/** * Copyright (C) ARM Limited 2010-2014. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. */ #define __STDC_FORMAT_MACROS #include "DriverSource.h" #include #include #include #include "Child.h" #include "Fifo.h" #include "Logging.h" #include "Sender.h" #include "SessionData.h" extern Child *child; DriverSource::DriverSource(sem_t *senderSem, sem_t *startProfile) : mFifo(NULL), mSenderSem(senderSem), mStartProfile(startProfile), mBufferSize(0), mBufferFD(0), mLength(1) { int driver_version = 0; if (readIntDriver("/dev/gator/version", &driver_version) == -1) { logg->logError(__FILE__, __LINE__, "Error reading gator driver version"); handleException(); } // Verify the driver version matches the daemon version if (driver_version != PROTOCOL_VERSION) { if ((driver_version > PROTOCOL_DEV) || (PROTOCOL_VERSION > PROTOCOL_DEV)) { // One of the mismatched versions is development version logg->logError(__FILE__, __LINE__, "DEVELOPMENT BUILD MISMATCH: gator driver version \"%d\" is not in sync with gator daemon version \"%d\".\n" ">> The following must be synchronized from engineering repository:\n" ">> * gator driver\n" ">> * gator daemon\n" ">> * Streamline", driver_version, PROTOCOL_VERSION); handleException(); } else { // Release version mismatch logg->logError(__FILE__, __LINE__, "gator driver version \"%d\" is different than gator daemon version \"%d\".\n" ">> Please upgrade the driver and daemon to the latest versions.", driver_version, PROTOCOL_VERSION); handleException(); } } int enable = -1; if (readIntDriver("/dev/gator/enable", &enable) != 0 || enable != 0) { logg->logError(__FILE__, __LINE__, "Driver already enabled, possibly a session is already in progress."); handleException(); } readIntDriver("/dev/gator/cpu_cores", &gSessionData->mCores); if (gSessionData->mCores == 0) { gSessionData->mCores = 1; } if (readIntDriver("/dev/gator/buffer_size", &mBufferSize) || mBufferSize <= 0) { logg->logError(__FILE__, __LINE__, "Unable to read the driver buffer size"); handleException(); } } DriverSource::~DriverSource() { delete mFifo; // Write zero for safety, as a zero should have already been written writeDriver("/dev/gator/enable", "0"); // Calls event_buffer_release in the driver if (mBufferFD) { close(mBufferFD); } } bool DriverSource::prepare() { // Create user-space buffers, add 5 to the size to account for the 1-byte type and 4-byte length logg->logMessage("Created %d MB collector buffer with a %d-byte ragged end", gSessionData->mTotalBufferSize, mBufferSize); mFifo = new Fifo(mBufferSize + 5, gSessionData->mTotalBufferSize*1024*1024, mSenderSem); return true; } void DriverSource::run() { // Get the initial pointer to the collect buffer char *collectBuffer = mFifo->start(); int bytesCollected = 0; logg->logMessage("********** Profiling started **********"); // Set the maximum backtrace depth if (writeReadDriver("/dev/gator/backtrace_depth", &gSessionData->mBacktraceDepth)) { logg->logError(__FILE__, __LINE__, "Unable to set the driver backtrace depth"); handleException(); } // open the buffer which calls userspace_buffer_open() in the driver mBufferFD = open("/dev/gator/buffer", O_RDONLY); if (mBufferFD < 0) { logg->logError(__FILE__, __LINE__, "The gator driver did not set up properly. Please view the linux console or dmesg log for more information on the failure."); handleException(); } // set the tick rate of the profiling timer if (writeReadDriver("/dev/gator/tick", &gSessionData->mSampleRate) != 0) { logg->logError(__FILE__, __LINE__, "Unable to set the driver tick"); handleException(); } // notify the kernel of the response type int response_type = gSessionData->mLocalCapture ? 0 : RESPONSE_APC_DATA; if (writeDriver("/dev/gator/response_type", response_type)) { logg->logError(__FILE__, __LINE__, "Unable to write the response type"); handleException(); } // Set the live rate if (writeReadDriver("/dev/gator/live_rate", &gSessionData->mLiveRate)) { logg->logError(__FILE__, __LINE__, "Unable to set the driver live rate"); handleException(); } logg->logMessage("Start the driver"); // This command makes the driver start profiling by calling gator_op_start() in the driver if (writeDriver("/dev/gator/enable", "1") != 0) { logg->logError(__FILE__, __LINE__, "The gator driver did not start properly. Please view the linux console or dmesg log for more information on the failure."); handleException(); } lseek(mBufferFD, 0, SEEK_SET); sem_post(mStartProfile); // Collect Data do { // This command will stall until data is received from the driver // Calls event_buffer_read in the driver errno = 0; bytesCollected = read(mBufferFD, collectBuffer, mBufferSize); // If read() returned due to an interrupt signal, re-read to obtain the last bit of collected data if (bytesCollected == -1 && errno == EINTR) { bytesCollected = read(mBufferFD, collectBuffer, mBufferSize); } // return the total bytes written logg->logMessage("Driver read of %d bytes", bytesCollected); // In one shot mode, stop collection once all the buffers are filled if (gSessionData->mOneShot && gSessionData->mSessionIsActive) { if (bytesCollected == -1 || mFifo->willFill(bytesCollected)) { logg->logMessage("One shot"); child->endSession(); } } collectBuffer = mFifo->write(bytesCollected); } while (bytesCollected > 0); logg->logMessage("Exit collect data loop"); } void DriverSource::interrupt() { // This command should cause the read() function in collect() to return and stop the driver from profiling if (writeDriver("/dev/gator/enable", "0") != 0) { logg->logMessage("Stopping kernel failed"); } } bool DriverSource::isDone() { return mLength <= 0; } void DriverSource::write(Sender *sender) { char *data = mFifo->read(&mLength); if (data != NULL) { sender->writeData(data, mLength, RESPONSE_APC_DATA); mFifo->release(); } } int DriverSource::readIntDriver(const char *fullpath, int *value) { char data[40]; // Sufficiently large to hold any integer const int fd = open(fullpath, O_RDONLY); if (fd < 0) { return -1; } const ssize_t bytes = read(fd, data, sizeof(data) - 1); close(fd); if (bytes < 0) { return -1; } data[bytes] = '\0'; char *endptr; errno = 0; *value = strtol(data, &endptr, 10); if (errno != 0 || *endptr != '\n') { logg->logMessage("Invalid value in file %s", fullpath); return -1; } return 0; } int DriverSource::readInt64Driver(const char *fullpath, int64_t *value) { char data[40]; // Sufficiently large to hold any integer const int fd = open(fullpath, O_RDONLY); if (fd < 0) { return -1; } const ssize_t bytes = read(fd, data, sizeof(data) - 1); close(fd); if (bytes < 0) { return -1; } data[bytes] = '\0'; char *endptr; errno = 0; *value = strtoll(data, &endptr, 10); if (errno != 0 || *endptr != '\n') { logg->logMessage("Invalid value in file %s", fullpath); return -1; } return 0; } int DriverSource::writeDriver(const char *fullpath, const char *data) { int fd = open(fullpath, O_WRONLY); if (fd < 0) { return -1; } if (::write(fd, data, strlen(data)) < 0) { close(fd); logg->logMessage("Opened but could not write to %s", fullpath); return -1; } close(fd); return 0; } int DriverSource::writeDriver(const char *path, int value) { char data[40]; // Sufficiently large to hold any integer snprintf(data, sizeof(data), "%d", value); return writeDriver(path, data); } int DriverSource::writeDriver(const char *path, int64_t value) { char data[40]; // Sufficiently large to hold any integer snprintf(data, sizeof(data), "%" PRIi64, value); return writeDriver(path, data); } int DriverSource::writeReadDriver(const char *path, int *value) { if (writeDriver(path, *value) || readIntDriver(path, value)) { return -1; } return 0; } int DriverSource::writeReadDriver(const char *path, int64_t *value) { if (writeDriver(path, *value) || readInt64Driver(path, value)) { return -1; } return 0; }