/* * Copyright (c) 2018 ARM Limited * All rights reserved * * The license below extends only to copyright in the software and shall * not be construed as granting a license to any other intellectual * property including but not limited to intellectual property relating * to a hardware implementation of the functionality of the software * licensed hereunder. You may use the software subject to the license * terms below provided that you ensure that this notice is replicated * unmodified and in its entirety in all distributions of the software, * modified or unmodified, in source code or in binary form. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer; * redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution; * neither the name of the copyright holders nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * Authors: Andreas Sandberg */ #include "arch/arm/semihosting.hh" #include #include "arch/arm/utility.hh" #include "base/logging.hh" #include "base/time.hh" #include "debug/Semihosting.hh" #include "dev/serial/serial.hh" #include "mem/physical.hh" #include "mem/port_proxy.hh" #include "params/ArmSemihosting.hh" #include "sim/byteswap.hh" #include "sim/sim_exit.hh" #include "sim/system.hh" const std::map ArmSemihosting::calls{ { 0x01, { "SYS_OPEN", &ArmSemihosting::callOpen, 3, 3 } }, { 0x02, { "SYS_CLOSE", &ArmSemihosting::callClose, 1, 1 } }, // Write(C|0) are special since we want to read the character // manually. We therefore declare them as having 0 params. { 0x03, { "SYS_WRITEC", &ArmSemihosting::callWriteC, 0, 0 } }, { 0x04, { "SYS_WRITE0", &ArmSemihosting::callWrite0, 1, 1 } }, { 0x05, { "SYS_WRITE", &ArmSemihosting::callWrite, 3, 3 } }, { 0x06, { "SYS_READ", &ArmSemihosting::callRead, 3, 3 } }, { 0x07, { "SYS_READC", &ArmSemihosting::callReadC, 0, 0 } }, { 0x08, { "SYS_ISERROR", &ArmSemihosting::callIsError, 1, 1 } }, { 0x09, { "SYS_ISTTY", &ArmSemihosting::callIsTTY, 1, 1 } }, { 0x0A, { "SYS_SEEK", &ArmSemihosting::callSeek, 2, 2 } }, { 0x0C, { "SYS_FLEN", &ArmSemihosting::callFLen, 1, 1 } }, { 0x0D, { "SYS_TMPNAM", &ArmSemihosting::callTmpNam, 3, 3 } }, { 0x0E, { "SYS_REMOVE", &ArmSemihosting::callRemove, 2, 2} }, { 0x0F, { "SYS_RENAME", &ArmSemihosting::callRename, 4, 4} }, { 0x10, { "SYS_CLOCK", &ArmSemihosting::callClock, 0, 0} }, { 0x11, { "SYS_TIME", &ArmSemihosting::callTime, 0, 0} }, { 0x12, { "SYS_SYSTEM", &ArmSemihosting::callSystem, 2, 2} }, { 0x13, { "SYS_ERRNO", &ArmSemihosting::callErrno, 0, 0 } }, { 0x15, { "SYS_GET_CMDLINE", &ArmSemihosting::callGetCmdLine, 2, 2} }, { 0x16, { "SYS_HEAPINFO", &ArmSemihosting::callHeapInfo, 1, 1} }, // Exit is special and requires custom handling in aarch32. { 0x18, { "SYS_EXIT", &ArmSemihosting::callExit, 0, 2 } }, { 0x20, { "SYS_EXIT_EXTENDED", &ArmSemihosting::callExitExtended, 2, 2 } }, { 0x30, { "SYS_ELAPSED", &ArmSemihosting::callElapsed, 0, 0 } }, { 0x31, { "SYS_TICKFREQ", &ArmSemihosting::callTickFreq, 0, 0 } }, }; const std::vector ArmSemihosting::fmodes{ "r", "rb", "r+", "r+b", "w", "wb", "w+", "w+b", "a", "ab", "a+", "a+b", }; const std::map ArmSemihosting::exitCodes{ { 0x20000, "semi:ADP_Stopped_BranchThroughZero" }, { 0x20001, "semi:ADP_Stopped_UndefinedInstr" }, { 0x20002, "semi:ADP_Stopped_SoftwareInterrupt" }, { 0x20003, "semi:ADP_Stopped_PrefetchAbort" }, { 0x20004, "semi:ADP_Stopped_DataAbort" }, { 0x20005, "semi:ADP_Stopped_AddressException" }, { 0x20006, "semi:ADP_Stopped_IRQ" }, { 0x20007, "semi:ADP_Stopped_FIQ" }, { 0x20020, "semi:ADP_Stopped_BreakPoint" }, { 0x20021, "semi:ADP_Stopped_WatchPoint" }, { 0x20022, "semi:ADP_Stopped_StepComplete" }, { 0x20023, "semi:ADP_Stopped_RunTimeErrorUnknown" }, { 0x20024, "semi:ADP_Stopped_InternalError" }, { 0x20025, "semi:ADP_Stopped_UserInterruption" }, { 0x20026, "semi:ADP_Stopped_ApplicationExit" }, { 0x20027, "semi:ADP_Stopped_StackOverflow" }, { 0x20028, "semi:ADP_Stopped_DivisionByZero" }, { 0x20029, "semi:ADP_Stopped_DivisionByZero" }, }; const std::vector ArmSemihosting::features{ 0x53, 0x48, 0x46, 0x42, // Magic 0x3, // EXT_EXIT_EXTENDED, EXT_STDOUT_STDERR }; const std::map ArmSemihosting::stdioMap{ {"cin", ::stdin}, {"stdin", ::stdin}, {"cout", ::stdout}, {"stdout", ::stdout}, {"cerr", ::stderr}, {"stderr", ::stderr}, }; ArmSemihosting::ArmSemihosting(const ArmSemihostingParams *p) : SimObject(p), cmdLine(p->cmd_line), memReserve(p->mem_reserve), stackSize(p->stack_size), timeBase([p]{ struct tm t = p->time; return mkutctime(&t); }()), tickShift(calcTickShift()), semiErrno(0), stdin(getSTDIO("stdin", p->stdin, "r")), stdout(getSTDIO("stdout", p->stdout, "w")), stderr(p->stderr == p->stdout ? stdout : getSTDIO("stderr", p->stderr, "w")) { // Create an empty place-holder file for position 0 as semi-hosting // calls typically expect non-zero file handles. files.push_back(nullptr); if (tickShift > 0) inform("Semihosting: Shifting elapsed ticks by %i bits.", tickShift); } uint64_t ArmSemihosting::call64(ThreadContext *tc, uint32_t op, uint64_t param) { const SemiCall *call = getCall(op, true); if (!call) { warn("Unknown aarch64 semihosting call: op = 0x%x, param = 0x%x", op, param); return (uint64_t)-1; } else if (!call->implemented64()) { warn("Unimplemented aarch64 semihosting call: " "%s (op = 0x%x, param = 0x%x)", call->name, op, param); return (uint64_t)-1; } std::vector argv(call->argc64 + 1); PortProxy &proxy = physProxy(tc); ByteOrder endian = ArmISA::byteOrder(tc); DPRINTF(Semihosting, "Semihosting call64: %s(0x%x)\n", call->name, param); argv[0] = param; for (int i = 0; i < call->argc64; ++i) { argv[i + 1] = proxy.read(param + i * 8, endian); DPRINTF(Semihosting, "\t: 0x%x\n", argv[i + 1]); } auto ret_errno = (this->*call->call)(tc, true, argv); semiErrno = ret_errno.second; DPRINTF(Semihosting, "\t ->: 0x%x, %i\n", ret_errno.first, ret_errno.second); return ret_errno.first; } uint32_t ArmSemihosting::call32(ThreadContext *tc, uint32_t op, uint32_t param) { const SemiCall *call = getCall(op, false); if (!call) { warn("Unknown aarch32 semihosting call: op = 0x%x, param = 0x%x", op, param); return (uint32_t)-1; } else if (!call->implemented32()) { warn("Unimplemented aarch32 semihosting call: " "%s (op = 0x%x, param = 0x%x)", call->name, op, param); return (uint32_t)-1; } std::vector argv(call->argc32 + 1); PortProxy &proxy = physProxy(tc); ByteOrder endian = ArmISA::byteOrder(tc); DPRINTF(Semihosting, "Semihosting call32: %s(0x%x)\n", call->name, param); argv[0] = param; for (int i = 0; i < call->argc32; ++i) { argv[i + 1] = proxy.read(param + i * 4, endian); DPRINTF(Semihosting, "\t: 0x%x\n", argv[i + 1]); } auto ret_errno = (this->*call->call)(tc, false, argv); semiErrno = ret_errno.second; DPRINTF(Semihosting, "\t ->: 0x%x, %i\n", ret_errno.first, ret_errno.second); return ret_errno.first; } void ArmSemihosting::serialize(CheckpointOut &cp) const { SERIALIZE_SCALAR(semiErrno); paramOut(cp, "num_files", files.size()); for (int i = 0; i < files.size(); i++) { // File closed? if (!files[i]) continue; files[i]->serializeSection(cp, csprintf("file%i", i)); } } void ArmSemihosting::unserialize(CheckpointIn &cp) { UNSERIALIZE_SCALAR(semiErrno); size_t num_files; paramIn(cp, "num_files", num_files); files.resize(num_files); for (int i = 0; i < num_files; i++) files[i] = FileBase::create(*this, cp, csprintf("file%i", i)); } PortProxy & ArmSemihosting::physProxy(ThreadContext *tc) { if (ArmISA::inSecureState(tc)) { if (!physProxyS) { System *sys = tc->getSystemPtr(); physProxyS.reset(new SecurePortProxy( sys->getSystemPort(), sys->cacheLineSize())); } return *physProxyS; } else { return tc->getPhysProxy(); } } std::string ArmSemihosting::readString(ThreadContext *tc, Addr ptr, size_t len) { std::vector buf(len + 1); buf[len] = '\0'; physProxy(tc).readBlob(ptr, (uint8_t *)buf.data(), len); return std::string(buf.data()); } ArmSemihosting::RetErrno ArmSemihosting::callOpen(ThreadContext *tc, bool aarch64, std::vector &argv) { const Addr name_base = argv[1]; const char *mode = argv[2] < fmodes.size() ? fmodes[argv[2]] : nullptr; const Addr name_size = argv[3]; DPRINTF(Semihosting, "Semihosting SYS_OPEN(0x%x, %i[%s], %i)\n", name_base, argv[2], mode ? mode : "-", name_size); if (!mode || !name_base) return retError(EINVAL); std::string fname = readString(tc, name_base, name_size); std::unique_ptr file = FileBase::create(*this, fname, mode); int64_t ret = file->open(); DPRINTF(Semihosting, "Semihosting SYS_OPEN(\"%s\", %i[%s]): %i\n", fname, argv[2], mode, ret); if (ret < 0) { return retError(-ret); } else { files.push_back(std::move(file)); return retOK(files.size() - 1); } } ArmSemihosting::RetErrno ArmSemihosting::callClose(ThreadContext *tc, bool aarch64, std::vector &argv) { if (argv[1] > files.size()) { DPRINTF(Semihosting, "Semihosting SYS_CLOSE(%i): Illegal file\n"); return retError(EBADF); } std::unique_ptr &file = files[argv[1]]; int64_t error = file->close(); DPRINTF(Semihosting, "Semihosting SYS_CLOSE(%i[%s]): %i\n", argv[1], file->fileName(), error); if (error < 0) { return retError(-error); } else { // Zap the pointer and free the entry in the file table as // well. files[argv[1]].reset(); return retOK(0); } } ArmSemihosting::RetErrno ArmSemihosting::callWriteC(ThreadContext *tc, bool aarch64, std::vector &argv) { const char c = physProxy(tc).read(argv[0]); DPRINTF(Semihosting, "Semihosting SYS_WRITEC('%c')\n", c); std::cout.put(c); return retOK(0); } ArmSemihosting::RetErrno ArmSemihosting::callWrite0(ThreadContext *tc, bool aarch64, std::vector &argv) { DPRINTF(Semihosting, "Semihosting SYS_WRITE0(...)\n"); PortProxy &proxy = physProxy(tc); for (Addr addr = (Addr)argv[0]; ; ++addr) { char data = proxy.read(addr); if (data == 0) break; std::cout.put(data); } return retOK(0); } ArmSemihosting::RetErrno ArmSemihosting::callWrite(ThreadContext *tc, bool aarch64, std::vector &argv) { if (argv[1] > files.size() || !files[argv[1]]) return RetErrno(argv[3], EBADF); std::vector buffer(argv[3]); physProxy(tc).readBlob(argv[2], buffer.data(), buffer.size()); int64_t ret = files[argv[1]]->write(buffer.data(), buffer.size()); if (ret < 0) { // No bytes written (we're returning the number of bytes not // written) return RetErrno(argv[3], -ret); } else { // Return the number of bytes not written return RetErrno(argv[3] - ret, 0); } } ArmSemihosting::RetErrno ArmSemihosting::callRead(ThreadContext *tc, bool aarch64, std::vector &argv) { if (argv[1] > files.size() || !files[argv[1]]) return RetErrno(argv[3], EBADF); std::vector buffer(argv[3]); int64_t ret = files[argv[1]]->read(buffer.data(), buffer.size()); if (ret < 0) { return RetErrno(argv[3], -ret); } else { panic_if(ret > buffer.size(), "Read longer than buffer size."); physProxy(tc).writeBlob(argv[2], buffer.data(), ret); // Return the number of bytes not written return retOK(argv[3] - ret); } } ArmSemihosting::RetErrno ArmSemihosting::callReadC(ThreadContext *tc, bool aarch64, std::vector &argv) { return retOK((char)std::cin.get()); } ArmSemihosting::RetErrno ArmSemihosting::callIsError(ThreadContext *tc, bool aarch64, std::vector &argv) { // Sign extend from a 32 bit integer in aarch32 since the argument // reader zero extends to a uint64_t. const int64_t status = (int64_t)(aarch64 ? argv[1] :sext<32>(argv[1])); // Assume there was an error if the status value is negative. return retOK(status < 0 ? 1 : 0); } ArmSemihosting::RetErrno ArmSemihosting::callIsTTY(ThreadContext *tc, bool aarch64, std::vector &argv) { if (argv[1] > files.size() || !files[argv[1]]) return retError(EBADF); int64_t ret = files[argv[1]]->isTTY(); if (ret < 0) { return retError(-ret); } else { return retOK(ret ? 1 : 0); } } ArmSemihosting::RetErrno ArmSemihosting::callSeek(ThreadContext *tc, bool aarch64, std::vector &argv) { if (argv[1] > files.size() || !files[argv[1]]) return retError(EBADF); int64_t ret = files[argv[1]]->seek(argv[2]); if (ret < 0) { return retError(-ret); } else { return retOK(0); } } ArmSemihosting::RetErrno ArmSemihosting::callFLen(ThreadContext *tc, bool aarch64, std::vector &argv) { if (argv[1] > files.size() || !files[argv[1]]) return retError(EBADF); int64_t ret = files[argv[1]]->isTTY(); if (ret < 0) { return retError(-ret); } else { return retOK(0); } } ArmSemihosting::RetErrno ArmSemihosting::callTmpNam(ThreadContext *tc, bool aarch64, std::vector &argv) { const Addr guest_buf = argv[1]; //const uint64_t id = argv[2]; const uint64_t max_len = argv[3]; std::vector buf(L_tmpnam); char *path = tmpnam(buf.data()); if (!path) return retError(EINVAL); const size_t path_len = strlen(path); if (path_len >= max_len) return retError(ENOSPC); physProxy(tc).writeBlob( guest_buf, (const uint8_t *)path, path_len + 1); return retOK(0); } ArmSemihosting::RetErrno ArmSemihosting::callRemove(ThreadContext *tc, bool aarch64, std::vector &argv) { std::string fname = readString(tc, argv[1], argv[2]); if (remove(fname.c_str()) != 0) { return retError(errno); } else { return retOK(0); } } ArmSemihosting::RetErrno ArmSemihosting::callRename(ThreadContext *tc, bool aarch64, std::vector &argv) { std::string from = readString(tc, argv[1], argv[2]); std::string to = readString(tc, argv[3], argv[4]); if (rename(from.c_str(), to.c_str()) != 0) { return retError(errno); } else { return retOK(0); } } ArmSemihosting::RetErrno ArmSemihosting::callClock(ThreadContext *tc, bool aarch64, std::vector &argv) { return retOK(curTick() / (SimClock::Int::s / 100)); } ArmSemihosting::RetErrno ArmSemihosting::callTime(ThreadContext *tc, bool aarch64, std::vector &argv) { return retOK(timeBase + round(curTick() / SimClock::Float::s)); } ArmSemihosting::RetErrno ArmSemihosting::callSystem(ThreadContext *tc, bool aarch64, std::vector &argv) { const std::string cmd = readString(tc, argv[1], argv[2]); warn("Semihosting: SYS_SYSTEM not implemented. Guest tried to run: %s\n", cmd); return retError(EINVAL); } ArmSemihosting::RetErrno ArmSemihosting::callErrno(ThreadContext *tc, bool aarch64, std::vector &argv) { // Preserve errno by returning it in errno as well. return RetErrno(semiErrno, semiErrno); } ArmSemihosting::RetErrno ArmSemihosting::callGetCmdLine(ThreadContext *tc, bool aarch64, std::vector &argv) { if (cmdLine.size() + 1 < argv[2]) { PortProxy &proxy = physProxy(tc); ByteOrder endian = ArmISA::byteOrder(tc); proxy.writeBlob( (Addr)argv[1], (const uint8_t *)cmdLine.c_str(), cmdLine.size() + 1); if (aarch64) proxy.write(argv[0] + 1 * 8, cmdLine.size(), endian); else proxy.write(argv[0] + 1 * 4, cmdLine.size(), endian); return retOK(0); } else { return retError(0); } } ArmSemihosting::RetErrno ArmSemihosting::callHeapInfo(ThreadContext *tc, bool aarch64, std::vector &argv) { const PhysicalMemory &phys = tc->getSystemPtr()->getPhysMem(); const AddrRangeList memories = phys.getConfAddrRanges(); fatal_if(memories.size() < 1, "No memories reported from System"); warn_if(memories.size() > 1, "Multiple physical memory ranges available. " "Using first range heap/stack."); const AddrRange memory = *memories.begin(); const Addr mem_start = memory.start() + memReserve; Addr mem_end = memory.end(); // Make sure that 32-bit guests can access their memory. if (!aarch64) { const Addr phys_max = (1ULL << 32) - 1; panic_if(mem_start > phys_max, "Physical memory out of range for a 32-bit guest."); if (mem_end > phys_max) { warn("Some physical memory out of range for a 32-bit guest."); mem_end = phys_max; } } fatal_if(mem_start + stackSize >= mem_end, "Physical memory too small to fit desired stack and a heap."); const Addr heap_base = mem_start; const Addr heap_limit = mem_end - stackSize + 1; const Addr stack_base = (mem_end + 1) & ~0x7ULL; // 8 byte stack alignment const Addr stack_limit = heap_limit; inform("Reporting heap/stack info to guest:\n" "\tHeap base: 0x%x\n" "\tHeap limit: 0x%x\n" "\tStack base: 0x%x\n" "\tStack limit: 0x%x\n", heap_base, heap_limit, stack_base, stack_limit); Addr base = argv[1]; PortProxy &proxy = physProxy(tc); ByteOrder endian = ArmISA::byteOrder(tc); if (aarch64) { proxy.write(base + 0 * 8, heap_base, endian); proxy.write(base + 1 * 8, heap_limit, endian); proxy.write(base + 2 * 8, stack_base, endian); proxy.write(base + 3 * 8, stack_limit, endian); } else { proxy.write(base + 0 * 4, heap_base, endian); proxy.write(base + 1 * 4, heap_limit, endian); proxy.write(base + 2 * 4, stack_base, endian); proxy.write(base + 3 * 4, stack_limit, endian); } return retOK(0); } ArmSemihosting::RetErrno ArmSemihosting::callExit(ThreadContext *tc, bool aarch64, std::vector &argv) { if (aarch64) { semiExit(argv[1], argv[2]); } else { semiExit(argv[0], 0); } return retOK(0); } ArmSemihosting::RetErrno ArmSemihosting::callExitExtended(ThreadContext *tc, bool aarch64, std::vector &argv) { semiExit(argv[1], argv[2]); return retOK(0); } void ArmSemihosting::semiExit(uint64_t code, uint64_t subcode) { auto it = exitCodes.find(code); if (it != exitCodes.end()) { exitSimLoop(it->second, subcode); } else { exitSimLoop(csprintf("semi:0x%x", code), subcode); } } ArmSemihosting::RetErrno ArmSemihosting::callElapsed(ThreadContext *tc, bool aarch64, std::vector &argv) { PortProxy &proxy = physProxy(tc); ByteOrder endian = ArmISA::byteOrder(tc); const uint64_t tick = semiTick(curTick()); if (aarch64) { proxy.write(argv[0], tick, endian); } else { proxy.write(argv[0] + 0 * 4, tick, endian); proxy.write(argv[0] + 1 * 4, tick >> 32, endian); } return retOK(0); } ArmSemihosting::RetErrno ArmSemihosting::callTickFreq(ThreadContext *tc, bool aarch64, std::vector &argv) { return retOK(semiTick(SimClock::Frequency)); } const ArmSemihosting::SemiCall * ArmSemihosting::getCall(uint32_t op, bool aarch64) { auto it = calls.find(op); if (it == calls.end()) return nullptr; else { return &it->second; } } FILE * ArmSemihosting::getSTDIO(const char *stream_name, const std::string &name, const char *mode) { auto it = stdioMap.find(name); if (it == stdioMap.end()) { FILE *f = fopen(name.c_str(), mode); if (!f) { fatal("Failed to open %s (%s): %s\n", stream_name, name, strerror(errno)); } return f; } else { return it->second; } } std::unique_ptr ArmSemihosting::FileBase::create( ArmSemihosting &parent, const std::string &fname, const char *mode) { std::unique_ptr file; if (fname == ":semihosting-features") { file.reset(new FileFeatures(parent, fname.c_str(), mode)); } else { file.reset(new File(parent, fname.c_str(), mode)); } return file; } std::unique_ptr ArmSemihosting::FileBase::create(ArmSemihosting &parent, CheckpointIn &cp, const std::string &sec) { std::unique_ptr file; ScopedCheckpointSection _sec(cp, sec); // Was the file open when the checkpoint was created? if (!cp.sectionExists(Serializable::currentSection())) return file; std::string fname, mode; paramIn(cp, "name", fname); paramIn(cp, "mode", mode); file = create(parent, fname, mode.c_str()); assert(file); file->unserialize(cp); return file; } void ArmSemihosting::FileBase::serialize(CheckpointOut &cp) const { paramOut(cp, "name", _name); SERIALIZE_SCALAR(mode); } void ArmSemihosting::FileBase::unserialize(CheckpointIn &cp) { /* Unserialization of name and mode happens in * ArmSemihosting::FileBase::create() */ } int64_t ArmSemihosting::FileBase::read(uint8_t *buffer, uint64_t size) { return -EINVAL; } int64_t ArmSemihosting::FileBase::write(const uint8_t *buffer, uint64_t size) { return -EINVAL; } int64_t ArmSemihosting::FileBase::seek(uint64_t pos) { return -EINVAL; } int64_t ArmSemihosting::FileBase::flen() { return -EINVAL; } ArmSemihosting::FileFeatures::FileFeatures( ArmSemihosting &_parent, const char *_name, const char *_mode) : FileBase(_parent, _name, _mode) { } int64_t ArmSemihosting::FileFeatures::read(uint8_t *buffer, uint64_t size) { int64_t len = 0; for (; pos < size && pos < ArmSemihosting::features.size(); pos++) buffer[len++] = ArmSemihosting::features[pos]; return len; } int64_t ArmSemihosting::FileFeatures::seek(uint64_t _pos) { if (_pos < ArmSemihosting::features.size()) { pos = _pos; return 0; } else { return -ENXIO; } } void ArmSemihosting::FileFeatures::serialize(CheckpointOut &cp) const { FileBase::serialize(cp); SERIALIZE_SCALAR(pos); } void ArmSemihosting::FileFeatures::unserialize(CheckpointIn &cp) { FileBase::unserialize(cp); UNSERIALIZE_SCALAR(pos); } ArmSemihosting::File::File(ArmSemihosting &_parent, const char *_name, const char *_perms) : FileBase(_parent, _name, _perms), file(nullptr) { } ArmSemihosting::File::~File() { if (file) close(); } int64_t ArmSemihosting::File::openImpl(bool in_cpt) { panic_if(file, "Trying to open an already open file.\n"); if (_name == ":tt") { if (mode[0] == 'r') { file = parent.stdin; } else if (mode[0] == 'w') { file = parent.stdout; } else if (mode[0] == 'a') { file = parent.stderr; } else { warn("Unknown file mode for the ':tt' special file"); return -EINVAL; } } else { std::string real_mode(this->mode); // Avoid truncating the file if we are restoring from a // checkpoint. if (in_cpt && real_mode[0] == 'w') real_mode[0] = 'a'; file = fopen(_name.c_str(), real_mode.c_str()); } return file ? 0 : -errno; } int64_t ArmSemihosting::File::close() { panic_if(!file, "Trying to close an already closed file.\n"); if (needClose()) { fclose(file); } file = nullptr; return 0; } bool ArmSemihosting::File::isTTY() const { return file == parent.stdout || file == parent.stderr || file == parent.stdin; } int64_t ArmSemihosting::File::read(uint8_t *buffer, uint64_t size) { panic_if(!file, "Trying to read from a closed file"); size_t ret = fread(buffer, 1, size, file); if (ret == 0) { // Error or EOF. Assume errors are due to invalid file // operations (e.g., reading a write-only stream). return ferror(file) ? -EINVAL : 0; } else { return ret; } } int64_t ArmSemihosting::File::write(const uint8_t *buffer, uint64_t size) { panic_if(!file, "Trying to write to a closed file"); size_t ret = fwrite(buffer, 1, size, file); if (ret == 0) { // Assume errors are due to invalid file operations (e.g., // writing a read-only stream). return -EINVAL; } else { return ret; } } int64_t ArmSemihosting::File::seek(uint64_t _pos) { panic_if(!file, "Trying to seek in a closed file"); errno = 0; if (fseek(file, _pos, SEEK_SET) == 0) return 0; else return -errno; } int64_t ArmSemihosting::File::flen() { errno = 0; long pos = ftell(file); if (pos < 0) return -errno; if (fseek(file, 0, SEEK_END) != 0) return -errno; long len = ftell(file); if (len < 0) return -errno; if (fseek(file, pos, SEEK_SET) != 0) return -errno; return len; } void ArmSemihosting::File::serialize(CheckpointOut &cp) const { FileBase::serialize(cp); if (!isTTY()) { long pos = file ? ftell(file) : 0; panic_if(pos < 0, "Failed to get file position."); SERIALIZE_SCALAR(pos); } } void ArmSemihosting::File::unserialize(CheckpointIn &cp) { FileBase::unserialize(cp); if (openImpl(true) < 0) { fatal("Failed to open file: %s", _name); } if (!isTTY()) { long pos = 0; UNSERIALIZE_SCALAR(pos); if (fseek(file, pos, SEEK_SET) != 0) { fatal("Failed seek to current position (%i) in '%s'", pos, _name); } } } ArmSemihosting * ArmSemihostingParams::create() { return new ArmSemihosting(this); }