/*-*- mode:c;indent-tabs-mode:nil;c-basic-offset:2;tab-width:8;coding:utf-8 -*-│
│vi: set net ft=c ts=2 sts=2 sw=2 fenc=utf-8 :vi│
╞══════════════════════════════════════════════════════════════════════════════╡
│ Copyright 2020 Justine Alexandra Roberts Tunney │
│ │
│ Permission to use, copy, modify, and/or distribute this software for │
│ any purpose with or without fee is hereby granted, provided that the │
│ above copyright notice and this permission notice appear in all copies. │
│ │
│ THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL │
│ WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED │
│ WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE │
│ AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL │
│ DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR │
│ PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER │
│ TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR │
│ PERFORMANCE OF THIS SOFTWARE. │
╚─────────────────────────────────────────────────────────────────────────────*/
#include "libc/assert.h"
#include "libc/atomic.h"
#include "libc/calls/createfileflags.internal.h"
#include "libc/calls/internal.h"
#include "libc/calls/sig.internal.h"
#include "libc/calls/state.internal.h"
#include "libc/calls/struct/fd.internal.h"
#include "libc/calls/struct/iovec.h"
#include "libc/calls/struct/sigset.internal.h"
#include "libc/calls/syscall_support-nt.internal.h"
#include "libc/cosmo.h"
#include "libc/errno.h"
#include "libc/fmt/itoa.h"
#include "libc/intrin/atomic.h"
#include "libc/intrin/describeflags.internal.h"
#include "libc/intrin/dll.h"
#include "libc/intrin/nomultics.internal.h"
#include "libc/intrin/strace.internal.h"
#include "libc/intrin/weaken.h"
#include "libc/macros.internal.h"
#include "libc/mem/mem.h"
#include "libc/nt/console.h"
#include "libc/nt/createfile.h"
#include "libc/nt/enum/accessmask.h"
#include "libc/nt/enum/consolemodeflags.h"
#include "libc/nt/enum/creationdisposition.h"
#include "libc/nt/enum/filesharemode.h"
#include "libc/nt/enum/vk.h"
#include "libc/nt/enum/wait.h"
#include "libc/nt/errors.h"
#include "libc/nt/runtime.h"
#include "libc/nt/struct/inputrecord.h"
#include "libc/nt/synchronization.h"
#include "libc/str/str.h"
#include "libc/str/utf16.h"
#include "libc/sysv/consts/o.h"
#include "libc/sysv/consts/sicode.h"
#include "libc/sysv/consts/sig.h"
#include "libc/sysv/errfuns.h"
#include "libc/thread/posixthread.internal.h"
#include "libc/thread/thread.h"
#include "libc/thread/tls.h"
#ifdef __x86_64__
/**
* @fileoverview Cosmopolitan Standard Input
*
* This file implements pollable terminal i/o for Windows consoles. On
* Windows 10 the "virtual terminal processing" feature works great on
* output but their solution for input processing isn't good enough to
* support running Linux programs like Emacs. This polyfill fixes that
* and it most importantly ensures we can poll() standard input, which
* would otherwise have been impossible. We aren't using threads. What
* we do instead is have termios behaviors e.g. canonical mode editing
* happen on demand as a side effect of read/poll/ioctl activity.
*/
struct VirtualKey {
int vk;
int normal_str;
int shift_str;
int ctrl_str;
int shift_ctrl_str;
};
#define S(s) W(s "\0\0")
#define W(s) (s[3] << 24 | s[2] << 16 | s[1] << 8 | s[0])
static const struct VirtualKey kVirtualKey[] = {
{kNtVkUp, S("A"), S("1;2A"), S("1;5A"), S("1;6A")},
{kNtVkDown, S("B"), S("1;2B"), S("1;5B"), S("1;6B")},
{kNtVkRight, S("C"), S("1;2C"), S("1;5C"), S("1;6C")},
{kNtVkLeft, S("D"), S("1;2D"), S("1;5D"), S("1;6D")},
{kNtVkInsert, S("2~"), S("2;2~"), S("2;5~"), S("2;6~")},
{kNtVkDelete, S("3~"), S("3;2~"), S("3;5~"), S("3;6~")},
{kNtVkHome, S("H"), S("1;2H"), S("1;5H"), S("1;6H")},
{kNtVkEnd, S("F"), S("1;2F"), S("1;5F"), S("1;6F")},
{kNtVkPrior, S("5~"), S("5;2~"), S("5;5~"), S("5;6~")},
{kNtVkNext, S("6~"), S("6;2~"), S("6;5~"), S("6;6~")},
{kNtVkF1, -S("OP"), S("1;2P"), S("11^"), S("1;6P")},
{kNtVkF2, -S("OQ"), S("1;2Q"), S("12^"), S("1;6Q")},
{kNtVkF3, -S("OR"), S("1;2R"), S("13^"), S("1;6R")},
{kNtVkF4, -S("OS"), S("1;2S"), S("14^"), S("1;6S")},
{kNtVkF5, S("15~"), S("28~"), S("15^"), S("28^")},
{kNtVkF6, S("17~"), S("29~"), S("17^"), S("29^")},
{kNtVkF7, S("18~"), S("31~"), S("18^"), S("31^")},
{kNtVkF8, S("19~"), S("32~"), S("19^"), S("32^")},
{kNtVkF9, S("20~"), S("33~"), S("20^"), S("33^")},
{kNtVkF10, S("21~"), S("34~"), S("21^"), S("34^")},
{kNtVkF11, S("23~"), S("23$"), S("23^"), S("23@")},
{kNtVkF12, S("24~"), S("24$"), S("24^"), S("24@")},
{0},
};
// TODO: How can we configure `less` to not need this bloat?
static const struct VirtualKey kDecckm[] = {
{kNtVkUp, -S("OA"), -S("OA"), S("A"), S("A")},
{kNtVkDown, -S("OB"), -S("OB"), S("B"), S("B")},
{kNtVkRight, -S("OC"), -S("OC"), S("C"), S("C")},
{kNtVkLeft, -S("OD"), -S("OD"), S("D"), S("D")},
{kNtVkPrior, S("5~"), S("5;2~"), S("5;5~"), S("5;6~")},
{kNtVkNext, S("6~"), S("6;2~"), S("6;5~"), S("6;6~")},
{0},
};
#define KEYSTROKE_CONTAINER(e) DLL_CONTAINER(struct Keystroke, elem, e)
struct Keystroke {
char buf[23];
unsigned char buflen;
struct Dll elem;
};
struct Keystrokes {
atomic_uint once;
bool end_of_file;
bool ohno_decckm;
uint16_t utf16hs;
atomic_int_fast16_t used;
int64_t cin, cot;
struct Dll *list;
struct Dll *line;
struct Dll *free;
pthread_mutex_t lock;
const struct VirtualKey *vkt;
struct Keystroke pool[512];
};
static struct Keystrokes __keystroke;
textwindows void __keystroke_wipe(void) {
bzero(&__keystroke, sizeof(__keystroke));
}
static textwindows void OpenConsole(void) {
__keystroke.vkt = kVirtualKey;
__keystroke.cin = CreateFile(u"CONIN$", kNtGenericRead | kNtGenericWrite,
kNtFileShareRead, 0, kNtOpenExisting, 0, 0);
__keystroke.cot = CreateFile(u"CONOUT$", kNtGenericRead | kNtGenericWrite,
kNtFileShareWrite, 0, kNtOpenExisting, 0, 0);
}
static textwindows int AddSignal(int sig) {
atomic_fetch_or_explicit(&__get_tls()->tib_sigpending, 1ull << (sig - 1),
memory_order_relaxed);
return 0;
}
static textwindows void InitConsole(void) {
cosmo_once(&__keystroke.once, OpenConsole);
}
static textwindows void LockKeystrokes(void) {
pthread_mutex_lock(&__keystroke.lock);
}
static textwindows void UnlockKeystrokes(void) {
pthread_mutex_unlock(&__keystroke.lock);
}
textwindows int64_t GetConsoleInputHandle(void) {
InitConsole();
return __keystroke.cin;
}
textwindows int64_t GetConsoleOutputHandle(void) {
InitConsole();
return __keystroke.cot;
}
static textwindows bool IsMouseModeCommand(int x) {
return x == 1000 || // SET_VT200_MOUSE
x == 1002 || // SET_BTN_EVENT_MOUSE
x == 1006 || // SET_SGR_EXT_MODE_MOUSE
x == 1015; // SET_URXVT_EXT_MODE_MOUSE
}
static textwindows int GetVirtualKey(uint16_t vk, bool shift, bool ctrl) {
for (int i = 0; __keystroke.vkt[i].vk; ++i) {
if (__keystroke.vkt[i].vk == vk) {
if (shift && ctrl) {
return __keystroke.vkt[i].shift_ctrl_str;
} else if (shift) {
return __keystroke.vkt[i].shift_str;
} else if (ctrl) {
return __keystroke.vkt[i].ctrl_str;
} else {
return __keystroke.vkt[i].normal_str;
}
}
}
return 0;
}
static textwindows int ProcessKeyEvent(const struct NtInputRecord *r, char *p) {
uint32_t c = r->Event.KeyEvent.uChar.UnicodeChar;
uint16_t vk = r->Event.KeyEvent.wVirtualKeyCode;
uint16_t cks = r->Event.KeyEvent.dwControlKeyState;
// ignore keyup events
if (!r->Event.KeyEvent.bKeyDown && (!c || vk != kNtVkMenu)) {
return 0;
}
#if 0
// this code is useful for troubleshooting why keys don't work
kprintf("bKeyDown=%hhhd wVirtualKeyCode=%s wVirtualScanCode=%s "
"UnicodeChar=%#x[%#lc] dwControlKeyState=%s\n",
r->Event.KeyEvent.bKeyDown,
DescribeVirtualKeyCode(r->Event.KeyEvent.wVirtualKeyCode),
DescribeVirtualKeyCode(r->Event.KeyEvent.wVirtualScanCode),
r->Event.KeyEvent.uChar.UnicodeChar,
r->Event.KeyEvent.uChar.UnicodeChar,
DescribeControlKeyState(r->Event.KeyEvent.dwControlKeyState));
#endif
// turn arrow/function keys into vt100/ansi/xterm byte sequences
int n = 0;
int v = GetVirtualKey(vk, !!(cks & kNtShiftPressed),
!!(cks & (kNtLeftCtrlPressed | kNtRightCtrlPressed)));
if (v) {
p[n++] = 033;
if (cks & (kNtLeftAltPressed | kNtRightAltPressed)) {
p[n++] = 033;
}
if (v > 0) {
p[n++] = '[';
} else {
v = -v;
}
do p[n++] = v;
while ((v >>= 8));
return n;
}
// ^/ (crtl+slash) maps to ^_ (ctrl-hyphen) on linux
if (vk == kNtVkOem_2 && (cks & (kNtLeftCtrlPressed | kNtRightCtrlPressed))) {
p[n++] = 037;
return n;
}
// handle cases where win32 doesn't provide character
if (!c) {
if (vk == '2' && (cks & (kNtLeftCtrlPressed | kNtRightCtrlPressed))) {
c = 0; // ctrl-2 → "\000"
} else if (isascii(vk) && isdigit(vk) &&
(cks & (kNtLeftCtrlPressed | kNtRightCtrlPressed))) {
c = 030 + (vk - '0'); // e.g. ctrl-3 → "\033"
} else if (isascii(vk) && isgraph(vk) &&
(cks & (kNtLeftCtrlPressed | kNtRightCtrlPressed))) {
c = vk ^ 0100; // e.g. ctrl-alt-b → "\033\002"
} else {
return 0;
}
}
// convert utf-16 to utf-32
if (IsHighSurrogate(c)) {
__keystroke.utf16hs = c;
return 0;
}
if (IsLowSurrogate(c)) {
c = MergeUtf16(__keystroke.utf16hs, c);
}
// enter sends \r with raw terminals
// make it a multics newline instead
if (c == '\r' && !(__ttyconf.magic & kTtyNoCr2Nl)) {
c = '\n';
}
// ctrl-space (^@) is literally zero
if (c == ' ' && (cks & (kNtLeftCtrlPressed | kNtRightCtrlPressed))) {
c = '\0';
}
// make backspace (^?) distinguishable from ctrl-h (^H)
if (c == kNtVkBack && !(cks & (kNtLeftCtrlPressed | kNtRightCtrlPressed))) {
c = 0177;
}
// handle ctrl-\ and ctrl-c
// note we define _POSIX_VDISABLE as zero
// tcsetattr() lets anyone reconfigure these keybindings
if (c && !(__ttyconf.magic & kTtyNoIsigs)) {
if (c == __ttyconf.vintr) {
return AddSignal(SIGINT);
} else if (c == __ttyconf.vquit) {
return AddSignal(SIGQUIT);
}
}
// handle ctrl-d which generates end-of-file, unless pending line data
// is present, in which case we flush that without the newline instead
if (c && c == __ttyconf.veof && !(__ttyconf.magic & kTtyUncanon)) {
if (dll_is_empty(__keystroke.line)) {
__keystroke.end_of_file = true;
} else {
dll_make_last(&__keystroke.list, __keystroke.line);
__keystroke.line = 0;
}
return 0;
}
// insert esc prefix when alt is held
// for example "h" becomes "\033h" (alt-h)
// if up arrow is "\033[A" then alt-up is "\033\033[A"
if ((cks & (kNtLeftAltPressed | kNtRightAltPressed)) &&
r->Event.KeyEvent.bKeyDown) {
p[n++] = 033;
}
// finally apply thompson-pike varint encoding
uint64_t w = tpenc(c);
do p[n++] = w;
while ((w >>= 8));
return n;
}
// To use the tty mouse events feature:
// - write(1, "\e[?1000;1002;1015;1006h") to enable
// - write(1, "\e[?1000;1002;1015;1006l") to disable
// See o//examples/ttyinfo.com and o//tool/viz/life.com
static textwindows int ProcessMouseEvent(const struct NtInputRecord *r,
char *b) {
char *p = b;
unsigned char e = 0;
uint32_t currentbs = __ttyconf.mousebs;
uint32_t ev = r->Event.MouseEvent.dwEventFlags;
uint32_t bs = r->Event.MouseEvent.dwButtonState;
ev &= kNtMouseMoved | kNtMouseWheeled;
bs &= kNtFromLeft1stButtonPressed | kNtRightmostButtonPressed;
if (ev & kNtMouseWheeled) {
// scroll wheel (unnatural mode)
bool isup = ((int)r->Event.MouseEvent.dwButtonState >> 16) > 0;
if (__ttyconf.magic & kTtyXtMouse) {
if (r->Event.MouseEvent.dwControlKeyState &
(kNtLeftCtrlPressed | kNtRightCtrlPressed)) {
e = isup ? 80 : 81;
} else {
e = isup ? 64 : 65;
}
goto OutputXtermMouseEvent;
} else if (!(r->Event.MouseEvent.dwControlKeyState &
(kNtShiftPressed | kNtLeftCtrlPressed | kNtRightCtrlPressed |
kNtLeftAltPressed | kNtRightAltPressed))) {
// we disable mouse highlighting when the tty is put in raw mode
// to mouse wheel events with widely understood vt100 arrow keys
*p++ = 033;
*p++ = !__keystroke.ohno_decckm ? '[' : 'O';
if (isup) {
*p++ = 'A';
} else {
*p++ = 'B';
}
}
} else if ((bs || currentbs) && (__ttyconf.magic & kTtyXtMouse)) {
if (bs && (ev & kNtMouseMoved) && currentbs) {
e |= 32; // dragging
}
if ((bs | currentbs) & kNtRightmostButtonPressed) {
e |= 2; // right
}
OutputXtermMouseEvent:
*p++ = 033;
*p++ = '[';
*p++ = '<';
p = FormatInt32(p, e);
*p++ = ';';
p = FormatInt32(p, (r->Event.MouseEvent.dwMousePosition.X + 1) & 0x7fff);
*p++ = ';';
p = FormatInt32(p, (r->Event.MouseEvent.dwMousePosition.Y + 1) & 0x7fff);
if (!bs && currentbs) {
*p++ = 'm'; // up
} else {
*p++ = 'M'; // down
}
__ttyconf.mousebs = bs;
}
return p - b;
}
static textwindows int ConvertConsoleInputToAnsi(const struct NtInputRecord *r,
char p[hasatleast 23]) {
switch (r->EventType) {
case kNtKeyEvent:
return ProcessKeyEvent(r, p);
case kNtMouseEvent:
return ProcessMouseEvent(r, p);
case kNtWindowBufferSizeEvent:
return AddSignal(SIGWINCH);
default:
return 0;
}
}
static textwindows struct Keystroke *NewKeystroke(void) {
struct Dll *e;
struct Keystroke *k = 0;
int i, n = ARRAYLEN(__keystroke.pool);
if (atomic_load_explicit(&__keystroke.used, memory_order_acquire) < n &&
(i = atomic_fetch_add(&__keystroke.used, 1)) < n) {
k = __keystroke.pool + i;
} else {
if ((e = dll_first(__keystroke.free))) {
k = KEYSTROKE_CONTAINER(e);
dll_remove(&__keystroke.free, &k->elem);
}
if (!k) {
if (_weaken(malloc)) {
k = _weaken(malloc)(sizeof(struct Keystroke));
} else {
enomem();
return 0;
}
}
}
if (k) {
bzero(k, sizeof(*k));
dll_init(&k->elem);
}
return k;
}
static textwindows void WriteTty(const char *p, size_t n) {
WriteFile(__keystroke.cot, p, n, 0, 0);
}
static textwindows bool IsCtl(int c) {
return isascii(c) && iscntrl(c) && c != '\n' && c != '\t';
}
static textwindows void WriteCtl(const char *p, size_t n) {
size_t i;
for (i = 0; i < n; ++i) {
if (IsCtl(p[i])) {
char ctl[2];
ctl[0] = '^';
ctl[1] = p[i] ^ 0100;
WriteTty(ctl, 2);
} else {
WriteTty(p + i, 1);
}
}
}
static textwindows void EchoTty(const char *p, size_t n) {
if (__ttyconf.magic & kTtyEchoRaw) {
WriteTty(p, n);
} else {
WriteCtl(p, n);
}
}
static textwindows void EraseCharacter(void) {
WriteTty("\b \b", 3);
}
static textwindows bool EraseKeystroke(void) {
struct Dll *e;
if ((e = dll_last(__keystroke.line))) {
struct Keystroke *k = KEYSTROKE_CONTAINER(e);
dll_remove(&__keystroke.line, e);
dll_make_first(&__keystroke.free, e);
for (int i = k->buflen; i--;) {
if ((k->buf[i] & 0300) == 0200) continue; // utf-8 cont
EraseCharacter();
if (!(__ttyconf.magic & kTtyEchoRaw) && IsCtl(k->buf[i])) {
EraseCharacter();
}
}
return true;
} else {
return false;
}
}
static textwindows void IngestConsoleInputRecord(struct NtInputRecord *r) {
// convert win32 console event into ansi
int len;
char buf[23];
if (!(len = ConvertConsoleInputToAnsi(r, buf))) {
return;
}
// handle backspace in canonical mode
if (len == 1 && buf[0] && //
(buf[0] & 255) == __ttyconf.verase && //
!(__ttyconf.magic & kTtyUncanon)) {
EraseKeystroke();
return;
}
// handle kill in canonical mode
if (len == 1 && buf[0] && //
(buf[0] & 255) == __ttyconf.vkill && //
!(__ttyconf.magic & kTtyUncanon)) {
while (EraseKeystroke()) {
}
return;
}
// allocate object to hold keystroke
struct Keystroke *k;
if (!(k = NewKeystroke())) {
STRACE("out of keystroke memory");
return;
}
memcpy(k->buf, buf, sizeof(k->buf));
k->buflen = len;
// echo input if it was successfully recorded
// assuming the win32 console isn't doing it already
if (!(__ttyconf.magic & kTtySilence)) {
EchoTty(buf, len);
}
// save keystroke to appropriate list
if (__ttyconf.magic & kTtyUncanon) {
dll_make_last(&__keystroke.list, &k->elem);
} else {
dll_make_last(&__keystroke.line, &k->elem);
// handle enter in canonical mode
if (len == 1 && buf[0] &&
((buf[0] & 255) == '\n' || //
(buf[0] & 255) == __ttyconf.veol || //
(buf[0] & 255) == __ttyconf.veol2)) {
dll_make_last(&__keystroke.list, __keystroke.line);
__keystroke.line = 0;
}
}
}
static textwindows void IngestConsoleInput(void) {
uint32_t i, n;
struct NtInputRecord records[16];
for (;;) {
if (__keystroke.end_of_file) return;
if (!GetNumberOfConsoleInputEvents(__keystroke.cin, &n)) {
goto UnexpectedEof;
}
if (!n) return;
n = MIN(ARRAYLEN(records), n);
if (!ReadConsoleInput(__keystroke.cin, records, n, &n)) {
goto UnexpectedEof;
}
for (i = 0; i < n && !__keystroke.end_of_file; ++i) {
IngestConsoleInputRecord(records + i);
}
}
UnexpectedEof:
STRACE("console read error %d", GetLastError());
__keystroke.end_of_file = true;
}
// Discards all unread stdin bytes.
textwindows int FlushConsoleInputBytes(void) {
int rc;
BLOCK_SIGNALS;
InitConsole();
LockKeystrokes();
FlushConsoleInputBuffer(__keystroke.cin);
dll_make_first(&__keystroke.free, __keystroke.list);
__keystroke.list = 0;
dll_make_first(&__keystroke.free, __keystroke.line);
__keystroke.line = 0;
rc = 0;
UnlockKeystrokes();
ALLOW_SIGNALS;
return rc;
}
// Returns number of stdin bytes that may be read without blocking.
textwindows int CountConsoleInputBytes(void) {
struct Dll *e;
int count = 0;
BLOCK_SIGNALS;
InitConsole();
LockKeystrokes();
IngestConsoleInput();
for (e = dll_first(__keystroke.list); e; e = dll_next(__keystroke.list, e)) {
count += KEYSTROKE_CONTAINER(e)->buflen;
}
if (!count && __keystroke.end_of_file) {
count = -1;
}
UnlockKeystrokes();
ALLOW_SIGNALS;
return count;
}
// Intercept ANSI TTY commands that enable features.
textwindows void InterceptTerminalCommands(const char *data, size_t size) {
int i;
unsigned x;
bool ismouse;
uint32_t cm, cm2;
enum { ASC, ESC, CSI, CMD } t;
GetConsoleMode(GetConsoleInputHandle(), &cm), cm2 = cm;
for (ismouse = false, x = i = t = 0; i < size; ++i) {
switch (t) {
case ASC:
if (data[i] == 033) {
t = ESC;
}
break;
case ESC:
if (data[i] == '[') {
t = CSI;
} else {
t = ASC;
}
break;
case CSI:
if (data[i] == '?') {
t = CMD;
x = 0;
} else {
t = ASC;
}
break;
case CMD:
if ('0' <= data[i] && data[i] <= '9') {
x *= 10;
x += data[i] - '0';
} else if (data[i] == ';') {
ismouse |= IsMouseModeCommand(x);
x = 0;
} else if (data[i] == 'h') {
if (x == 1) {
__keystroke.vkt = kDecckm; // \e[?1h decckm on
__keystroke.ohno_decckm = true;
} else if ((ismouse |= IsMouseModeCommand(x))) {
__ttyconf.magic |= kTtyXtMouse;
cm2 |= kNtEnableMouseInput;
cm2 &= ~kNtEnableQuickEditMode; // take mouse
}
t = ASC;
} else if (data[i] == 'l') {
if (x == 1) {
__keystroke.vkt = kVirtualKey; // \e[?1l decckm off
__keystroke.ohno_decckm = false;
} else if ((ismouse |= IsMouseModeCommand(x))) {
__ttyconf.magic &= ~kTtyXtMouse;
cm2 |= kNtEnableQuickEditMode; // release mouse
}
t = ASC;
}
break;
default:
__builtin_unreachable();
}
}
if (cm2 != cm) {
SetConsoleMode(GetConsoleInputHandle(), cm2);
}
}
static textwindows bool DigestConsoleInput(char *data, size_t size, int *rc) {
// handle eof once available input is consumed
if (dll_is_empty(__keystroke.list) && __keystroke.end_of_file) {
*rc = 0;
return true;
}
// copy keystroke(s) into user buffer
int toto = 0;
struct Dll *e;
while (size && (e = dll_first(__keystroke.list))) {
struct Keystroke *k = KEYSTROKE_CONTAINER(e);
uint32_t got = MIN(size, k->buflen);
uint32_t remain = k->buflen - got;
if (got) {
memcpy(data, k->buf, got);
data += got;
size -= got;
toto += got;
}
if (remain) {
memmove(k->buf, k->buf + got, remain);
} else {
dll_remove(&__keystroke.list, e);
dll_make_first(&__keystroke.free, e);
}
k->buflen = remain;
if ((__ttyconf.magic & kTtyUncanon) && toto >= __ttyconf.vmin) {
break;
}
}
// return result
if (toto) {
*rc = toto;
return true;
} else {
return false;
}
}
static textwindows int WaitForConsole(struct Fd *f, sigset_t waitmask) {
int sig;
int64_t sem;
uint32_t wi, ms = -1;
int handler_was_called;
struct PosixThread *pt;
if (!__ttyconf.vmin) {
if (!__ttyconf.vtime) {
return 0; // non-blocking w/o raising eagain
} else {
ms = __ttyconf.vtime * 100;
}
}
if (f->flags & _O_NONBLOCK) {
return eagain(); // standard unix non-blocking
}
if (_check_cancel() == -1) return -1;
if ((sig = __sig_get(waitmask))) {
handler_was_called = __sig_relay(sig, SI_KERNEL, waitmask);
if (_check_cancel() == -1) return -1;
if (handler_was_called != 1) return -2;
return eintr();
}
pt = _pthread_self();
pt->pt_semaphore = sem = CreateSemaphore(0, 0, 1, 0);
pthread_cleanup_push((void *)CloseHandle, (void *)sem);
pt->pt_blkmask = waitmask;
atomic_store_explicit(&pt->pt_blocker, PT_BLOCKER_SEM, memory_order_release);
wi = WaitForMultipleObjects(2, (int64_t[2]){__keystroke.cin, sem}, 0, ms);
atomic_store_explicit(&pt->pt_blocker, 0, memory_order_release);
pthread_cleanup_pop(true);
if (wi == kNtWaitTimeout) return 0; // vtime elapsed
if (wi == 0) return -2; // console data
if (wi != 1) return __winerr(); // wait failed
if (!(sig = __sig_get(waitmask))) return eintr();
handler_was_called = __sig_relay(sig, SI_KERNEL, waitmask);
if (_check_cancel() == -1) return -1;
if (handler_was_called != 1) return -2;
return eintr();
}
static textwindows ssize_t ReadFromConsole(struct Fd *f, void *data,
size_t size, sigset_t waitmask) {
int rc;
InitConsole();
do {
LockKeystrokes();
IngestConsoleInput();
bool done = DigestConsoleInput(data, size, &rc);
UnlockKeystrokes();
if (done) return rc;
} while ((rc = WaitForConsole(f, waitmask)) == -2);
return rc;
}
textwindows ssize_t sys_read_nt_impl(int fd, void *data, size_t size,
int64_t offset, sigset_t waitmask) {
// switch to terminal polyfill if reading from win32 console
struct Fd *f = g_fds.p + fd;
if (f->kind == kFdDevNull) {
return 0;
}
if (f->kind == kFdConsole) {
return ReadFromConsole(f, data, size, waitmask);
}
// perform heavy lifting
ssize_t rc;
rc = sys_readwrite_nt(fd, data, size, offset, f->handle, waitmask, ReadFile);
if (rc != -2) return rc;
// mops up win32 errors
switch (GetLastError()) {
case kNtErrorBrokenPipe: // broken pipe
case kNtErrorNoData: // closing named pipe
case kNtErrorHandleEof: // pread read past EOF
return 0; //
case kNtErrorAccessDenied: // read doesn't return EACCESS
return ebadf(); //
default:
return __winerr();
}
}
static textwindows ssize_t sys_read_nt2(int fd, const struct iovec *iov,
size_t iovlen, int64_t opt_offset,
sigset_t waitmask) {
ssize_t rc;
size_t i, total;
if (opt_offset < -1) return einval();
while (iovlen && !iov[0].iov_len) iov++, iovlen--;
if (iovlen) {
for (total = i = 0; i < iovlen; ++i) {
if (!iov[i].iov_len) continue;
rc = sys_read_nt_impl(fd, iov[i].iov_base, iov[i].iov_len, opt_offset,
waitmask);
if (rc == -1) {
if (total && errno != ECANCELED) {
return total;
} else {
return -1;
}
}
total += rc;
if (opt_offset != -1) opt_offset += rc;
if (rc < iov[i].iov_len) break;
}
return total;
} else {
return sys_read_nt_impl(fd, NULL, 0, opt_offset, waitmask);
}
}
textwindows ssize_t sys_read_nt(int fd, const struct iovec *iov, size_t iovlen,
int64_t opt_offset) {
ssize_t rc;
sigset_t m = __sig_block();
rc = sys_read_nt2(fd, iov, iovlen, opt_offset, m);
__sig_unblock(m);
return rc;
}
#endif /* __x86_64__ */