/* Disassembly display. Copyright (C) 1998-2020 Free Software Foundation, Inc. Contributed by Hewlett-Packard Company. This file is part of GDB. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include "defs.h" #include "arch-utils.h" #include "symtab.h" #include "breakpoint.h" #include "frame.h" #include "value.h" #include "source.h" #include "disasm.h" #include "tui/tui.h" #include "tui/tui-command.h" #include "tui/tui-data.h" #include "tui/tui-win.h" #include "tui/tui-layout.h" #include "tui/tui-winsource.h" #include "tui/tui-stack.h" #include "tui/tui-file.h" #include "tui/tui-disasm.h" #include "tui/tui-source.h" #include "progspace.h" #include "objfiles.h" #include "cli/cli-style.h" #include "gdb_curses.h" struct tui_asm_line { CORE_ADDR addr; std::string addr_string; size_t addr_size; std::string insn; }; /* Helper function to find the number of characters in STR, skipping any ANSI escape sequences. */ static size_t len_without_escapes (const std::string &str) { size_t len = 0; const char *ptr = str.c_str (); char c; while ((c = *ptr++) != '\0') { if (c == '\033') { ui_file_style style; size_t n_read; if (style.parse (ptr, &n_read)) ptr += n_read; else { /* Shouldn't happen, but just skip the ESC if it somehow does. */ ++ptr; } } else ++len; } return len; } /* Function to disassemble up to COUNT instructions starting from address PC into the ASM_LINES vector (which will be emptied of any previous contents). Return the address of the COUNT'th instruction after pc. When ADDR_SIZE is non-null then place the maximum size of an address and label into the value pointed to by ADDR_SIZE, and set the addr_size field on each item in ASM_LINES, otherwise the addr_size fields within ASM_LINES are undefined. It is worth noting that ASM_LINES might not have COUNT entries when this function returns. If the disassembly is truncated for some other reason, for example, we hit invalid memory, then ASM_LINES can have fewer entries than requested. */ static CORE_ADDR tui_disassemble (struct gdbarch *gdbarch, std::vector &asm_lines, CORE_ADDR pc, int count, size_t *addr_size = nullptr) { bool term_out = source_styling && gdb_stdout->can_emit_style_escape (); string_file gdb_dis_out (term_out); /* Must start with an empty list. */ asm_lines.clear (); /* Now construct each line. */ for (int i = 0; i < count; ++i) { tui_asm_line tal; CORE_ADDR orig_pc = pc; try { pc = pc + gdb_print_insn (gdbarch, pc, &gdb_dis_out, NULL); } catch (const gdb_exception_error &except) { /* If PC points to an invalid address then we'll catch a MEMORY_ERROR here, this should stop the disassembly, but otherwise is fine. */ if (except.error != MEMORY_ERROR) throw; return pc; } /* Capture the disassembled instruction. */ tal.insn = std::move (gdb_dis_out.string ()); gdb_dis_out.clear (); /* And capture the address the instruction is at. */ tal.addr = orig_pc; print_address (gdbarch, orig_pc, &gdb_dis_out); tal.addr_string = std::move (gdb_dis_out.string ()); gdb_dis_out.clear (); if (addr_size != nullptr) { size_t new_size; if (term_out) new_size = len_without_escapes (tal.addr_string); else new_size = tal.addr_string.size (); *addr_size = std::max (*addr_size, new_size); tal.addr_size = new_size; } asm_lines.push_back (std::move (tal)); } return pc; } /* Look backward from ADDR for an address from which we can start disassembling, this needs to be something we can be reasonably confident will fall on an instruction boundary. We use msymbol addresses, or the start of a section. */ static CORE_ADDR tui_find_backward_disassembly_start_address (CORE_ADDR addr) { struct bound_minimal_symbol msym, msym_prev; msym = lookup_minimal_symbol_by_pc_section (addr - 1, nullptr, lookup_msym_prefer::TEXT, &msym_prev); if (msym.minsym != nullptr) return BMSYMBOL_VALUE_ADDRESS (msym); else if (msym_prev.minsym != nullptr) return BMSYMBOL_VALUE_ADDRESS (msym_prev); /* Find the section that ADDR is in, and look for the start of the section. */ struct obj_section *section = find_pc_section (addr); if (section != NULL) return obj_section_addr (section); return addr; } /* Find the disassembly address that corresponds to FROM lines above or below the PC. Variable sized instructions are taken into account by the algorithm. */ static CORE_ADDR tui_find_disassembly_address (struct gdbarch *gdbarch, CORE_ADDR pc, int from) { CORE_ADDR new_low; int max_lines; max_lines = (from > 0) ? from : - from; if (max_lines == 0) return pc; std::vector asm_lines; new_low = pc; if (from > 0) { /* Always disassemble 1 extra instruction here, then if the last instruction fails to disassemble we will take the address of the previous instruction that did disassemble as the result. */ tui_disassemble (gdbarch, asm_lines, pc, max_lines + 1); new_low = asm_lines.back ().addr; } else { /* In order to disassemble backwards we need to find a suitable address to start disassembling from and then work forward until we re-find the address we're currently at. We can then figure out which address will be at the top of the TUI window after our backward scroll. During our backward disassemble we need to be able to distinguish between the case where the last address we _can_ disassemble is ADDR, and the case where the disassembly just happens to stop at ADDR, for this reason we increase MAX_LINES by one. */ max_lines++; /* When we disassemble a series of instructions this will hold the address of the last instruction disassembled. */ CORE_ADDR last_addr; /* And this will hold the address of the next instruction that would have been disassembled. */ CORE_ADDR next_addr; /* As we search backward if we find an address that looks like a promising starting point then we record it in this structure. If the next address we try is not a suitable starting point then we will fall back to the address held here. */ gdb::optional possible_new_low; /* The previous value of NEW_LOW so we know if the new value is different or not. */ CORE_ADDR prev_low; do { /* Find an address from which we can start disassembling. */ prev_low = new_low; new_low = tui_find_backward_disassembly_start_address (new_low); /* Disassemble forward. */ next_addr = tui_disassemble (gdbarch, asm_lines, new_low, max_lines); last_addr = asm_lines.back ().addr; /* If disassembling from the current value of NEW_LOW reached PC (or went past it) then this would do as a starting point if we can't find anything better, so remember it. */ if (last_addr >= pc && new_low != prev_low && asm_lines.size () >= max_lines) possible_new_low.emplace (new_low); /* Continue searching until we find a value of NEW_LOW from which disassembling MAX_LINES instructions doesn't reach PC. We know this means we can find the required number of previous instructions then. */ } while ((last_addr > pc || (last_addr == pc && asm_lines.size () < max_lines)) && new_low != prev_low); /* If we failed to disassemble the required number of lines then the following walk forward is not going to work, it assumes that ASM_LINES contains exactly MAX_LINES entries. Instead we should consider falling back to a previous possible start address in POSSIBLE_NEW_LOW. */ if (asm_lines.size () < max_lines) { if (!possible_new_low.has_value ()) return new_low; /* Take the best possible match we have. */ new_low = *possible_new_low; next_addr = tui_disassemble (gdbarch, asm_lines, new_low, max_lines); last_addr = asm_lines.back ().addr; gdb_assert (asm_lines.size () >= max_lines); } /* Scan forward disassembling one instruction at a time until the last visible instruction of the window matches the pc. We keep the disassembled instructions in the 'lines' window and shift it downward (increasing its addresses). */ int pos = max_lines - 1; if (last_addr < pc) do { pos++; if (pos >= max_lines) pos = 0; CORE_ADDR old_next_addr = next_addr; std::vector single_asm_line; next_addr = tui_disassemble (gdbarch, single_asm_line, next_addr, 1); /* If there are some problems while disassembling exit. */ if (next_addr <= old_next_addr) return pc; gdb_assert (single_asm_line.size () == 1); asm_lines[pos] = single_asm_line[0]; } while (next_addr <= pc); pos++; if (pos >= max_lines) pos = 0; new_low = asm_lines[pos].addr; /* When scrolling backward the addresses should move backward, or at the very least stay the same if we are at the first address that can be disassembled. */ gdb_assert (new_low <= pc); } return new_low; } /* Function to set the disassembly window's content. */ bool tui_disasm_window::set_contents (struct gdbarch *arch, const struct symtab_and_line &sal) { int i; int max_lines; CORE_ADDR cur_pc; struct tui_locator_window *locator = tui_locator_win_info_ptr (); int tab_len = tui_tab_width; int insn_pos; CORE_ADDR pc = sal.pc; if (pc == 0) return false; m_gdbarch = arch; m_start_line_or_addr.loa = LOA_ADDRESS; m_start_line_or_addr.u.addr = pc; cur_pc = locator->addr; /* Window size, excluding highlight box. */ max_lines = height - 2; /* Get temporary table that will hold all strings (addr & insn). */ std::vector asm_lines; size_t addr_size = 0; tui_disassemble (m_gdbarch, asm_lines, pc, max_lines, &addr_size); /* Align instructions to the same column. */ insn_pos = (1 + (addr_size / tab_len)) * tab_len; /* Now construct each line. */ m_content.resize (max_lines); m_max_length = -1; for (i = 0; i < max_lines; i++) { tui_source_element *src = &m_content[i]; std::string line; CORE_ADDR addr; if (i < asm_lines.size ()) { line = (asm_lines[i].addr_string + n_spaces (insn_pos - asm_lines[i].addr_size) + asm_lines[i].insn); addr = asm_lines[i].addr; } else { line = ""; addr = 0; } const char *ptr = line.c_str (); int line_len; src->line = tui_copy_source_line (&ptr, &line_len); m_max_length = std::max (m_max_length, line_len); src->line_or_addr.loa = LOA_ADDRESS; src->line_or_addr.u.addr = addr; src->is_exec_point = (addr == cur_pc && line.size () > 0); } return true; } void tui_get_begin_asm_address (struct gdbarch **gdbarch_p, CORE_ADDR *addr_p) { struct tui_locator_window *locator; struct gdbarch *gdbarch = get_current_arch (); CORE_ADDR addr = 0; locator = tui_locator_win_info_ptr (); if (locator->addr == 0) { if (have_full_symbols () || have_partial_symbols ()) { set_default_source_symtab_and_line (); struct symtab_and_line sal = get_current_source_symtab_and_line (); if (sal.symtab != nullptr) find_line_pc (sal.symtab, sal.line, &addr); } if (addr == 0) { struct bound_minimal_symbol main_symbol = lookup_minimal_symbol (main_name (), nullptr, nullptr); if (main_symbol.minsym != nullptr) addr = BMSYMBOL_VALUE_ADDRESS (main_symbol); } } else /* The target is executing. */ { gdbarch = locator->gdbarch; addr = locator->addr; } *gdbarch_p = gdbarch; *addr_p = addr; } /* Determine what the low address will be to display in the TUI's disassembly window. This may or may not be the same as the low address input. */ CORE_ADDR tui_get_low_disassembly_address (struct gdbarch *gdbarch, CORE_ADDR low, CORE_ADDR pc) { int pos; /* Determine where to start the disassembly so that the pc is about in the middle of the viewport. */ if (TUI_DISASM_WIN != NULL) pos = TUI_DISASM_WIN->height; else if (TUI_CMD_WIN == NULL) pos = tui_term_height () / 2 - 2; else pos = tui_term_height () - TUI_CMD_WIN->height - 2; pos = (pos - 2) / 2; pc = tui_find_disassembly_address (gdbarch, pc, -pos); if (pc < low) pc = low; return pc; } /* Scroll the disassembly forward or backward vertically. */ void tui_disasm_window::do_scroll_vertical (int num_to_scroll) { if (!m_content.empty ()) { CORE_ADDR pc; pc = m_start_line_or_addr.u.addr; symtab_and_line sal {}; sal.pspace = current_program_space; sal.pc = tui_find_disassembly_address (m_gdbarch, pc, num_to_scroll); update_source_window_as_is (m_gdbarch, sal); } } bool tui_disasm_window::location_matches_p (struct bp_location *loc, int line_no) { return (m_content[line_no].line_or_addr.loa == LOA_ADDRESS && m_content[line_no].line_or_addr.u.addr == loc->address); } bool tui_disasm_window::addr_is_displayed (CORE_ADDR addr) const { if (m_content.size () < SCROLL_THRESHOLD) return false; for (size_t i = 0; i < m_content.size () - SCROLL_THRESHOLD; ++i) { if (m_content[i].line_or_addr.loa == LOA_ADDRESS && m_content[i].line_or_addr.u.addr == addr) return true; } return false; } void tui_disasm_window::maybe_update (struct frame_info *fi, symtab_and_line sal) { CORE_ADDR low; struct gdbarch *frame_arch = get_frame_arch (fi); if (find_pc_partial_function (sal.pc, NULL, &low, NULL) == 0) { /* There is no symbol available for current PC. There is no safe way how to "disassemble backwards". */ low = sal.pc; } else low = tui_get_low_disassembly_address (frame_arch, low, sal.pc); struct tui_line_or_address a; a.loa = LOA_ADDRESS; a.u.addr = low; if (!addr_is_displayed (sal.pc)) { sal.pc = low; update_source_window (frame_arch, sal); } else { a.u.addr = sal.pc; set_is_exec_point_at (a); } } void tui_disasm_window::display_start_addr (struct gdbarch **gdbarch_p, CORE_ADDR *addr_p) { *gdbarch_p = m_gdbarch; *addr_p = m_start_line_or_addr.u.addr; }