/** * call-seq: * hdfs.utime(path, options={}) -> retval * * Changes the last modified and/or last access time in seconds since the Unix * epoch for the supplied file. Returns true if successful; raises a * DFSException if this fails. * * options can have the following keys: * * * *atime*: Time object or Integer representing seconds since the Unix epoch * to set as the time of last file access. * * *mtime*: Time object or Integer representing seconds since the Unix epoch * to set as the time of last file modification. */ VALUE HDFS_File_System_utime(int argc, VALUE* argv, VALUE self) { FSData* data = get_FSData(self); VALUE path, options; rb_scan_args(argc, argv, "11", &path, &options); // Sets default values for keyword args, type-checks supplied value. options = NIL_P(options) ? rb_hash_new() : options; if (TYPE(options) != T_HASH) { rb_raise(rb_eArgError, "options must be of type Hash"); return Qnil; } VALUE r_atime = rb_hash_aref(options, rb_eval_string(":atime")); VALUE r_mtime = rb_hash_aref(options, rb_eval_string(":mtime")); // Converts any Time objects to seconds since the Unix epoch. r_atime = rb_funcall(r_atime, rb_intern("to_i"), 0); r_mtime = rb_funcall(r_mtime, rb_intern("to_i"), 0); // Sets default values for last modified and/or last access time. tTime hdfsAccessTime = NIL_P(r_atime) ? -1 : NUM2LONG(r_atime); tTime hdfsModifiedTime = NIL_P(r_mtime) ? -1 : NUM2LONG(r_mtime); if (hdfsUtime(data->fs, StringValuePtr(path), hdfsModifiedTime, hdfsAccessTime) == -1) { rb_raise(e_dfs_exception, "Error while setting modified time %lu, access time %lu at path %s: %s", (long) hdfsModifiedTime, (long) hdfsAccessTime, StringValuePtr(path), get_error(errno)); return Qnil; } return Qtrue; }
int dfs_utimens(const char *path, const struct timespec ts[2]) { struct hdfsConn *conn = NULL; hdfsFS fs; int ret = 0; dfs_context *dfs = (dfs_context*)fuse_get_context()->private_data; TRACE1("utimens", path) assert(path); assert(dfs); assert('/' == *path); time_t aTime = ts[0].tv_sec; time_t mTime = ts[1].tv_sec; ret = fuseConnectAsThreadUid(&conn); if (ret) { fprintf(stderr, "fuseConnectAsThreadUid: failed to open a libhdfs " "connection! error %d.\n", ret); ret = -EIO; goto cleanup; } fs = hdfsConnGetFs(conn); if (hdfsUtime(fs, path, mTime, aTime)) { hdfsFileInfo *info = hdfsGetPathInfo(fs, path); if (info == NULL) { ret = (errno > 0) ? -errno : -ENOENT; goto cleanup; } // Silently ignore utimens failure for directories, otherwise // some programs like tar will fail. if (info->mKind == kObjectKindDirectory) { ret = 0; } else { ret = (errno > 0) ? -errno : -EACCES; } goto cleanup; } ret = 0; cleanup: if (conn) { hdfsConnRelease(conn); } return ret; }
int main(int argc, char **argv) { hdfsFS fs = hdfsConnect("default", 0); if(!fs) { fprintf(stderr, "Oops! Failed to connect to hdfs!\n"); exit(-1); } hdfsFS lfs = hdfsConnect(NULL, 0); if(!lfs) { fprintf(stderr, "Oops! Failed to connect to 'local' hdfs!\n"); exit(-1); } const char* writePath = "/tmp/testfile.txt"; { //Write tests hdfsFile writeFile = hdfsOpenFile(fs, writePath, O_WRONLY|O_CREAT, 0, 0, 0); if(!writeFile) { fprintf(stderr, "Failed to open %s for writing!\n", writePath); exit(-1); } fprintf(stderr, "Opened %s for writing successfully...\n", writePath); char* buffer = "Hello, World!"; tSize num_written_bytes = hdfsWrite(fs, writeFile, (void*)buffer, strlen(buffer)+1); fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); tOffset currentPos = -1; if ((currentPos = hdfsTell(fs, writeFile)) == -1) { fprintf(stderr, "Failed to get current file position correctly! Got %ld!\n", currentPos); exit(-1); } fprintf(stderr, "Current position: %ld\n", currentPos); if (hdfsFlush(fs, writeFile)) { fprintf(stderr, "Failed to 'flush' %s\n", writePath); exit(-1); } fprintf(stderr, "Flushed %s successfully!\n", writePath); hdfsCloseFile(fs, writeFile); } { //Read tests const char* readPath = "/tmp/testfile.txt"; int exists = hdfsExists(fs, readPath); if (exists) { fprintf(stderr, "Failed to validate existence of %s\n", readPath); exit(-1); } hdfsFile readFile = hdfsOpenFile(fs, readPath, O_RDONLY, 0, 0, 0); if (!readFile) { fprintf(stderr, "Failed to open %s for reading!\n", readPath); exit(-1); } fprintf(stderr, "hdfsAvailable: %d\n", hdfsAvailable(fs, readFile)); tOffset seekPos = 1; if(hdfsSeek(fs, readFile, seekPos)) { fprintf(stderr, "Failed to seek %s for reading!\n", readPath); exit(-1); } tOffset currentPos = -1; if((currentPos = hdfsTell(fs, readFile)) != seekPos) { fprintf(stderr, "Failed to get current file position correctly! Got %ld!\n", currentPos); exit(-1); } fprintf(stderr, "Current position: %ld\n", currentPos); static char buffer[32]; tSize num_read_bytes = hdfsRead(fs, readFile, (void*)buffer, sizeof(buffer)); fprintf(stderr, "Read following %d bytes:\n%s\n", num_read_bytes, buffer); num_read_bytes = hdfsPread(fs, readFile, 0, (void*)buffer, sizeof(buffer)); fprintf(stderr, "Read following %d bytes:\n%s\n", num_read_bytes, buffer); hdfsCloseFile(fs, readFile); } int totalResult = 0; int result = 0; { //Generic file-system operations const char* srcPath = "/tmp/testfile.txt"; const char* dstPath = "/tmp/testfile2.txt"; fprintf(stderr, "hdfsCopy(remote-local): %s\n", ((result = hdfsCopy(fs, srcPath, lfs, srcPath)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsCopy(remote-remote): %s\n", ((result = hdfsCopy(fs, srcPath, fs, dstPath)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsMove(local-local): %s\n", ((result = hdfsMove(lfs, srcPath, lfs, dstPath)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsMove(remote-local): %s\n", ((result = hdfsMove(fs, srcPath, lfs, srcPath)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsRename: %s\n", ((result = hdfsRename(fs, dstPath, srcPath)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsCopy(remote-remote): %s\n", ((result = hdfsCopy(fs, srcPath, fs, dstPath)) ? "Failed!" : "Success!")); totalResult += result; const char* slashTmp = "/tmp"; const char* newDirectory = "/tmp/newdir"; fprintf(stderr, "hdfsCreateDirectory: %s\n", ((result = hdfsCreateDirectory(fs, newDirectory)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsSetReplication: %s\n", ((result = hdfsSetReplication(fs, srcPath, 2)) ? "Failed!" : "Success!")); totalResult += result; char buffer[256]; const char *resp; fprintf(stderr, "hdfsGetWorkingDirectory: %s\n", ((resp = hdfsGetWorkingDirectory(fs, buffer, sizeof(buffer))) ? buffer : "Failed!")); totalResult += (resp ? 0 : 1); fprintf(stderr, "hdfsSetWorkingDirectory: %s\n", ((result = hdfsSetWorkingDirectory(fs, slashTmp)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsGetWorkingDirectory: %s\n", ((resp = hdfsGetWorkingDirectory(fs, buffer, sizeof(buffer))) ? buffer : "Failed!")); totalResult += (resp ? 0 : 1); fprintf(stderr, "hdfsGetDefaultBlockSize: %ld\n", hdfsGetDefaultBlockSize(fs)); fprintf(stderr, "hdfsGetCapacity: %ld\n", hdfsGetCapacity(fs)); fprintf(stderr, "hdfsGetUsed: %ld\n", hdfsGetUsed(fs)); hdfsFileInfo *fileInfo = NULL; if((fileInfo = hdfsGetPathInfo(fs, slashTmp)) != NULL) { fprintf(stderr, "hdfsGetPathInfo - SUCCESS!\n"); fprintf(stderr, "Name: %s, ", fileInfo->mName); fprintf(stderr, "Type: %c, ", (char)(fileInfo->mKind)); fprintf(stderr, "Replication: %d, ", fileInfo->mReplication); fprintf(stderr, "BlockSize: %ld, ", fileInfo->mBlockSize); fprintf(stderr, "Size: %ld, ", fileInfo->mSize); fprintf(stderr, "LastMod: %s", ctime(&fileInfo->mLastMod)); fprintf(stderr, "Owner: %s, ", fileInfo->mOwner); fprintf(stderr, "Group: %s, ", fileInfo->mGroup); char permissions[10]; permission_disp(fileInfo->mPermissions, permissions); fprintf(stderr, "Permissions: %d (%s)\n", fileInfo->mPermissions, permissions); hdfsFreeFileInfo(fileInfo, 1); } else { totalResult++; fprintf(stderr, "waah! hdfsGetPathInfo for %s - FAILED!\n", slashTmp); } hdfsFileInfo *fileList = 0; int numEntries = 0; if((fileList = hdfsListDirectory(fs, slashTmp, &numEntries)) != NULL) { int i = 0; for(i=0; i < numEntries; ++i) { fprintf(stderr, "Name: %s, ", fileList[i].mName); fprintf(stderr, "Type: %c, ", (char)fileList[i].mKind); fprintf(stderr, "Replication: %d, ", fileList[i].mReplication); fprintf(stderr, "BlockSize: %ld, ", fileList[i].mBlockSize); fprintf(stderr, "Size: %ld, ", fileList[i].mSize); fprintf(stderr, "LastMod: %s", ctime(&fileList[i].mLastMod)); fprintf(stderr, "Owner: %s, ", fileList[i].mOwner); fprintf(stderr, "Group: %s, ", fileList[i].mGroup); char permissions[10]; permission_disp(fileList[i].mPermissions, permissions); fprintf(stderr, "Permissions: %d (%s)\n", fileList[i].mPermissions, permissions); } hdfsFreeFileInfo(fileList, numEntries); } else { if (errno) { totalResult++; fprintf(stderr, "waah! hdfsListDirectory - FAILED!\n"); } else { fprintf(stderr, "Empty directory!\n"); } } char*** hosts = hdfsGetHosts(fs, srcPath, 0, 1); if(hosts) { fprintf(stderr, "hdfsGetHosts - SUCCESS! ... \n"); int i=0; while(hosts[i]) { int j = 0; while(hosts[i][j]) { fprintf(stderr, "\thosts[%d][%d] - %s\n", i, j, hosts[i][j]); ++j; } ++i; } } else { totalResult++; fprintf(stderr, "waah! hdfsGetHosts - FAILED!\n"); } char *newOwner = "root"; // setting tmp dir to 777 so later when connectAsUser nobody, we can write to it short newPerm = 0666; // chown write fprintf(stderr, "hdfsChown: %s\n", ((result = hdfsChown(fs, writePath, NULL, "users")) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsChown: %s\n", ((result = hdfsChown(fs, writePath, newOwner, NULL)) ? "Failed!" : "Success!")); totalResult += result; // chmod write fprintf(stderr, "hdfsChmod: %s\n", ((result = hdfsChmod(fs, writePath, newPerm)) ? "Failed!" : "Success!")); totalResult += result; sleep(2); tTime newMtime = time(NULL); tTime newAtime = time(NULL); // utime write fprintf(stderr, "hdfsUtime: %s\n", ((result = hdfsUtime(fs, writePath, newMtime, newAtime)) ? "Failed!" : "Success!")); totalResult += result; // chown/chmod/utime read hdfsFileInfo *finfo = hdfsGetPathInfo(fs, writePath); fprintf(stderr, "hdfsChown read: %s\n", ((result = (strcmp(finfo->mOwner, newOwner) != 0)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsChmod read: %s\n", ((result = (finfo->mPermissions != newPerm)) ? "Failed!" : "Success!")); totalResult += result; // will later use /tmp/ as a different user so enable it fprintf(stderr, "hdfsChmod: %s\n", ((result = hdfsChmod(fs, "/tmp/", 0777)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr,"newMTime=%ld\n",newMtime); fprintf(stderr,"curMTime=%ld\n",finfo->mLastMod); fprintf(stderr, "hdfsUtime read (mtime): %s\n", ((result = (finfo->mLastMod != newMtime)) ? "Failed!" : "Success!")); totalResult += result; // No easy way to turn on access times from hdfs_test right now // fprintf(stderr, "hdfsUtime read (atime): %s\n", ((result = (finfo->mLastAccess != newAtime)) ? "Failed!" : "Success!")); // totalResult += result; hdfsFreeFileInfo(finfo, 1); // Clean up fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(fs, newDirectory)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(fs, srcPath)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(lfs, srcPath)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(lfs, dstPath)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsExists: %s\n", ((result = hdfsExists(fs, newDirectory)) ? "Success!" : "Failed!")); totalResult += (result ? 0 : 1); } totalResult += (hdfsDisconnect(fs) != 0); { // // Now test as connecting as a specific user // This is only meant to test that we connected as that user, not to test // the actual fs user capabilities. Thus just create a file and read // the owner is correct. const char *tuser = "******"; const char* writePath = "/tmp/usertestfile.txt"; const char **groups = (const char**)malloc(sizeof(char*)* 2); groups[0] = "users"; groups[1] = "nobody"; fs = hdfsConnectAsUser("default", 0, tuser, groups, 2); if(!fs) { fprintf(stderr, "Oops! Failed to connect to hdfs as user %s!\n",tuser); exit(-1); } hdfsFile writeFile = hdfsOpenFile(fs, writePath, O_WRONLY|O_CREAT, 0, 0, 0); if(!writeFile) { fprintf(stderr, "Failed to open %s for writing!\n", writePath); exit(-1); } fprintf(stderr, "Opened %s for writing successfully...\n", writePath); char* buffer = "Hello, World!"; tSize num_written_bytes = hdfsWrite(fs, writeFile, (void*)buffer, strlen(buffer)+1); fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); if (hdfsFlush(fs, writeFile)) { fprintf(stderr, "Failed to 'flush' %s\n", writePath); exit(-1); } fprintf(stderr, "Flushed %s successfully!\n", writePath); hdfsCloseFile(fs, writeFile); hdfsFileInfo *finfo = hdfsGetPathInfo(fs, writePath); fprintf(stderr, "hdfs new file user is correct: %s\n", ((result = (strcmp(finfo->mOwner, tuser) != 0)) ? "Failed!" : "Success!")); totalResult += result; } totalResult += (hdfsDisconnect(fs) != 0); if (totalResult != 0) { return -1; } else { return 0; } }
int main(int argc, char **argv) { const char *writePath = "/tmp/testfile.txt"; const char *fileContents = "Hello, World!"; const char *readPath = "/tmp/testfile.txt"; const char *srcPath = "/tmp/testfile.txt"; const char *dstPath = "/tmp/testfile2.txt"; const char *slashTmp = "/tmp"; const char *newDirectory = "/tmp/newdir"; const char *newOwner = "root"; const char *tuser = "******"; const char *appendPath = "/tmp/appends"; const char *userPath = "/tmp/usertestfile.txt"; char buffer[32], buffer2[256], rdbuffer[32]; tSize num_written_bytes, num_read_bytes; hdfsFS fs, lfs; hdfsFile writeFile, readFile, localFile, appendFile, userFile; tOffset currentPos, seekPos; int exists, totalResult, result, numEntries, i, j; const char *resp; hdfsFileInfo *fileInfo, *fileList, *finfo; char *buffer3; char permissions[10]; char ***hosts; short newPerm = 0666; tTime newMtime, newAtime; fs = hdfsConnectNewInstance("default", 0); if(!fs) { fprintf(stderr, "Oops! Failed to connect to hdfs!\n"); exit(-1); } lfs = hdfsConnectNewInstance(NULL, 0); if(!lfs) { fprintf(stderr, "Oops! Failed to connect to 'local' hdfs!\n"); exit(-1); } { //Write tests writeFile = hdfsOpenFile(fs, writePath, O_WRONLY|O_CREAT, 0, 0, 0); if(!writeFile) { fprintf(stderr, "Failed to open %s for writing!\n", writePath); exit(-1); } fprintf(stderr, "Opened %s for writing successfully...\n", writePath); num_written_bytes = hdfsWrite(fs, writeFile, (void*)fileContents, (tSize)(strlen(fileContents)+1)); if (num_written_bytes != strlen(fileContents) + 1) { fprintf(stderr, "Failed to write correct number of bytes - expected %d, got %d\n", (int)(strlen(fileContents) + 1), (int)num_written_bytes); exit(-1); } fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); currentPos = -1; if ((currentPos = hdfsTell(fs, writeFile)) == -1) { fprintf(stderr, "Failed to get current file position correctly! Got %" PRId64 "!\n", currentPos); exit(-1); } fprintf(stderr, "Current position: %" PRId64 "\n", currentPos); if (hdfsFlush(fs, writeFile)) { fprintf(stderr, "Failed to 'flush' %s\n", writePath); exit(-1); } fprintf(stderr, "Flushed %s successfully!\n", writePath); if (hdfsHFlush(fs, writeFile)) { fprintf(stderr, "Failed to 'hflush' %s\n", writePath); exit(-1); } fprintf(stderr, "HFlushed %s successfully!\n", writePath); hdfsCloseFile(fs, writeFile); } { //Read tests exists = hdfsExists(fs, readPath); if (exists) { fprintf(stderr, "Failed to validate existence of %s\n", readPath); exit(-1); } readFile = hdfsOpenFile(fs, readPath, O_RDONLY, 0, 0, 0); if (!readFile) { fprintf(stderr, "Failed to open %s for reading!\n", readPath); exit(-1); } if (!hdfsFileIsOpenForRead(readFile)) { fprintf(stderr, "hdfsFileIsOpenForRead: we just opened a file " "with O_RDONLY, and it did not show up as 'open for " "read'\n"); exit(-1); } fprintf(stderr, "hdfsAvailable: %d\n", hdfsAvailable(fs, readFile)); seekPos = 1; if(hdfsSeek(fs, readFile, seekPos)) { fprintf(stderr, "Failed to seek %s for reading!\n", readPath); exit(-1); } currentPos = -1; if((currentPos = hdfsTell(fs, readFile)) != seekPos) { fprintf(stderr, "Failed to get current file position correctly! Got %" PRId64 "!\n", currentPos); exit(-1); } fprintf(stderr, "Current position: %" PRId64 "\n", currentPos); if (!hdfsFileUsesDirectRead(readFile)) { fprintf(stderr, "Direct read support incorrectly not detected " "for HDFS filesystem\n"); exit(-1); } fprintf(stderr, "Direct read support detected for HDFS\n"); // Test the direct read path if(hdfsSeek(fs, readFile, 0)) { fprintf(stderr, "Failed to seek %s for reading!\n", readPath); exit(-1); } memset(buffer, 0, sizeof(buffer)); num_read_bytes = hdfsRead(fs, readFile, (void*)buffer, sizeof(buffer)); if (strncmp(fileContents, buffer, strlen(fileContents)) != 0) { fprintf(stderr, "Failed to read (direct). Expected %s but got %s (%d bytes)\n", fileContents, buffer, num_read_bytes); exit(-1); } fprintf(stderr, "Read (direct) following %d bytes:\n%s\n", num_read_bytes, buffer); if (hdfsSeek(fs, readFile, 0L)) { fprintf(stderr, "Failed to seek to file start!\n"); exit(-1); } // Disable the direct read path so that we really go through the slow // read path hdfsFileDisableDirectRead(readFile); num_read_bytes = hdfsRead(fs, readFile, (void*)buffer, sizeof(buffer)); fprintf(stderr, "Read following %d bytes:\n%s\n", num_read_bytes, buffer); memset(buffer, 0, strlen(fileContents + 1)); num_read_bytes = hdfsPread(fs, readFile, 0, (void*)buffer, sizeof(buffer)); fprintf(stderr, "Read following %d bytes:\n%s\n", num_read_bytes, buffer); hdfsCloseFile(fs, readFile); // Test correct behaviour for unsupported filesystems localFile = hdfsOpenFile(lfs, writePath, O_WRONLY|O_CREAT, 0, 0, 0); if(!localFile) { fprintf(stderr, "Failed to open %s for writing!\n", writePath); exit(-1); } num_written_bytes = hdfsWrite(lfs, localFile, (void*)fileContents, (tSize)(strlen(fileContents) + 1)); hdfsCloseFile(lfs, localFile); localFile = hdfsOpenFile(lfs, writePath, O_RDONLY, 0, 0, 0); if (hdfsFileUsesDirectRead(localFile)) { fprintf(stderr, "Direct read support incorrectly detected for local " "filesystem\n"); exit(-1); } hdfsCloseFile(lfs, localFile); } totalResult = 0; result = 0; { //Generic file-system operations fprintf(stderr, "hdfsCopy(remote-local): %s\n", ((result = hdfsCopy(fs, srcPath, lfs, srcPath)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsCopy(remote-remote): %s\n", ((result = hdfsCopy(fs, srcPath, fs, dstPath)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsMove(local-local): %s\n", ((result = hdfsMove(lfs, srcPath, lfs, dstPath)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsMove(remote-local): %s\n", ((result = hdfsMove(fs, srcPath, lfs, srcPath)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsRename: %s\n", ((result = hdfsRename(fs, dstPath, srcPath)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsCopy(remote-remote): %s\n", ((result = hdfsCopy(fs, srcPath, fs, dstPath)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsCreateDirectory: %s\n", ((result = hdfsCreateDirectory(fs, newDirectory)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsSetReplication: %s\n", ((result = hdfsSetReplication(fs, srcPath, 2)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsGetWorkingDirectory: %s\n", ((resp = hdfsGetWorkingDirectory(fs, buffer2, sizeof(buffer2))) != 0 ? buffer2 : "Failed!")); totalResult += (resp ? 0 : 1); fprintf(stderr, "hdfsSetWorkingDirectory: %s\n", ((result = hdfsSetWorkingDirectory(fs, slashTmp)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsGetWorkingDirectory: %s\n", ((resp = hdfsGetWorkingDirectory(fs, buffer2, sizeof(buffer2))) != 0 ? buffer2 : "Failed!")); totalResult += (resp ? 0 : 1); fprintf(stderr, "hdfsGetDefaultBlockSize: %" PRId64 "\n", hdfsGetDefaultBlockSize(fs)); fprintf(stderr, "hdfsGetCapacity: %" PRId64 "\n", hdfsGetCapacity(fs)); fprintf(stderr, "hdfsGetUsed: %" PRId64 "\n", hdfsGetUsed(fs)); fileInfo = NULL; if((fileInfo = hdfsGetPathInfo(fs, slashTmp)) != NULL) { fprintf(stderr, "hdfsGetPathInfo - SUCCESS!\n"); fprintf(stderr, "Name: %s, ", fileInfo->mName); fprintf(stderr, "Type: %c, ", (char)(fileInfo->mKind)); fprintf(stderr, "Replication: %d, ", fileInfo->mReplication); fprintf(stderr, "BlockSize: %" PRId64 ", ", fileInfo->mBlockSize); fprintf(stderr, "Size: %" PRId64 ", ", fileInfo->mSize); fprintf(stderr, "LastMod: %s", ctime(&fileInfo->mLastMod)); fprintf(stderr, "Owner: %s, ", fileInfo->mOwner); fprintf(stderr, "Group: %s, ", fileInfo->mGroup); permission_disp(fileInfo->mPermissions, permissions); fprintf(stderr, "Permissions: %d (%s)\n", fileInfo->mPermissions, permissions); hdfsFreeFileInfo(fileInfo, 1); } else { totalResult++; fprintf(stderr, "waah! hdfsGetPathInfo for %s - FAILED!\n", slashTmp); } fileList = 0; fileList = hdfsListDirectory(fs, newDirectory, &numEntries); if (!(fileList == NULL && numEntries == 0 && !errno)) { fprintf(stderr, "waah! hdfsListDirectory for empty %s - FAILED!\n", newDirectory); totalResult++; } else { fprintf(stderr, "hdfsListDirectory for empty %s - SUCCESS!\n", newDirectory); } fileList = 0; if((fileList = hdfsListDirectory(fs, slashTmp, &numEntries)) != NULL) { for(i=0; i < numEntries; ++i) { fprintf(stderr, "Name: %s, ", fileList[i].mName); fprintf(stderr, "Type: %c, ", (char)fileList[i].mKind); fprintf(stderr, "Replication: %d, ", fileList[i].mReplication); fprintf(stderr, "BlockSize: %" PRId64 ", ", fileList[i].mBlockSize); fprintf(stderr, "Size: %" PRId64 ", ", fileList[i].mSize); fprintf(stderr, "LastMod: %s", ctime(&fileList[i].mLastMod)); fprintf(stderr, "Owner: %s, ", fileList[i].mOwner); fprintf(stderr, "Group: %s, ", fileList[i].mGroup); permission_disp(fileList[i].mPermissions, permissions); fprintf(stderr, "Permissions: %d (%s)\n", fileList[i].mPermissions, permissions); } hdfsFreeFileInfo(fileList, numEntries); } else { if (errno) { totalResult++; fprintf(stderr, "waah! hdfsListDirectory - FAILED!\n"); } else { fprintf(stderr, "Empty directory!\n"); } } hosts = hdfsGetHosts(fs, srcPath, 0, 1); if(hosts) { fprintf(stderr, "hdfsGetHosts - SUCCESS! ... \n"); i=0; while(hosts[i]) { j = 0; while(hosts[i][j]) { fprintf(stderr, "\thosts[%d][%d] - %s\n", i, j, hosts[i][j]); ++j; } ++i; } } else { totalResult++; fprintf(stderr, "waah! hdfsGetHosts - FAILED!\n"); } // setting tmp dir to 777 so later when connectAsUser nobody, we can write to it // chown write fprintf(stderr, "hdfsChown: %s\n", ((result = hdfsChown(fs, writePath, NULL, "users")) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsChown: %s\n", ((result = hdfsChown(fs, writePath, newOwner, NULL)) != 0 ? "Failed!" : "Success!")); totalResult += result; // chmod write fprintf(stderr, "hdfsChmod: %s\n", ((result = hdfsChmod(fs, writePath, newPerm)) != 0 ? "Failed!" : "Success!")); totalResult += result; sleep(2); newMtime = time(NULL); newAtime = time(NULL); // utime write fprintf(stderr, "hdfsUtime: %s\n", ((result = hdfsUtime(fs, writePath, newMtime, newAtime)) != 0 ? "Failed!" : "Success!")); totalResult += result; // chown/chmod/utime read finfo = hdfsGetPathInfo(fs, writePath); fprintf(stderr, "hdfsChown read: %s\n", ((result = (strcmp(finfo->mOwner, newOwner))) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsChmod read: %s\n", ((result = (finfo->mPermissions != newPerm)) != 0 ? "Failed!" : "Success!")); totalResult += result; // will later use /tmp/ as a different user so enable it fprintf(stderr, "hdfsChmod: %s\n", ((result = hdfsChmod(fs, "/tmp/", 0777)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr,"newMTime=%ld\n",newMtime); fprintf(stderr,"curMTime=%ld\n",finfo->mLastMod); fprintf(stderr, "hdfsUtime read (mtime): %s\n", ((result = (finfo->mLastMod != newMtime)) != 0 ? "Failed!" : "Success!")); totalResult += result; // No easy way to turn on access times from hdfs_test right now // fprintf(stderr, "hdfsUtime read (atime): %s\n", ((result = (finfo->mLastAccess != newAtime)) != 0 ? "Failed!" : "Success!")); // totalResult += result; hdfsFreeFileInfo(finfo, 1); // Clean up fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(fs, newDirectory, 1)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(fs, srcPath, 1)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(lfs, srcPath, 1)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(lfs, dstPath, 1)) != 0 ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsExists: %s\n", ((result = hdfsExists(fs, newDirectory)) != 0 ? "Success!" : "Failed!")); totalResult += (result ? 0 : 1); } { // TEST APPENDS // CREATE appendFile = hdfsOpenFile(fs, appendPath, O_WRONLY, 0, 0, 0); if(!appendFile) { fprintf(stderr, "Failed to open %s for writing!\n", appendPath); exit(-1); } fprintf(stderr, "Opened %s for writing successfully...\n", appendPath); buffer3 = "Hello,"; num_written_bytes = hdfsWrite(fs, appendFile, (void*)buffer3, (tSize)strlen(buffer3)); fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); if (hdfsFlush(fs, appendFile)) { fprintf(stderr, "Failed to 'flush' %s\n", appendPath); exit(-1); } fprintf(stderr, "Flushed %s successfully!\n", appendPath); hdfsCloseFile(fs, appendFile); // RE-OPEN appendFile = hdfsOpenFile(fs, appendPath, O_WRONLY|O_APPEND, 0, 0, 0); if(!appendFile) { fprintf(stderr, "Failed to open %s for writing!\n", appendPath); exit(-1); } fprintf(stderr, "Opened %s for writing successfully...\n", appendPath); buffer3 = " World"; num_written_bytes = hdfsWrite(fs, appendFile, (void*)buffer3, (tSize)(strlen(buffer3) + 1)); fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); if (hdfsFlush(fs, appendFile)) { fprintf(stderr, "Failed to 'flush' %s\n", appendPath); exit(-1); } fprintf(stderr, "Flushed %s successfully!\n", appendPath); hdfsCloseFile(fs, appendFile); // CHECK size finfo = hdfsGetPathInfo(fs, appendPath); fprintf(stderr, "fileinfo->mSize: == total %s\n", ((result = (finfo->mSize == (tOffset)(strlen("Hello, World") + 1))) == 1 ? "Success!" : "Failed!")); totalResult += (result ? 0 : 1); // READ and check data readFile = hdfsOpenFile(fs, appendPath, O_RDONLY, 0, 0, 0); if (!readFile) { fprintf(stderr, "Failed to open %s for reading!\n", appendPath); exit(-1); } num_read_bytes = hdfsRead(fs, readFile, (void*)rdbuffer, sizeof(rdbuffer)); fprintf(stderr, "Read following %d bytes:\n%s\n", num_read_bytes, rdbuffer); fprintf(stderr, "read == Hello, World %s\n", ((result = (strcmp(rdbuffer, "Hello, World"))) == 0 ? "Success!" : "Failed!")); hdfsCloseFile(fs, readFile); // DONE test appends } totalResult += (hdfsDisconnect(fs) != 0); { // // Now test as connecting as a specific user // This is only meant to test that we connected as that user, not to test // the actual fs user capabilities. Thus just create a file and read // the owner is correct. fs = hdfsConnectAsUserNewInstance("default", 0, tuser); if(!fs) { fprintf(stderr, "Oops! Failed to connect to hdfs as user %s!\n",tuser); exit(-1); } userFile = hdfsOpenFile(fs, userPath, O_WRONLY|O_CREAT, 0, 0, 0); if(!userFile) { fprintf(stderr, "Failed to open %s for writing!\n", userPath); exit(-1); } fprintf(stderr, "Opened %s for writing successfully...\n", userPath); num_written_bytes = hdfsWrite(fs, userFile, (void*)fileContents, (tSize)(strlen(fileContents)+1)); fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); if (hdfsFlush(fs, userFile)) { fprintf(stderr, "Failed to 'flush' %s\n", userPath); exit(-1); } fprintf(stderr, "Flushed %s successfully!\n", userPath); hdfsCloseFile(fs, userFile); finfo = hdfsGetPathInfo(fs, userPath); fprintf(stderr, "hdfs new file user is correct: %s\n", ((result = (strcmp(finfo->mOwner, tuser))) != 0 ? "Failed!" : "Success!")); totalResult += result; } totalResult += (hdfsDisconnect(fs) != 0); if (totalResult != 0) { return -1; } else { return 0; } }
int main(int argc, char **argv) { char buffer[32]; tSize num_written_bytes; const char* slashTmp = "/tmp"; int nnPort; char *rwTemplate, *rwTemplate2, *newDirTemplate, *appendTemplate, *userTemplate, *rwPath = NULL; const char* fileContents = "Hello, World!"; const char* nnHost = NULL; if (argc != 2) { fprintf(stderr, "usage: test_libwebhdfs_ops <username>\n"); exit(1); } struct NativeMiniDfsConf conf = { .doFormat = 1, .webhdfsEnabled = 1, .namenodeHttpPort = 50070, }; cluster = nmdCreate(&conf); if (!cluster) { fprintf(stderr, "Failed to create the NativeMiniDfsCluster.\n"); exit(1); } if (nmdWaitClusterUp(cluster)) { fprintf(stderr, "Error when waiting for cluster to be ready.\n"); exit(1); } if (nmdGetNameNodeHttpAddress(cluster, &nnPort, &nnHost)) { fprintf(stderr, "Error when retrieving namenode host address.\n"); exit(1); } hdfsFS fs = hdfsConnectAsUserNewInstance(nnHost, nnPort, argv[1]); if(!fs) { fprintf(stderr, "Oops! Failed to connect to hdfs!\n"); exit(-1); } { // Write tests rwTemplate = strdup("/tmp/helloWorldXXXXXX"); if (!rwTemplate) { fprintf(stderr, "Failed to create rwTemplate!\n"); exit(1); } rwPath = mktemp(rwTemplate); // hdfsOpenFile hdfsFile writeFile = hdfsOpenFile(fs, rwPath, O_WRONLY|O_CREAT, 0, 0, 0); if(!writeFile) { fprintf(stderr, "Failed to open %s for writing!\n", rwPath); exit(1); } fprintf(stderr, "Opened %s for writing successfully...\n", rwPath); // hdfsWrite num_written_bytes = hdfsWrite(fs, writeFile, (void*)fileContents, (int) strlen(fileContents) + 1); if (num_written_bytes != strlen(fileContents) + 1) { fprintf(stderr, "Failed to write correct number of bytes - " "expected %d, got %d\n", (int)(strlen(fileContents) + 1), (int) num_written_bytes); exit(1); } fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); // hdfsTell tOffset currentPos = -1; if ((currentPos = hdfsTell(fs, writeFile)) == -1) { fprintf(stderr, "Failed to get current file position correctly. Got %" PRId64 "!\n", currentPos); exit(1); } fprintf(stderr, "Current position: %" PRId64 "\n", currentPos); hdfsCloseFile(fs, writeFile); // Done test write } sleep(1); { //Read tests int available = 0, exists = 0; // hdfsExists exists = hdfsExists(fs, rwPath); if (exists) { fprintf(stderr, "Failed to validate existence of %s\n", rwPath); exists = hdfsExists(fs, rwPath); if (exists) { fprintf(stderr, "Still failed to validate existence of %s\n", rwPath); exit(1); } } hdfsFile readFile = hdfsOpenFile(fs, rwPath, O_RDONLY, 0, 0, 0); if (!readFile) { fprintf(stderr, "Failed to open %s for reading!\n", rwPath); exit(1); } if (!hdfsFileIsOpenForRead(readFile)) { fprintf(stderr, "hdfsFileIsOpenForRead: we just opened a file " "with O_RDONLY, and it did not show up as 'open for " "read'\n"); exit(1); } available = hdfsAvailable(fs, readFile); fprintf(stderr, "hdfsAvailable: %d\n", available); // hdfsSeek, hdfsTell tOffset seekPos = 1; if(hdfsSeek(fs, readFile, seekPos)) { fprintf(stderr, "Failed to seek %s for reading!\n", rwPath); exit(1); } tOffset currentPos = -1; if((currentPos = hdfsTell(fs, readFile)) != seekPos) { fprintf(stderr, "Failed to get current file position correctly! Got %" PRId64 "!\n", currentPos); exit(1); } fprintf(stderr, "Current position: %" PRId64 "\n", currentPos); if(hdfsSeek(fs, readFile, 0)) { fprintf(stderr, "Failed to seek %s for reading!\n", rwPath); exit(1); } // hdfsRead memset(buffer, 0, sizeof(buffer)); tSize num_read_bytes = hdfsRead(fs, readFile, buffer, sizeof(buffer)); if (strncmp(fileContents, buffer, strlen(fileContents)) != 0) { fprintf(stderr, "Failed to read (direct). " "Expected %s but got %s (%d bytes)\n", fileContents, buffer, num_read_bytes); exit(1); } fprintf(stderr, "Read following %d bytes:\n%s\n", num_read_bytes, buffer); if (hdfsSeek(fs, readFile, 0L)) { fprintf(stderr, "Failed to seek to file start!\n"); exit(1); } // hdfsPread memset(buffer, 0, strlen(fileContents + 1)); num_read_bytes = hdfsPread(fs, readFile, 0, buffer, sizeof(buffer)); fprintf(stderr, "Read following %d bytes:\n%s\n", num_read_bytes, buffer); hdfsCloseFile(fs, readFile); // Done test read } int totalResult = 0; int result = 0; { //Generic file-system operations char *srcPath = rwPath; char buffer[256]; const char *resp; rwTemplate2 = strdup("/tmp/helloWorld2XXXXXX"); if (!rwTemplate2) { fprintf(stderr, "Failed to create rwTemplate2!\n"); exit(1); } char *dstPath = mktemp(rwTemplate2); newDirTemplate = strdup("/tmp/newdirXXXXXX"); if (!newDirTemplate) { fprintf(stderr, "Failed to create newDirTemplate!\n"); exit(1); } char *newDirectory = mktemp(newDirTemplate); // hdfsRename fprintf(stderr, "hdfsRename: %s\n", ((result = hdfsRename(fs, rwPath, dstPath)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsRename back: %s\n", ((result = hdfsRename(fs, dstPath, srcPath)) ? "Failed!" : "Success!")); totalResult += result; // hdfsCreateDirectory fprintf(stderr, "hdfsCreateDirectory: %s\n", ((result = hdfsCreateDirectory(fs, newDirectory)) ? "Failed!" : "Success!")); totalResult += result; // hdfsSetReplication fprintf(stderr, "hdfsSetReplication: %s\n", ((result = hdfsSetReplication(fs, srcPath, 1)) ? "Failed!" : "Success!")); totalResult += result; // hdfsGetWorkingDirectory, hdfsSetWorkingDirectory fprintf(stderr, "hdfsGetWorkingDirectory: %s\n", ((resp = hdfsGetWorkingDirectory(fs, buffer, sizeof(buffer))) ? buffer : "Failed!")); totalResult += (resp ? 0 : 1); const char* path[] = {"/foo", "/foo/bar", "foobar", "//foo/bar//foobar", "foo//bar", "foo/bar///", "/", "////"}; int i; for (i = 0; i < 8; i++) { fprintf(stderr, "hdfsSetWorkingDirectory: %s, %s\n", ((result = hdfsSetWorkingDirectory(fs, path[i])) ? "Failed!" : "Success!"), hdfsGetWorkingDirectory(fs, buffer, sizeof(buffer))); totalResult += result; } fprintf(stderr, "hdfsSetWorkingDirectory: %s\n", ((result = hdfsSetWorkingDirectory(fs, slashTmp)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsGetWorkingDirectory: %s\n", ((resp = hdfsGetWorkingDirectory(fs, buffer, sizeof(buffer))) ? buffer : "Failed!")); totalResult += (resp ? 0 : 1); // hdfsGetPathInfo hdfsFileInfo *fileInfo = NULL; if((fileInfo = hdfsGetPathInfo(fs, slashTmp)) != NULL) { fprintf(stderr, "hdfsGetPathInfo - SUCCESS!\n"); fprintf(stderr, "Name: %s, ", fileInfo->mName); fprintf(stderr, "Type: %c, ", (char)(fileInfo->mKind)); fprintf(stderr, "Replication: %d, ", fileInfo->mReplication); fprintf(stderr, "BlockSize: %"PRId64", ", fileInfo->mBlockSize); fprintf(stderr, "Size: %"PRId64", ", fileInfo->mSize); fprintf(stderr, "LastMod: %s", ctime(&fileInfo->mLastMod)); fprintf(stderr, "Owner: %s, ", fileInfo->mOwner); fprintf(stderr, "Group: %s, ", fileInfo->mGroup); char permissions[10]; permission_disp(fileInfo->mPermissions, permissions); fprintf(stderr, "Permissions: %d (%s)\n", fileInfo->mPermissions, permissions); hdfsFreeFileInfo(fileInfo, 1); } else { totalResult++; fprintf(stderr, "hdfsGetPathInfo for %s - FAILED!\n", slashTmp); } // hdfsListDirectory hdfsFileInfo *fileList = 0; int numEntries = 0; if((fileList = hdfsListDirectory(fs, slashTmp, &numEntries)) != NULL) { int i = 0; for(i=0; i < numEntries; ++i) { fprintf(stderr, "Name: %s, ", fileList[i].mName); fprintf(stderr, "Type: %c, ", (char)fileList[i].mKind); fprintf(stderr, "Replication: %d, ", fileList[i].mReplication); fprintf(stderr, "BlockSize: %"PRId64", ", fileList[i].mBlockSize); fprintf(stderr, "Size: %"PRId64", ", fileList[i].mSize); fprintf(stderr, "LastMod: %s", ctime(&fileList[i].mLastMod)); fprintf(stderr, "Owner: %s, ", fileList[i].mOwner); fprintf(stderr, "Group: %s, ", fileList[i].mGroup); char permissions[10]; permission_disp(fileList[i].mPermissions, permissions); fprintf(stderr, "Permissions: %d (%s)\n", fileList[i].mPermissions, permissions); } hdfsFreeFileInfo(fileList, numEntries); } else { if (errno) { totalResult++; fprintf(stderr, "waah! hdfsListDirectory - FAILED!\n"); } else { fprintf(stderr, "Empty directory!\n"); } } char *newOwner = "root"; // Setting tmp dir to 777 so later when connectAsUser nobody, // we can write to it short newPerm = 0666; // hdfsChown fprintf(stderr, "hdfsChown: %s\n", ((result = hdfsChown(fs, rwPath, NULL, "users")) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsChown: %s\n", ((result = hdfsChown(fs, rwPath, newOwner, NULL)) ? "Failed!" : "Success!")); totalResult += result; // hdfsChmod fprintf(stderr, "hdfsChmod: %s\n", ((result = hdfsChmod(fs, rwPath, newPerm)) ? "Failed!" : "Success!")); totalResult += result; sleep(2); tTime newMtime = time(NULL); tTime newAtime = time(NULL); // utime write fprintf(stderr, "hdfsUtime: %s\n", ((result = hdfsUtime(fs, rwPath, newMtime, newAtime)) ? "Failed!" : "Success!")); totalResult += result; // chown/chmod/utime read hdfsFileInfo *finfo = hdfsGetPathInfo(fs, rwPath); fprintf(stderr, "hdfsChown read: %s\n", ((result = (strcmp(finfo->mOwner, newOwner) != 0)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsChmod read: %s\n", ((result = (finfo->mPermissions != newPerm)) ? "Failed!" : "Success!")); totalResult += result; // will later use /tmp/ as a different user so enable it fprintf(stderr, "hdfsChmod: %s\n", ((result = hdfsChmod(fs, slashTmp, 0777)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr,"newMTime=%ld\n",newMtime); fprintf(stderr,"curMTime=%ld\n",finfo->mLastMod); fprintf(stderr, "hdfsUtime read (mtime): %s\n", ((result = (finfo->mLastMod != newMtime / 1000)) ? "Failed!" : "Success!")); totalResult += result; // Clean up hdfsFreeFileInfo(finfo, 1); fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(fs, newDirectory, 1)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(fs, srcPath, 1)) ? "Failed!" : "Success!")); totalResult += result; fprintf(stderr, "hdfsExists: %s\n", ((result = hdfsExists(fs, newDirectory)) ? "Success!" : "Failed!")); totalResult += (result ? 0 : 1); // Done test generic operations } { // Test Appends appendTemplate = strdup("/tmp/appendsXXXXXX"); if (!appendTemplate) { fprintf(stderr, "Failed to create appendTemplate!\n"); exit(1); } char *appendPath = mktemp(appendTemplate); const char* helloBuffer = "Hello,"; hdfsFile writeFile = NULL; // Create writeFile = hdfsOpenFile(fs, appendPath, O_WRONLY, 0, 0, 0); if(!writeFile) { fprintf(stderr, "Failed to open %s for writing!\n", appendPath); exit(1); } fprintf(stderr, "Opened %s for writing successfully...\n", appendPath); num_written_bytes = hdfsWrite(fs, writeFile, helloBuffer, (int) strlen(helloBuffer)); fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); hdfsCloseFile(fs, writeFile); fprintf(stderr, "hdfsSetReplication: %s\n", ((result = hdfsSetReplication(fs, appendPath, 1)) ? "Failed!" : "Success!")); totalResult += result; // Re-Open for Append writeFile = hdfsOpenFile(fs, appendPath, O_WRONLY | O_APPEND, 0, 0, 0); if(!writeFile) { fprintf(stderr, "Failed to open %s for writing!\n", appendPath); exit(1); } fprintf(stderr, "Opened %s for appending successfully...\n", appendPath); helloBuffer = " World"; num_written_bytes = hdfsWrite(fs, writeFile, helloBuffer, (int)strlen(helloBuffer) + 1); fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); hdfsCloseFile(fs, writeFile); // Check size hdfsFileInfo *finfo = hdfsGetPathInfo(fs, appendPath); fprintf(stderr, "fileinfo->mSize: == total %s\n", ((result = (finfo->mSize == strlen("Hello, World") + 1)) ? "Success!" : "Failed!")); totalResult += (result ? 0 : 1); // Read and check data hdfsFile readFile = hdfsOpenFile(fs, appendPath, O_RDONLY, 0, 0, 0); if (!readFile) { fprintf(stderr, "Failed to open %s for reading!\n", appendPath); exit(1); } tSize num_read_bytes = hdfsRead(fs, readFile, buffer, sizeof(buffer)); fprintf(stderr, "Read following %d bytes:\n%s\n", num_read_bytes, buffer); fprintf(stderr, "read == Hello, World %s\n", (result = (strcmp(buffer, "Hello, World") == 0)) ? "Success!" : "Failed!"); hdfsCloseFile(fs, readFile); // Cleanup fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(fs, appendPath, 1)) ? "Failed!" : "Success!")); totalResult += result; // Done test appends } totalResult += (hdfsDisconnect(fs) != 0); { // // Now test as connecting as a specific user // This only meant to test that we connected as that user, not to test // the actual fs user capabilities. Thus just create a file and read // the owner is correct. const char *tuser = "******"; userTemplate = strdup("/tmp/usertestXXXXXX"); if (!userTemplate) { fprintf(stderr, "Failed to create userTemplate!\n"); exit(1); } char* userWritePath = mktemp(userTemplate); hdfsFile writeFile = NULL; fs = hdfsConnectAsUserNewInstance("default", 50070, tuser); if(!fs) { fprintf(stderr, "Oops! Failed to connect to hdfs as user %s!\n",tuser); exit(1); } writeFile = hdfsOpenFile(fs, userWritePath, O_WRONLY|O_CREAT, 0, 0, 0); if(!writeFile) { fprintf(stderr, "Failed to open %s for writing!\n", userWritePath); exit(1); } fprintf(stderr, "Opened %s for writing successfully...\n", userWritePath); num_written_bytes = hdfsWrite(fs, writeFile, fileContents, (int)strlen(fileContents) + 1); fprintf(stderr, "Wrote %d bytes\n", num_written_bytes); hdfsCloseFile(fs, writeFile); hdfsFileInfo *finfo = hdfsGetPathInfo(fs, userWritePath); if (finfo) { fprintf(stderr, "hdfs new file user is correct: %s\n", ((result = (strcmp(finfo->mOwner, tuser) != 0)) ? "Failed!" : "Success!")); } else { fprintf(stderr, "hdfsFileInfo returned by hdfsGetPathInfo is NULL\n"); result = -1; } totalResult += result; // Cleanup fprintf(stderr, "hdfsDelete: %s\n", ((result = hdfsDelete(fs, userWritePath, 1)) ? "Failed!" : "Success!")); totalResult += result; // Done test specific user } totalResult += (hdfsDisconnect(fs) != 0); // Shutdown the native minidfscluster nmdShutdown(cluster); nmdFree(cluster); fprintf(stderr, "totalResult == %d\n", totalResult); if (totalResult != 0) { return -1; } else { return 0; } }