limine/common/lib/readline.c
2022-12-30 07:58:46 +01:00

480 lines
12 KiB
C

#include <stdint.h>
#include <stddef.h>
#include <lib/readline.h>
#include <lib/libc.h>
#include <lib/misc.h>
#include <lib/term.h>
#include <lib/print.h>
#if defined (BIOS)
# include <lib/real.h>
#elif defined (UEFI)
# include <efi.h>
#endif
#include <drivers/serial.h>
#include <sys/cpu.h>
int getchar(void) {
for (;;) {
int ret = pit_sleep_and_quit_on_keypress(65535);
if (ret != 0) {
return ret;
}
}
}
int getchar_internal(uint8_t scancode, uint8_t ascii, uint32_t shift_state) {
switch (scancode) {
#if defined (BIOS)
case 0x44:
return GETCHAR_F10;
case 0x4b:
return GETCHAR_CURSOR_LEFT;
case 0x4d:
return GETCHAR_CURSOR_RIGHT;
case 0x48:
return GETCHAR_CURSOR_UP;
case 0x50:
return GETCHAR_CURSOR_DOWN;
case 0x53:
return GETCHAR_DELETE;
case 0x4f:
return GETCHAR_END;
case 0x47:
return GETCHAR_HOME;
case 0x49:
return GETCHAR_PGUP;
case 0x51:
return GETCHAR_PGDOWN;
case 0x01:
return GETCHAR_ESCAPE;
#elif defined (UEFI)
case SCAN_F10:
return GETCHAR_F10;
case SCAN_LEFT:
return GETCHAR_CURSOR_LEFT;
case SCAN_RIGHT:
return GETCHAR_CURSOR_RIGHT;
case SCAN_UP:
return GETCHAR_CURSOR_UP;
case SCAN_DOWN:
return GETCHAR_CURSOR_DOWN;
case SCAN_DELETE:
return GETCHAR_DELETE;
case SCAN_END:
return GETCHAR_END;
case SCAN_HOME:
return GETCHAR_HOME;
case SCAN_PAGE_UP:
return GETCHAR_PGUP;
case SCAN_PAGE_DOWN:
return GETCHAR_PGDOWN;
case SCAN_ESC:
return GETCHAR_ESCAPE;
#endif
}
switch (ascii) {
case '\r':
return '\n';
case '\b':
return '\b';
}
if (shift_state & (GETCHAR_LCTRL | GETCHAR_RCTRL)) {
switch (ascii) {
case 'a': return GETCHAR_HOME;
case 'e': return GETCHAR_END;
case 'p': return GETCHAR_CURSOR_UP;
case 'n': return GETCHAR_CURSOR_DOWN;
case 'b': return GETCHAR_CURSOR_LEFT;
case 'f': return GETCHAR_CURSOR_RIGHT;
default: break;
}
}
// Guard against non-printable values
if (ascii < 0x20 || ascii > 0x7e) {
return -1;
}
return ascii;
}
#if defined (BIOS)
int _pit_sleep_and_quit_on_keypress(uint32_t ticks);
static int input_sequence(void) {
int val = 0;
for (;;) {
int ret = -1;
size_t retries = 0;
while (ret == -1 && retries < 1000000) {
ret = serial_in();
retries++;
}
if (ret == -1) {
return 0;
}
switch (ret) {
case 'A':
return GETCHAR_CURSOR_UP;
case 'B':
return GETCHAR_CURSOR_DOWN;
case 'C':
return GETCHAR_CURSOR_RIGHT;
case 'D':
return GETCHAR_CURSOR_LEFT;
case 'F':
return GETCHAR_END;
case 'H':
return GETCHAR_HOME;
}
if (ret > '9' || ret < '0') {
break;
}
val *= 10;
val += ret - '0';
}
switch (val) {
case 3:
return GETCHAR_DELETE;
case 5:
return GETCHAR_PGUP;
case 6:
return GETCHAR_PGDOWN;
case 21:
return GETCHAR_F10;
}
return 0;
}
int pit_sleep_and_quit_on_keypress(int seconds) {
if (!serial) {
return _pit_sleep_and_quit_on_keypress(seconds * 18);
}
for (int i = 0; i < seconds * 18; i++) {
int ret = _pit_sleep_and_quit_on_keypress(1);
if (ret != 0) {
return ret;
}
ret = serial_in();
if (ret != -1) {
again:
switch (ret) {
case '\r':
return '\n';
case 0x1b:
delay(10000);
ret = serial_in();
if (ret == -1) {
return GETCHAR_ESCAPE;
}
if (ret == '[') {
return input_sequence();
}
goto again;
case 0x7f:
return '\b';
}
return ret;
}
}
return 0;
}
#endif
#if defined (UEFI)
static int input_sequence(bool ext,
EFI_SIMPLE_TEXT_INPUT_EX_PROTOCOL *exproto,
EFI_SIMPLE_TEXT_IN_PROTOCOL *sproto) {
EFI_STATUS status;
EFI_KEY_DATA kd;
int val = 0;
for (;;) {
if (ext == false) {
status = sproto->ReadKeyStroke(sproto, &kd.Key);
} else {
status = exproto->ReadKeyStrokeEx(exproto, &kd);
}
if (status != EFI_SUCCESS) {
return 0;
}
switch (kd.Key.UnicodeChar) {
case 'A':
return GETCHAR_CURSOR_UP;
case 'B':
return GETCHAR_CURSOR_DOWN;
case 'C':
return GETCHAR_CURSOR_RIGHT;
case 'D':
return GETCHAR_CURSOR_LEFT;
case 'F':
return GETCHAR_END;
case 'H':
return GETCHAR_HOME;
}
if (kd.Key.UnicodeChar > '9' || kd.Key.UnicodeChar < '0') {
break;
}
val *= 10;
val += kd.Key.UnicodeChar - '0';
}
switch (val) {
case 3:
return GETCHAR_DELETE;
case 5:
return GETCHAR_PGUP;
case 6:
return GETCHAR_PGDOWN;
case 21:
return GETCHAR_F10;
}
return 0;
}
int pit_sleep_and_quit_on_keypress(int seconds) {
EFI_KEY_DATA kd;
UINTN which;
EFI_EVENT events[2];
EFI_GUID exproto_guid = EFI_SIMPLE_TEXT_INPUT_EX_PROTOCOL_GUID;
EFI_GUID sproto_guid = EFI_SIMPLE_TEXT_INPUT_PROTOCOL_GUID;
EFI_SIMPLE_TEXT_INPUT_EX_PROTOCOL *exproto = NULL;
EFI_SIMPLE_TEXT_IN_PROTOCOL *sproto = NULL;
bool use_sproto = false;
if (gBS->HandleProtocol(gST->ConsoleInHandle, &exproto_guid, (void **)&exproto) != EFI_SUCCESS) {
if (gBS->HandleProtocol(gST->ConsoleInHandle, &sproto_guid, (void **)&sproto) != EFI_SUCCESS) {
if (gST->ConIn != NULL) {
sproto = gST->ConIn;
} else {
panic(false, "Your input device doesn't have an input protocol!");
}
}
events[0] = sproto->WaitForKey;
use_sproto = true;
} else {
events[0] = exproto->WaitForKeyEx;
}
gBS->CreateEvent(EVT_TIMER, TPL_CALLBACK, NULL, NULL, &events[1]);
gBS->SetTimer(events[1], TimerRelative, 10000000 * seconds);
again:
memset(&kd, 0, sizeof(EFI_KEY_DATA));
gBS->WaitForEvent(2, events, &which);
if (which == 1) {
return 0;
}
EFI_STATUS status;
if (use_sproto) {
status = sproto->ReadKeyStroke(sproto, &kd.Key);
} else {
status = exproto->ReadKeyStrokeEx(exproto, &kd);
}
if (status != EFI_SUCCESS) {
goto again;
}
if ((kd.KeyState.KeyShiftState & EFI_SHIFT_STATE_VALID) == 0) {
kd.KeyState.KeyShiftState = 0;
}
if (kd.Key.ScanCode == 0x08) {
return '\b';
}
if (kd.Key.ScanCode == SCAN_ESC) {
gBS->CreateEvent(EVT_TIMER, TPL_CALLBACK, NULL, NULL, &events[1]);
gBS->SetTimer(events[1], TimerRelative, 100000);
gBS->WaitForEvent(2, events, &which);
if (which == 1) {
return GETCHAR_ESCAPE;
}
if (use_sproto) {
status = sproto->ReadKeyStroke(sproto, &kd.Key);
} else {
status = exproto->ReadKeyStrokeEx(exproto, &kd);
}
if (status != EFI_SUCCESS) {
goto again;
}
if (kd.Key.UnicodeChar == '[') {
return input_sequence(!use_sproto, exproto, sproto);
}
}
int ret = getchar_internal(kd.Key.ScanCode, kd.Key.UnicodeChar,
kd.KeyState.KeyShiftState);
if (ret == -1) {
goto again;
}
return ret;
}
#endif
static void reprint_string(int x, int y, const char *s) {
size_t orig_x, orig_y;
FOR_TERM(TERM->cursor_enabled = false);
terms[0]->get_cursor_pos(terms[0], &orig_x, &orig_y);
set_cursor_pos_helper(x, y);
print("%s", s);
set_cursor_pos_helper(orig_x, orig_y);
FOR_TERM(TERM->cursor_enabled = true);
}
static void cursor_back(void) {
size_t x, y;
terms[0]->get_cursor_pos(terms[0], &x, &y);
if (x) {
x--;
} else if (y) {
y--;
x = terms[0]->cols - 1;
}
set_cursor_pos_helper(x, y);
}
static void cursor_fwd(void) {
size_t x, y;
terms[0]->get_cursor_pos(terms[0], &x, &y);
if (x < terms[0]->cols - 1) {
x++;
} else {
x = 0;
if (y < terms[0]->rows - 1) {
y++;
}
}
set_cursor_pos_helper(x, y);
}
void readline(const char *orig_str, char *buf, size_t limit) {
bool prev_autoflush = terms[0]->autoflush;
FOR_TERM(TERM->autoflush = false);
size_t orig_str_len = strlen(orig_str);
memmove(buf, orig_str, orig_str_len);
buf[orig_str_len] = 0;
size_t orig_x, orig_y;
terms[0]->get_cursor_pos(terms[0], &orig_x, &orig_y);
print("%s", orig_str);
for (size_t i = orig_str_len; ; ) {
FOR_TERM(TERM->double_buffer_flush(TERM));
int c = getchar();
switch (c) {
case GETCHAR_CURSOR_LEFT:
if (i) {
i--;
cursor_back();
}
continue;
case GETCHAR_CURSOR_RIGHT:
if (i < strlen(buf)) {
i++;
cursor_fwd();
}
continue;
case '\b':
if (i) {
i--;
cursor_back();
case GETCHAR_DELETE:;
size_t j;
if (buf[i] == 0) {
continue;
}
for (j = i; ; j++) {
buf[j] = buf[j+1];
if (!buf[j]) {
buf[j] = ' ';
break;
}
}
reprint_string(orig_x, orig_y, buf);
buf[j] = 0;
}
continue;
case '\n':
print("\n");
goto out;
case GETCHAR_END:
for (size_t j = 0; j < strlen(buf) - i; j++) {
cursor_fwd();
}
i = strlen(buf);
continue;
case GETCHAR_HOME:
for (size_t j = 0; j < i; j++) {
cursor_back();
}
i = 0;
continue;
default: {
if (strlen(buf) < limit - 1 && isprint(c)) {
for (size_t j = strlen(buf); ; j--) {
buf[j+1] = buf[j];
if (j == i)
break;
}
buf[i] = c;
i++;
size_t prev_x, prev_y;
terms[0]->get_cursor_pos(terms[0], &prev_x, &prev_y);
cursor_fwd();
reprint_string(orig_x, orig_y, buf);
// If cursor has wrapped around, move the line start position up one row
if (prev_x == terms[0]->cols - 1 && prev_y == terms[0]->rows - 1) {
orig_y--;
print("\n\e[J"); // Clear the bottom line
}
}
}
}
}
out:
FOR_TERM(TERM->double_buffer_flush(TERM));
FOR_TERM(TERM->autoflush = prev_autoflush);
}