/* * Implementation of GPTData class derivative with curses-based text-mode * interaction * Copyright (C) 2011-2022 Roderick W. Smith * * 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 2 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, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * */ #include #include #include #include #if defined (__APPLE__) || (__FreeBSD__) #include #else #include #endif #include "gptcurses.h" #include "support.h" using namespace std; // # of lines to reserve for general information and headers (RESERVED_TOP) // and for options and messages (RESERVED_BOTTOM) #define RESERVED_TOP 7 #define RESERVED_BOTTOM 5 int GPTDataCurses::numInstances = 0; GPTDataCurses::GPTDataCurses(void) { if (numInstances > 0) { refresh(); } else { setlocale( LC_ALL , "" ); initscr(); cbreak(); noecho(); intrflush(stdscr, false); keypad(stdscr, true); nonl(); numInstances++; } // if/else firstSpace = NULL; lastSpace = NULL; currentSpace = NULL; currentSpaceNum = -1; whichOptions = ""; // current set of options currentKey = 'b'; // currently selected option displayType = USE_CURSES; } // GPTDataCurses constructor GPTDataCurses::~GPTDataCurses(void) { numInstances--; if ((numInstances == 0) && !isendwin()) endwin(); } // GPTDataCurses destructor /************************************************ * * * Functions relating to Spaces data structures * * * ************************************************/ void GPTDataCurses::EmptySpaces(void) { Space *trash; while (firstSpace != NULL) { trash = firstSpace; firstSpace = firstSpace->nextSpace; delete trash; } // if numSpaces = 0; lastSpace = NULL; } // GPTDataCurses::EmptySpaces() // Create Spaces from partitions. Does NOT creates Spaces to represent // unpartitioned space on the disk. // Returns the number of Spaces created. int GPTDataCurses::MakeSpacesFromParts(void) { uint32_t i; Space *tempSpace; EmptySpaces(); for (i = 0; i < numParts; i++) { if (partitions[i].IsUsed()) { tempSpace = new Space; tempSpace->firstLBA = partitions[i].GetFirstLBA(); tempSpace->lastLBA = partitions[i].GetLastLBA(); tempSpace->origPart = &partitions[i]; tempSpace->partNum = (int) i; LinkToEnd(tempSpace); } // if } // for return numSpaces; } // GPTDataCurses::MakeSpacesFromParts() // Add a single empty Space to the current Spaces linked list and sort the result.... void GPTDataCurses::AddEmptySpace(uint64_t firstLBA, uint64_t lastLBA) { Space *tempSpace; tempSpace = new Space; tempSpace->firstLBA = firstLBA; tempSpace->lastLBA = lastLBA; tempSpace->origPart = &emptySpace; tempSpace->partNum = -1; LinkToEnd(tempSpace); SortSpaces(); } // GPTDataCurses::AddEmptySpace(); // Add Spaces to represent the unallocated parts of the partition table. // Returns the number of Spaces added. int GPTDataCurses::AddEmptySpaces(void) { int numAdded = 0; Space *current; SortSpaces(); if (firstSpace == NULL) { AddEmptySpace(GetFirstUsableLBA(), GetLastUsableLBA()); numAdded++; } else { current = firstSpace; while ((current != NULL) /* && (current->partNum != -1) */ ) { if ((current == firstSpace) && (current->firstLBA > GetFirstUsableLBA())) { AddEmptySpace(GetFirstUsableLBA(), current->firstLBA - 1); numAdded++; } // if if ((current == lastSpace) && (current->lastLBA < GetLastUsableLBA())) { AddEmptySpace(current->lastLBA + 1, GetLastUsableLBA()); numAdded++; } // if if ((current->prevSpace != NULL) && (current->prevSpace->lastLBA < (current->firstLBA - 1))) { AddEmptySpace(current->prevSpace->lastLBA + 1, current->firstLBA - 1); numAdded++; } // if current = current->nextSpace; } // while } // if/else return numAdded; } // GPTDataCurses::AddEmptySpaces() // Remove the specified Space from the linked list and set its previous and // next pointers to NULL. void GPTDataCurses::UnlinkSpace(Space *theSpace) { if (theSpace != NULL) { if (theSpace->prevSpace != NULL) theSpace->prevSpace->nextSpace = theSpace->nextSpace; if (theSpace->nextSpace != NULL) theSpace->nextSpace->prevSpace = theSpace->prevSpace; if (theSpace == firstSpace) firstSpace = theSpace->nextSpace; if (theSpace == lastSpace) lastSpace = theSpace->prevSpace; theSpace->nextSpace = NULL; theSpace->prevSpace = NULL; numSpaces--; } // if } // GPTDataCurses::UnlinkSpace // Link theSpace to the end of the current linked list. void GPTDataCurses::LinkToEnd(Space *theSpace) { if (lastSpace == NULL) { firstSpace = lastSpace = theSpace; theSpace->nextSpace = NULL; theSpace->prevSpace = NULL; } else { theSpace->prevSpace = lastSpace; theSpace->nextSpace = NULL; lastSpace->nextSpace = theSpace; lastSpace = theSpace; } // if/else numSpaces++; } // GPTDataCurses::LinkToEnd() // Sort spaces into ascending order by on-disk position. void GPTDataCurses::SortSpaces(void) { Space *oldFirst, *oldLast, *earliest = NULL, *current = NULL; oldFirst = firstSpace; oldLast = lastSpace; firstSpace = lastSpace = NULL; while (oldFirst != NULL) { current = earliest = oldFirst; while (current != NULL) { if (current->firstLBA < earliest->firstLBA) earliest = current; current = current->nextSpace; } // while if (oldFirst == earliest) oldFirst = earliest->nextSpace; if (oldLast == earliest) oldLast = earliest->prevSpace; UnlinkSpace(earliest); LinkToEnd(earliest); } // while } // GPTDataCurses::SortSpaces() // Identify the spaces on the disk, a "space" being defined as a partition // or an empty gap between, before, or after partitions. The spaces are // presented to users in the main menu display. void GPTDataCurses::IdentifySpaces(void) { MakeSpacesFromParts(); AddEmptySpaces(); } // GPTDataCurses::IdentifySpaces() /************************** * * * Data display functions * * * **************************/ // Display a single Space on line # lineNum. // Returns a pointer to the space being displayed Space* GPTDataCurses::ShowSpace(int spaceNum, int lineNum) { Space *space; int i = 0; #ifdef USE_UTF16 char temp[40]; #endif space = firstSpace; while ((space != NULL) && (i < spaceNum)) { space = space->nextSpace; i++; } // while if ((space != NULL) && (lineNum < (LINES - 5))) { ClearLine(lineNum); if (space->partNum == -1) { // space is empty move(lineNum, 12); printw("%s", BytesToIeee((space->lastLBA - space->firstLBA + 1), blockSize).c_str()); move(lineNum, 24); printw("free space"); } else { // space holds a partition move(lineNum, 3); printw("%d", space->partNum + 1); move(lineNum, 12); printw("%s", BytesToIeee((space->lastLBA - space->firstLBA + 1), blockSize).c_str()); move(lineNum, 24); printw("%s", space->origPart->GetTypeName().c_str()); move(lineNum, 50); #ifdef USE_UTF16 space->origPart->GetDescription().extract(0, 39, temp, 39); printw(temp); #else printw("%s", space->origPart->GetDescription().c_str()); #endif } // if/else } // if return space; } // GPTDataCurses::ShowSpace // Display the partitions, being sure that the space #selected is displayed // and highlighting that space. // Returns the number of the space being shown (should be selected, but will // be -1 if something weird happens) int GPTDataCurses::DisplayParts(int selected) { int lineNum = 5, i = 0, retval = -1, numToShow, pageNum; string theLine; move(lineNum++, 0); theLine = "Part. # Size Partition Type Partition Name"; printw("%s", theLine.c_str()); move(lineNum++, 0); theLine = "----------------------------------------------------------------"; printw("%s", theLine.c_str()); numToShow = LINES - RESERVED_TOP - RESERVED_BOTTOM; pageNum = selected / numToShow; for (i = pageNum * numToShow; i <= (pageNum + 1) * numToShow - 1; i++) { if (i < numSpaces) { // real space; show it if (i == selected) { currentSpaceNum = i; if (displayType == USE_CURSES) { attron(A_REVERSE); currentSpace = ShowSpace(i, lineNum++); attroff(A_REVERSE); } else { currentSpace = ShowSpace(i, lineNum); move(lineNum++, 0); printw(">"); } DisplayOptions(i); retval = selected; } else { ShowSpace(i, lineNum++); } } else { // blank in display ClearLine(lineNum++); } // if/else } // for refresh(); return retval; } // GPTDataCurses::DisplayParts() /********************************************** * * * Functions corresponding to main menu items * * * **********************************************/ // Delete the specified partition and re-detect partitions and spaces.... void GPTDataCurses::DeletePartition(int partNum) { if (!GPTData::DeletePartition(partNum)) Report("Could not delete partition!"); IdentifySpaces(); if (currentSpaceNum >= numSpaces) { currentSpaceNum = numSpaces - 1; currentSpace = lastSpace; } // if } // GPTDataCurses::DeletePartition() // Displays information on the specified partition void GPTDataCurses::ShowInfo(int partNum) { uint64_t size; #ifdef USE_UTF16 char temp[NAME_SIZE + 1]; #endif clear(); move(2, (COLS - 29) / 2); printw("Information for partition #%d\n\n", partNum + 1); printw("Partition GUID code: %s (%s)\n", partitions[partNum].GetType().AsString().c_str(), partitions[partNum].GetTypeName().c_str()); printw("Partition unique GUID: %s\n", partitions[partNum].GetUniqueGUID().AsString().c_str()); printw("First sector: %llu (at %s)\n", (long long unsigned int) partitions[partNum].GetFirstLBA(), BytesToIeee(partitions[partNum].GetFirstLBA(), blockSize).c_str()); printw("Last sector: %llu (at %s)\n", (long long unsigned int) partitions[partNum].GetLastLBA(), BytesToIeee(partitions[partNum].GetLastLBA(), blockSize).c_str()); size = partitions[partNum].GetLastLBA() - partitions[partNum].GetFirstLBA() + 1; printw("Partition size: %llu sectors (%s)\n", (long long unsigned int) size, BytesToIeee(size, blockSize).c_str()); printw("Attribute flags: %016llx\n", (long long unsigned int) partitions[partNum].GetAttributes().GetAttributes()); #ifdef USE_UTF16 partitions[partNum].GetDescription().extract(0, NAME_SIZE , temp, NAME_SIZE ); printw("Partition name: '%s'\n", temp); #else printw("Partition name: '%s'\n", partitions[partNum].GetDescription().c_str()); #endif PromptToContinue(); } // GPTDataCurses::ShowInfo() // Prompt for and change a partition's name.... void GPTDataCurses::ChangeName(int partNum) { char temp[NAME_SIZE + 1]; if (ValidPartNum(partNum)) { move(LINES - 4, 0); clrtobot(); move(LINES - 4, 0); #ifdef USE_UTF16 partitions[partNum].GetDescription().extract(0, NAME_SIZE , temp, NAME_SIZE ); printw("Current partition name is '%s'\n", temp); #else printw("Current partition name is '%s'\n", partitions[partNum].GetDescription().c_str()); #endif printw("Enter new partition name, or to use the current name:\n"); echo(); getnstr(temp, NAME_SIZE ); partitions[partNum].SetName((string) temp); noecho(); } // if } // GPTDataCurses::ChangeName() // Change the partition's type code.... void GPTDataCurses::ChangeType(int partNum) { char temp[80] = "L\0"; PartType tempType; echo(); do { move(LINES - 4, 0); clrtobot(); move(LINES - 4, 0); printw("Current type is %04x (%s)\n", partitions[partNum].GetType().GetHexType(), partitions[partNum].GetTypeName().c_str()); printw("Hex code or GUID (L to show codes, Enter = %04x): ", partitions[partNum].GetType().GetHexType()); getnstr(temp, 79); if ((temp[0] == 'L') || (temp[0] == 'l')) { ShowTypes(); } else { if (temp[0] == '\0') tempType = partitions[partNum].GetType().GetHexType(); tempType = temp; partitions[partNum].SetType(tempType); } // if } while ((temp[0] == 'L') || (temp[0] == 'l') || (partitions[partNum].GetType() == (GUIDData) "0x0000")); noecho(); } // GPTDataCurses::ChangeType // Sets the partition alignment value void GPTDataCurses::SetAlignment(void) { int alignment; char conversion_specifier[] = "%d"; move(LINES - 4, 0); clrtobot(); printw("Current partition alignment, in sectors, is %d.", GetAlignment()); do { move(LINES - 3, 0); printw("Type new alignment value, in sectors: "); echo(); scanw(conversion_specifier, &alignment); noecho(); } while ((alignment == 0) || (alignment > MAX_ALIGNMENT)); GPTData::SetAlignment(alignment); } // GPTDataCurses::SetAlignment() // Verify the data structures. Note that this function leaves curses mode and // relies on the underlying GPTData::Verify() function to report on problems void GPTDataCurses::Verify(void) { char junk; def_prog_mode(); endwin(); GPTData::Verify(); cout << "\nPress the key to continue: "; cin.get(junk); reset_prog_mode(); refresh(); } // GPTDataCurses::Verify() // Create a new partition in the space pointed to by currentSpace. void GPTDataCurses::MakeNewPart(void) { uint64_t size, newFirstLBA = 0, newLastLBA = 0, lastAligned; int partNum; char inLine[80]; move(LINES - 4, 0); clrtobot(); lastAligned = currentSpace->lastLBA + 1; Align(&lastAligned); lastAligned--; // Discard end-alignment attempt if it's giving us an invalid end point.... if (!IsFree(lastAligned)) lastAligned = currentSpace->lastLBA; while ((newFirstLBA < currentSpace->firstLBA) || (newFirstLBA > currentSpace->lastLBA)) { move(LINES - 4, 0); clrtoeol(); newFirstLBA = currentSpace->firstLBA; Align(&newFirstLBA); printw("First sector (%llu-%llu, default = %llu): ", (long long unsigned int) newFirstLBA, (long long unsigned int) currentSpace->lastLBA, (long long unsigned int) newFirstLBA); echo(); getnstr(inLine, 79); noecho(); newFirstLBA = IeeeToInt(inLine, blockSize, currentSpace->firstLBA, currentSpace->lastLBA, sectorAlignment, newFirstLBA); Align(&newFirstLBA); } // while if (newFirstLBA > lastAligned) size = currentSpace->lastLBA - newFirstLBA + 1; else size = lastAligned - newFirstLBA + 1; while ((newLastLBA > currentSpace->lastLBA) || (newLastLBA < newFirstLBA)) { move(LINES - 3, 0); clrtoeol(); printw("Size in sectors or {KMGTP} (default = %llu): ", (long long unsigned int) size); echo(); getnstr(inLine, 79); noecho(); newLastLBA = newFirstLBA + IeeeToInt(inLine, blockSize, 1, size, sectorAlignment, size) - 1; } // while partNum = FindFirstFreePart(); if (CreatePartition(partNum, newFirstLBA, newLastLBA)) { // created OK; set type code & name.... ChangeType(partNum); ChangeName(partNum); } else { Report("Error creating partition!"); } // if/else } // GPTDataCurses::MakeNewPart() // Prompt user for permission to save data and, if it's given, do so! void GPTDataCurses::SaveData(void) { string answer = ""; char inLine[80]; move(LINES - 4, 0); clrtobot(); move (LINES - 2, 14); printw("Warning!! This may destroy data on your disk!"); echo(); while ((answer != "yes") && (answer != "no")) { move (LINES - 4, 2); printw("Are you sure you want to write the partition table to disk? (yes or no): "); getnstr(inLine, 79); answer = inLine; if ((answer != "yes") && (answer != "no")) { move(LINES - 2, 0); clrtoeol(); move(LINES - 2, 14); printw("Please enter 'yes' or 'no'"); } // if } // while() noecho(); if (answer == "yes") { if (SaveGPTData(1)) { if (!myDisk.DiskSync()) Report("The kernel may be using the old partition table. Reboot to use the new\npartition table!"); } else { Report("Problem saving data! Your partition table may be damaged!"); } } } // GPTDataCurses::SaveData() // Back up the partition table, prompting user for a filename.... void GPTDataCurses::Backup(void) { char inLine[80]; ClearBottom(); move(LINES - 3, 0); printw("Enter backup filename to save: "); echo(); getnstr(inLine, 79); noecho(); SaveGPTBackup(inLine); } // GPTDataCurses::Backup() // Load a GPT backup from a file void GPTDataCurses::LoadBackup(void) { char inLine[80]; ClearBottom(); move(LINES - 3, 0); printw("Enter backup filename to load: "); echo(); getnstr(inLine, 79); noecho(); if (!LoadGPTBackup(inLine)) Report("Restoration failed!"); IdentifySpaces(); } // GPTDataCurses::LoadBackup() // Display some basic help information void GPTDataCurses::ShowHelp(void) { int i = 0; clear(); move(0, (COLS - 22) / 2); printw("Help screen for cgdisk"); move(2, 0); printw("This is cgdisk, a curses-based disk partitioning program. You can use it\n"); printw("to create, delete, and modify partitions on your hard disk.\n\n"); attron(A_BOLD); printw("Use cgdisk only on GUID Partition Table (GPT) disks!\n"); attroff(A_BOLD); printw("Use cfdisk on Master Boot Record (MBR) disks.\n\n"); printw("Command Meaning\n"); printw("------- -------\n"); while (menuMain[i].key != 0) { printw(" %c %s\n", menuMain[i].key, menuMain[i].desc.c_str()); i++; } // while() PromptToContinue(); } // GPTDataCurses::ShowHelp() /************************************ * * * User input and menuing functions * * * ************************************/ // Change the currently-selected space.... void GPTDataCurses::ChangeSpaceSelection(int delta) { if (currentSpace != NULL) { while ((delta > 0) && (currentSpace->nextSpace != NULL)) { currentSpace = currentSpace->nextSpace; delta--; currentSpaceNum++; } // while while ((delta < 0) && (currentSpace->prevSpace != NULL)) { currentSpace = currentSpace->prevSpace; delta++; currentSpaceNum--; } // while } // if // Below will hopefully never be true; bad counting error (bug), so reset to // the first Space as a failsafe.... if (DisplayParts(currentSpaceNum) != currentSpaceNum) { currentSpaceNum = 0; currentSpace = firstSpace; DisplayParts(currentSpaceNum); } // if } // GPTDataCurses // Move option selection left or right.... void GPTDataCurses::MoveSelection(int delta) { int newKeyNum; // Begin with a sanity check to ensure a valid key is selected.... if (whichOptions.find(currentKey) == string::npos) currentKey = 'n'; newKeyNum = whichOptions.find(currentKey); newKeyNum += delta; if (newKeyNum < 0) newKeyNum = whichOptions.length() - 1; newKeyNum %= whichOptions.length(); currentKey = whichOptions[newKeyNum]; DisplayOptions(currentKey); } // GPTDataCurses::MoveSelection() // Show user's options. Refers to currentSpace to determine which options to show. // Highlights the option with the key selectedKey; or a default if that's invalid. void GPTDataCurses::DisplayOptions(char selectedKey) { uint64_t i, j = 0, firstLine, numPerLine; string optionName, optionDesc = ""; if (currentSpace != NULL) { if (currentSpace->partNum == -1) { // empty space is selected whichOptions = EMPTY_SPACE_OPTIONS; if (whichOptions.find(selectedKey) == string::npos) selectedKey = 'n'; } else { // a partition is selected whichOptions = PARTITION_OPTIONS; if (whichOptions.find(selectedKey) == string::npos) selectedKey = 't'; } // if/else firstLine = LINES - 4; numPerLine = (COLS - 8) / 12; ClearBottom(); move(firstLine, 0); for (i = 0; i < whichOptions.length(); i++) { optionName = ""; for (j = 0; menuMain[j].key; j++) { if (menuMain[j].key == whichOptions[i]) { optionName = menuMain[j].name; if (whichOptions[i] == selectedKey) optionDesc = menuMain[j].desc; } // if } // for move(firstLine + i / numPerLine, (i % numPerLine) * 12 + 4); if (whichOptions[i] == selectedKey) { attron(A_REVERSE); printw("[ %s ]", optionName.c_str()); attroff(A_REVERSE); } else { printw("[ %s ]", optionName.c_str()); } // if/else } // for move(LINES - 1, (COLS - optionDesc.length()) / 2); printw("%s", optionDesc.c_str()); currentKey = selectedKey; } // if } // GPTDataCurses::DisplayOptions() // Accept user input and process it. Returns when the program should terminate. void GPTDataCurses::AcceptInput() { int inputKey, exitNow = 0; do { refresh(); inputKey = getch(); switch (inputKey) { case KEY_UP: ChangeSpaceSelection(-1); break; case KEY_DOWN: ChangeSpaceSelection(+1); break; case 339: // page up key ChangeSpaceSelection(RESERVED_TOP + RESERVED_BOTTOM - LINES); break; case 338: // page down key ChangeSpaceSelection(LINES - RESERVED_TOP - RESERVED_BOTTOM); break; case KEY_LEFT: MoveSelection(-1); break; case KEY_RIGHT: MoveSelection(+1); break; case KEY_ENTER: case 13: exitNow = Dispatch(currentKey); break; case 27: // escape key exitNow = 1; break; default: exitNow = Dispatch(inputKey); break; } // switch() } while (!exitNow); } // GPTDataCurses::AcceptInput() // Operation has been selected, so do it. Returns 1 if the program should // terminate on return from this program, 0 otherwise. int GPTDataCurses::Dispatch(char operation) { int exitNow = 0; switch (operation) { case 'a': case 'A': SetAlignment(); break; case 'b': case 'B': Backup(); break; case 'd': case 'D': if (ValidPartNum(currentSpace->partNum)) DeletePartition(currentSpace->partNum); break; case 'h': case 'H': ShowHelp(); break; case 'i': case 'I': if (ValidPartNum(currentSpace->partNum)) ShowInfo(currentSpace->partNum); break; case 'l': case 'L': LoadBackup(); break; case 'm': case 'M': if (ValidPartNum(currentSpace->partNum)) ChangeName(currentSpace->partNum); break; case 'n': case 'N': if (currentSpace->partNum < 0) { MakeNewPart(); IdentifySpaces(); } // if break; case 'q': case 'Q': exitNow = 1; break; case 't': case 'T': if (ValidPartNum(currentSpace->partNum)) ChangeType(currentSpace->partNum); break; case 'v': case 'V': Verify(); break; case 'w': case 'W': SaveData(); break; default: break; } // switch() DrawMenu(); return exitNow; } // GPTDataCurses::Dispatch() // Draws the main menu void GPTDataCurses::DrawMenu(void) { string title="cgdisk "; title += GPTFDISK_VERSION; string drive="Disk Drive: "; drive += device; ostringstream size; size << "Size: " << diskSize << ", " << BytesToIeee(diskSize, blockSize); clear(); move(0, (COLS - title.length()) / 2); printw("%s", title.c_str()); move(2, (COLS - drive.length()) / 2); printw("%s", drive.c_str()); move(3, (COLS - size.str().length()) / 2); printw("%s", size.str().c_str()); DisplayParts(currentSpaceNum); } // DrawMenu int GPTDataCurses::MainMenu(void) { if (((LINES - RESERVED_TOP - RESERVED_BOTTOM) < 2) || (COLS < 80)) { Report("Display is too small; it must be at least 80 x 14 characters!"); } else { if (GPTData::Verify() > 0) Report("Warning! Problems found on disk! Use the Verify function to learn more.\n" "Using gdisk or some other program may be necessary to repair the problems."); IdentifySpaces(); currentSpaceNum = 0; DrawMenu(); AcceptInput(); } // if/else endwin(); return 0; } // GPTDataCurses::MainMenu /*********************************************************** * * * Non-class support functions (mostly related to ncurses) * * * ***********************************************************/ // Clears the specified line of all data.... void ClearLine(int lineNum) { move(lineNum, 0); clrtoeol(); } // ClearLine() // Clear the last few lines of the display void ClearBottom(void) { move(LINES - RESERVED_BOTTOM, 0); clrtobot(); } // ClearBottom() void PromptToContinue(void) { ClearBottom(); move(LINES - 2, (COLS - 29) / 2); printw("Press any key to continue...."); cbreak(); getch(); } // PromptToContinue() // Display one line of text on the screen and prompt to press any key to continue. void Report(string theText) { clear(); move(0, 0); printw("%s", theText.c_str()); move(LINES - 2, (COLS - 29) / 2); printw("Press any key to continue...."); cbreak(); getch(); } // Report() // Displays all the partition type codes and then prompts to continue.... // NOTE: This function temporarily exits curses mode as a matter of // convenience. void ShowTypes(void) { PartType tempType; char junk; def_prog_mode(); endwin(); tempType.ShowAllTypes(LINES - 3); cout << "\nPress the key to continue: "; cin.get(junk); reset_prog_mode(); refresh(); } // ShowTypes()