/* SPDX-License-Identifier: LGPL-2.1-or-later */ #include #include #include "console.h" #include "util.h" #define SYSTEM_FONT_WIDTH 8 #define SYSTEM_FONT_HEIGHT 19 #define HORIZONTAL_MAX_OK 1920 #define VERTICAL_MAX_OK 1080 #define VIEWPORT_RATIO 10 static inline void event_closep(EFI_EVENT *event) { if (!*event) return; BS->CloseEvent(*event); } /* * Reading input from the console sounds like an easy task to do, but thanks to broken * firmware it is actually a nightmare. * * There is a SimpleTextInput and SimpleTextInputEx API for this. Ideally we want to use * TextInputEx, because that gives us Ctrl/Alt/Shift key state information. Unfortunately, * it is not always available and sometimes just non-functional. * * On some firmware, calling ReadKeyStroke or ReadKeyStrokeEx on the default console input * device will just freeze no matter what (even though it *reported* being ready). * Also, multiple input protocols can be backed by the same device, but they can be out of * sync. Falling back on a different protocol can end up with double input. * * Therefore, we will preferably use TextInputEx for ConIn if that is available. Additionally, * we look for the first TextInputEx device the firmware gives us as a fallback option. It * will replace ConInEx permanently if it ever reports a key press. * Lastly, a timer event allows us to provide a input timeout without having to call into * any input functions that can freeze on us or using a busy/stall loop. */ EFI_STATUS console_key_read(uint64_t *key, uint64_t timeout_usec) { static EFI_SIMPLE_TEXT_INPUT_EX_PROTOCOL *conInEx = NULL, *extraInEx = NULL; static bool checked = false; UINTN index; EFI_STATUS err; _cleanup_(event_closep) EFI_EVENT timer = NULL; assert(key); if (!checked) { /* Get the *first* TextInputEx device.*/ err = BS->LocateProtocol(&SimpleTextInputExProtocol, NULL, (void **) &extraInEx); if (err != EFI_SUCCESS || BS->CheckEvent(extraInEx->WaitForKeyEx) == EFI_INVALID_PARAMETER) /* If WaitForKeyEx fails here, the firmware pretends it talks this * protocol, but it really doesn't. */ extraInEx = NULL; /* Get the TextInputEx version of ST->ConIn. */ err = BS->HandleProtocol(ST->ConsoleInHandle, &SimpleTextInputExProtocol, (void **) &conInEx); if (err != EFI_SUCCESS || BS->CheckEvent(conInEx->WaitForKeyEx) == EFI_INVALID_PARAMETER) conInEx = NULL; if (conInEx == extraInEx) extraInEx = NULL; checked = true; } err = BS->CreateEvent(EVT_TIMER, 0, NULL, NULL, &timer); if (err != EFI_SUCCESS) return log_error_status_stall(err, L"Error creating timer event: %r", err); EFI_EVENT events[] = { timer, conInEx ? conInEx->WaitForKeyEx : ST->ConIn->WaitForKey, extraInEx ? extraInEx->WaitForKeyEx : NULL, }; UINTN n_events = extraInEx ? 3 : 2; /* Watchdog rearming loop in case the user never provides us with input or some * broken firmware never returns from WaitForEvent. */ for (;;) { uint64_t watchdog_timeout_sec = 5 * 60, watchdog_ping_usec = watchdog_timeout_sec / 2 * 1000 * 1000; /* SetTimer expects 100ns units for some reason. */ err = BS->SetTimer( timer, TimerRelative, MIN(timeout_usec, watchdog_ping_usec) * 10); if (err != EFI_SUCCESS) return log_error_status_stall(err, L"Error arming timer event: %r", err); (void) BS->SetWatchdogTimer(watchdog_timeout_sec, 0x10000, 0, NULL); err = BS->WaitForEvent(n_events, events, &index); (void) BS->SetWatchdogTimer(watchdog_timeout_sec, 0x10000, 0, NULL); if (err != EFI_SUCCESS) return log_error_status_stall(err, L"Error waiting for events: %r", err); /* We have keyboard input, process it after this loop. */ if (timer != events[index]) break; /* The EFI timer fired instead. If this was a watchdog timeout, loop again. */ if (timeout_usec == UINT64_MAX) continue; else if (timeout_usec > watchdog_ping_usec) { timeout_usec -= watchdog_ping_usec; continue; } /* The caller requested a timeout? They shall have one! */ return EFI_TIMEOUT; } /* If the extra input device we found returns something, always use that instead * to work around broken firmware freezing on ConIn/ConInEx. */ if (extraInEx && BS->CheckEvent(extraInEx->WaitForKeyEx) == EFI_SUCCESS) { conInEx = extraInEx; extraInEx = NULL; } /* Do not fall back to ConIn if we have a ConIn that supports TextInputEx. * The two may be out of sync on some firmware, giving us double input. */ if (conInEx) { EFI_KEY_DATA keydata; uint32_t shift = 0; err = conInEx->ReadKeyStrokeEx(conInEx, &keydata); if (err != EFI_SUCCESS) return err; if (FLAGS_SET(keydata.KeyState.KeyShiftState, EFI_SHIFT_STATE_VALID)) { /* Do not distinguish between left and right keys (set both flags). */ if (keydata.KeyState.KeyShiftState & EFI_CONTROL_PRESSED) shift |= EFI_CONTROL_PRESSED; if (keydata.KeyState.KeyShiftState & EFI_ALT_PRESSED) shift |= EFI_ALT_PRESSED; if (keydata.KeyState.KeyShiftState & EFI_LOGO_PRESSED) shift |= EFI_LOGO_PRESSED; /* Shift is not supposed to be reported for keys that can be represented as uppercase * unicode chars (Shift+f is reported as F instead). Some firmware does it anyway, so * filter those out. */ if ((keydata.KeyState.KeyShiftState & EFI_SHIFT_PRESSED) && keydata.Key.UnicodeChar == 0) shift |= EFI_SHIFT_PRESSED; } /* 32 bit modifier keys + 16 bit scan code + 16 bit unicode */ *key = KEYPRESS(shift, keydata.Key.ScanCode, keydata.Key.UnicodeChar); return EFI_SUCCESS; } else if (BS->CheckEvent(ST->ConIn->WaitForKey) == EFI_SUCCESS) { EFI_INPUT_KEY k; err = ST->ConIn->ReadKeyStroke(ST->ConIn, &k); if (err != EFI_SUCCESS) return err; *key = KEYPRESS(0, k.ScanCode, k.UnicodeChar); return EFI_SUCCESS; } return EFI_NOT_READY; } static EFI_STATUS change_mode(int64_t mode) { EFI_STATUS err; int32_t old_mode; /* SetMode expects a UINTN, so make sure these values are sane. */ mode = CLAMP(mode, CONSOLE_MODE_RANGE_MIN, CONSOLE_MODE_RANGE_MAX); old_mode = MAX(CONSOLE_MODE_RANGE_MIN, ST->ConOut->Mode->Mode); err = ST->ConOut->SetMode(ST->ConOut, mode); if (err == EFI_SUCCESS) return EFI_SUCCESS; /* Something went wrong. Output is probably borked, so try to revert to previous mode. */ if (ST->ConOut->SetMode(ST->ConOut, old_mode) == EFI_SUCCESS) return err; /* Maybe the device is on fire? */ ST->ConOut->Reset(ST->ConOut, true); ST->ConOut->SetMode(ST->ConOut, CONSOLE_MODE_RANGE_MIN); return err; } EFI_STATUS query_screen_resolution(uint32_t *ret_w, uint32_t *ret_h) { EFI_STATUS err; EFI_GRAPHICS_OUTPUT_PROTOCOL *go; err = BS->LocateProtocol(&GraphicsOutputProtocol, NULL, (void **) &go); if (err != EFI_SUCCESS) return err; if (!go->Mode || !go->Mode->Info) return EFI_DEVICE_ERROR; *ret_w = go->Mode->Info->HorizontalResolution; *ret_h = go->Mode->Info->VerticalResolution; return EFI_SUCCESS; } static int64_t get_auto_mode(void) { uint32_t screen_width, screen_height; if (query_screen_resolution(&screen_width, &screen_height) == EFI_SUCCESS) { bool keep = false; /* Start verifying if we are in a resolution larger than Full HD * (1920x1080). If we're not, assume we're in a good mode and do not * try to change it. */ if (screen_width <= HORIZONTAL_MAX_OK && screen_height <= VERTICAL_MAX_OK) keep = true; /* For larger resolutions, calculate the ratio of the total screen * area to the text viewport area. If it's less than 10 times bigger, * then assume the text is readable and keep the text mode. */ else { uint64_t text_area; UINTN x_max, y_max; uint64_t screen_area = (uint64_t)screen_width * (uint64_t)screen_height; console_query_mode(&x_max, &y_max); text_area = SYSTEM_FONT_WIDTH * SYSTEM_FONT_HEIGHT * (uint64_t)x_max * (uint64_t)y_max; if (text_area != 0 && screen_area/text_area < VIEWPORT_RATIO) keep = true; } if (keep) return ST->ConOut->Mode->Mode; } /* If we reached here, then we have a high resolution screen and the text * viewport is less than 10% the screen area, so the firmware developer * screwed up. Try to switch to a better mode. Mode number 2 is first non * standard mode, which is provided by the device manufacturer, so it should * be a good mode. * Note: MaxMode is the number of modes, not the last mode. */ if (ST->ConOut->Mode->MaxMode > CONSOLE_MODE_FIRMWARE_FIRST) return CONSOLE_MODE_FIRMWARE_FIRST; /* Try again with mode different than zero (assume user requests * auto mode due to some problem with mode zero). */ if (ST->ConOut->Mode->MaxMode > CONSOLE_MODE_80_50) return CONSOLE_MODE_80_50; return CONSOLE_MODE_80_25; } EFI_STATUS console_set_mode(int64_t mode) { switch (mode) { case CONSOLE_MODE_KEEP: /* If the firmware indicates the current mode is invalid, change it anyway. */ if (ST->ConOut->Mode->Mode < CONSOLE_MODE_RANGE_MIN) return change_mode(CONSOLE_MODE_RANGE_MIN); return EFI_SUCCESS; case CONSOLE_MODE_NEXT: if (ST->ConOut->Mode->MaxMode <= CONSOLE_MODE_RANGE_MIN) return EFI_UNSUPPORTED; mode = MAX(CONSOLE_MODE_RANGE_MIN, ST->ConOut->Mode->Mode); do { mode = (mode + 1) % ST->ConOut->Mode->MaxMode; if (change_mode(mode) == EFI_SUCCESS) break; /* If this mode is broken/unsupported, try the next. * If mode is 0, we wrapped around and should stop. */ } while (mode > CONSOLE_MODE_RANGE_MIN); return EFI_SUCCESS; case CONSOLE_MODE_AUTO: return change_mode(get_auto_mode()); case CONSOLE_MODE_FIRMWARE_MAX: /* Note: MaxMode is the number of modes, not the last mode. */ return change_mode(ST->ConOut->Mode->MaxMode - 1LL); default: return change_mode(mode); } } EFI_STATUS console_query_mode(UINTN *x_max, UINTN *y_max) { EFI_STATUS err; assert(x_max); assert(y_max); err = ST->ConOut->QueryMode(ST->ConOut, ST->ConOut->Mode->Mode, x_max, y_max); if (err != EFI_SUCCESS) { /* Fallback values mandated by UEFI spec. */ switch (ST->ConOut->Mode->Mode) { case CONSOLE_MODE_80_50: *x_max = 80; *y_max = 50; break; case CONSOLE_MODE_80_25: default: *x_max = 80; *y_max = 25; } } return err; }