) {
core->anal->gp = saved_gp;
if (saved_arena) {
r_reg_arena_poke (core->anal->reg, saved_arena);
R_FREE (saved_arena);
}
}
core->anal->stackptr = saved_stackptr;
r_config_set_i (core->config, "asm.lines.bb", asm_lines);
}
r_config_set (core->config, "asm.bb.middle", orig_bb_middle);
}
static inline char cmd_pxb_p(char input) {
return IS_PRINTABLE (input)? input: '.';
}
static inline int cmd_pxb_k(const ut8 *buffer, int x) {
return buffer[3 - x] << (8 * x);
}
static const char* bits_to_c_code_fmtstr(int bits) {
switch (bits) {
case 16:
return "0x%04x";
case 32:
return "0x%08xU";
case 64:
return "0x%016" PFMT64x "ULL";
default:
return "0x%02x";
}
}
static void print_c_code(RPrint *p, ut64 addr, ut8 *buf, int len, int ws, int w) {
const char *fmtstr;
int i, bits;
ws = R_MAX (1, R_MIN (ws, 8));
bits = ws * 8;
fmtstr = bits_to_c_code_fmtstr (bits);
len /= ws;
p->cb_printf ("#define _BUFFER_SIZE %d\n", len);
p->cb_printf ("const uint%d_t buffer[%d] = {", bits, len);
p->interrupt = 0;
for (i = 0; !p->interrupt && i < len; i++) {
if (!(i % w)) {
p->cb_printf ("\n ");
}
r_print_cursor (p, i, 1, 1);
p->cb_printf (fmtstr, r_read_ble (buf, p->big_endian, bits));
if ((i + 1) < len) {
p->cb_printf (",");
if ((i + 1) % w) {
p->cb_printf (" ");
}
}
r_print_cursor (p, i, 1, 0);
buf += ws;
}
p->cb_printf ("\n};\n");
}
R_API void r_print_code(RPrint *p, ut64 addr, ut8 *buf, int len, char lang) {
int i, w = p->cols * 0.7;
if (w < 1) {
w = 1;
}
switch (lang) {
case '?':
r_core_cmd_help ((RCore *)p->user, help_msg_pc);
break;
case '*':
p->cb_printf ("wx ");
for (i = 0; !p->interrupt && i < len; i++) {
if (i && !(i % 16)) {
p->cb_printf (";s+16\nwx ");
}
p->cb_printf ("%02x", buf[i]);
}
if (i && !(i % 16)) {
p->cb_printf (";s+16\n");
} else {
p->cb_printf (";s+%d\n", (i % 16));
}
p->cb_printf ("s-%d\n", len);
break;
case 'A': // "pcA"
/* implemented in core because of disasm :( */
break;
case 'a': // "pca"
p->cb_printf ("shellcode:");
for (i = 0; !p->interrupt && i < len; i++) {
if (!(i % 8)) {
p->cb_printf ("\n.byte ");
} else {
p->cb_printf (", ");
}
p->cb_printf ("0x%02x", buf[i]);
}
p->cb_printf ("\n.equ shellcode_len, %d\n", len);
break;
case 's': // "pcs"
p->cb_printf ("\"");
for (i = 0; !p->interrupt && i < len; i++) {
p->cb_printf ("\\x%02x", buf[i]);
}
p->cb_printf ("\"\n");
break;
case 'S': // "pcS"
{
const int trunksize = 16;
for (i = 0; !p->interrupt && i < len; i++) {
if (!(i % trunksize)) {
p->cb_printf ("printf \"");
}
p->cb_printf ("\\%03o", buf[i]);
if ((i % trunksize) == (trunksize - 1)) {
p->cb_printf ("\" %s bin\n", (i <= trunksize)? ">": ">>");
}
}
if ((i % trunksize)) {
p->cb_printf ("\" %s bin\n", (i <= trunksize)? ">": ">>");
}
} break;
case 'J': { // "pcJ"
char *out = malloc (len * 3);
p->cb_printf ("var buffer = new Buffer(\"");
out[0] = 0;
r_base64_encode (out, buf, len);
p->cb_printf ("%s", out);
p->cb_printf ("\", 'base64');\n");
free (out);
} break;
case 'j': // "pcj"
p->cb_printf ("[");
for (i = 0; !p->interrupt && i < len; i++) {
r_print_cursor (p, i, 1, 1);
p->cb_printf ("%d%s", buf[i], (i + 1 < len)? ",": "");
r_print_cursor (p, i, 1, 0);
}
p->cb_printf ("]\n");
break;
case 'P':
case 'p': // "pcp" "pcP"
p->cb_printf ("import struct\nbuf = struct.pack (\"%dB\", *[", len);
for (i = 0; !p->interrupt && i < len; i++) {
if (!(i % w)) {
p->cb_printf ("\n");
}
r_print_cursor (p, i, 1, 1);
p->cb_printf ("0x%02x%s", buf[i], (i + 1 < len)? ",": "])");
r_print_cursor (p, i, 1, 0);
}
p->cb_printf ("\n");
break;
case 'h': // "pch"
print_c_code (p, addr, buf, len, 2, p->cols / 2); // 9
break;
case 'w': // "pcw"
print_c_code (p, addr, buf, len, 4, p->cols / 3); // 6);
break;
case 'd': // "pcd"
print_c_code (p, addr, buf, len, 8, p->cols / 5); //3);
break;
default:
print_c_code (p, addr, buf, len, 1, p->cols / 1.5); // 12);
break;
}
}
static int cmd_print(void *data, const char *input) {
RCore *core = (RCore *) data;
int i, l, len, ret;
ut8* block;
ut32 tbs = core->blocksize;
ut64 n, off, from, to, at, ate, piece;
ut64 tmpseek = UT64_MAX;
const int addrbytes = core->io->addrbytes;
i = l = len = ret = 0;
n = off = from = to = at = ate = piece = 0;
PJ *pj = NULL;
r_print_init_rowoffsets (core->print);
off = UT64_MAX;
l = len = core->blocksize;
if (input[0] && input[1]) {
int idx = (input[0] == 'h')? 2: 1;
const char *p = off? strchr (input + idx, ' '): NULL;
if (p) {
l = (int) r_num_math (core->num, p + 1);
/* except disasm and memoryfmt (pd, pm) */
if (input[0] != 'd' && input[0] != 'D' && input[0] != 'm' &&
input[0] != 'a' && input[0] != 'f' && input[0] != 'i' && input[0] != 'I') {
if (l < 0) {
off = core->offset + l;
len = l = -l;
tmpseek = core->offset;
} else {
len = l;
if (l > core->blocksize) {
if (core->fixedblock) {
l = core->blocksize;
} else if (!r_core_block_size (core, l)) {
goto beach;
}
}
}
} else {
len = l;
}
}
}
if (len > core->blocksize) {
len = core->blocksize;
}
if (input[0] != 'd' && input[0] != 'm' && input[0] != 'a' && input[0] != 'f') {
n = core->blocksize_max;
i = (int) n;
if (i != n) {
i = 0;
}
if (i && l > i) {
eprintf ("This block size is too big (0x%"PFMT64x
" < 0x%x). Did you mean 'p%c @ %s' instead?\n",
n, l, *input, input + 2);
goto beach;
}
}
if (input[0] == 'x' || input[0] == 'D') {
if (l > 0 && tmpseek == UT64_MAX) {
if (!r_core_block_size (core, l)) {
eprintf ("This block size is too big. Did you mean 'p%c @ %s' instead?\n",
*input, input + 2);
goto beach;
}
}
}
if (input[0] && input[0] != 'z' && input[1] == 'f' && input[2]!='?') {
RAnalFunction *f = r_anal_get_fcn_in (core->anal, core->offset, 0);
// R_ANAL_FCN_TYPE_FCN|R_ANAL_FCN_TYPE_SYM);
if (f) {
len = r_anal_fcn_size (f);
if (len > core->blocksize) {
len = core->blocksize;
}
} else {
eprintf ("p: Cannot find function at 0x%08"PFMT64x "\n", core->offset);
core->num->value = 0;
goto beach;
}
}
// TODO figure out why `f eax=33; f test=eax; pa call test` misassembles if len is 0
core->num->value = len ? len : core->blocksize;
if (off != UT64_MAX) {
r_core_seek (core, off, SEEK_SET);
r_core_block_read (core);
}
// TODO After core->block is removed, this should be changed to a block read.
block = core->block;
switch (*input) {
case 'w': // "pw"
if (input[1] == 'n') {
cmd_print_pwn (core);
} else if (input[1] == 'd') {
if (!r_sandbox_enable (0)) {
char *cwd = r_sys_getdir ();
if (cwd) {
r_cons_println (cwd);
free (cwd);
}
}
} else {
r_cons_printf ("| pwd display current working directory\n");
}
break;
case 'j': // "pj"
if (input[1] == '?') {
r_core_cmd_help (core, help_msg_pj);
} else if (input[1] == '.') {
if (input[2] == '.') {
ut8 *data = calloc (core->offset + 1, 1);
if (data) {
data[core->offset] = 0;
(void)r_io_read_at (core->io, 0, data, core->offset);
char *res = r_print_json_path ((const char *)data, core->offset);
if (res) {
eprintf ("-> res(%s)\n", res);
}
/*
char *res = r_print_json_indent ((char*)data, false, " ", NULL);
print_json_path (core, res);
free (res);
*/
} else {
eprintf ("Cannot allocate %d\n", (int)(core->offset));
}
} else {
r_core_cmdf (core, "pj %"PFMT64u" @ 0", core->offset);
}
} else {
if (core->blocksize < 4 || !memcmp (core->block, "\xff\xff\xff\xff", 4)) {
eprintf ("Cannot read\n");
} else {
char *res = r_print_json_indent ((const char *)core->block, true, " ", NULL);
r_cons_printf ("%s\n", res);
free (res);
}
}
break;
case 'h': // "ph"
cmd_print_ph (core, input + 1);
break;
case 'v': // "pv"
cmd_print_pv (core, input + 1, block);
break;
case '-': // "p-"
return cmd_print_blocks (core, input + 1);
case '=': // "p="
cmd_print_bars (core, input);
break;
case 'A': // "pA"
{
const ut64 saved_from = r_config_get_i (core->config, "search.from"),
saved_to = r_config_get_i (core->config, "search.to"),
saved_maxhits = r_config_get_i (core->config, "search.maxhits");
int want = r_num_math (core->num, input + 1);
if (input[1] == '?') {
r_core_cmd0 (core, "/A?");
} else {
r_config_set_i (core->config, "search.maxhits", want);
r_config_set_i (core->config, "search.from", core->offset);
r_config_set_i (core->config, "search.to", core->offset + core->blocksize);
r_core_cmd0 (core, "/A");
r_config_set_i (core->config, "search.maxhits", saved_maxhits);
r_config_set_i (core->config, "search.from", saved_from);
r_config_set_i (core->config, "search.to", saved_to);
}
}
break;
case 'a': // "pa"
{
const char *arg = NULL;
if (input[1] != '\0') {
arg = r_str_trim_ro (input + 2);
}
if (input[1] == 'e') { // "pae"
if (input[2] == '?') {
r_cons_printf ("|Usage: pae [asm] print ESIL expression of the given assembly expression\n");
} else {
int printed = 0;
int bufsz;
RAnalOp aop = {0};
r_asm_set_pc (core->assembler, core->offset);
RAsmCode *acode = r_asm_massemble (core->assembler, input + 2);
if (acode && *acode->buf_hex) {
bufsz = strlen (acode->buf_hex) >> 1;
while (printed < bufsz) {
aop.size = 0;
if (r_anal_op (core->anal, &aop, core->offset,
(const ut8 *)acode->buf + printed, bufsz - printed, R_ANAL_OP_MASK_ESIL) > 0) {
const char *str = R_STRBUF_SAFEGET (&aop.esil);
r_cons_println (str);
} else {
eprintf ("Cannot decode instruction\n");
break;
}
if (aop.size < 1) {
eprintf ("Cannot decode instruction\n");
break;
}
printed += aop.size;
r_anal_op_fini (&aop);
}
}
}
} else if (input[1] == 'D') { // "paD"
if (input[2] == '?') {
r_cons_printf ("|Usage: paD [hex] print assembly expression from hexpairs and show hexpairs\n");
} else {
r_core_cmdf (core, "pdi@x:%s", input + 2);
}
} else if (input[1] == 'd') { // "pad*"
switch (input[2]) {
case 'e': // "pade"
if (input[3] == '?') {
r_cons_printf ("|Usage: pade [hex] print ESIL expression from hexpairs\n");
} else {
int printed = 0;
int bufsz;
RAnalOp aop = { 0 };
char *hex_arg = calloc (1, strlen (arg) + 1);
if (hex_arg) {
bufsz = r_hex_str2bin (arg + 1, (ut8 *)hex_arg);
while (printed < bufsz) {
aop.size = 0;
if (r_anal_op (core->anal, &aop, core->offset,
(const ut8 *)hex_arg + printed, bufsz - printed, R_ANAL_OP_MASK_ESIL) > 0) {
const char *str = R_STRBUF_SAFEGET (&aop.esil);
r_cons_println (str);
} else {
eprintf ("Cannot decode instruction\n");
break;
}
if (aop.size < 1) {
eprintf ("Cannot decode instruction\n");
break;
}
printed += aop.size;
r_anal_op_fini (&aop);
}
free (hex_arg);
}
}
break;
case ' ': // "pad"
{
r_asm_set_pc (core->assembler, core->offset);
RAsmCode *c = r_asm_mdisassemble_hexstr (core->assembler, arg);
if (c) {
r_cons_print (c->buf_asm);
r_asm_code_free (c);
} else {
eprintf ("Invalid hexstr\n");
}
break;
}
case '?': // "pad?"
r_cons_printf ("|Usage: pad [hex] print assembly expression from hexpairs\n");
break;
default:
r_cons_printf ("|Usage: pa[edD] [asm|hex] print (dis)assembled\n");
break;
}
} else if (input[1] == '?') {
r_core_cmd_help (core, help_msg_pa);
} else {
int i;
int bytes;
r_asm_set_pc (core->assembler, core->offset);
RAsmCode *acode = r_asm_massemble (core->assembler, input + 1);
if (acode && *acode->buf_hex) {
bytes = strlen (acode->buf_hex) >> 1;
for (i = 0; i < bytes; i++) {
ut8 b = acode->buf[i]; // core->print->big_endian? (bytes - 1 - i): i ];
r_cons_printf ("%02x", b);
}
r_cons_newline ();
r_asm_code_free (acode);
}
}
}
break;
case 'b': { // "pb"
if (input[1] == '?') {
r_cons_printf ("|Usage: p[bB] [len] ([skip]) ; see also pB and pxb\n");
} else if (l != 0) {
int from, to;
const int size = len * 8;
char *spc, *buf = malloc (size + 1);
spc = strchr (input, ' ');
if (spc) {
len = r_num_math (core->num, spc + 1);
if (len < 1) {
len = 1;
}
spc = strchr (spc + 1, ' ');
if (spc) {
from = r_num_math (core->num, spc + 1);
} else {
from = 0;
}
to = from + len;
} else {
from = 0;
to = size;
}
if (buf) {
int buf_len;
r_str_bits (buf, block, size, NULL);
buf_len = strlen (buf);
if (from >= 0 && to >= 0) {
if (from >= buf_len) {
from = buf_len;
}
if (to < buf_len) {
buf[to] = 0;
//buf[buf_len - 1] = 0;
}
r_cons_println (buf + from);
}
free (buf);
} else {
eprintf ("ERROR: Cannot malloc %d byte(s)\n", size);
}
}
}
break;
case 'B': { // "pB"
if (input[1] == '?') {
r_cons_printf ("|Usage: p[bB] [len] bitstream of N bytes\n");
} else if (l != 0) {
int size;
char *buf;
if (!r_core_block_size (core, len)) {
len = core->blocksize;
}
size = len * 8;
buf = malloc (size + 1);
if (buf) {
r_str_bits (buf, core->block, size, NULL);
r_cons_println (buf);
free (buf);
} else {
eprintf ("ERROR: Cannot malloc %d byte(s)\n", size);
}
}
}
break;
case 'I': // "pI"
switch (input[1]) {
case 'j': // "pIj" is the same as pDj
if (l != 0) {
if (input[2]) {
cmd_pDj (core, input + 2);
} else {
cmd_pDj (core, sdb_fmt ("%d", core->blocksize));
}
}
break;
case 'f': // "pIf"
{
const RAnalFunction *f = r_anal_get_fcn_in (core->anal, core->offset,
R_ANAL_FCN_TYPE_FCN | R_ANAL_FCN_TYPE_SYM);
if (f) {
r_core_print_disasm_instructions (core,
r_anal_fcn_size (f), 0);
break;
}
}
case 'd': // "pId" is the same as pDi
if (l) {
r_core_disasm_pdi (core, 0, l, 0);
}
break;
case '?': // "pi?"
r_cons_printf ("|Usage: p[iI][df] [len] print N instructions/bytes"
"(f=func) (see pi? and pdi)\n");
break;
default:
if (l) {
r_core_print_disasm_instructions (core, l, 0);
}
}
break;
case 'i': // "pi"
switch (input[1]) {
case '?':
// r_cons_printf ("|Usage: pi[defj] [num]\n");
r_core_cmd_help (core, help_msg_pi);
break;
case 'a': // "pia" is like "pda", but with "pi" output
if (l != 0) {
r_core_print_disasm_all (core, core->offset,
l, len, 'i');
}
break;
case 'j': // pij is the same as pdj
if (l != 0) {
cmd_pdj (core, input + 2, block);
}
break;
case 'd': // "pid" is the same as pdi
if (l != 0) {
r_core_disasm_pdi (core, l, 0, 0);
}
break;
case 'e': // "pie"
if (l != 0) {
r_core_disasm_pdi (core, l, 0, 'e');
}
break;
case 'f': // "pif"
if (input[2] == '?') { // "pif?"
r_core_cmd_help(core, help_msg_pif);
} else if (input[2] == 'j') {
r_core_cmdf (core, "pdfj%s", input + 3);
} else if (input[2] == 'c') { // "pifc"
RListIter *iter;
RAnalRef *refi;
RList *refs = NULL;
PJ *pj = NULL;
// check for bounds
if (input[3] !=0) {
if (input[3] == 'j') { // "pifcj"
pj = pj_new ();
pj_a (pj);
}
}
// get function in current offset
RAnalFunction *f = r_anal_get_fcn_in (core->anal, core->offset,
R_ANAL_FCN_TYPE_FCN | R_ANAL_FCN_TYPE_SYM);
// validate that a function was found in the given address
if (!f) {
// print empty json object
if (pj) {
pj_end (pj);
r_cons_println (pj_string(pj));
pj_free (pj);
}
break;
}
// get all the calls of the function
refs = r_core_anal_fcn_get_calls (core, f);
// sanity check
if (!r_list_empty (refs)) {
// store current configurations
RConfigHold *hc = r_config_hold_new (core->config);
r_config_save_num (hc, "asm.offset", NULL);
r_config_save_num (hc, "asm.comments", NULL);
r_config_save_num (hc, "asm.tabs", NULL);
r_config_save_num (hc, "asm.bytes", NULL);
r_config_save_num (hc, "emu.str", NULL);
// temporarily replace configurations
r_config_set_i (core->config, "asm.offset", false);
r_config_set_i (core->config, "asm.comments", false);
r_config_set_i (core->config, "asm.tabs", 0);
r_config_set_i (core->config, "asm.bytes", false);
r_config_set_i (core->config, "emu.str", false);
// iterate over all call references
r_list_foreach (refs, iter, refi) {
if (pj) {
RFlagItem *f = r_flag_get_i (core->flags, refi->addr);
char *dst = r_str_newf ((f? f->name: "0x%08"PFMT64x), refi->addr);
pj_o (pj);
pj_ks (pj, "dest", dst);
pj_kn (pj, "addr", refi->addr);
pj_kn (pj, "at", refi->at);
pj_end (pj);
} else {
char *s = r_core_cmd_strf (core, "pdi %i @ 0x%08"PFMT64x, 1, refi->at);
r_cons_printf ("%s", s);
}
}
// restore saved configuration
r_config_restore (hc);
r_config_hold_free (hc);
}
// print json object
if (pj) {
pj_end (pj);
r_cons_println (pj_string (pj));
pj_free (pj);
}
} else if (l != 0) {
RAnalFunction *f = r_anal_get_fcn_in (core->anal, core->offset,
R_ANAL_FCN_TYPE_FCN | R_ANAL_FCN_TYPE_SYM);
if (f) {
ut32 bsz = core->blocksize;
// int fsz = r_anal_fcn_realsize (f);
int fsz = r_anal_fcn_size (f); // we want max-min here
r_core_block_size (core, fsz);
r_core_print_disasm_instructions (core, fsz, 0);
r_core_block_size (core, bsz);
} else {
r_core_print_disasm_instructions (core,
core->blocksize, l);
}
}
break;
case 'r': // "pir"
{
RAnalFunction *f = r_anal_get_fcn_in (core->anal, core->offset,
R_ANAL_FCN_TYPE_FCN | R_ANAL_FCN_TYPE_SYM);
if (f) {
func_walk_blocks (core, f, input[2], 'I', input[2] == '.');
} else {
eprintf ("Cannot find function at 0x%08"PFMT64x "\n", core->offset);
core->num->value = 0;
}
}
break;
case 'b': // "pib"
{
RAnalBlock *b = r_anal_bb_from_offset (core->anal, core->offset);
if (b) {
r_core_print_disasm_instructions (core, b->size - (core->offset - b->addr), 0);
} else {
eprintf ("Cannot find function at 0x%08"PFMT64x "\n", core->offset);
core->num->value = 0;
}
}
break;
default: // "pi"
if (l != 0) {
r_core_print_disasm_instructions (core, 0, l);
}
break;
}
goto beach;
case 'D': // "pD"
case 'd': // "pd"
{
ut64 use_blocksize = core->blocksize;
ut8 bw_disassemble = false;
ut32 pd_result = false, processed_cmd = false;
bool formatted_json = false;
if (input[1] && input[2]) {
// "pd--" // context disasm
if (!strncmp (input + 1, "--", 2)) {
char *offs = r_str_newf ("%s", input + 2);
if (offs) {
ut64 sz = r_num_math (core->num, offs);
char *fmt;
if (((st64)sz * -1) > core->offset) {
// the offset is smaller than the negative value
// so only print -offset
fmt = r_str_newf ("d %"PFMT64d, -1 * core->offset);
} else {
fmt = r_str_newf ("d %s", input + 2);
}
if (fmt) {
cmd_print (core, fmt);
strcpy (fmt + 2, input + 3);
cmd_print (core, fmt);
free (fmt);
}
free (offs);
}
ret = 0;
goto beach;
}
}
const char *sp = strchr (input + 1, ' ');
if (!sp && (input[1] == '-' || IS_DIGIT (input[1]))) {
sp = input + 1;
}
if (sp && *sp) {
int n = (int) r_num_math (core->num, r_str_trim_ro (sp)); //input + 1));
if (!n) {
goto beach;
}
use_blocksize = n;
}
if (core->blocksize_max < use_blocksize && (int) use_blocksize < -core->blocksize_max) {
eprintf ("This block size is too big (%"PFMT64u "<%"PFMT64u "). Did you mean 'p%c @ 0x%08"PFMT64x "' instead?\n",
(ut64) core->blocksize_max, (ut64) use_blocksize, input[0], (ut64) use_blocksize);
goto beach;
} else if (core->blocksize_max < use_blocksize && (int) use_blocksize > -(int)core->blocksize_max) {
bw_disassemble = true;
l = use_blocksize; // negative
use_blocksize = -use_blocksize;
} else {
l = use_blocksize;
}
switch (input[1]) {
case 'C': // "pdC"
r_core_disasm_pdi (core, l, 0, 'C');
pd_result = 0;
processed_cmd = true;
break;
case 'c': // "pdc" // "pDc"
r_core_pseudo_code (core, input + 2);
pd_result = 0;
processed_cmd = true;
break;
case 'k': // "pdk" -print class
{
int len = 0;
ut64 at = findClassBounds (core, r_str_trim_ro (input + 2), &len);
return r_core_cmdf (core, "pD %d @ %"PFMT64u, len, at);
}
case 'i': // "pdi" // "pDi"
processed_cmd = true;
if (*input == 'D') {
r_core_disasm_pdi (core, 0, l, 0);
} else {
r_core_disasm_pdi (core, l, 0, 0);
}
pd_result = 0;
break;
case 'a': // "pda"
processed_cmd = true;
r_core_print_disasm_all (core, core->offset, l, len, input[2]);
pd_result = true;
break;
case 'R': // "pdR"
processed_cmd = true;
if (input[2] == 'j') {
disasm_recursive (core, core->offset, use_blocksize, 'j');
} else {
disasm_recursive (core, core->offset, use_blocksize, 'D');
}
pd_result = true;
break;
case 'r': // "pdr"
processed_cmd = true;
{
RAnalFunction *f = r_anal_get_fcn_in (core->anal, core->offset, 0);
// R_ANAL_FCN_TYPE_FCN|R_ANAL_FCN_TYPE_SYM);
if (f) {
func_walk_blocks (core, f, input[2], 'D', input[2] == '.');
} else {
eprintf ("Cannot find function at 0x%08"PFMT64x "\n", core->offset);
}
pd_result = true;
}
break;
case 'b': // "pdb"
processed_cmd = true;
if (input[2] == '?') {
r_cons_printf ("Usage: pdb[j] - disassemble basic block\n");
} else {
RAnalBlock *b = r_anal_bb_from_offset (core->anal, core->offset);
if (b) {
ut8 *block = malloc (b->size + 1);
if (block) {
r_io_read_at (core->io, b->addr, block, b->size);
if (input[2] == 'j') {
pj = pj_new ();
if (!pj) {
break;
}
pj_a (pj);
r_core_print_disasm_json (core, b->addr, block, b->size, 0, pj);
pj_end (pj);
r_cons_printf ("%s\n", pj_string (pj));
pj_free (pj);
} else {
core->num->value = r_core_print_disasm (
core->print, core, b->addr, block,
b->size, 9999, 0, 2, input[2] == 'J', NULL, NULL);
}
free (block);
pd_result = 0;
}
} else {
eprintf ("Cannot find function at 0x%08"PFMT64x "\n", core->offset);
core->num->value = 0;
}
}
break;
case 's': // "pds" and "pdsf"
processed_cmd = true;
if (input[2] == '?') {
r_cons_printf ("Usage: pds[bf] - sumarize N bytes or function (pdfs)\n");
} else {
disasm_strings (core, input, NULL);
}
break;
case 'f': // "pdf"
processed_cmd = true;
if (input[2] == '?') {
r_core_cmd_help(core, help_msg_pdf);
} else if (input[2] == 's') { // "pdfs"
ut64 oseek = core->offset;
int oblock = core->blocksize;
RAnalFunction *f = r_anal_get_fcn_in (core->anal, core->offset,
R_ANAL_FCN_TYPE_FCN | R_ANAL_FCN_TYPE_SYM);
if (f) {
ut32 rs = r_anal_fcn_realsize (f);
ut32 fs = r_anal_fcn_size (f);
r_core_seek (core, oseek, SEEK_SET);
r_core_block_size (core, R_MAX (rs, fs));
disasm_strings (core, input, f);
r_core_block_size (core, oblock);
r_core_seek (core, oseek, SEEK_SET);
}
processed_cmd = true;
} else {
ut32 bsz = core->blocksize;
RAnalFunction *f = r_anal_get_fcn_in (core->anal, core->offset, R_ANAL_FCN_TYPE_ROOT);
if (!f) {
f = r_anal_get_fcn_in (core->anal, core->offset, 0);
}
RAnalFunction *tmp_func;
ut32 cont_size = 0;
RListIter *locs_it = NULL;
if (f && f->fcn_locs) {
locs_it = f->fcn_locs->head;
}
if (f && input[2] == 'j') { // "pdfj"
ut8 *loc_buf = NULL;
RAnalBlock *b;
ut32 fcn_size = r_anal_fcn_realsize (f);
const char *orig_bb_middle = r_config_get (core->config, "asm.bb.middle");
r_config_set_i (core->config, "asm.bb.middle", false);
cont_size = tmp_get_contsize (f);
pj = pj_new ();
if (!pj) {
break;
}
pj_o (pj);
pj_ks (pj, "name", f->name);
pj_kn (pj, "size", fcn_size);
pj_kn (pj, "addr", f->addr);
pj_k (pj, "ops");
pj_a (pj);
// instructions are all outputted as a json list
// DEAD CODE cont_size = f->_size > 0 ? f->_size : r_anal_fcn_realsize (f);
// TODO: can loc jump to another locs?
for (; locs_it && (tmp_func = locs_it->data); locs_it = locs_it->n) {
if (tmp_func->addr > f->addr) {
break;
}
cont_size = tmp_get_contsize (tmp_func);
loc_buf = calloc (cont_size, 1);
r_io_read_at (core->io, tmp_func->addr, loc_buf, cont_size);
r_core_print_disasm_json (core, tmp_func->addr, loc_buf, cont_size, 0, pj);
free (loc_buf);
}
r_list_foreach (f->bbs, locs_it, b) {
ut8 *buf = malloc (b->size);
if (buf) {
r_io_read_at (core->io, b->addr, buf, b->size);
r_core_print_disasm_json (core, b->addr, buf, b->size, 0, pj);
free (buf);
} else {
eprintf ("cannot allocate %d byte(s)\n", b->size);
}
}
for (; locs_it && (tmp_func = locs_it->data); locs_it = locs_it->n) {
cont_size = tmp_get_contsize (tmp_func);
loc_buf = calloc (cont_size, 1);
if (loc_buf) {
r_io_read_at (core->io, tmp_func->addr, loc_buf, cont_size);
r_core_print_disasm_json (core, tmp_func->addr, loc_buf, cont_size, 0, pj);
free (loc_buf);
}
}
pj_end (pj);
pj_end (pj);
r_cons_printf ("%s\n", pj_string (pj));
pj_free (pj);
pd_result = 0;
r_config_set (core->config, "asm.bb.middle", orig_bb_middle);
} else if (f) {
#if 0
for (; locs_it && (tmp_func = locs_it->data); locs_it = locs_it->n) {
if (tmp_func->addr > f->addr) {
break;
}
cont_size = tmp_get_contsize (tmp_func);
r_core_cmdf (core, "pD %d @ 0x%08" PFMT64x, cont_size, tmp_func->addr);
}
cont_size = tmp_get_contsize (f);
#endif
ut32 linear = f->_size;
ut32 bbsum = r_anal_fcn_realsize (f);
if (bbsum + 4096 < linear) {
eprintf ("Linear size differs too much from the bbsum, please use pdr instead.\n");
} else {
ut64 at = f->addr;
ut64 sz = f->_size > 0 ? f->_size : r_anal_fcn_realsize (f);
ut32 rs = r_anal_fcn_realsize (f);
sz = R_MAX (sz, rs);
ut8 *buf = calloc (sz, 1);
(void)r_io_read_at (core->io, at, buf, sz);
core->num->value = r_core_print_disasm (core->print, core, at, buf, sz, sz, 0, 1, 0, NULL, f);
free (buf);
// r_core_cmdf (core, "pD %d @ 0x%08" PFMT64x, f->_size > 0 ? f->_size: r_anal_fcn_realsize (f), f->addr);
}
#if 0
for (; locs_it && (tmp_func = locs_it->data); locs_it = locs_it->n) {
cont_size = tmp_get_contsize (tmp_func);
r_core_cmdf (core, "pD %d @ 0x%08" PFMT64x, cont_size, tmp_func->addr);
}
#endif
pd_result = 0;
} else {
eprintf ("pdf: Cannot find function at 0x%08"PFMT64x "\n", core->offset);
processed_cmd = true;
core->num->value = 0;
}
if (bsz != core->blocksize) {
r_core_block_size (core, bsz);
}
}
l = 0;
break;
case 'p': // "pdp"
processed_cmd = true;
disasm_ropchain (core, core->offset, 'D');
pd_result = true;
break;
case 'l': // "pdl"
processed_cmd = true;
{
RAsmOp asmop;
int j, ret;
if (!l) {
l = len;
}
r_cons_break_push (NULL, NULL);
for (i = j = 0; i < core->blocksize && j < l; i += ret, j++) {
ret = r_asm_disassemble (core->assembler, &asmop, block + i, len - i);
if (r_cons_is_breaked ()) {
break;
}
r_cons_printf ("%d\n", ret);
if (ret < 1) {
ret = 1;
}
}
r_cons_break_pop ();
pd_result = 0;
}
break;
case 'j': // pdj
processed_cmd = true;
if (*input == 'D') {
cmd_pDj (core, input + 2);
} else {
cmd_pdj (core, input + 2, block);
}
r_cons_newline ();
pd_result = 0;
break;
case 'J': // pdJ
formatted_json = true;
break;
case 0:
/* "pd" -> will disassemble blocksize/4 instructions */
if (*input == 'd' && !core->fixedblock) {
l /= 4;
}
break;
case '?': // "pd?"
processed_cmd = true;
r_core_cmd_help (core, help_msg_pd);
pd_result = 0;
}
if (!processed_cmd) {
ut64 addr = core->offset;
ut8 *block1 = NULL;
ut64 start;
if (bw_disassemble) {
block1 = malloc (core->blocksize);
if (l < 0) {
l = -l;
}
if (block1) {
if (*input == 'D') { // pD
free (block1);
if (!(block1 = malloc (l))) {
break;
}
r_io_read_at (core->io, addr - l, block1, l); // core->blocksize);
core->num->value = r_core_print_disasm (core->print, core, addr - l, block1, l, l, 0, 1, formatted_json, NULL, NULL);
} else { // pd
int instr_len;
if (!r_core_prevop_addr (core, core->offset, l, &start)) {
// anal ignorance.
start = r_core_prevop_addr_force (core, core->offset, l);
}
instr_len = core->offset - start;
ut64 prevaddr = core->offset;
int bs = core->blocksize, bs1 = addrbytes * instr_len;
if (bs1 > bs) {
ut8 *tmpblock = realloc (block1, bs1);
if (!tmpblock) {
eprintf ("Memory reallocation failed.\n");
free (block1);
break;
}
block1 = tmpblock;
}
r_core_seek (core, prevaddr - instr_len, true);
memcpy (block1, block, bs);
if (bs1 > bs) {
r_io_read_at (core->io, addr + bs / addrbytes,
block1 + (bs - bs % addrbytes),
bs1 - (bs - bs % addrbytes));
}
core->num->value = r_core_print_disasm (core->print,
core, core->offset, block1, R_MAX (bs, bs1), l, 0, 1, formatted_json, NULL, NULL);
r_core_seek (core, prevaddr, true);
}
}
} else {
const int bs = core->blocksize;
// XXX: issue with small blocks
if (*input == 'D' && l > 0) {
if (l > R_CORE_MAX_DISASM) { // pD
eprintf ("Block size too big\n");
return 1;
}
block1 = malloc (addrbytes * l);
if (block1) {
if (addrbytes * l > core->blocksize) {
r_io_read_at (core->io, addr, block1, addrbytes * l); // core->blocksize);
} else {
memcpy (block1, block, addrbytes * l);
}
core->num->value = r_core_print_disasm (core->print,
core, addr, block1, addrbytes * l, l, 0, 1, formatted_json, NULL, NULL);
} else {
eprintf ("Cannot allocate %d byte(s)\n", addrbytes * l);
}
} else {
int bs1 = l * 16;
int bsmax = R_MAX (bs, bs1);
block1 = malloc (bsmax + 1);
if (block1) {
memcpy (block1, block, bs);
if (bs1 > bs) {
r_io_read_at (core->io, addr + bs / addrbytes, block1 + (bs - bs % addrbytes),
bs1 - (bs - bs % addrbytes));
}
core->num->value = r_core_print_disasm (core->print,
core, addr, block1, bs, l, 0, 0, formatted_json, NULL, NULL);
}
}
}
free (block1);
if (formatted_json) {
r_cons_print ("\n");
}
}
if (processed_cmd) {
ret = pd_result;
goto beach;
}
}
break;
case 's': // "ps"
switch (input[1]) {
case '?':
r_core_cmd_help (core, help_msg_ps);
break;
case 'j': // "psj"
if (l > 0) {
char *str, *type;
ut64 vaddr = UT64_MAX;
RBinObject *obj = r_bin_cur_object (core->bin);
RBinSection *section = NULL;
if (input[2] == ' ' && input[3]) {
len = r_num_math (core->num, input + 3);
len = R_MIN (len, core->blocksize);
}
/* try to get the section that contains the
* string, by considering current offset as
* paddr and if it isn't, trying to consider it
* as vaddr. */
if ((section = r_bin_get_section_at (obj, core->offset, true))) {
vaddr = core->offset + section->vaddr - section->paddr;
}
r_cons_printf ("{\"string\":");
str = r_str_utf16_encode ((const char *) core->block, len);
r_cons_printf ("\"%s\"", str);
r_cons_printf (",\"offset\":%"PFMT64u, core->offset);
r_cons_printf (",\"section\":\"%s\"", vaddr == UT64_MAX? "unknown": section->name);
r_cons_printf (",\"length\":%d", len);
switch (get_string_type (core->block, len)) {
case 'w': type = "wide"; break;
case 'a': type = "ascii"; break;
case 'u': type = "utf"; break;
default: type = "unknown"; break;
}
r_cons_printf (",\"type\":\"%s\"}", type);
r_cons_newline ();
free (str);
}
break;
case 'i': // "psi"
if (l > 0) {
ut8 *buf = malloc (1024 + 1);
int delta = 512;
ut8 *p, *e, *b;
if (!buf) {
return 0;
}
buf[1024] = 0;
if (core->offset < delta) {
delta = core->offset;
}
p = buf + delta;
r_io_read_at (core->io, core->offset - delta, buf, 1024);
for (b = p; b > buf; b--) {
if (!IS_PRINTABLE (*b)) {
b++;
break;
}
}
for (e = p; e < (buf + 1024); e++) {
if (!IS_PRINTABLE (*b)) {
*e = 0;
e--;
break;
}
}
r_cons_strcat ((const char *) b);
r_cons_newline ();
// r_print_string (core->print, core->offset, b,
// (size_t)(e-b), 0);
free (buf);
}
break;
case 'x': // "psx"
if (l > 0) {
r_print_string (core->print, core->offset, block, len, R_PRINT_STRING_ESC_NL);
}
break;
case 'b': // "psb"
if (l > 0) {
int quiet = input[2] == 'q'; // "psbq"
char *s = malloc (core->blocksize + 1);
int i, j, hasnl = 0;
if (s) {
if (!quiet) {
r_print_offset (core->print, core->offset, 0, 0, 0, 0, NULL);
}
// TODO: filter more chars?
for (i = j = 0; i < core->blocksize; i++) {
char ch = (char) block[i];
if (!ch) {
if (!hasnl) {
s[j] = 0;
if (*s) {
r_cons_println (s);
if (!quiet) {
r_print_offset (core->print, core->offset + i, 0, 0, 0, 0, NULL);
}
}
j = 0;
s[0] = 0;
}
hasnl = 1;
continue;
}
hasnl = 0;
if (IS_PRINTABLE (ch)) {
s[j++] = ch;
}
}
s[j] = 0;
r_cons_print (s); // TODO: missing newline?
free (s);
}
}
break;
case 'z': // "psz"
if (l > 0) {
char *s = malloc (core->blocksize + 1);
int i, j;
if (s) {
// TODO: filter more chars?
for (i = j = 0; i < core->blocksize; i++) {
char ch = (char) core->block[i];
if (!ch) {
break;
}
if (IS_PRINTABLE (ch)) {
s[j++] = ch;
}
}
s[j] = '\0';
r_cons_println (s);
free (s);
}
}
break;
case 'p': // "psp"
if (l > 0) {
int mylen = core->block[0];
// TODO: add support for 2-4 byte length pascal strings
if (mylen < core->blocksize) {
r_print_string (core->print, core->offset,
core->block + 1, mylen, R_PRINT_STRING_ZEROEND);
core->num->value = mylen;
} else {
core->num->value = 0; // error
}
}
break;
case 'w': // "psw"
if (l > 0) {
r_print_string (core->print, core->offset, core->block, len,
R_PRINT_STRING_WIDE | R_PRINT_STRING_ZEROEND);
}
break;
case 'W': // "psw"
if (l > 0) {
r_print_string (core->print, core->offset, core->block, len,
R_PRINT_STRING_WIDE32 | R_PRINT_STRING_ZEROEND);
}
break;
case ' ': // "ps"
r_print_string (core->print, core->offset, core->block, l, 0);
break;
case 'u': // "psu"
if (l > 0) {
char *str = r_str_utf16_encode (
(const char *) core->block, len);
r_cons_println (str);
free (str);
}
break;
case 's': // "pss"
if (l > 0) {
int h, w = r_cons_get_size (&h);
int colwidth = r_config_get_i (core->config, "hex.cols") * 2;
core->print->width = (colwidth == 32)?w: colwidth; // w;
int bs = core->blocksize;
if (len == bs) {
len = (h * w) / 3;
r_core_block_size (core, len);
}
r_print_string (core->print, core->offset, core->block,
len, R_PRINT_STRING_WRAP);
r_core_block_size (core, bs);
}
break;
case '+': // "ps+"
if (l > 0) {
ut64 bitness = r_config_get_i (core->config, "asm.bits");
if (bitness != 32 && bitness != 64) {
eprintf ("Error: bitness of %" PFMT64u " not supported\n", bitness);
break;
}
if (*core->block & 0x1) { // "long" string
if (bitness == 64) {
r_core_cmdf (core, "ps @ 0x%" PFMT64x, *((ut64 *)core->block + 2));
} else {
r_core_cmdf (core, "ps @ 0x%" PFMT32x, *((ut32 *)core->block + 2));
}
} else {
r_print_string (core->print, core->offset, core->block + 1,
len, R_PRINT_STRING_ZEROEND);
}
}
break;
default:
if (l > 0) {
r_print_string (core->print, core->offset, core->block,
len, R_PRINT_STRING_ZEROEND);
}
break;
}
break;
case 'm': // "pm"
if (input[1] == '?') {
r_cons_printf ("|Usage: pm [file|directory]\n"
"| r_magic will use given file/dir as reference\n"
"| output of those magic can contain expressions like:\n"
"| foo@0x40 # use 'foo' magic file on address 0x40\n"
"| @0x40 # use current magic file on address 0x40\n"
"| \\n # append newline\n"
"| e dir.magic # defaults to " R_JOIN_2_PATHS ("{R2_PREFIX}", R2_SDB_MAGIC) "\n"
"| /m # search for magic signatures\n"
);
} else {
// XXX: need cmd_magic header for r_core_magic
if (l > 0) {
r_core_magic (core, input + 1, true);
}
}
break;
case 'u': // "pu"
if (input[1] == '?') {
r_cons_printf ("|Usage: pu[w] [len] print N url"
"encoded bytes (w=wide)\n");
} else {
if (l > 0) {
r_print_string (core->print, core->offset, core->block, len,
R_PRINT_STRING_URLENCODE |
((input[1] == 'w')? R_PRINT_STRING_WIDE: 0));
}
}
break;
case 'c': // "pc"
if (l) {
const ut8 *buf = core->block;
int i = 0;
int j = 0;
if (input[1] == 'A') { // "pcA"
r_cons_printf ("sub_0x%08"PFMT64x ":\n", core->offset);
for (i = 0; i < len; i++) {
RAsmOp asmop = {
0
};
(void) r_asm_disassemble (core->assembler, &asmop, buf + i, len - i);
int sz = asmop.size;
if (sz < 1) {
sz = 1;
}
r_cons_printf (" .byte ");
for (j = 0; j < sz; j++) {
r_cons_printf ("%s0x%02x", j? ", ": "", buf[i]);
i++;
}
r_cons_printf (" // %s\n", r_strbuf_get (&asmop.buf_asm));
i--;
}
r_cons_printf (".equ shellcode_len, %d\n", len);
} else {
r_print_code (core->print, core->offset, core->block, len, input[1]);
}
}
break;
case 'C': // "pC"
switch (input[1]) {
case 0:
cmd_pCd (core, "");
break;
case ' ':
case 'd':
cmd_pCd (core, input + 2);
break;
case 'D':
cmd_pCD (core, input + 2);
break;
case 'a':
cmd_pCx (core, input + 2, "pxa");
break;
case 'A':
cmd_pCx (core, input + 2, "pxA");
break;
case 'x':
cmd_pCx (core, input + 2, "px");
break;
case 'w':
cmd_pCx (core, input + 2, "pxw");
break;
case 'c':
cmd_pCx (core, input + 2, "pc");
break;
default:
eprintf ("Usage: pCd\n");
break;
}
break;
case 'r': // "pr"
switch (input[1]) {
case 'c': // "prc" // color raw dump
cmd_prc (core, block, len);
break;
case '?':
r_core_cmd_help (core, help_msg_pr);
break;
case 'g': // "prg" // gunzip
switch (input[2]) {
case '?':
r_core_cmd_help (core, help_msg_prg);
break;
case 'i': // "prgi"
{
int outlen = 0;
int inConsumed = 0;
ut8 *out;
out = r_inflate (block, core->blocksize, &inConsumed, &outlen);
r_cons_printf ("%d\n", inConsumed);
free (out);
}
break;
case 'o': // "prgo"
{
int outlen = 0;
ut8 *out;
out = r_inflate (block, core->blocksize, NULL, &outlen);
r_cons_printf ("%d\n", outlen);
free (out);
}
break;
default:
{
int outlen = 0;
ut8 *out;
out = r_inflate (block, core->blocksize, NULL, &outlen);
if (out) {
r_cons_memcat ((const char *) out, outlen);
}
free (out);
}
}
break;
/* TODO: compact */
case 'l': // "prl"
if (l != 0) {
printraw (core, len, 1);
}
break;
case 'x': // "prx"
if (l != 0) {
printraw (core, len, 2);
}
break;
case 'z': // "prz"
if (l != 0) {
printraw (core, strlen ((const char *) core->block), 0);
}
break;
default:
if (l != 0) {
printraw (core, len, 0);
}
break;
}
break;
case '3': // "p3" [file]
if (input[1] == '?') {
eprintf ("Usage: p3 [file] - print 3D stereogram image of current block\n");
} else if (input[1] == ' ') {
char *data = r_file_slurp (input + 2, NULL);
char *res = r_print_stereogram (data, 78, 20);
r_print_stereogram_print (core->print, res);
// if (data) eprintf ("%s\n", data);
free (res);
free (data);
} else {
char *res = r_print_stereogram_bytes (block, core->blocksize);
r_print_stereogram_print (core->print, res);
free (res);
}
break;
case 'x': // "px"
{
int show_offset = r_config_get_i (core->config, "asm.offset");
if (show_offset) {
core->print->flags |= R_PRINT_FLAGS_OFFSET;
} else {
core->print->flags &= ~R_PRINT_FLAGS_OFFSET;
}
int show_header = r_config_get_i (core->config, "hex.header");
if (show_header) {
core->print->flags |= R_PRINT_FLAGS_HEADER;
} else {
core->print->flags &= ~R_PRINT_FLAGS_HEADER;
}
/* Don't show comments in default case */
core->print->use_comments = false;
}
r_cons_break_push (NULL, NULL);
switch (input[1]) {
case 'j': // "pxj"
r_print_jsondump (core->print, core->block, core->blocksize, 8);
break;
case '/': // "px/"
r_core_print_examine (core, input + 2);
break;
case '?':
r_core_cmd_help (core, help_msg_px);
break;
case '0': // "px0"
if (l) {
int len = r_str_nlen ((const char *)core->block, core->blocksize);
r_print_bytes (core->print, core->block, len, "%02x");
}
break;
case 'a': // "pxa"
if (l != 0) {
if (len % 16) {
len += 16 - (len % 16);
}
annotated_hexdump (core, input + 2, len);
}
break;
case 'x': // "pxx"
if (l != 0) {
core->print->flags |= R_PRINT_FLAGS_NONHEX;
r_print_hexdump (core->print, core->offset,
core->block, len, 8, 1, 1);
core->print->flags &= ~R_PRINT_FLAGS_NONHEX;
}
break;
case 'X': // "pxX"
if (l != 0) {
ut8 *buf = calloc (len, 4);
if (buf) {
r_io_read_at (core->io, core->offset, buf, len * 4);
core->print->flags |= R_PRINT_FLAGS_NONHEX;
r_print_hexdump (core->print, core->offset, buf, len * 4, 8, 1, 1);
core->print->flags &= ~R_PRINT_FLAGS_NONHEX;
free (buf);
}
}
break;
case 'A': // "pxA"
if (input[2] == '?') {
r_core_cmd_help (core, help_msg_pxA);
} else if (l) {
cmd_print_pxA (core, len, input + 1);
}
break;
case 'b': // "pxb"
if (l) {
ut32 n;
int i, c;
char buf[32];
for (i = c = 0; i < len; i++, c++) {
if (c == 0) {
r_print_offset (core->print,
core->offset + i, 0, 0, 0, 0, NULL);
}
r_str_bits (buf, core->block + i, 8, NULL);
// split bits
memmove (buf + 5, buf + 4, 5);
buf[4] = 0;
r_print_cursor (core->print, i, 1, 1);
r_cons_printf ("%s.%s ", buf, buf + 5);
r_print_cursor (core->print, i, 1, 0);
if (c == 3) {
const ut8 *b = core->block + i - 3;
int (*k) (const ut8 *, int) = cmd_pxb_k;
char (*p) (char) = cmd_pxb_p;
n = k (b, 0) | k (b, 1) | k (b, 2) | k (b, 3);
r_cons_printf ("0x%08x %c%c%c%c\n",
n, p (b[0]), p (b[1]), p (b[2]), p (b[3]));
c = -1;
}
}
}
break;
case 'c': // "pxc"
{
int ocomments = core->print->use_comments;
core->print->use_comments = core->print->flags & R_PRINT_FLAGS_COMMENT;
if (l) {
ut64 from = r_config_get_i (core->config, "diff.from");
ut64 to = r_config_get_i (core->config, "diff.to");
if (from == to && !from) {
r_core_block_size (core, len);
len = core->blocksize;
r_print_hexdump (core->print, core->offset,
core->block, core->blocksize, 16, 1, 1);
} else {
r_core_print_cmp (core, from, to);
}
core->num->value = len;
}
core->print->use_comments = ocomments;
}
break;
case 'i': // "pxi"
if (l != 0) {
r_print_hexii (core->print, core->offset, core->block,
core->blocksize, r_config_get_i (core->config, "hex.cols"));
}
break;
case 'o': // "pxo"
if (l != 0) {
r_print_hexdump (core->print, core->offset,
core->block, len, 8, 1, 1);
}
break;
case 't': // "pxt"
{
ut64 origin = core->offset;
const char *arg = strchr (input, ' ');
if (arg) {
origin = r_num_math (core->num, arg + 1);
}
// _pointer_table does r_core_cmd with @, so it modifies core->block
// and this results in an UAF access when iterating over the jmptable
// so we do a new allocation to avoid that issue
ut8 *block = calloc (len, 1);
if (block) {
memcpy (block, core->block, len);
_pointer_table (core, origin, core->offset, block, len, 4, input[2]);
free (block);
}
}
break;
case 'd': // "pxd"
if (input[2] == '?') {
r_core_cmd_help (core, help_msg_pxd);
} else if (l != 0) {
switch (input[2]) {
case '1':
// 1 byte signed words (byte)
r_print_hexdump (core->print, core->offset,
core->block, len, -1, 4, 1);
break;
case '2':
// 2 byte signed words (short)
r_print_hexdump (core->print, core->offset,
core->block, len, -10, 2, 1);
break;
case '8':
r_print_hexdump (core->print, core->offset,
core->block, len, -8, 4, 1);
break;
case '4':
case ' ':
case 0:
// 4 byte signed words
r_print_hexdump (core->print, core->offset,
core->block, len, 10, 4, 1);
break;
default:
r_core_cmd_help (core, help_msg_pxd);
break;
}
}
break;
case 'w': // "pxw"
if (l != 0) {
if (input[2] == 'j') {
r_print_jsondump (core->print, core->block, len, 32);
} else {
r_print_hexdump (core->print, core->offset, core->block, len, 32, 4, 1);
}
}
break;
case 'W': // "pxW"
if (l) {
bool printOffset = (input[2] != 'q' && r_config_get_i (core->config, "asm.offset"));
len = len - (len % 4);
for (i = 0; i < len; i += 4) {
const char *a, *b;
char *fn;
RPrint *p = core->print;
RFlagItem *f;
ut32 v = r_read_ble32 (core->block + i, core->print->big_endian);
if (p && p->colorfor) {
a = p->colorfor (p->user, v, true);
if (a && *a) {
b = Color_RESET;
} else {
a = b = "";
}
} else {
a = b = "";
}
f = r_flag_get_at (core->flags, v, true);
fn = NULL;
if (f) {
st64 delta = (v - f->offset);
if (delta >= 0 && delta < 8192) {
if (v == f->offset) {
fn = strdup (f->name);
} else {
fn = r_str_newf ("%s+%d",
f->name, v - f->offset);
}
}
}
if (printOffset) {
r_cons_printf ("0x%08"PFMT64x " %s0x%08"PFMT64x "%s%s%s\n",
(ut64) core->offset + i, a, (ut64) v,
b, fn? " ": "", fn? fn: "");
} else {
r_cons_printf ("%s0x%08"PFMT64x "%s\n", a, (ut64) v, b);
}
free (fn);
}
}
break;
case 'r': // "pxr"
if (l) {
if (input[2] == 'j') {
PJ *pj = pj_new ();
if (!pj) {
return 0;
}
int base = core->anal->bits;
pj_a (pj);
const char *comma = "";
const ut8 *buf = core->block;
int withref = 0;
const int wordsize = base / 8;
for (i = 0; i < core->blocksize; i += wordsize) {
ut64 addr = core->offset + i;
ut64 *foo = (ut64 *) (buf + i);
ut64 val = *foo;
if (base == 32) {
val &= UT32_MAX;
}
pj_o (pj);
pj_kn (pj, "addr", addr);
pj_kn (pj, "value", val);
comma = ",";
// XXX: this only works in little endian
withref = 0;
if (core->print->hasrefs) {
char *rstr = core->print->hasrefs (core->print->user, val, true);
if (rstr && *rstr) {
char *ns = r_str_escape (rstr);
pj_ks (pj, "ref", r_str_trim_ro (ns));
pj_end (pj);
free (ns);
withref = 1;
}
free (rstr);
}
if (!withref) {
pj_end (pj);
}
}
pj_end (pj);
r_cons_println (pj_string (pj));
pj_free (pj);
} else {
const int ocols = core->print->cols;
int bitsize = core->assembler->bits;
/* Thumb is 16bit arm but handles 32bit data */
if (bitsize == 16) {
bitsize = 32;
}
core->print->cols = 1;
core->print->flags |= R_PRINT_FLAGS_REFS;
r_cons_break_push (NULL, NULL);
r_print_hexdump (core->print, core->offset,
core->block, R_MIN (len, core->blocksize),
bitsize, bitsize / 8, 1);
r_cons_break_pop ();
core->print->flags &= ~R_PRINT_FLAGS_REFS;
core->print->cols = ocols;
}
}
break;
case 'h': // "pxh"
if (l) {
if (input[2] == 'j') {
r_print_jsondump (core->print, core->block, len, 16);
} else {
r_print_hexdump (core->print, core->offset,
core->block, len, 32, 2, 1);
}
}
break;
case 'H': // "pxH"
if (l != 0) {
len = len - (len % 2);
for (i = 0; i < len; i += 2) {
const char *a, *b;
char *fn;
RPrint *p = core->print;
RFlagItem *f;
ut64 v = (ut64) r_read_ble16 (core->block + i, p->big_endian);
if (p && p->colorfor) {
a = p->colorfor (p->user, v, true);
if (a && *a) {
b = Color_RESET;
} else {
a = b = "";
}
} else {
a = b = "";
}
f = r_flag_get_at (core->flags, v, true);
fn = NULL;
if (f) {
st64 delta = (v - f->offset);
if (delta >= 0 && delta < 8192) {
if (v == f->offset) {
fn = strdup (f->name);
} else {
fn = r_str_newf ("%s+%d", f->name, v - f->offset);
}
}
}
r_cons_printf ("0x%08"PFMT64x " %s0x%04"PFMT64x "%s %s\n",
(ut64) core->offset + i, a, v, b, fn? fn: "");
free (fn);
}
}
break;
case 'q': // "pxq"
if (l) {
if (input[2] == 'j') {
r_print_jsondump (core->print, core->block, len, 64);
} else {
r_print_hexdump (core->print, core->offset, core->block, len, 64, 8, 1);
}
}
break;
case 'Q': // "pxQ"
// TODO. show if flag name, or inside function
if (l) {
bool printOffset = (input[2] != 'q' && r_config_get_i (core->config, "asm.offset"));
len = len - (len % 8);
for (i = 0; i < len; i += 8) {
const char *a, *b;
char *fn;
RPrint *p = core->print;
RFlagItem *f;
ut64 v = r_read_ble64 (core->block + i, p->big_endian);
if (p && p->colorfor) {
a = p->colorfor (p->user, v, true);
if (a && *a) {
b = Color_RESET;
} else {
a = b = "";
}
} else {
a = b = "";
}
f = r_flag_get_at (core->flags, v, true);
fn = NULL;
if (f) {
st64 delta = (v - f->offset);
if (delta >= 0 && delta < 8192) {
if (v == f->offset) {
fn = strdup (f->name);
} else {
fn = r_str_newf ("%s+%d", f->name, v - f->offset);
}
}
}
if (printOffset) {
r_cons_printf ("0x%08"PFMT64x " %s0x%016"PFMT64x "%s %s\n",
(ut64) core->offset + i, a, v, b, fn? fn: "");
} else {
r_cons_printf ("%s0x%016"PFMT64x "%s\n", a, v, b);
}
free (fn);
}
}
break;
case 's': // "pxs"
if (l) {
core->print->flags |= R_PRINT_FLAGS_SPARSE;
r_print_hexdump (core->print, core->offset, core->block, len, 16, 1, 1);
core->print->flags &= (((ut32) - 1) & (~R_PRINT_FLAGS_SPARSE));
}
break;
case 'e': // "pxe" // emoji dump
if (l != 0) {
int j;
char emoji[] = {
'\x8c', '\x80', '\x8c', '\x82', '\x8c', '\x85', '\x8c', '\x88',
'\x8c', '\x99', '\x8c', '\x9e', '\x8c', '\x9f', '\x8c', '\xa0',
'\x8c', '\xb0', '\x8c', '\xb1', '\x8c', '\xb2', '\x8c', '\xb3',
'\x8c', '\xb4', '\x8c', '\xb5', '\x8c', '\xb7', '\x8c', '\xb8',
'\x8c', '\xb9', '\x8c', '\xba', '\x8c', '\xbb', '\x8c', '\xbc',
'\x8c', '\xbd', '\x8c', '\xbe', '\x8c', '\xbf', '\x8d', '\x80',
'\x8d', '\x81', '\x8d', '\x82', '\x8d', '\x83', '\x8d', '\x84',
'\x8d', '\x85', '\x8d', '\x86', '\x8d', '\x87', '\x8d', '\x88',
'\x8d', '\x89', '\x8d', '\x8a', '\x8d', '\x8b', '\x8d', '\x8c',
'\x8d', '\x8d', '\x8d', '\x8e', '\x8d', '\x8f', '\x8d', '\x90',
'\x8d', '\x91', '\x8d', '\x92', '\x8d', '\x93', '\x8d', '\x94',
'\x8d', '\x95', '\x8d', '\x96', '\x8d', '\x97', '\x8d', '\x98',
'\x8d', '\x9c', '\x8d', '\x9d', '\x8d', '\x9e', '\x8d', '\x9f',
'\x8d', '\xa0', '\x8d', '\xa1', '\x8d', '\xa2', '\x8d', '\xa3',
'\x8d', '\xa4', '\x8d', '\xa5', '\x8d', '\xa6', '\x8d', '\xa7',
'\x8d', '\xa8', '\x8d', '\xa9', '\x8d', '\xaa', '\x8d', '\xab',
'\x8d', '\xac', '\x8d', '\xad', '\x8d', '\xae', '\x8d', '\xaf',
'\x8d', '\xb0', '\x8d', '\xb1', '\x8d', '\xb2', '\x8d', '\xb3',
'\x8d', '\xb4', '\x8d', '\xb5', '\x8d', '\xb6', '\x8d', '\xb7',
'\x8d', '\xb8', '\x8d', '\xb9', '\x8d', '\xba', '\x8d', '\xbb',
'\x8d', '\xbc', '\x8e', '\x80', '\x8e', '\x81', '\x8e', '\x82',
'\x8e', '\x83', '\x8e', '\x84', '\x8e', '\x85', '\x8e', '\x88',
'\x8e', '\x89', '\x8e', '\x8a', '\x8e', '\x8b', '\x8e', '\x8c',
'\x8e', '\x8d', '\x8e', '\x8e', '\x8e', '\x8f', '\x8e', '\x92',
'\x8e', '\x93', '\x8e', '\xa0', '\x8e', '\xa1', '\x8e', '\xa2',
'\x8e', '\xa3', '\x8e', '\xa4', '\x8e', '\xa5', '\x8e', '\xa6',
'\x8e', '\xa7', '\x8e', '\xa8', '\x8e', '\xa9', '\x8e', '\xaa',
'\x8e', '\xab', '\x8e', '\xac', '\x8e', '\xad', '\x8e', '\xae',
'\x8e', '\xaf', '\x8e', '\xb0', '\x8e', '\xb1', '\x8e', '\xb2',
'\x8e', '\xb3', '\x8e', '\xb4', '\x8e', '\xb5', '\x8e', '\xb7',
'\x8e', '\xb8', '\x8e', '\xb9', '\x8e', '\xba', '\x8e', '\xbb',
'\x8e', '\xbd', '\x8e', '\xbe', '\x8e', '\xbf', '\x8f', '\x80',
'\x8f', '\x81', '\x8f', '\x82', '\x8f', '\x83', '\x8f', '\x84',
'\x8f', '\x86', '\x8f', '\x87', '\x8f', '\x88', '\x8f', '\x89',
'\x8f', '\x8a', '\x90', '\x80', '\x90', '\x81', '\x90', '\x82',
'\x90', '\x83', '\x90', '\x84', '\x90', '\x85', '\x90', '\x86',
'\x90', '\x87', '\x90', '\x88', '\x90', '\x89', '\x90', '\x8a',
'\x90', '\x8b', '\x90', '\x8c', '\x90', '\x8d', '\x90', '\x8e',
'\x90', '\x8f', '\x90', '\x90', '\x90', '\x91', '\x90', '\x92',
'\x90', '\x93', '\x90', '\x94', '\x90', '\x95', '\x90', '\x96',
'\x90', '\x97', '\x90', '\x98', '\x90', '\x99', '\x90', '\x9a',
'\x90', '\x9b', '\x90', '\x9c', '\x90', '\x9d', '\x90', '\x9e',
'\x90', '\x9f', '\x90', '\xa0', '\x90', '\xa1', '\x90', '\xa2',
'\x90', '\xa3', '\x90', '\xa4', '\x90', '\xa5', '\x90', '\xa6',
'\x90', '\xa7', '\x90', '\xa8', '\x90', '\xa9', '\x90', '\xaa',
'\x90', '\xab', '\x90', '\xac', '\x90', '\xad', '\x90', '\xae',
'\x90', '\xaf', '\x90', '\xb0', '\x90', '\xb1', '\x90', '\xb2',
'\x90', '\xb3', '\x90', '\xb4', '\x90', '\xb5', '\x90', '\xb6',
'\x90', '\xb7', '\x90', '\xb8', '\x90', '\xb9', '\x90', '\xba',
'\x90', '\xbb', '\x90', '\xbc', '\x90', '\xbd', '\x90', '\xbe',
'\x91', '\x80', '\x91', '\x82', '\x91', '\x83', '\x91', '\x84',
'\x91', '\x85', '\x91', '\x86', '\x91', '\x87', '\x91', '\x88',
'\x91', '\x89', '\x91', '\x8a', '\x91', '\x8b', '\x91', '\x8c',
'\x91', '\x8d', '\x91', '\x8e', '\x91', '\x8f', '\x91', '\x90',
'\x91', '\x91', '\x91', '\x92', '\x91', '\x93', '\x91', '\x94',
'\x91', '\x95', '\x91', '\x96', '\x91', '\x97', '\x91', '\x98',
'\x91', '\x99', '\x91', '\x9a', '\x91', '\x9b', '\x91', '\x9c',
'\x91', '\x9d', '\x91', '\x9e', '\x91', '\x9f', '\x91', '\xa0',
'\x91', '\xa1', '\x91', '\xa2', '\x91', '\xa3', '\x91', '\xa4',
'\x91', '\xa5', '\x91', '\xa6', '\x91', '\xa7', '\x91', '\xa8',
'\x91', '\xa9', '\x91', '\xaa', '\x91', '\xae', '\x91', '\xaf',
'\x91', '\xba', '\x91', '\xbb', '\x91', '\xbc', '\x91', '\xbd',
'\x91', '\xbe', '\x91', '\xbf', '\x92', '\x80', '\x92', '\x81',
'\x92', '\x82', '\x92', '\x83', '\x92', '\x84', '\x92', '\x85'
};
int cols = core->print->cols;
if (cols < 1) {
cols = 1;
}
for (i = 0; i < len; i += cols) {
r_print_addr (core->print, core->offset + i);
for (j = i; j < i + cols; j += 1) {
ut8 *p = (ut8 *) core->block + j;
if (j < len) {
r_cons_printf ("\xf0\x9f%c%c ", emoji[*p * 2], emoji[*p * 2 + 1]);
} else {
r_cons_print (" ");
}
}
r_cons_print (" ");
for (j = i; j < len && j < i + cols; j += 1) {
ut8 *p = (ut8 *) core->block + j;
r_print_byte (core->print, "%c", j, *p);
}
r_cons_newline ();
}
}
break;
case 'l': // "pxl"
len = core->print->cols * len;
/* fallthrough */
default:
if (l) {
ut64 from = r_config_get_i (core->config, "diff.from");
ut64 to = r_config_get_i (core->config, "diff.to");
if (from == to && !from) {
if (!r_core_block_size (core, len)) {
len = core->blocksize;
}
r_print_hexdump (core->print, r_core_pava (core, core->offset),
core->block, len, 16, 1, 1);
} else {
r_core_print_cmp (core, from, to);
}
core->num->value = len;
}
break;
}
r_cons_break_pop ();
break;
case '2': // "p2"
if (l) {
if (input[1] == '?') {
r_cons_printf ("|Usage: p2 [number of bytes representing tiles]\n"
"NOTE: Only full tiles will be printed\n");
} else {
r_print_2bpp_tiles (core->print, core->block, len / 16);
}
}
break;
case '6': // "p6"
if (l) {
int malen = (core->blocksize * 4) + 1;
ut8 *buf = malloc (malen);
if (!buf) {
break;
}
memset (buf, 0, malen);
switch (input[1]) {
case 'd': // "p6d"
if (r_base64_decode (buf, (const char *) block, len)) {
r_cons_println ((const char *) buf);
} else {
eprintf ("r_base64_decode: invalid stream\n");
}
break;
case 'e': // "p6e"
len = len > core->blocksize? core->blocksize: len;
r_base64_encode ((char *) buf, block, len);
r_cons_println ((const char *) buf);
break;
case '?':
default:
r_core_cmd_help(core, help_msg_p6);
break;
}
free (buf);
}
break;
case '8': // "p8"
if (input[1] == '?') {
r_cons_printf ("|Usage: p8[fj] [len] 8bit hexpair list of bytes (see pcj)\n");
} else if (l) {
if (!r_core_block_size (core, len)) {
len = core->blocksize;
}
block = core->block;
if (input[1] == 'j') { // "p8j"
r_core_cmdf (core, "pcj %s", input + 2);
} else if (input[1] == 'f') { // "p8f"
r_core_cmdf (core, "p8 $F @ $B");
} else {
r_print_bytes (core->print, block, len, "%02x");
}
}
break;
case 'g': // "pg"
cmd_print_gadget (core, input + 1);
break;
case 'f': // "pf"
cmd_print_format (core, input, block, len);
break;
case 'F': // "pF"
cmd_print_fromage (core, input + 1, block, len);
break;
case 'k': // "pk"
if (input[1] == '?') {
r_cons_printf ("|Usage: pk [len] print key in randomart\n");
r_cons_printf ("|Usage: pkill [process-name]\n");
} else if (!strncmp (input, "kill", 4)) {
RListIter *iter;
RDebugPid *pid;
const char *arg = strchr (input, ' ');
RList *pids = (core->dbg->h && core->dbg->h->pids)
? core->dbg->h->pids (core->dbg, 0): NULL;
if (arg && *++arg) {
r_list_foreach (pids, iter, pid) {
if (strstr (pid->path, arg)) {
r_cons_printf ("dk 9 %d\n", pid->pid);
}
// r_debug_kill (core->dbg, pid->pid, pid->pid, 9); // kill -9
}
}
r_list_free (pids);
} else if (l > 0) {
len = len > core->blocksize? core->blocksize: len;
char *s = r_print_randomart (block, len, core->offset);
r_cons_println (s);
free (s);
}
break;
case 'K': // "pK"
if (input[1] == '?') {
r_cons_printf ("|Usage: pK [len] print key in randomart mosaic\n");
} else if (l > 0) {
len = len > core->blocksize? core->blocksize: len;
int w, h;
RConsCanvas *c;
w = r_cons_get_size (&h);
ut64 offset0 = core->offset;
int cols = (w / 20);
int rows = (h / 12);
int i, j;
char *s;
if (rows < 1) {
rows = 1;
}
c = r_cons_canvas_new (w, rows * 11);
for (i = 0; i < rows; i++) {
for (j = 0; j < cols; j++) {
r_cons_canvas_gotoxy (c, j * 20, i * 11);
core->offset += len;
r_io_read_at (core->io, core->offset, core->block, len);
s = r_print_randomart (core->block, len, core->offset);
r_cons_canvas_write (c, s);
free (s);
}
}
r_cons_canvas_print (c);
r_cons_canvas_free (c);
r_io_read_at (core->io, offset0, core->block, len);
core->offset = offset0;
r_cons_printf ("\n");
}
break;
case 'n': // easter
eprintf ("easter egg license has expired\n");
break;
case 't': // "pt"
switch (input[1]) {
case '.':
{
char nowstr[64] = {0};
r_print_date_get_now (core->print, nowstr);
r_cons_printf ("%s\n", nowstr);
}
break;
case ' ':
case '\0':
// len must be multiple of 4 since r_mem_copyendian move data in fours - sizeof(ut32)
if (len < sizeof (ut32)) {
eprintf ("You should change the block size: b %d\n", (int) sizeof (ut32));
}
if (len % sizeof (ut32)) {
len = len - (len % sizeof (ut32));
}
for (l = 0; l < len; l += sizeof (ut32)) {
r_print_date_unix (core->print, block + l, sizeof (ut32));
}
break;
case 'h': // "pth"
// len must be multiple of 4 since r_mem_copyendian move data in fours - sizeof(ut32)
if (len < sizeof (ut32)) {
eprintf ("You should change the block size: b %d\n", (int) sizeof (ut32));
}
if (len % sizeof (ut32)) {
len = len - (len % sizeof (ut32));
}
for (l = 0; l < len; l += sizeof (ut32)) {
r_print_date_hfs (core->print, block + l, sizeof (ut32));
}
break;
case 'd': // "ptd"
// len must be multiple of 4 since r_print_date_dos read buf+3
// if block size is 1 or 5 for example it reads beyond the buffer
if (len < sizeof (ut32)) {
eprintf ("You should change the block size: b %d\n", (int) sizeof (ut32));
}
if (len % sizeof (ut32)) {
len = len - (len % sizeof (ut32));
}
for (l = 0; l < len; l += sizeof (ut32)) {
r_print_date_dos (core->print, block + l, sizeof (ut32));
}
break;
case 'n': // "ptn"
if (len < sizeof (ut64)) {
eprintf ("You should change the block size: b %d\n", (int) sizeof (ut64));
}
if (len % sizeof (ut64)) {
len = len - (len % sizeof (ut64));
}
for (l = 0; l < len; l += sizeof (ut64)) {
r_print_date_w32 (core->print, block + l, sizeof (ut64));
}
break;
case '?':
r_core_cmd_help (core, help_msg_pt);
break;
}
break;
case 'q': // "pq"
if (input[1] == '?') {
eprintf ("Usage: pq[z] [len]\n");
break;
}
if (input[1] == 'z') { // "pqz"
len = r_str_nlen ((const char *)block, core->blocksize);
} else {
if (len < 1) {
len = 0;
}
if (len > core->blocksize) {
len = core->blocksize;
}
}
bool inverted = (input[1] == 'i'); // pqi -- inverted colors
char *res = r_qrcode_gen (block, len, r_config_get_i (core->config, "scr.utf8"), inverted);
if (res) {
r_cons_printf ("%s\n", res);
free (res);
}
break;
case 'z': // "pz"
if (input[1] == '?') {
r_core_cmd_help (core, help_msg_pz);
} else {
RIOMap* map;
RListIter *iter;
RList *list = r_core_get_boundaries_prot (core, -1, NULL, "zoom");
if (list && r_list_length (list) > 0) {
RListIter *iter1 = list->head;
RIOMap* map1 = iter1->data;
from = map1->itv.addr;
r_list_foreach (list, iter, map) {
to = r_itv_end (map->itv);
}
} else {
from = core->offset;
to = from + core->blocksize;
}
ut64 maxsize = r_config_get_i (core->config, "zoom.maxsz");
int oldva = core->io->va;
char *oldmode = NULL;
bool do_zoom = true;
core->io->va = 0;
if (input[1] && input[1] != ' ') {
oldmode = strdup (r_config_get (core->config, "zoom.byte"));
if (!r_config_set (core->config, "zoom.byte", input + 1)) {
do_zoom = false;
}
}
if (do_zoom && l > 0) {
r_print_zoom (core->print, core, printzoomcallback,
from, to, l, (int) maxsize);
}
if (oldmode) {
r_config_set (core->config, "zoom.byte", oldmode);
}
core->io->va = oldva;
R_FREE (oldmode);
r_list_free (list);
}
break;
default:
r_core_cmd_help (core, help_msg_p);
break;
}
beach:
if (tmpseek != UT64_MAX) {
r_core_seek (core, tmpseek, SEEK_SET);
r_core_block_read (core);
}
if (tbs != core->blocksize) {
r_core_block_size (core, tbs);
}
return ret;
}
static int cmd_hexdump(void *data, const char *input) {
return cmd_print (data, input - 1);
}
static int lenof(ut64 off, int two) {
char buf[64];
buf[0] = 0;
if (two) {
snprintf (buf, sizeof (buf), "+0x%"PFMT64x, off);
} else {
snprintf (buf, sizeof (buf), "0x%08"PFMT64x, off);
}
return strlen (buf);
}
R_API void r_print_offset_sg(RPrint *p, ut64 off, int invert, int offseg, int seggrn, int offdec, int delta, const char *label) {
char space[32] = {
0
};
const char *white;
const char *reset = p->resetbg? Color_RESET: Color_RESET_NOBG;
bool show_color = p->flags & R_PRINT_FLAGS_COLOR;
if (show_color) {
char rgbstr[32];
const char *k = r_cons_singleton ()->context->pal.offset; // TODO etooslow. must cache
if (p->flags & R_PRINT_FLAGS_RAINBOW) {
k = r_cons_rgb_str_off (rgbstr, sizeof (rgbstr), off);
}
if (invert) {
r_cons_invert (true, true);
}
if (offseg) {
ut32 s, a;
a = off & 0xffff;
s = (off - a) >> seggrn;
if (offdec) {
snprintf (space, sizeof (space), "%d:%d", s & 0xffff, a & 0xffff);
white = r_str_pad (' ', 9 - strlen (space));
r_cons_printf ("%s%s%s%s", k, white, space, reset);
} else {
r_cons_printf ("%s%04x:%04x%s", k, s & 0xFFFF, a & 0xFFFF, reset);
}
} else {
int sz = lenof (off, 0);
int sz2 = lenof (delta, 1);
if (delta > 0 || label) {
if (label) {
const int label_padding = 10;
if (delta > 0) {
if (offdec) {
const char *pad = r_str_pad (' ', sz - sz2 + label_padding);
r_cons_printf ("%s%s%s+%d%s", k, label, reset, delta, pad);
} else {
const char *pad = r_str_pad (' ', sz - sz2 + label_padding);
r_cons_printf ("%s%s%s+0x%x%s", k, label, reset, delta, pad);
}
} else {
const char *pad = r_str_pad (' ', sz + label_padding);
r_cons_printf ("%s%s%s%s", k, label, reset, pad);
}
} else {
const char *pad = r_str_pad (' ', sz - sz2);
if (offdec) {
r_cons_printf ("%s+%d%s", pad, delta, reset);
} else {
r_cons_printf ("%s+0x%x%s", pad, delta, reset);
}
}
} else {
if (offdec) {
snprintf (space, sizeof (space), "%"PFMT64u, off);
white = r_str_pad (' ', 10 - strlen (space));
r_cons_printf ("%s%s%s%s", k, white, space, reset);
} else {
if (p->wide_offsets) {
r_cons_printf ("%s0x%016"PFMT64x "%s", k, off, reset);
} else {
r_cons_printf ("%s0x%08"PFMT64x "%s", k, off, reset);
}
}
}
}
r_cons_print (" ");
} else {
if (offseg) {
ut32 s, a;
a = off & 0xffff;
s = (off - a) >> seggrn;
if (offdec) {
snprintf (space, sizeof (space), "%d:%d", s & 0xffff, a & 0xffff);
white = r_str_pad (' ', 9 - strlen (space));
r_cons_printf ("%s%s%s", white, space, reset);
} else {
r_cons_printf ("%04x:%04x", s & 0xFFFF, a & 0xFFFF);
}
} else {
int sz = lenof (off, 0);
int sz2 = lenof (delta, 1);
const char *pad = r_str_pad (' ', sz - 5 - sz2 - 3);
if (delta > 0) {
if (offdec) {
r_cons_printf ("%s+%d%s", pad, delta, reset);
} else {
r_cons_printf ("%s+0x%x%s", pad, delta, reset);
}
} else {
if (offdec) {
snprintf (space, sizeof (space), "%"PFMT64u, off);
white = r_str_pad (' ', 10 - strlen (space));
r_cons_printf ("%s%s", white, space);
} else {
r_cons_printf ("0x%08"PFMT64x " ", off);
}
}
}
}
}
// TODO : move to r_util? .. depends on r_cons...
// XXX: dupe of r_print_addr
R_API void r_print_offset(RPrint *p, ut64 off, int invert, int offseg, int offdec, int delta, const char *label) {
r_print_offset_sg(p, off, invert, offseg, 4, offdec, delta, label);
}