/* radare2 - LGPL - Copyright 2009-2017 - pancake */ #include "r_core.h" R_API int r_core_setup_debugger (RCore *r, const char *debugbackend, bool attach) { int pid, *p = NULL; bool is_gdb = !strcmp (debugbackend, "gdb"); RIODesc * fd = r->file ? r_io_desc_get (r->io, r->file->fd) : NULL; const char *prompt = NULL; p = fd ? fd->data : NULL; r_config_set_i (r->config, "cfg.debug", 1); if (!p) { eprintf ("Invalid debug io\n"); return false; } r_config_set (r->config, "io.ff", "true"); r_core_cmdf (r, "dL %s", debugbackend); if (!is_gdb) { pid = r_io_desc_get_pid (fd); r_core_cmdf (r, "dp=%d", pid); if (attach) { r_core_cmdf (r, "dpa %d", pid); } } //this makes to attach twice showing warnings in the output //we get "resource busy" so it seems isn't an issue r_core_cmd (r, ".dr*", 0); /* honor dbg.bep */ { const char *bep = r_config_get (r->config, "dbg.bep"); if (bep) { if (!strcmp (bep, "loader")) { /* do nothing here */ } else if (!strcmp (bep, "entry")) { r_core_cmd (r, "dcu entry0", 0); } else { r_core_cmdf (r, "dcu %s", bep); } } } r_core_cmd (r, "sr PC", 0); /* set the prompt if it's not been set already by the callbacks */ prompt = r_config_get (r->config, "cmd.prompt"); if (prompt && !strcmp (prompt, "")) { if (r_config_get_i (r->config, "dbg.status")) { r_config_set (r->config, "cmd.prompt", ".dr*;drd;sr PC;pi 1;s-"); } else { r_config_set (r->config, "cmd.prompt", ".dr*"); } } r_config_set (r->config, "cmd.vprompt", ".dr*"); return true; } R_API int r_core_seek_base (RCore *core, const char *hex) { ut64 addr = r_num_tail (core->num, core->offset, hex); return r_core_seek (core, addr, 1); } R_API bool r_core_dump(RCore *core, const char *file, ut64 addr, ut64 size, int append) { ut64 i; ut8 *buf; int bs = core->blocksize; FILE *fd; if (append) { fd = r_sandbox_fopen (file, "ab"); } else { r_sys_truncate (file, 0); fd = r_sandbox_fopen (file, "wb"); } if (!fd) { eprintf ("Cannot open '%s' for writing\n", file); return false; } /* some io backends seems to be buggy in those cases */ if (bs > 4096) bs = 4096; buf = malloc (bs); if (!buf) { eprintf ("Cannot alloc %d byte(s)\n", bs); fclose (fd); return false; } r_cons_break_push (NULL, NULL); for (i = 0; i < size; i += bs) { if (r_cons_is_breaked ()) { break; } if ((i + bs) > size) { bs = size - i; } r_io_read_at (core->io, addr + i, buf, bs); if (fwrite (buf, bs, 1, fd) < 1) { eprintf ("write error\n"); break; } } r_cons_break_pop (); fclose (fd); free (buf); return true; } R_API int r_core_write_op(RCore *core, const char *arg, char op) { int i, j, len, ret = false; char *str = NULL; ut8 *buf; // XXX we can work with config.block instead of dupping it buf = (ut8 *)malloc (core->blocksize); if (!buf) { goto beach; } memcpy (buf, core->block, core->blocksize); if (op!='e') { // fill key buffer either from arg or from clipboard if (arg) { // parse arg for key // r_hex_str2bin() is guaranteed to output maximum half the // input size, or 1 byte if there is just a single nibble. str = (char *)malloc (strlen (arg) / 2 + 1); if (!str) goto beach; len = r_hex_str2bin (arg, (ut8 *)str); // Output is invalid if there was just a single nibble, // but in that case, len is negative (-1). if (len <= 0) { eprintf ("Invalid hexpair string\n"); goto beach; } } else { // use clipboard as key len = core->yank_buf->length; if (len <= 0) { eprintf ("Clipboard is empty and no value argument(s) given\n"); goto beach; } str = r_mem_dup (core->yank_buf->buf, len); if (!str) goto beach; } } else len = 0; // execute the operand if (op=='e') { int wordsize = 1; char *os, *p, *s = strdup (arg); int n, from = 0, to = 0, dif = 0, step = 1; n = from = to; os = s; to = UT8_MAX; // p = strchr (s, ' '); if (p) { *p = 0; from = r_num_math (core->num, s); s = p + 1; } p = strchr (s, ' '); if (p) { *p = 0; to = r_num_math (core->num, s); s = p + 1; } p = strchr (s, ' '); if (p) { *p = 0; step = r_num_math (core->num, s); s = p + 1; wordsize = r_num_math (core->num, s); } else { step = r_num_math (core->num, s); } free (os); eprintf ("from %d to %d step %d size %d\n", from, to, step, wordsize); dif = (to <= from)? UT8_MAX: to - from + 1; if (wordsize == 1) { if (to < 1 || to > UT8_MAX) { to = UT8_MAX; } from %= (UT8_MAX + 1); } if (dif < 1) { dif = UT8_MAX + 1; } if (step < 1) { step = 1; } if (wordsize < 1) { wordsize = 1; } if (wordsize == 1) { for (i = n = 0; i < core->blocksize; i++, n += step) { buf[i] = (ut8)(n % dif) + from; } } else if (wordsize == 2) { ut16 num16 = from; for (i = 0; i < core->blocksize; i += wordsize, num16 += step) { r_write_le16 (buf + i, num16); } } else if (wordsize == 4) { ut32 num32 = from; for (i = 0; i < core->blocksize; i += wordsize, num32 += step) { r_write_le32 (buf + i, num32); } } else if (wordsize == 8) { ut64 num64 = from; for (i = 0; i < core->blocksize; i += wordsize, num64 += step) { r_write_le64 (buf + i, num64); } } else { eprintf ("Invalid word size. Use 1, 2, 4 or 8\n"); } } else if (op=='2' || op=='4') { op -= '0'; // if i < core->blocksize would pass the test but buf[i+3] goes beyond the buffer if (core->blocksize > 3) { for (i=0; iblocksize-3; i+=op) { /* endian swap */ ut8 tmp = buf[i]; buf[i] = buf[i+3]; buf[i+3] = tmp; if (op == 4) { tmp = buf[i + 1]; buf[i + 1] = buf[i + 2]; buf[i + 2] = tmp; } } } } else { for (i=j=0; iblocksize; i++) { switch (op) { case 'x': buf[i] ^= str[j]; break; case 'a': buf[i] += str[j]; break; case 's': buf[i] -= str[j]; break; case 'm': buf[i] *= str[j]; break; case 'w': buf[i] = str[j]; break; case 'd': buf[i] = (str[j])? buf[i] / str[j]: 0; break; case 'r': buf[i] >>= str[j]; break; case 'l': buf[i] <<= str[j]; break; case 'o': buf[i] |= str[j]; break; case 'A': buf[i] &= str[j]; break; } j++; if (j>=len) j=0; /* cyclic key */ } } ret = r_core_write_at (core, core->offset, buf, core->blocksize); beach: free (buf); free (str); return ret; } static void choose_bits_anal_hints(RCore *core, ut64 addr, int *bits) { RAnalRange *range; RListIter *iter; r_list_foreach (core->anal->bits_ranges, iter, range) { if (addr >= range->from && addr < range->to) { *bits = range->bits; return; } } } R_API void r_core_seek_archbits(RCore *core, ut64 addr) { int bits = 0; const char *arch = r_io_section_get_archbits (core->io, addr, &bits); if (!bits && !core->fixedbits) { //if we found bits related with anal hints pick it up choose_bits_anal_hints (core, addr, &bits); } if (bits && !core->fixedbits) { r_config_set_i (core->config, "asm.bits", bits); } if (arch && !core->fixedarch) { r_config_set (core->config, "asm.arch", arch); } } R_API bool r_core_seek(RCore *core, ut64 addr, bool rb) { core->offset = r_io_seek (core->io, addr, R_IO_SEEK_SET); if (rb) { r_core_block_read (core); } return core->offset == addr; } R_API int r_core_seek_delta(RCore *core, st64 addr) { ut64 tmp = core->offset; int ret; if (addr == 0) { return true; } if (addr > 0LL) { /* TODO: check end of file */ addr += tmp; } else { /* check < 0 */ if (-addr > tmp) { addr = 0; } else { addr += tmp; } } core->offset = addr; ret = r_core_seek (core, addr, 1); //ret = r_core_block_read (core); //if (ret == -1) // memset (core->block, 0xff, core->blocksize); // core->offset = tmp; return ret; } R_API bool r_core_write_at(RCore *core, ut64 addr, const ut8 *buf, int size) { bool ret; if (!core) { return false; } ret = r_io_write_at (core->io, addr, buf, size); if (addr >= core->offset && addr <= core->offset + core->blocksize - 1) { r_core_block_read (core); } return ret; } R_API int r_core_extend_at(RCore *core, ut64 addr, int size) { int ret; if (!core->io || !core->file || size < 1) { return false; } ret = r_io_use_fd (core->io, core->file->fd); if (ret != -1) { ret = r_io_extend_at (core->io, addr, size); if (addr >= core->offset && addr <= core->offset+core->blocksize) { r_core_block_read (core); } } return (ret==-1)? false: true; } R_API int r_core_shift_block(RCore *core, ut64 addr, ut64 b_size, st64 dist) { // bstart - block start, fstart file start ut64 fend = 0, fstart = 0, bstart = 0, file_sz = 0; ut8 * shift_buf = NULL; int res = false; if (!core->io || !core->file) { return false; } if (b_size == 0 || b_size == (ut64) -1) { res = r_io_use_fd (core->io, core->file->fd); file_sz = r_io_size (core->io); if (file_sz == UT64_MAX) { file_sz = 0; } #if 0 bstart = r_io_seek (core->io, addr, R_IO_SEEK_SET); fend = r_io_seek (core->io, 0, R_IO_SEEK_END); if (fend < 1) { fend = 0; } #else bstart = 0; fend = file_sz; #endif fstart = file_sz - fend; b_size = fend > bstart ? fend - bstart: 0; } if ((st64)b_size < 1) { return false; } shift_buf = calloc (b_size, 1); if (!shift_buf) { eprintf ("Cannot allocated %d byte(s)\n", (int)b_size); return false; } // cases // addr + b_size + dist > file_end //if ( (addr+b_size) + dist > file_end ) { // res = false; //} // addr + b_size + dist < file_start (should work since dist is signed) //else if ( (addr+b_size) + dist < 0 ) { // res = false; //} // addr + dist < file_start if (addr + dist < fstart) { res = false; // addr + dist > file_end } else if ( (addr) + dist > fend) { res = false; } else { r_io_use_fd (core->io, core->file->fd); r_io_read_at (core->io, addr, shift_buf, b_size); r_io_write_at (core->io, addr + dist, shift_buf, b_size); res = true; } r_core_seek (core, addr, 1); free (shift_buf); return res; } R_API int r_core_block_read(RCore *core) { if (core && core->block) { return r_io_read_at (core->io, core->offset, core->block, core->blocksize); } return -1; } R_API int r_core_is_valid_offset (RCore *core, ut64 offset) { if (!core) { eprintf ("r_core_is_valid_offset: core is NULL\n"); r_sys_backtrace (); return R_FAIL; } return r_io_is_valid_offset (core->io, offset, 0); }