/* syscalls.c --- implement system calls for the RX simulator. Copyright (C) 2005-2018 Free Software Foundation, Inc. Contributed by Red Hat, Inc. This file is part of the GNU simulators. 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 "config.h" #include #include #include #include #include #include "gdb/callback.h" #include "cpu.h" #include "mem.h" #include "syscalls.h" #include "syscall.h" /* The current syscall callbacks we're using. */ static struct host_callback_struct *callbacks; void set_callbacks (struct host_callback_struct *cb) { callbacks = cb; } struct host_callback_struct * get_callbacks (void) { return callbacks; } /* Arguments 1..4 are in R1..R4, remainder on stack. Return value in R1..R4 as needed. structs bigger than 16 bytes: pointer pushed on stack last We only support arguments that fit in general registers. The system call number is in R5. We expect ssycalls to look like this in libgloss: _exit: mov #SYS_exit, r5 int #255 rts */ int argp, stackp; static int arg () { int rv = 0; argp++; if (argp < 4) return get_reg (argp); rv = mem_get_si (get_reg (sp) + stackp); stackp += 4; return rv; } static void read_target (char *buffer, int address, int count, int asciiz) { char byte; while (count > 0) { byte = mem_get_qi (address++); *buffer++ = byte; if (asciiz && (byte == 0)) return; count--; } } static void write_target (char *buffer, int address, int count, int asciiz) { char byte; while (count > 0) { byte = *buffer++; mem_put_qi (address++, byte); if (asciiz && (byte == 0)) return; count--; } } #define PTRSZ (A16 ? 2 : 3) static char *callnames[] = { "SYS_zero", "SYS_exit", "SYS_open", "SYS_close", "SYS_read", "SYS_write", "SYS_lseek", "SYS_unlink", "SYS_getpid", "SYS_kill", "SYS_fstat", "SYS_sbrk", "SYS_argvlen", "SYS_argv", "SYS_chdir", "SYS_stat", "SYS_chmod", "SYS_utime", "SYS_time", "SYS_gettimeofday", "SYS_times", "SYS_link" }; int rx_syscall (int id) { static char buf[256]; int rv; argp = 0; stackp = 4; if (trace) printf ("\033[31m/* SYSCALL(%d) = %s */\033[0m\n", id, id <= SYS_link ? callnames[id] : "unknown"); switch (id) { case SYS_exit: { int ec = arg (); if (verbose) printf ("[exit %d]\n", ec); return RX_MAKE_EXITED (ec); } break; case SYS_open: { int path = arg (); /* The open function is defined as taking a variable number of arguments because the third parameter to it is optional: open (const char * filename, int flags, ...); Hence the oflags and cflags arguments will be on the stack and we need to skip the (empty) argument registers r3 and r4. */ argp = 4; int oflags = arg (); int cflags = arg (); read_target (buf, path, 256, 1); if (trace) printf ("open(\"%s\",0x%x,%#o) = ", buf, oflags, cflags); if (callbacks) /* The callback vector ignores CFLAGS. */ rv = callbacks->open (callbacks, buf, oflags); else { int h_oflags = 0; if (oflags & 0x0001) h_oflags |= O_WRONLY; if (oflags & 0x0002) h_oflags |= O_RDWR; if (oflags & 0x0200) h_oflags |= O_CREAT; if (oflags & 0x0008) h_oflags |= O_APPEND; if (oflags & 0x0400) h_oflags |= O_TRUNC; rv = open (buf, h_oflags, cflags); } if (trace) printf ("%d\n", rv); put_reg (1, rv); } break; case SYS_close: { int fd = arg (); if (callbacks) rv = callbacks->close (callbacks, fd); else if (fd > 2) rv = close (fd); else rv = 0; if (trace) printf ("close(%d) = %d\n", fd, rv); put_reg (1, rv); } break; case SYS_read: { int fd = arg (); int addr = arg (); int count = arg (); if (count > sizeof (buf)) count = sizeof (buf); if (callbacks) rv = callbacks->read (callbacks, fd, buf, count); else rv = read (fd, buf, count); if (trace) printf ("read(%d,%d) = %d\n", fd, count, rv); if (rv > 0) write_target (buf, addr, rv, 0); put_reg (1, rv); } break; case SYS_write: { int fd = arg (); int addr = arg (); int count = arg (); if (count > sizeof (buf)) count = sizeof (buf); if (trace) printf ("write(%d,0x%x,%d)\n", fd, addr, count); read_target (buf, addr, count, 0); if (trace) fflush (stdout); if (callbacks) rv = callbacks->write (callbacks, fd, buf, count); else rv = write (fd, buf, count); if (trace) printf ("write(%d,%d) = %d\n", fd, count, rv); put_reg (1, rv); } break; case SYS_getpid: put_reg (1, 42); break; case SYS_gettimeofday: { int tvaddr = arg (); struct timeval tv; rv = gettimeofday (&tv, 0); if (trace) printf ("gettimeofday: %ld sec %ld usec to 0x%x\n", tv.tv_sec, tv.tv_usec, tvaddr); mem_put_si (tvaddr, tv.tv_sec); mem_put_si (tvaddr + 4, tv.tv_usec); put_reg (1, rv); } break; case SYS_kill: { int pid = arg (); int sig = arg (); if (pid == 42) { if (verbose) printf ("[signal %d]\n", sig); return RX_MAKE_STOPPED (sig); } } break; case 11: { int heaptop_arg = arg (); if (trace) printf ("sbrk: heap top set to %x\n", heaptop_arg); heaptop = heaptop_arg; if (heapbottom == 0) heapbottom = heaptop_arg; } break; case 255: { int addr = arg (); mem_put_si (addr, rx_cycles + mem_usage_cycles()); } break; } return RX_MAKE_STEPPED (); }