This chapter lists all of the public C functions and macros of the Netscape Server Applications Programming Interface (NSAPI) in alphabetic order. These are the functions you use when writing your own Server Application Functions (SAFs).
See Chapter 2, SAFs in the magnus.conf File for a list of the predefined Init SAFs. For more information about the other predefined SAFs used in obj.conf, see the Sun Java System Web Server 6.1 SP8 Administrator’s Configuration File Reference.
Each function provides the name, syntax, parameters, return value, a description of what the function does, and sometimes an example of its use and a list of related functions.
For more information on data structures, see Chapter 8, Data Structure Reference include directory in the build for Sun Java System Web Server 6.1.
For an alphabetical list of function names, see Appendix A, Alphabetical List of NSAPI Functions and Macros
The CALLOC macro is a platform-independent substitute for the C library routine calloc. It allocates num*size bytes from the request’s memory pool. If pooled memory has been disabled in the configuration file (with the pool-init built-in SAF), PERM_CALLOC and CALLOC both obtain their memory from the system heap.
void *CALLOC(int size)
A void pointer to a block of memory.
int size is the size in bytes of each element.
char *name;name = (char *) CALLOC(100);
FREE, REALLOC, STRDUP, PERM_MALLOC, PERM_FREE, PERM_REALLOC, PERM_STRDUP
The cinfo_find() function uses the MIME types information to find the type, encoding, and/or language based on the extension(s) of the URI or local file name. Use this information to send headers (rq->srvhdrs) to the client indicating the content-type, content-encoding, and content-language of the data it will be receiving from the server.
The name used is everything after the last slash (/) or the whole string if no slash is found. File name extensions are not case-sensitive. The name may contain multiple extensions separated by period (.) to indicate type, encoding, or language. For example, the URI a/b/filename.jp.txt.zip could represent a Japanese language, text/plain type, zip encoded file.
cinfo *cinfo_find(char *uri);
A pointer to a newly allocated cinfo structure if content info was found, or NULL if no content was found.
The cinfo structure that is allocated and returned contains pointers to the content-type, content-encoding, and content-language, if found. Each is a pointer into static data in the types database, or NULL if not found. Do not free these pointers. You should free the cinfo structure when you are done using it.
char *uri is a URI or local file name. Multiple file name extensions should be separated by periods (.).
The condvar_init function is a critical-section function that initializes and returns a new condition variable associated with a specified critical-section variable. You can use the condition variable to prevent interference between two threads of execution.
CONDVAR condvar_init(CRITICAL id);
A newly allocated condition variable (CONDVAR).
CRITICAL id is a critical-section variable.
condvar_notify, condvar_terminate, condvar_wait, crit_init, crit_enter, crit_exit, crit_terminate
The condvar_notify function is a critical-section function that activates threads that are blocked on the given critical-section variable. Use this function to awaken threads of execution of a given critical section. First, use crit_enter to gain ownership of the critical section. Then use the returned critical-section variable to call condvar_notify to awaken the threads. Finally, when condvar_notify returns, call crit_exit to surrender ownership of the critical section.
void condvar_notify(CONDVAR cv);
void
CONDVAR cv is a condition variable.
condvar_init, condvar_terminate, condvar_wait, crit_init, crit_enter, crit_exit, crit_terminate
The condvar_terminate function is a critical-section function that frees a condition variable. Use this function to free a previously allocated condition variable.
Terminating a condition variable that is in use can lead to unpredictable results.
void condvar_terminate(CONDVAR cv);
void
CONDVAR cv is a condition variable.
condvar_init, condvar_notify, condvar_wait, crit_init, crit_enter, crit_exit, crit_terminate
The condvar_wait function is a critical-section function that blocks on a given condition variable. Use this function to wait for a critical section (specified by a condition variable argument) to become available. The calling thread is blocked until another thread calls condvar_notify with the same condition variable argument. The caller must have entered the critical section associated with this condition variable before calling condvar_wait.
void condvar_wait(CONDVAR cv);
void
CONDVAR cv is a condition variable.
condvar_init, condvar_terminate, condvar_notify, crit_init, crit_enter, crit_exit, crit_terminate
The crit_enter function is a critical-section function that attempts to enter a critical section. Use this function to gain ownership of a critical section. If another thread already owns the section, the calling thread is blocked until the first thread surrenders ownership by calling crit_exit.
void crit_enter(CRITICAL crvar);
void
CRITICAL crvar is a critical-section variable.
crit_init, crit_exit, crit_terminate
The crit_exit function is a critical-section function that surrenders ownership of a critical section. Use this function to surrender ownership of a critical section. If another thread is blocked waiting for the section, the block will be removed and the waiting thread will be given ownership of the section.
void crit_exit(CRITICAL crvar);
void
CRITICAL crvar is a critical-section variable.
crit_init, crit_enter, crit_terminate
The crit_init function is a critical-section function that creates and returns a new critical-section variable (a variable of type CRITICAL). Use this function to obtain a new instance of a variable of type CRITICAL (a critical-section variable) to be used in managing the prevention of interference between two threads of execution. At the time of its creation, no thread owns the critical section.
Threads must not own or be waiting for the critical section when crit_terminate is called.
CRITICAL crit_init(void);
A newly allocated critical-section variable (CRITICAL).
none
crit_enter, crit_exit, crit_terminate
The crit_terminate function is a critical-section function that removes a previously allocated critical-section variable (a variable of type CRITICAL). Use this function to release a critical-section variable previously obtained by a call to crit_init.
void crit_terminate(CRITICAL crvar);
void
CRITICAL crvar is a critical-section variable.
crit_init, crit_enter, crit_exit
The daemon_atrestart function lets you register a callback function named by fn to be used when the server terminates. Use this function when you need a callback function to deallocate resources allocated by an initialization function. The daemon_atrestart function is a generalization of the magnus_atrestart function.
The magnus.conf directives TerminateTimeout and ChildRestartCallback also affect the callback of NSAPI functions.
void daemon_atrestart(void (*fn)(void *), void *data);
void
void (* fn) (void *) is the callback function.
void *data is the parameter passed to the callback function when the server is restarted.
/* Register the log_close function, passing it NULL */ /* to close *a log file when the server is *//* restarted or shutdown. */ daemon_atrestart(log_close, NULL);NSAPI_PUBLIC void log_close(void *parameter) {system_fclose(global_logfd);}
The fc_open function returns a pointer to PRFileDesc that refers to an open file (fileName). The fileName must be the full path name of an existing file. The file is opened in read-only mode. The application calling this function should not modify the currency of the file pointed to by the PRFileDesc * unless the DUP_FILE_DESC is also passed to this function. In other words, the application (at minimum) should not issue a read operation based on this pointer that would modify the currency for the PRFileDesc *. If such a read operation is required (that may change the currency for the PRFileDesc * ), then the application should call this function with the argument DUP_FILE_DESC.
On a successful call to this function, a valid pointer to PRFileDesc is returned and the handle 'FcHdl'is properly initialized. The size information for the file is stored in the 'fileSize' member of the handle.
PRFileDesc *fc_open(const char *fileName, FcHdl *hDl, PRUint32 flags, Session *sn, Request *rq);
Pointer to PRFileDesc, or NULL on failure.
const char *fileName is the full path name of the file to be opened.
FcHdl*hDl is a valid pointer to a structure of type FcHdl.
PRUint32 flags can be 0 or DUP_FILE_DESC.
Session *sn is a pointer to the session.
Request *rq is a pointer to the request.
The fc_close function closes a file opened using fc_open. This function should only be called with files opened using fc_open.
void fc_close(PRFileDesc *fd, FcHdl *hDl);
void
PRFileDesc *fd is a valid pointer returned from a prior call to fc_open.
FcHdl *hDl is a valid pointer to a structure of type FcHdl. This pointer must have been initialized by a prior call to fc_open.
The filebuf_buf2sd function sends a file buffer to a socket (descriptor) and returns the number of bytes sent.
Use this function to send the contents of an entire file to the client.
int filebuf_buf2sd(filebuf *buf, SYS_NETFD sd);
The number of bytes sent to the socket if successful, or the constant IO_ERROR if the file buffer could not be sent.
filebuf *buf is the file buffer that must already have been opened.
SYS_NETFD sd is the platform-independent socket descriptor. Normally this will be obtained from the csd (client socket descriptor) field of the sn (session) structure.
if (filebuf_buf2sd(buf, sn->csd) == IO_ERROR) return(REQ_EXIT);
filebuf_close, filebuf_open, filebuf_open_nostat, filebuf_getc
The filebuf_close function deallocates a file buffer and closes its associated file.
Generally, use filebuf_open first to open a file buffer, and then filebuf_getc to access the information in the file. After you have finished using the file buffer, use filebuf_close to close it.
void filebuf_close(filebuf *buf);
void
filebuf *buf is the file buffer previously opened with filebuf_open.
filebuf_close(buf);
filebuf_open, filebuf_open_nostat, filebuf_buf2sd, filebuf_getc
The filebuf_getc function retrieves a character from the current file position and returns it as an integer. It then increments the current file position.
Use filebuf_getc to sequentially read characters from a buffered file.
filebuf_getc(filebuf b);
An integer containing the character retrieved, or the constant IO_EOF or IO_ERROR upon an end of file or error.
filebuf b is the name of the file buffer.
filebuf_close, filebuf_buf2sd, filebuf_open, filter_create
The filebuf_open function opens a new file buffer for a previously opened file. It returns a new buffer structure. Buffered files provide more efficient file access by guaranteeing the use of buffered file I/O in environments where it is not supported by the operating system.
filebuf *filebuf_open(SYS_FILE fd, int sz);
A pointer to a new buffer structure to hold the data if successful, or NULL if no buffer could be opened.
SYS_FILE fd is the platform-independent file descriptor of the file which has already been opened.
int sz is the size, in bytes, to be used for the buffer.
filebuf *buf = filebuf_open(fd, FILE_BUFFERSIZE);if (!buf) { system_fclose(fd);}
filebuf_getc, filebuf_buf2sd, filebuf_close, filebuf_open_nostat
The filebuf_open_nostat function opens a new file buffer for a previously opened file. It returns a new buffer structure. Buffered files provide more efficient file access by guaranteeing the use of buffered file I/O in environments where it is not supported by the operating system.
This function is the same filebuf_open, but is more efficient, since it does not need to call the request_stat_path function. It requires that the stat information be passed in.
filebuf* filebuf_open_nostat(SYS_FILE fd, int sz, struct stat *finfo);
A pointer to a new buffer structure to hold the data if successful, or NULL if no buffer could be opened.
SYS_FILE fd is the platform-independent file descriptor of the file that has already been opened.
int sz is the size, in bytes, to be used for the buffer.
struct stat *finfo is the file information of the file. Before calling the filebuf_open_nostat function, you must call the request_stat_path function to retrieve the file information.
filebuf *buf = filebuf_open_nostat(fd, FILE_BUFFERSIZE, &finfo); if (!buf) { system_fclose(fd); }
filebuf_close, filebuf_open, filebuf_getc, filebuf_buf2sd
The filter_create function defines a new filter.
The name parameter specifies a unique name for the filter. If a filter with the specified name already exists, it will be replaced.
Names beginning with magnus- or server- are reserved by the server.
The order parameter indicates the position of the filter in the filter stack by specifying what class of functionality the filter implements.
The following table describes parameters allowed order constants and their associated meanings for the filter_create function. The left column lists the name of the constant, the middle column describes the functionality the filter implements, and the right column lists the position the filter occupies in the filter stack.
Table 7–1 filter-create constants
Constant |
Functionality Filter Implements |
Position in Filter Stack |
---|---|---|
FILTER_CONTENT_TRANSLATION |
Translates content from one form to another (for example, XSLT) |
Top |
FILTER_CONTENT_CODING |
Encodes content (for example, HTTP gzip compression) |
Middle |
FILTER_TRANSFER_CODING |
Encodes entity bodies for transmission (for example, HTTP chunking) |
Bottom |
The methods parameter specifies a pointer to a FilterMethods structure. Before calling filter_create, you must first initialize the FilterMethods structure using the FILTER_METHODS_INITIALIZER macro, and then assign function pointers to the individual FilterMethods members (for example, insert, read, write, and so on) that correspond to the filter methods the filter will support.
filter_create returns const Filter *, a pointer to an opaque representation of the filter. This value may be passed to filter_insert to insert the filter in a particular filter stack.
const Filter *filter_create(const char *name, int order, const FilterMethods *methods);
The const Filter * that identifies the filter or NULL if an error occurred.
const char *name is the name of the filter.
int order is one of the order constants above.
const FilterMethods *methods contains pointers to the filter methods the filter supports.
FilterMethods methods = FILTER_METHODS_INITIALIZER; const Filter *filter; /* This filter will only support the "read" filter method */ methods.read = my_input_filter_read; /* Create the filter */ filter = filter_create("my-input-filter", FILTER_CONTENT_TRANSLATION, &methods);
The filter_find function finds the filter with the specified name.
const Filter *filter_find(const char *name);
The const Filter * that identifies the filter, or NULL if the specified filter does not exist.
const char *name is the name of the filter of interest.
The filter_insert function inserts a filter into a filter stack, creating a new filter layer and installing the filter at that layer. The filter layer's position in the stack is determined by the order value specified when filter_create was called, and any explicit ordering configured by init-filter-order. If a filter layer with the same order value already exists in the stack, the new layer is inserted above that layer.
Parameters may be passed to the filter using the pb and data parameters. The semantics of the data parameter are defined by individual filters. However, all filters must be able to handle a data parameter of NULL.
When possible, plug-in developers should avoid calling filter_insert directly, and instead use the insert-filter SAF (applicable in Input-class directives).
int filter_insert(SYS_NETFD sd, pblock *pb, Session *sn, Request *rq, void *data, const Filter *filter);
Returns REQ_PROCEED if the specified filter was inserted successfully, or REQ_NOACTION if the specified filter was not inserted because it was not required. Any other return value indicates an error.
SYS_NETFD sd is NULL (reserved for future use).
pblock *pb is a set of parameters to pass to the specified filter's init method.
Session *sn is the Session.
Request *rq is the Request.
void *data is filter-defined private data.
const Filter *filter is the filter to insert.
The filter_layer function returns the layer in a filter stack that corresponds to the specified filter.
FilterLayer *filter_layer(SYS_NETFD sd, const Filter *filter);
The topmost FilterLayer * associated with the specified filter, or NULL if the specified filter is not part of the specified filter stack.
SYS_NETFD sd is the filter stack to inspect.
const Filter *filter is the filter of interest.
The filter_name function returns the name of the specified filter. The caller should not free the returned string.
const char *filter_name(const Filter *filter);
The name of the specified filter, or NULL if an error occurred.
const Filter *filter is the filter of interest.
The filter_remove function removes the specified filter from the specified filter stack, destroying a filter layer. If the specified filter was inserted into the filter stack multiple times, only that filter's topmost filter layer is destroyed.
When possible, plug-in developers should avoid calling filter_remove directly, and instead use the remove-filter SAF (applicable in Input-, Output-, Service-, and Error-class directives).
int filter_remove(SYS_NETFD sd, const Filter *filter);
Returns REQ_PROCEED if the specified filter was removed successfully or REQ_NOACTION if the specified filter was not part of the filter stack. Any other return value indicates an error.
SYS_NETFD sd is the filter stack, sn->csd.
const Filter *filter is the filter to remove.
The flush filter method is called when buffered data should be sent. Filters that buffer outgoing data should implement the flush filter method.
Upon receiving control, a flush implementation must write any buffered data to the filter layer immediately below it. Before returning success, a flush implementation must successfully call the net_flush function:
net_flush(layer->lower).
int flush(FilterLayer *layer);
0 on success or -1 if an error occurred.
FilterLayer *layer is the filter layer the filter is installed in.
int myfilter_flush(FilterLayer *layer) { MyFilterContext context = (MyFilterContext *)layer->context->data; if (context->buf.count) { int rv; rv = net_write(layer->lower, context->buf.data, context->buf.count); if (rv != context->buf.count) return -1; /* failed to flush data */ context->buf.count = 0; } return net_flush(layer->lower); }
The FREE macro is a platform-independent substitute for the C library routine free. It deallocates the space previously allocated by MALLOC, CALLOC, or STRDUP from the request’s memory pool.
FREE(void *ptr);
void
void *ptr is a (void *) pointer to a block of memory. If the pointer is not one created by MALLOC, CALLOC, or STRDUP, the behavior is undefined.
char *name;name = (char *) MALLOC(256);...FREE(name);
CALLOC, REALLOC, STRDUP, PERM_MALLOC, PERM_FREE, PERM_REALLOC, PERM_STRDUP
The func_exec function executes the function named by the fn entry in a specified pblock. If the function name is not found, it logs the error and returns REQ_ABORTED.
You can use this function to execute a built-in SAF by identifying it in the pblock.
int func_exec(pblock *pb, Session *sn, Request *rq);
The value returned by the executed function, or the constant REQ_ABORTED if no function was executed.
pblock pb is the pblock containing the function name (fn) and parameters.
Session *sn is the Session.
Request *rq is the Request.
The Session and Request parameters are the same as the ones passed into your SAF.
The func_find function returns a pointer to the function specified by name. If the function does not exist, it returns NULL.
FuncPtr func_find(char *name);
A pointer to the chosen function, suitable for dereferencing, or NULL if the function could not be found.
char *name is the name of the function.
/* this block of code does the same thing as func_exec */char *afunc = pblock_findval("afunction", pb);FuncPtr afnptr = func_find(afunc); if (afnptr) return (afnptr)(pb, sn, rq);
The func_insert function dynamically inserts a named function into the server's table of functions. This function should only be called during the Init stage.
FuncStruct *func_insert(char *name, FuncPtr fn);
Returns the FuncStruct structure that identifies the newly inserted function. The caller should not modify the contents of the FuncStruct structure.
char *name is the name of the function.
FuncPtr fn is the pointer to the function.
func_insert("my-service-saf", &my_service_saf);
The insert filter method is called when a filter is inserted into a filter stack by the filter_insert function or insert-filter SAF (applicable in Input-class directives).
int insert(FilterLayer *layer, pblock *pb);
Returns REQ_PROCEED if the filter should be inserted into the filter stack, REQ_NOACTION if the filter should not be inserted because it is not required, or REQ_ABORTED if the filter should not be inserted because of an error.
FilterLayer *layer is the filter layer at which the filter is being inserted.
pblock *pb is the set of parameters passed to filter_insert or specified by the fn="insert-filter" directive.
FilterMethods myfilter_methods = FILTER_METHODS_INITIALIZER;const Filter *myfilter;int myfilter_insert(FilterLayer *layer, pblock *pb) {if (pblock_findval("dont-insert-filter", pb)) return REQ_NOACTION;return REQ_PROCEED;}...myfilter_methods.insert = &myfilter_insert; myfilter = filter_create("myfilter", &myfilter_methods);...
The log_error function creates an entry in an error log, recording the date, the severity, and a specified text.
int log_error(int degree, char *func, Session *sn, Request *rq, char *fmt, ...);
0 if the log entry was created, or -1 if the log entry was not created.
int degree specifies the severity of the error. It must be one of the following constants:
LOG_WARN -- warning LOG_MISCONFIG -- a syntax error or permission violation LOG_SECURITY -- an authentication failure or 403 error from a hostLOG_FAILURE -- an internal problemLOG_CATASTROPHE -- a nonrecoverable server errorLOG_INFORM -- an informational message
char *func is the name of the function where the error has occurred.
Session *sn is the Session.
Request *rq is the Request.
The Session and Request parameters are the same as the ones passed into your SAF.
char *fmt specifies the format for the printf function that delivers the message.
... represents a sequence of parameters for the printf function.
log_error(LOG_WARN, "send-file", sn, rq, "error opening buffer from %s (%s)"), path, system_errmsg(fd));
The MALLOC macro is a platform-independent substitute for the C library routine malloc. It normally allocates from the request’s memory pool. If pooled memory has been disabled in the configuration file (with the pool-init built-in SAF), PERM_MALLOC and MALLOC both obtain their memory from the system heap.
void *MALLOC(int size)
A void pointer to a block of memory.
int size is the number of bytes to allocate.
/* Allocate 256 bytes for a name */char *name;name = (char *) MALLOC(256);
FREE, CALLOC, REALLOC, STRDUP, PERM_MALLOC, PERM_FREE, PERM_CALLOC, PERM_REALLOC, PERM_STRDUP
The net_flush function flushes any buffered data. If you require that data be sent immediately, call net_flush after calling network output functions such as net_write or net_sendfile.
int net_flush(SYS_NETFD sd);
0 on success, or a negative value if an error occurred.
SYS_NETFD sd is the socket to flush.
net_write(sn->csd, "Please wait... ", 15); net_flush(sn->csd); /* Perform some time-intensive operation */ ... net_write(sn->csd, "Thank you.\n", 11);
The net_ip2host function transforms a textual IP address into a fully-qualified domain name and returns it.
This function works only if the DNS directive is enabled in the magnus.conf file. For more information, see Chapter 2, SAFs in the magnus.conf File.
char *net_ip2host(char *ip, int verify);
A new string containing the fully-qualified domain name if the transformation was accomplished, or NULL if the transformation was not accomplished.
char *ip is the IP address as a character string in dotted-decimal notation: nnn.nnn.nnn.nnn
int verify, if nonzero, specifies that the function should verify the fully-qualified domain name. Though this requires an extra query, you should use it when checking access control.
The net_read function reads bytes from a specified socket into a specified buffer. The function waits to receive data from the socket until either at least one byte is available in the socket or the specified time has elapsed.
int net_read (SYS_NETFD sd, char *buf, int sz, int timeout);
The number of bytes read, which will not exceed the maximum size, sz. A negative value is returned if an error has occurred, in which case errno is set to the constant ETIMEDOUT if the operation did not complete before timeout seconds elapsed.
SYS_NETFD sd is the platform-independent socket descriptor.
char *buf is the buffer to receive the bytes.
int sz is the maximum number of bytes to read.
int timeout is the number of seconds to allow for the read operation before returning. The purpose of timeout is not to return because not enough bytes were read in the given time, but to limit the amount of time devoted to waiting until some data arrives.
The net_sendfile function sends the contents of a specified file to a specified socket. Either the whole file or a fraction may be sent, and the contents of the file may optionally be preceded and/or followed by caller-specified data.
Parameters are passed to net_sendfile in the sendfiledata structure. Before invoking net_sendfile, the caller must initialize every sendfiledata structure member.
int net_sendfile(SYS_NETFD sd, const sendfiledata *sfd);
A positive number indicates the number of bytes successfully written, including the headers, file contents, and trailers. A negative value indicates an error.
SYS_NETFD sd is the socket to write to.
const sendfiledata *sfd identifies the data to send.
The following Service SAF sends a file bracketed by the strings "begin" and "end."
#include <string.h> #include "nsapi.h" NSAPI_PUBLIC int service_net_sendfile(pblock *pb, Session *sn, Request *rq) { char *path; SYS_FILE fd; struct sendfiledata sfd; int rv; path = pblock_findval("path", rq->vars); fd = system_fopenRO(path); if (!fd) { log_error(LOG_MISCONFIG, "service-net-sendfile", sn, rq, "Error opening %s (%s)", path, system_errmsg()); return REQ_ABORTED; } sfd.fd = fd; /* file to send */ sfd.offset = 0; /* start sending from the beginning */ sfd.len = 0; /* send the whole file */ sfd.header = "begin"; /* header data to send before the file */ sfd.hlen = strlen(sfd.header); /* length of header data */ sfd.trailer = "end"; /* trailer data to send after the file */ sfd.tlen = strlen(sfd.trailer); /* length of trailer data */ /* send the headers, file, and trailers to the client */ rv = net_sendfile(sn->csd, &sfd); system_fclose(fd); if (rv < 0) { log_error(LOG_INFORM, "service-net-sendfile", sn, rq,"Error sending %s (%s)", path, system_errmsg()); return REQ_ABORTED; } return REQ_PROCEED; }
The net_write function writes a specified number of bytes to a specified socket from a specified buffer.
int net_write(SYS_NETFD sd, char *buf, int sz);
The number of bytes written, which may be less than the requested size if an error occurred.
SYS_NETFD sd is the platform-independent socket descriptor.
char *buf is the buffer containing the bytes.
int sz is the number of bytes to write.
if (net_write(sn->csd, FIRSTMSG, strlen(FIRSTMSG)) == IO_ERROR) return REQ_EXIT;
The netbuf_buf2sd function sends a buffer to a socket. You can use this function to send data from IPC pipes to the client.
int netbuf_buf2sd(netbuf *buf, SYS_NETFD sd, int len);
The number of bytes transferred to the socket, if successful, or the constant IO_ERROR if unsuccessful.
netbuf *buf is the buffer to send.
SYS_NETFD sd is the platform-independent identifier of the socket.
int len is the length of the buffer.
netbuf_close, netbuf_getc, netbuf_grab, netbuf_open, netbuf_getbytes
The netbuf_close function deallocates a network buffer and closes its associated files. Use this function when you need to deallocate the network buffer and close the socket.
You should never close the netbuf parameter in a session structure.
void netbuf_close(netbuf *buf);
void
netbuf *buf is the buffer to close.
netbuf_buf2sd, netbuf_getc, netbuf_grab, netbuf_open, netbuf_getbytes
The netbuf_getbytes function reads bytes from a network buffer into a caller-supplied buffer. If the network buffer is empty, the function waits to receive data from the network buffer's socket until either at least one byte is available from the socket or the network buffer's timeout has elapsed.
int netbuf_getbytes(netbuf *buf, char *buffer, int sz);
The number of bytes placed into buffer (between 1 and sz) if the operation is successful, the constant NETBUF_EOF on end of file, or the constant NETBUF_ERROR if an error occurred.
netbuf *buf is the buffer from which to retrieve bytes.
char *buffer is the caller-supplied buffer that receives the bytes.
int sz is the maximum number of bytes to read.
int cl = 0; * Read the entire request body */ for (;;) { char mybuf[1024]; int rv; rv = netbuf_getbytes(sn->inbuf, mybuf, sizeof(mybuf)); if (rv == NETBUF_EOF) { log_error(LOG_INFORM, "mysaf", sn, rq, "Received %d byte(s)", cl); break; } if (rv == NETBUF_ERROR) { log_error(LOG_FAILURE, "mysaf", sn, rq, "Error reading request body (%s)", cl, system_errmsg()); break; } cl += rv; }
netbuf_buf2sd, netbuf_close, netbuf_getc, netbuf_grab, netbuf_open
The netbuf_getc function retrieves a character from the cursor position of the network buffer specified by b.
netbuf_getc(netbuf b);
The integer representing the character if one was retrieved, or the constant IO_EOF or IO_ERROR for end of file or error.
netbuf b is the buffer from which to retrieve one character.
netbuf_buf2sd, netbuf_close, netbuf_grab, netbuf_open, netbuf_getbytes
The netbuf_grab function reads sz number of bytes from the network buffer’s (buf) socket into the network buffer. If the buffer is not large enough it is resized. The data can be retrieved from buf->inbuf on success.
This function is used by the function netbuf_buf2sd.
int netbuf_grab(netbuf *buf, int sz);
The number of bytes actually read (between 1 and sz) if the operation was successful, or the constant IO_EOF or IO_ERROR for end of file or error.
netbuf *buf is the buffer to read into.
int sz is the number of bytes to read.
netbuf_buf2sd, netbuf_close, netbuf_grab, netbuf_open, netbuf_getbytes
The netbuf_open function opens a new network buffer and returns it. You can use netbuf_open to create a netbuf structure and start using buffered I/O on a socket.
netbuf* netbuf_open(SYS_NETFD sd, int sz);
A pointer to a new netbuf structure (network buffer).
SYS_NETFD sd is the platform-independent identifier of the socket.
int sz is the number of characters to allocate for the network buffer.
netbuf_buf2sd, netbuf_close, netbuf_getc, netbuf_grab, netbuf_getbytes
Plugin developers may define an nsapi_module_init function, which is a module initialization entry point that enables a plug-in to create filters when it is loaded. When an NSAPI module contains an nsapi_module_init function, the server will call that function immediately after loading the module. The nsapi_module_init presents the same interface as an Init SAF, and it must follow the same rules.
The nsapi_module_init function may be used to register SAFs with func_insert, create filters with filter_create, register virtual server initialization/destruction callbacks with vs_register_cb, and perform other initialization tasks.
int nsapi_module_init(pblock *pb, Session *sn, Request *rq);
REQ_PROCEED on success, or REQ_ABORTED on error.
pblock *pb is a set of parameters specified by the fn="load-modules" directive.
Session *sn (the Session) is NULL.
Request *rq (the Request) is NULL.
The NSAPI_RUNTIME_VERSION macro defines the NSAPI version available at runtime. This is the same as the highest NSAPI version supported by the server the plug-in is running in. The NSAPI version is encoded as in USE_NSAPI_VERSION.
The value returned by the NSAPI_RUNTIME_VERSION macro is valid only in iPlanet™ Web Server 6.0, Netscape Enterprise Server 6.0, and Sun Java System Web Server 6.1. That is, the server must support NSAPI 3.1 for this macro to return a valid value. Additionally, to use NSAPI_RUNTIME_VERSION, you must compile against an nsapi.h header file that supports NSAPI 3.2 or higher.
Plugin developers should not attempt to set the value of the NSAPI_RUNTIME_VERSION macro directly. Instead, see the USE_NSAPI_VERSION macro.
int NSAPI_RUNTIME_VERSION
NSAPI_PUBLIC int log_nsapi_runtime_version(pblock *pb, Session *sn, Request *rq) { log_error(LOG_INFORM, "log-nsapi-runtime-version", sn, rq, "Server supports NSAPI version %d.%d\n", NSAPI_RUNTIME_VERSION / 100, NSAPI_RUNTIME_VERSION % 100); return REQ_PROCEED; }
NSAPI_VERSION,USE_NSAPI_VERSION
The NSAPI_VERSION macro defines the NSAPI version used at compile time. This value is determined by the value of the USE_NSAPI_VERSION macro. If the plug-in developer did not define USE_NSAPI_VERSION, by the highest NSAPI version supported by the nsapi.h header the plug-in was compiled against. The NSAPI version is encoded as in USE_NSAPI_VERSION.
Plugin developers should not attempt to set the value of the NSAPI_VERSION macro directly. Instead, see the USE_NSAPI_VERSION macro.
int NSAPI_VERSION
NSAPI_PUBLIC int log_nsapi_compile_time_version(pblock *pb, Session *sn, Request *rq) { log_error(LOG_INFORM, "log-nsapi-compile-time-version", sn, rq, "Plugin compiled against NSAPI version %d.%d\n", NSAPI_VERSION / 100, NSAPI_VERSION % 100); return REQ_PROCEED; }
NSAPI_RUNTIME_VERSION, USE_NSAPI_VERSION
The param_create function creates a pb_param structure containing a specified name and value. The name and value are copied. Use this function to prepare a pb_param structure to be used in calls to pblock routines such as pblock_pinsert.
pb_param *param_create(char *name, char *value);
A pointer to a new pb_param structure.
char *name is the string containing the name.
char *value is the string containing the value.
pb_param *newpp = param_create("content-type","text/plain"); pblock_pinsert(newpp, rq->srvhdrs);
param_free, pblock_pinsert, pblock_remove
The param_free function frees the pb_param structure specified by pp and its associated structures. Use the param_free function to dispose a pb_param after removing it from a pblock with pblock_remove.
int param_free(pb_param *pp);
1 if the parameter was freed or 0 if the parameter was NULL.
pb_param *pp is the name-value pair stored in a pblock.
if (param_free(pblock_remove("content-type", rq-srvhdrs))) return; /* we removed it */
param_create, pblock_pinsert, pblock_remove
The pblock_copy function copies the entries of the source pblock and adds them into the destination pblock. Any previous entries in the destination pblock are left intact.
void pblock_copy(pblock *src, pblock *dst);
void
pblock *src is the source pblock.
pblock *dst is the destination pblock.
Names and values are newly allocated so that the original pblock may be freed, or the new pblock changed without affecting the original pblock.
pblock_create, pblock_dup, pblock_free, pblock_find, pblock_findval, pblock_remove, pblock_nvinsert
The pblock_create function creates a new pblock. The pblock maintains an internal hash table for fast name-value pair lookups.
pblock *pblock_create(int n);
A pointer to a newly allocated pblock.
int n is the size of the hash table (number of name-value pairs) for the pblock.
pblock_copy, pblock_dup, pblock_find, pblock_findval, pblock_free, pblock_nvinsert, pblock_remove
The pblock_dup function duplicates a pblock. It is equivalent to a sequence of pblock_create and pblock_copy.
pblock *pblock_dup(pblock *src);
A pointer to a newly allocated pblock.
pblock *src is the source pblock.
pblock_create, pblock_find, pblock_findval, pblock_free, pblock_nvinsert, pblock_remove
The pblock_find function finds a specified name-value pair entry in a pblock, and returns the pb_param structure. If you only want the value associated with the name, use the pblock_findval function.
This function is implemented as a macro.
pb_param *pblock_find(char *name, pblock *pb);
A pointer to the pb_param structure if one was found, or NULL if name was not found.
char *name is the name of a name-value pair.
pblock *pb is the pblock to be searched.
pblock_copy, pblock_dup, pblock_findval, pblock_free, pblock_nvinsert, pblock_remove
The pblock_findval function finds the value of a specified name in a pblock. If you just want the pb_param structure of the pblock, use the pblock_find function.
The pointer returned is a pointer into the pblock. Do not FREE it. If you want to modify it, do a STRDUP and modify the copy.
char *pblock_findval(char *name, pblock *pb);
A string containing the value associated with the name or NULL if no match was found.
char *name is the name of a name-value pair.
pblock *pb is the pblock to be searched.
see pblock_nvinsert.
pblock_create, pblock_copy, pblock_find, pblock_free, pblock_nvinsert, pblock_remove, request_header
The pblock_free function frees a specified pblock and any entries inside it. If you want to save a variable in the pblock, remove the variable using the function pblock_remove and save the resulting pointer.
void pblock_free(pblock *pb);
void
pblock *pb is the pblock to be freed.
pblock_copy, pblock_create, pblock_dup, pblock_find, pblock_findval, pblock_nvinsert, pblock_remove
The pblock_nninsert function creates a new entry with a given name and a numeric value in the specified pblock. The numeric value is first converted into a string. The name and value parameters are copied.
pb_param *pblock_nninsert(char *name, int value, pblock *pb);
A pointer to the new pb_param structure.
char *name is the name of the new entry.
int value is the numeric value being inserted into the pblock. This parameter must be an integer. If the value you assign is not a number, then instead use the function pblock_nvinsert to create the parameter.
pblock *pb is the pblock into which the insertion occurs.
pblock_copy, pblock_create, pblock_find, pblock_free, pblock_nvinsert, pblock_remove, pblock_str2pblock
The pblock_nvinsert function creates a new entry with a given name and character value in the specified pblock. The name and value parameters are copied.
pb_param *pblock_nvinsert(char *name, char *value, pblock *pb);
A pointer to the newly allocated pb_param structure.
char *name is the name of the new entry.
char *value is the string value of the new entry.
pblock *pb is the pblock into which the insertion occurs.
pblock_nvinsert("content-type", "text/html", rq->srvhdrs);
pblock_copy, pblock_create, pblock_find, pblock_free, pblock_nninsert, pblock_remove, pblock_str2pblock
The pblock_pb2env function copies a specified pblock into a specified environment. The function creates one new environment entry for each name-value pair in the pblock. Use this function to send pblock entries to a program that you are going to execute.
char **pblock_pb2env(pblock *pb, char **env);
A pointer to the environment.
pblock *pb is the pblock to be copied.
char **env is the environment into which the pblock is to be copied.
pblock_copy, pblock_create, pblock_find, pblock_free, pblock_nvinsert, pblock_remove, pblock_str2pblock
The pblock_pblock2str function copies all parameters of a specified pblock into a specified string. The function allocates additional non-heap space for the string, if needed.
Use this function to stream the pblock for archival and other purposes.
char *pblock_pblock2str(pblock *pb, char *str);
The new version of the str parameter. If str is NULL, this is a new string; otherwise, it is a reallocated string. In either case, it is allocated from the request’s memory pool.
pblock *pb is the pblock to be copied.
char *str is the string into which the pblock is to be copied. It must have been allocated by MALLOC or REALLOC, not by PERM_MALLOC or PERM_REALLOC (which allocate from the system heap).
Each name-value pair in the string is separated from its neighbor pair by a space, and is in the format name="value."
pblock_copy, pblock_create, pblock_find, pblock_free, pblock_nvinsert, pblock_remove, pblock_str2pblock
The function pblock_pinsert inserts a pb_param structure into a pblock.
void pblock_pinsert(pb_param *pp, pblock *pb);
void
pb_param *pp is the pb_param structure to insert.
pblock *pb is the pblock.
pblock_copy, pblock_create, pblock_find, pblock_free, pblock_nvinsert, pblock_remove, pblock_str2pblock
The pblock_remove function removes a specified name-value entry from a specified pblock. If you use this function, you should eventually call param_free to deallocate the memory used by the pb_param structure.
pb_param *pblock_remove(char *name, pblock *pb);
A pointer to the named pb_param structure if it was found, or NULL if the named pb_param was not found.
char *name is the name of the pb_param to be removed.
pblock *pb is the pblock from which the name-value entry is to be removed.
pblock_copy, pblock_create, pblock_find, pblock_free, pblock_nvinsert, param_create, param_free
The pblock_str2pblock function scans a string for parameter pairs, adds them to a pblock, and returns the number of parameters added.
int pblock_str2pblock(char *str, pblock *pb);
The number of parameter pairs added to the pblock, if any, or -1 if an error occurred.
char *str is the string to be scanned.
The name-value pairs in the string can have the format name=value or name="value".
All backslashes (\) must be followed by a literal character. If string values are found with no unescaped = signs (no name=), it assumes the names 1, 2, 3, and so on, depending on the string position. For example, if pblock_str2pblock finds "some strings together", the function treats the strings as if they appeared in name-value pairs as 1="some" 2="strings" 3="together".
pblock *pb is the pblock into which the name-value pairs are stored.
pblock_copy, pblock_create, pblock_find, pblock_free, pblock_nvinsert, pblock_remove, pblock_pblock2str
The PERM_CALLOC macro is a platform-independent substitute for the C library routine calloc. It allocates int size bytes of memory that persist after the request that is being processed has been completed. If pooled memory has been disabled in the configuration file (with the pool-init built-in SAF), PERM_CALLOC and CALLOC both obtain their memory from the system heap.
void *PERM_CALLOC(int size)
A void pointer to a block of memory.
int size is the size in bytes of each element.
char **name;name = (char **) PERM_CALLOC(100);
PERM_FREE, PERM_STRDUP, PERM_MALLOC, PERM_REALLOC, MALLOC, FREE, CALLOC, STRDUP, REALLOC
The PERM_FREE macro is a platform-independent substitute for the C library routine free. It deallocates the persistent space previously allocated by PERM_MALLOC, PERM_CALLOC, or PERM_STRDUP. If pooled memory has been disabled in the configuration file (with the pool-init built-in SAF), both PERM_FREE and FREE deallocates memory in the system heap.
PERM_FREE(void *ptr);
void
void *ptr is a (void *) pointer to block of memory. If the pointer is not one created by PERM_MALLOC, PERM_CALLOC, or PERM_STRDUP, the behavior is undefined.
char *name;name = (char *) PERM_MALLOC(256);...PERM_FREE(name);
FREE, MALLOC, CALLOC, REALLOC, STRDUP, PERM_MALLOC, PERM_CALLOC, PERM_REALLOC, PERM_STRDUP
The PERM_MALLOC macro is a platform-independent substitute for the C library routine malloc. It provides allocation of memory that persists after the request that is being processed has been completed. If pooled memory has been disabled in the configuration file (with the pool-init built-in SAF), PERM_MALLOC and MALLOC both obtain their memory from the system heap.
void *PERM_MALLOC(int size)
A void pointer to a block of memory.
int size is the number of bytes to allocate.
/* Allocate 256 bytes for a name */char *name;name = (char *) PERM_MALLOC(256);
PERM_FREE, PERM_STRDUP, PERM_CALLOC, PERM_REALLOC, MALLOC, FREE, CALLOC, STRDUP, REALLOC
The PERM_REALLOC macro is a platform-independent substitute for the C library routine realloc. It changes the size of a specified memory block that was originally created by MALLOC, CALLOC, or STRDUP. The contents of the object remains unchanged up to the lesser of the old and new sizes. If the new size is larger, the new space is uninitialized.
Calling PERM_REALLOC for a block that was allocated with MALLOC, CALLOC, or STRDUP will not work.
void *PERM_REALLOC(vod *ptr, int size)
A void pointer to a block of memory.
void *ptr a void pointer to a block of memory created by PERM_MALLOC, PERM_CALLOC, or PERM_STRDUP.
int size is the number of bytes to which the memory block should be resized.
char *name;name = (char *) PERM_MALLOC(256);if (NotBigEnough()) name = (char *) PERM_REALLOC(512);
PERM_MALLOC,PERM_FREE, PERM_CALLOC, PERM_STRDUP, MALLOC, FREE, STRDUP, CALLOC, REALLOC
The PERM_STRDUP macro is a platform-independent substitute for the C library routine strdup. It creates a new copy of a string in memory that persists after the request that is being processed has been completed. If pooled memory has been disabled in the configuration file (with the pool-init built-in SAF), PERM_STRDUP and STRDUP both obtain their memory from the system heap.
The PERM_STRDUP routine is functionally equivalent to:
newstr = (char *) PERM_MALLOC(strlen(str) + 1);strcpy(newstr, str); |
A string created with PERM_STRDUP should be disposed with PERM_FREE.
char *PERM_STRDUP(char *ptr);
A pointer to the new string.
char *ptr is a pointer to a string.
PERM_MALLOC,PERM_FREE, PERM_CALLOC, PERM_REALLOC, MALLOC, FREE, STRDUP, CALLOC, REALLOC
The prepare_nsapi_thread function allows threads that are not created by the server to act like server-created threads. This function must be called before any NSAPI functions are called from a thread that is not server-created.
void prepare_nsapi_thread(Request *rq, Session *sn);
void
Request *rq is the Request.
Session *sn is the Session.
The Request and Session parameters are the same as the ones passed into your SAF.
The protocol_dump822 function prints headers from a specified pblock into a specific buffer, with a specified size and position. Use this function to serialize the headers so that they can be sent, for example, in a mail message.
char *protocol_dump822(pblock *pb, char *t, int *pos, int tsz);
A pointer to the buffer, which will be reallocated if necessary.
The function also modifies *pos to the end of the headers in the buffer.
pblock *pb is the pblock structure.
char *t is the buffer, allocated with MALLOC, CALLOC, or STRDUP.
int *pos is the position within the buffer at which the headers are to be dumped.
int tsz is the size of the buffer.
protocol_start_response, protocol_status
The protocol_set_finfo function retrieves the content-length and last-modified date from a specified stat structure and adds them to the response headers (rq->srvhdrs). Call protocol_set_finfo before calling protocol_start_response.
int protocol_set_finfo(Session *sn, Request *rq, struct stat *finfo);
The constant REQ_PROCEED if the request can proceed normally, or the constant REQ_ABORTED if the function should treat the request normally but not send any output to the client.
Session *sn is the Session.
Request *rq is the Request.
The Session and Request parameters are the same as the ones passed into your SAF.
stat *finfo is the stat structure for the file.
The stat structure contains the information about the file from the file system. You can get the stat structure info using request_stat_path.
protocol_start_response, protocol_status
The protocol_start_response function initiates the HTTP response for a specified session and request. If the protocol version is HTTP/0.9, the function does nothing, because that version has no concept of status. If the protocol version is HTTP/1.0, the function sends a status line followed by the response headers. Use this function to set up HTTP and prepare the client and server to receive the body (or data) of the response.
int protocol_start_response(Session *sn, Request *rq);
The constant REQ_PROCEED if the operation succeeded, in which case you should send the data you were preparing to send.
The constant REQ_NOACTION if the operation succeeded but the request method was HEAD, in which case no data should be sent to the client.
The constant REQ_ABORTED if the operation did not succeed.
Session *sn is the Session.
Request *rq is the Request.
The Session and Request parameters are the same as the ones passed into your SAF.
/* A noaction response from this function means the request was HEAD */if (protocol_start_response(sn, rq) == REQ_NOACTION) filebuf_close(groupbuf); /* close our file*/ return REQ_PROCEED;}
The protocol_status function sets the session status to indicate whether an error condition occurred. If the reason string is NULL, the server attempts to find a reason string for the given status code. If it finds none, it returns “Unknown reason.” The reason string is sent to the client in the HTTP response line. Use this function to set the status of the response before calling the function protocol_start_response.
For the complete list of valid status code constants, please refer to the file "nsapi.h" in the server distribution.
void protocol_status(Session *sn, Request *rq, int n, char *r);
void, but it sets values in the Session/Request designated by sn/rq for the status code and the reason string.
Session *sn is the Session.
Request *rq is the Request.
The Session and Request parameters are the same as the ones passed into your SAF.
int n is one of the status code constants above.
char *r is the reason string.
/* if we find extra path-info, the URL was bad so tell the *//* browser it was not found */if (t = pblock_findval("path-info", rq->vars)) protocol_status(sn, rq, PROTOCOL_NOT_FOUND, NULL); log_error(LOG_WARN, "function-name", sn, rq, "%s not found", path); return REQ_ABORTED;}
The protocol_uri2url function takes strings containing the given URI prefix and URI suffix, and creates a newly allocated, fully qualified URL in the form http://(server):(port)(prefix)(suffix). See protocol_uri2url_dynamic.
If you want to omit either the URI prefix or suffix, use "" instead of NULL as the value for either parameter.
char *protocol_uri2url(char *prefix, char *suffix);
A new string containing the URL.
char *prefix is the prefix.
char *suffix is the suffix.
protocol_start_response, protocol_status, pblock_nvinsert, protocol_uri2url_dynamic
The protocol_uri2url function takes strings containing the given URI prefix and URI suffix, and creates a newly allocated, fully qualified URL in the form http://(server):(port)(prefix)(suffix).
If you want to omit either the URI prefix or suffix, use "" instead of NULL as the value for either parameter.
The protocol_uri2url_dynamic function is similar to the protocol_uri2url function, but should be used whenever the session and request structures are available. This ensures that the URL it constructs refers to the host that the client specified.
char *protocol_uri2url(char *prefix, char *suffix, Session *sn, Request *rq);
A new string containing the URL.
char *prefix is the prefix.
char *suffix is the suffix.
Session *sn is the Session.
Request *rq is the Request.
The Session and Request parameters are the same as the ones passed into your SAF.
protocol_start_response, protocol_status, protocol_uri2url_dynamic
The read filter method is called when input data is required. Filters that modify or consume incoming data should implement the read filter method.
Upon receiving control, a read implementation should fill buf with up to amount bytes of input data. This data may be obtained by calling the net_read function, as shown in the example below.
int read(FilterLayer *layer, void *buf, int amount, int timeout);
The number of bytes placed in buf on success, 0 if no data is available, or a negative value if an error occurred.
FilterLayer *layer is the filter layer in which the filter is installed.
void *buf is the buffer in which data should be placed.
int amount is the maximum number of bytes that should be placed in the buffer.
int timeout is the number of seconds to allow for the read operation before returning. The purpose of timeout is not to return because not enough bytes were read in the given time, but to limit the amount of time devoted to waiting until some data arrives.
int myfilter_read(FilterLayer *layer, void *buf, int amount, int timeout){ return net_read(layer->lower, buf, amount, timeout);}
The REALLOC macro is a platform-independent substitute for the C library routine realloc. It changes the size of a specified memory block that was originally created by MALLOC, CALLOC, or STRDUP. The contents of the object remains unchanged up to the lesser of the old and new sizes. If the new size is larger, the new space is uninitialized.
Calling REALLOC for a block that was allocated with PERM_MALLOC, PERM_CALLOC, or PERM_STRDUP will not work.
void *REALLOC(void *ptr, int size);
A pointer to the new space if the request could be satisfied.
void *ptr is a (void *) pointer to a block of memory. If the pointer is not one created by MALLOC, CALLOC, or STRDUP, the behavior is undefined.
int size is the number of bytes to allocate.
char *name;name = (char *) MALLOC(256);if (NotBigEnough()) name = (char *) REALLOC(512);
MALLOC, FREE, STRDUP, CALLOC, PERM_MALLOC, PERM_FREE, PERM_REALLOC, PERM_CALLOC, PERM_STRDUP
The remove filter method is called when the filter stack is destroyed, or when a filter is removed from a filter stack by the filter_remove function or remove-filter SAF (applicable in Input-, Output-, Service-, and Error-class directives).
Note that it may be too late to flush buffered data when the remove method is invoked. For this reason, filters that buffer outgoing data should implement the flush filter method.
void remove(FilterLayer *layer);
void
FilterLayer *layer is the filter layer the filter is installed in.
The request_get_vs function finds the VirtualServer* to which a request is directed.
The returned VirtualServer* is valid only for the current request. To retrieve a virtual server ID that is valid across requests, use vs_get_id.
const VirtualServer* request_get_vs(Request* rq);
The VirtualServer* to which the request is directed.
Request *rq is the request for which the VirtualServer* is returned.
The request_header function finds an entry in the pblock containing the client’s HTTP request headers (rq->headers). You must use this function rather than pblock_findval when accessing the client headers, since the server may begin processing the request before the headers have been completely read.
int request_header(char *name, char **value, Session *sn, Request *rq);
A result code, REQ_PROCEED if the header was found, REQ_ABORTED if the header was not found, REQ_EXIT if there was an error reading from the client.
char *name is the name of the header.
char **value is the address where the function will place the value of the specified header. If none is found, the function stores a NULL.
Session *sn is the Session.
Request *rq is the Request.
The Session and Request parameters are the same as the ones passed into your SAF.
request_create, request_free
The request_stat_path function returns the file information structure for a specified path or, if none is specified, the path entry in the vars pblock in the specified request structure. If the resulting file name points to a file that the server can read, request_stat_path returns a new file information structure. This structure contains information on the size of the file, its owner, when it was created, and when it was last modified.
You should use request_stat_path to retrieve information on the file you are currently accessing (instead of calling stat directly), because this function keeps track of previous calls for the same path and returns its cached information.
struct stat *request_stat_path(char *path, Request *rq);
Returns a pointer to the file information structure for the file named by the path parameter. Do not free this structure. Returns NULL if the file is not valid or the server cannot read it. In this case, it also leaves an error message describing the problem in rq->staterr.
char *path is the string containing the name of the path. If the value of path is NULL, the function uses the path entry in the vars pblock in the request structure denoted by rq.
Request *rq is the request identifier for a Server Application Function call.
fi = request_stat_path(path, rq);
request_create, request_free, request_header
The request_translate_uri function performs virtual to physical mapping on a specified URI during a specified session. Use this function when you want to determine which file would be sent back if a given URI is accessed.
char *request_translate_uri(char *uri, Session *sn);
A path string if it performed the mapping, or NULL if it could not perform the mapping.
char *uri is the name of the URI.
Session *sn is the Session parameter that is passed into your SAF.
request_create, request_free, request_header
The sendfile filter method is called when the contents of a file are to be sent. Filters that modify or consume outgoing data may choose to implement the sendfile filter method.
If a filter implements the write filter method but not the sendfile filter method, the server will automatically translate net_sendfile calls to net_write calls. As a result, filters interested in the outgoing data stream do not need to implement the sendfile filter method. However, for performance reasons, it is beneficial for filters that implement the write filter method to also implement the sendfile filter method.
int sendfile(FilterLayer *layer, const sendfiledata *data);
The number of bytes consumed, which may be less than the requested amount if an error occurred.
FilterLayer *layer is the filter layer the filter is installed in.
const sendfiledata *sfd identifies the data to send.
int myfilter_sendfile(FilterLayer *layer, const sendfiledata *sfd) { return net_sendfile(layer->lower, sfd); }
The session_dns function resolves the IP address of the client associated with a specified session into its DNS name. It returns a newly allocated string. You can use session_dns to change the numeric IP address into something more readable.
The session_maxdns function verifies that the client is who it claims to be; the session_dns function does not perform this verification.
This function works only if the DNS directive is enabled in the magnus.conf file. For more information, seeChapter 2, SAFs in the magnus.conf File
char *session_dns(Session *sn);
A string containing the host name, or NULL if the DNS name cannot be found for the IP address.
Session *sn is the Session.
The Session is the same as the one passed to your SAF.
The session_maxdns function resolves the IP address of the client associated with a specified session into its DNS name. It returns a newly allocated string. You can use session_maxdns to change the numeric IP address into something more readable.
This function works only if the DNS directive is enabled in the magnus.conf file. For more information, seeChapter 2, SAFs in the magnus.conf File
char *session_maxdns(Session *sn);
A string containing the host name, or NULL if the DNS name cannot be found for the IP address.
Session *sn is the Session.
The Session is the same as the one passed to your SAF.
The shexp_casecmp function validates a specified shell expression and compares it with a specified string. It returns one of three possible values representing match, no match, and invalid comparison. The comparison (in contrast to that of the shexp_cmp function) is not case-sensitive.
Use this function if you have a shell expression like *.netscape.com and you want to make sure that a string matches it, such as foo.netscape.com.
int shexp_casecmp(char *str, char *exp);
0 if a match was found.
1 if no match was found.
-1 if the comparison resulted in an invalid expression.
char *str is the string to be compared.
char *exp is the shell expression (wildcard pattern) to compare against.
shexp_cmp, shexp_match, shexp_valid
The shexp_casecmp function validates a specified shell expression and compares it with a specified string. It returns one of three possible values representing match, no match, and invalid comparison. The comparison (in contrast to that of the shexp_casecmp function) is case-sensitive.
Use this function if you have a shell expression like *.netscape.com and you want to make sure that a string matches it, such as foo.netscape.com.
int shexp_cmp(char *str, char *exp);
0 if a match was found.
1 if no match was found.
-1 if the comparison resulted in an invalid expression.
char *str is the string to be compared.
char *exp is the shell expression (wildcard pattern) to compare against.
/* Use wildcard match to see if this path is one we want */char *path;char *match = "/usr/netscape/*";if (shexp_cmp(path, match) != 0) return REQ_NOACTION; /* no match */
shexp_casecmp, shexp_match, shexp_valid
The shexp_match function compares a specified prevalidated shell expression against a specified string. It returns one of three possible values representing match, no match, and invalid comparison. The comparison (in contrast to that of the shexp_casecmp function) is case-sensitive.
The shexp_match function doesn’t perform validation of the shell expression; instead the function assumes that you have already called shexp_valid.
Use this function if you have a shell expression such as *.netscape.com, and you want to make sure that a string matches it, such as foo.netscape.com.
int shexp_match(char *str, char *exp);
0 if a match was found.
1 if no match was found.
-1 if the comparison resulted in an invalid expression.
char *str is the string to be compared.
char *exp is the prevalidated shell expression (wildcard pattern) to compare against.
shexp_casecmp, shexp_cmp, shexp_valid
The shexp_valid function validates a specified shell expression named by exp. Use this function to validate a shell expression before using the function shexp_match to compare the expression with a string.
int shexp_valid(char *exp);
The constant NON_SXP if exp is a standard string.
The constant INVALID_SXP if exp is a shell expression, but invalid.
The constant VALID_SXP if exp is a valid shell expression.
char *exp is the shell expression (wildcard pattern) to be validated.
shexp_casecmp, shexp_match, shexp_cmp
The STRDUP macro is a platform-independent substitute for the C library routine strdup. It creates a new copy of a string in the request’s memory pool.
The STRDUP routine is functionally equivalent to:
newstr = (char *) MALLOC(strlen(str) + 1); strcpy(newstr, str); |
A string created with STRDUP should be disposed with FREE.
char *STRDUP(char *ptr);
A pointer to the new string.
char *ptr is a pointer to a string.
char *name1 = "MyName";char *name2 = STRDUP(name1);
MALLOC, FREE, CALLOC, REALLOC, PERM_MALLOC, PERM_FREE, PERM_CALLOC, PERM_REALLOC, PERM_STRDUP
The system_errmsg function returns the last error that occurred from the most recent system call. This function is implemented as a macro that returns an entry from the global array sys_errlist. Use this macro to help with I/O error diagnostics.
char *system_errmsg(int param1);
A string containing the text of the latest error message that resulted from a system call. Do not FREE this string.
int param1 is reserved, and should always have the value 0.
system_fopenRO, system_fopenRW, system_fopenWA, system_lseek, system_fread, system_fwrite, system_fwrite_atomic, system_flock, system_ulock, system_fclose
The system_fclose function closes a specified file descriptor. The system_fclose function must be called for every file descriptor opened by any of the system_fopen functions.
int system_fclose(SYS_FILE fd);
0 if the close succeeded, or the constant IO_ERROR if the close failed.
SYS_FILE fd is the platform-independent file descriptor.
SYS_FILE logfd; system_fclose(logfd);
system_errmsg, system_fopenRO, system_fopenRW, system_fopenWA, system_lseek, system_fread, system_fwrite, system_fwrite_atomic, system_flock, system_ulock
The system_flock function locks the specified file against interference from other processes. Use system_flock if you do not want other processes to use the file you currently have open. Overusing file locking can cause performance degradation and possibly lead to deadlocks.
int system_flock(SYS_FILE fd);
The constant IO_OKAY if the lock succeeded, or the constant IO_ERROR if the lock failed.
SYS_FILE fd is the platform-independent file descriptor.
system_errmsg, system_fopenRO, system_fopenRW, system_fopenWA, system_lseek, system_fread, system_fwrite, system_fwrite_atomic, system_ulock, system_fclose
The system_fopenRO function opens the file identified by path in read-only mode and returns a valid file descriptor. Use this function to open files that will not be modified by your program. In addition, you can use system_fopenRO to open a new file buffer structure using filebuf_open.
SYS_FILE system_fopenRO(char *path);
The system-independent file descriptor (SYS_FILE) if the open succeeded, or 0 if the open failed.
char *path is the file name.
system_errmsg, system_fopenRW, system_fopenWA, system_lseek, system_fread, system_fwrite, system_fwrite_atomic, system_flock, system_ulock, system_fclose
The system_fopenRW function opens the file identified by path in read-write mode and returns a valid file descriptor. If the file already exists, system_fopenRW does not truncate it. Use this function to open files that will be read from and written to by your program.
SYS_FILE system_fopenRW(char *path);
The system-independent file descriptor (SYS_FILE) if the open succeeded, or 0 if the open failed.
char *path is the file name.
SYS_FILE fd;fd = system_fopenRO(pathname);if (fd == SYS_ERROR_FD) break;
system_errmsg, system_fopenRO, system_fopenWA, system_lseek, system_fread, system_fwrite, system_fwrite_atomic, system_flock, system_ulock, system_fclose
The system_fopenWA function opens the file identified by path in write-append mode and returns a valid file descriptor. Use this function to open those files to which your program will append data.
SYS_FILE system_fopenWA(char *path);
The system-independent file descriptor (SYS_FILE) if the open succeeded, or 0 if the open failed.
char *path is the file name.
system_errmsg, system_fopenRO, system_fopenRW, system_lseek, system_fread, system_fwrite, system_fwrite_atomic, system_flock, system_ulock, system_fclose
The system_fread function reads a specified number of bytes from a specified file into a specified buffer. It returns the number of bytes read. Before system_fread can be used, you must open the file using any of the system_fopen functions (except system_fopenWA).
int system_fread(SYS_FILE fd, char *buf, int sz);
The number of bytes read, which may be less than the requested size if an error occurred or the end of the file was reached before that number of characters were obtained.
SYS_FILE fd is the platform-independent file descriptor.
char *buf is the buffer to receive the bytes.
int sz is the number of bytes to read.
system_errmsg, system_fopenRO, system_fopenRW, system_fopenWA, system_lseek, system_fwrite, system_fwrite_atomic, system_flock, system_ulock, system_fclose
The system_fwrite function writes a specified number of bytes from a specified buffer into a specified file.
Before system_fwrite can be used, you must open the file using any of the system_fopen functions (except system_fopenRO).
int system_fwrite(SYS_FILE fd, char *buf, int sz);
The constant IO_OKAY if the write succeeded, or the constant IO_ERROR if the write failed.
SYS_FILE fd is the platform-independent file descriptor.
char *buf is the buffer containing the bytes to be written.
int sz is the number of bytes to write to the file.
system_errmsg, system_fopenRO, system_fopenRW, system_fopenWA, system_lseek, system_fread, system_fwrite_atomic, system_flock, system_ulock, system_fclose
The system_fwrite_atomic function writes a specified number of bytes from a specified buffer into a specified file. The function also locks the file prior to performing the write, and then unlocks it when done, thereby avoiding interference between simultaneous write actions. Before system_fwrite_atomic can be used, you must open the file using any of the system_fopen functions, except system_fopenRO.
int system_fwrite_atomic(SYS_FILE fd, char *buf, int sz);
The constant IO_OKAY if the write/lock succeeded, or the constant IO_ERROR if the write/lock failed.
SYS_FILE fd is the platform-independent file descriptor.
char *buf is the buffer containing the bytes to be written.
int sz is the number of bytes to write to the file.
SYS_FILE logfd;char *logmsg = "An error occurred."; system_fwrite_atomic(logfd, logmsg, strlen(logmsg));
system_errmsg, system_fopenRO, system_fopenRW, system_fopenWA, system_lseek, system_fread, system_fwrite, system_flock, system_ulock, system_fclose
The system_gmtime function is a thread-safe version of the standard gmtime function. It returns the current time adjusted to Greenwich Mean Time.
struct tm *system_gmtime(const time_t *tp, const struct tm *res);
A pointer to a calendar time (tm) structure containing the GMT time. Depending on your system, the pointer may point to the data item represented by the second parameter, or it may point to a statically-allocated item. For portability, do not assume either situation.
time_t *tp is an arithmetic time.
tm *res is a pointer to a calendar time (tm) structure.
time_t tp;struct tm res, *resp;tp = time(NULL);resp = system_gmtime(&tp, &res);
system_localtime, util_strftime
The system_localtime function is a thread-safe version of the standard localtime function. It returns the current time in the local time zone.
struct tm *system_localtime(const time_t *tp, const struct tm *res);
A pointer to a calendar time (tm) structure containing the local time. Depending on your system, the pointer may point to the data item represented by the second parameter, or it may point to a statically-allocated item. For portability, do not assume either situation.
time_t *tp is an arithmetic time.
tm *res is a pointer to a calendar time (tm) structure.
system_gmtime, util_strftime
The system_lseek function sets the file position of a file. This affects where data from system_fread or system_fwrite is read or written.
int system_lseek(SYS_FILE fd, int offset, int whence);
The offset, in bytes, of the new position from the beginning of the file if the operation succeeded, or -1 if the operation failed.
SYS_FILE fd is the platform-independent file descriptor.
int offset is a number of bytes relative to whence. It may be negative.
int whence is one of the following constants:
SEEK_SET, from the beginning of the file.
SEEK_CUR, from the current file position.
SEEK_END, from the end of the file.
system_errmsg, system_fopenRO, system_fopenRW, system_fopenWA, system_fread, system_fwrite, system_fwrite_atomic, system_flock, system_ulock, system_fclose
The system_rename function renames a file. It may not work on directories if the old and new directories are on different file systems.
int system_rename(char *old, char *new);
0 if the operation succeeded, or -1 if the operation failed.
char *old is the old name of the file.
char *new is the new name for the file.
The system_ulock function unlocks the specified file that has been locked by the function system_lock. For more information about locking, see system_flock.
int system_ulock(SYS_FILE fd);
The constant IO_OKAY if the operation succeeded, or the constant IO_ERROR if the operation failed.
SYS_FILE fd is the platform-independent file descriptor.
system_errmsg, system_fopenRO, system_fopenRW, system_fopenWA, system_fread, system_fwrite, system_fwrite_atomic, system_flock, system_fclose
The system_unix2local function converts a specified UNIX-style path name to a local file system path name. Use this function when you have a file name in the UNIX format (such as one containing forward slashes), and you need to access a file on another system such as Windows. You can use system_unix2local to convert the UNIX file name into the format that Windows accepts. In the UNIX environment this function does nothing, but may be called for portability.
char *system_unix2local(char *path, char *lp);
A pointer to the local file system path string.
char *path is the UNIX-style path name to be converted.
char *lp is the local path name.
You must allocate the parameter lp, and it must contain enough space to hold the local path name.
system_fclose, system_flock, system_fopenRO, system_fopenRW, system_fopenWA, system_fwrite
The systhread_attach function makes an existing thread into a platform-independent thread.
SYS_THREAD systhread_attach(void);
A SYS_THREAD pointer to the platform-independent thread.
none
systhread_current, systhread_getdata, systhread_init, systhread_newkey, systhread_setdata, systhread_sleep, systhread_start, systhread_timerset
The systhread_current function returns a pointer to the current thread.
SYS_THREAD systhread_current(void);
A SYS_THREAD pointer to the current thread.
none
systhread_getdata, systhread_newkey, systhread_setdata, systhread_sleep, systhread_start, systhread_timerset
The systhread_getdata function gets data that is associated with a specified key in the current thread.
void *systhread_getdata(int key);
A pointer to the data that was earlier used with the systhread_setkey function from the current thread, using the same value of key if the call succeeds. Returns NULL if the call did not succeed. For example, if the systhread_setkey function was never called with the specified key during this session.
int key is the value associated with the stored data by a systhread_setdata function. Keys are assigned by the systhread_newkey function.
systhread_current, systhread_newkey, systhread_setdata, systhread_sleep, systhread_start, systhread_timerset
The systhread_newkey function allocates a new integer key (identifier) for thread-private data. Use this key to identify a variable that you want to localize to the current thread, then use the systhread_setdata function to associate a value with the key.
int systhread_newkey(void);
An integer key.
none
systhread_current, systhread_getdata, systhread_setdata, systhread_sleep, systhread_start, systhread_timerset
The systhread_setdata function associates data with a specified key number for the current thread. Keys are assigned by the systhread_newkey function.
void systhread_setdata(int key, void *data);
void
int key is the priority of the thread.
void *data is the pointer to the string of data to be associated with the value of key.
systhread_current, systhread_getdata, systhread_newkey, systhread_sleep, systhread_start, systhread_timerset
The systhread_sleep function puts the calling thread to sleep for a given time.
void systhread_sleep(int milliseconds);
void
int milliseconds is the number of milliseconds the thread is to sleep.
systhread_current, systhread_getdata, systhread_newkey, systhread_setdata, systhread_start, systhread_timerset
The systhread_start function creates a thread with the given priority, allocates a stack of a specified number of bytes, and calls a specified function with a specified argument.
SYS_THREAD systhread_start(int prio, int stksz, void (*fn)(void *), void *arg);
A new SYS_THREAD pointer if the call succeeded, or the constant SYS_THREAD_ERROR if the call did not succeed.
int prio is the priority of the thread. Priorities are system-dependent.
int stksz is the stack size in bytes. If stksz is zero (0), the function allocates a default size.
void (*fn)(void *) is the function to call.
void *arg is the argument for the fn function.
systhread_current, systhread_getdata, systhread_newkey, systhread_setdata, systhread_sleep, systhread_timerset
The systhread_timerset function starts or resets the interrupt timer interval for a thread system.
Most of the systems do not allow the timer interval to be changed, this should be considered a suggestion, rather than a command.
void systhread_timerset(int usec);
void
int usec is the time, in microseconds
systhread_current, systhread_getdata, systhread_newkey, systhread_setdata, systhread_sleep,systhread_start
Plugin developers can define the USE_NSAPI_VERSION macro before including the nsapi.h header file to request a particular version of NSAPI. The requested NSAPI version is encoded by multiplying the major version number by 100 and then adding this to the minor version number. For example, the following code requests NSAPI 3.2 features:
#define USE_NSAPI_VERSION 302 /* We want NSAPI 3.2 (Web Server 6.1) */ #include "nsapi.h"
To develop a plug-in that is compatible across multiple server versions, define USE_NSAPI_VERSION to the highest NSAPI version supported by all of the target server versions.
The following table lists server versions and the highest NSAPI version supported by each:
Table 7–2 NSAPI Versions Supported by Different Servers
Server Version |
NSAPI Version |
---|---|
iPlanet Web Server 4.1 |
3.0 |
iPlanet Web Server 6.0 |
3.1 |
Netscape Enterprise Server 6.0 |
3.1 |
Netscape Enterprise Server 6.1 |
3.1 |
Sun Java System Application Server 7.0 |
3.1 |
Sun Java System Web Server 6.1 |
3.2 |
It is an error to request a version of NSAPI higher than the highest version supported by the nsapi.h header that the plug-in is being compiled against. Additionally, to use USE_NSAPI_VERSION, you must compile against an nsapi.h header file that supports NSAPI 3.2 or higher.
int USE_NSAPI_VERSION
The following code can be used when building a plug-in designed to work with iPlanet Web Server 4.1 and Sun Java System Web Server 6.1:
#define USE_NSAPI_VERSION 300 /* We want NSAPI 3.0 (Web Server 4.1) */ #include "nsapi.h"
NSAPI_RUNTIME_VERSION, NSAPI_VERSION
The util_can_exec function checks that a specified file can be executed, returning either a 1 (executable) or a 0. The function checks if the file can be executed by the user with the given user and group ID.
Use this function before executing a program using the exec system call.
int util_can_exec(struct stat *finfo, uid_t uid, gid_t gid);
1 if the file is executable, or 0 if the file is not executable.
stat *finfo is the stat structure associated with a file.
uid_t uid is the UNIX user id.
gid_t gid is the UNIX group id. Together with uid, this determines the permissions of the UNIX user.
util_env_create, util_getline, util_hostname
The util_chdir2path function changes the current directory to a specified directory, where you can access a file.
When running under Windows, use a critical section to ensure that more than one thread does not call this function at the same time.
Use util_chdir2path when you want to make file access a little quicker, because you do not need to use a full path.
int util_chdir2path(char *path);
0 if the directory was changed, or -1 if the directory could not be changed.
char *path is the name of a directory.
The parameter must be a writable string because it isn’t permanently modified.
The util_cookie_find function finds a specific cookie in a cookie string and returns its value.
char *util_cookie_find(char *cookie, char *name);
If successful, returns a pointer to the NULL-terminated value of the cookie. Otherwise, returns NULL. This function modifies the cookie string parameter by NULL terminating the name and value.
char *cookie is the value of the Cookie: request header.
char *name is the name of the cookie whose value is to be retrieved.
The util_env_find function locates the string denoted by a name in a specified environment and returns the associated value. Use this function to find an entry in an environment.
char *util_env_find(char **env, char *name);
The value of the environment variable if it is found, or NULL if the string was not found.
char **env is the environment.
char *name is the name of an environment variable in env.
util_env_replace, util_env_str, util_env_free, util_env_create
The util_env_free function frees a specified environment. Use this function to de-allocate an environment you created using the function util_env_create.
void util_env_free(char **env);
void
char **env is the environment to be freed.
util_env_replace, util_env_str, util_env_find, util_env_create
The util_env_replace function replaces the occurrence of the variable denoted by a name in a specified environment with a specified value. Use this function to change the value of a setting in an environment.
void util_env_replace(char **env, char *name, char *value);
void
char **env is the environment.
char *name is the name of a name-value pair.
char *value is the new value to be stored.
util_env_str, util_env_free, util_env_find, util_env_create
The util_env_str function creates an environment entry and returns it. This function does not check for non-alphanumeric symbols in the name (such as the equal sign “=”). You can use this function to create a new environment entry.
char *util_env_str(char *name, char *value);
A newly allocated string containing the name-value pair.
char *name is the name of a name-value pair.
char *value is the new value to be stored.
util_env_replace, util_env_free, util_env_find, util_env_create
The util_getline function scans the specified file buffer to find a line feed or carriage return/line feed terminated string. The string is copied into the specified buffer, and NULL-terminates it. The function returns a value that indicates whether the operation stored a string in the buffer, encountered an error, or reached the end of the file.
Use this function to scan lines of a text file, such as a configuration file.
int util_getline(filebuf *buf, int lineno, int maxlen, char *line);
0 if successful; line contains the string.
1 if the end of file was reached; line contains the string.
-1 if an error occurred; line contains a description of the error.
filebuf *buf is the file buffer to be scanned.
int lineno is used to include the line number in the error message when an error occurs. The caller is responsible for making sure the line number is accurate.
int maxlen is the maximum number of characters that can be written into l.
char *l is the buffer in which to store the string. The user is responsible for allocating and deallocating line.
util_can_exec, util_env_create, util_hostname
The util_hostname function retrieves the local host name and returns it as a string. If the function cannot find a fully-qualified domain name, it returns NULL. You may reallocate or free this string. Use this function to determine the name of the system you are on.
char *util_hostname(void);
If a fully-qualified domain name was found, returns a string containing that name else returns NULL.
none
The util_is_mozilla function checks whether a specified user-agent header string is a Netscape browser of at least a specified revision level, returning a 1 if it is, and 0 otherwise. This function uses strings to specify the revision level to avoid ambiguities such as 1.56 > 1.5.
int util_is_mozilla(char *ua, char *major, char *minor);
1 if the user-agent is a Netscape browser, or 0 if the user-agent is not a Netscape browser.
char *ua is the user-agent string from the request headers.
char *major is the major release number (to the left of the decimal point).
char *minor is the minor release number (to the right of the decimal point).
The util_is_url function checks whether a string is a URL, returning 1 if it is and 0 otherwise. The string is a URL if it begins with alphabets followed by a colon (:).
int util_is_url(char *url);
1 if the string specified by url is a URL, or 0 if the string specified by url is not a URL.
char *url is the string to be examined.
util_is_mozilla, util_later_than
The util_itoa function converts a specified integer to a string, and returns the length of the string. Use this function to create a textual representation of a number.
int util_itoa(int i, char *a);
The length of the string created.
int i is the integer to be converted.
char *a is the ASCII string that represents the value. The user is responsible for the allocation and deallocation of a, and it should be at least 32 bytes long.
The util_later_than function compares the date specified in a time structure against a date specified in a string. If the date in the string is later than or equal to the one in the time structure, the function returns 1. Use this function to handle RFC 822, RFC 850, and ctime formats.
int util_later_than(struct tm *lms, char *ims);
1 if the date represented by ims is the same as or later than that represented by the lms, or 0 if the date represented by ims is earlier than that represented by the lms.
tm *lms is the time structure containing a date.
char *ims is the string containing a date.
The util_sh_escape function parses a specified string and places a backslash (\) in front of any shell-special characters, returning the resultant string. Use this function to ensure that strings from clients won’t cause a shell to do anything unexpected.
The shell-special characters includes space and the following characters:
&;~'"|*?~<>^()[]{}$\#!
char *util_sh_escape(char *s);
A newly allocated string.
char *s is the string to be parsed.
The util_snprintf function formats a specified string, using a specified format, into a specified buffer using the printf-style syntax and performs bounds checking. It returns the number of characters in the formatted buffer.
For more information, see the documentation on the printf function for the runtime library of your compiler.
int util_snprintf(char *s, int n, char *fmt, ...);
The number of characters formatted into the buffer.
char *s is the buffer to receive the formatted string.
int n is the maximum number of bytes allowed to be copied.
char *fmt is the format string. The function handles only %d and %s strings. It does not handle any width or precision strings.
... represents a sequence of parameters for the printf function.
util_sprintf, util_vsnprintf, util_vsprintf
The util_sprintf function formats a specified string, using a specified format, into a specified buffer, using the printf-style syntax without bounds checking. It returns the number of characters in the formatted buffer.
Because util_sprintf doesn’t perform bounds checking, use this function only if you are certain that the string fits the buffer. Otherwise, use the function util_snprintf. For more information, see the documentation on the printf function for the runtime library of your compiler.
int util_sprintf(char *s, char *fmt, ...);
The number of characters formatted into the buffer.
char *s is the buffer to receive the formatted string.
char *fmt is the format string. The function handles only %d and %s strings. It does not handle any width or precision strings.
... represents a sequence of parameters for the printf function.
char *logmsg;int len;logmsg = (char *) MALLOC(256);len = util_sprintf(logmsg, "%s %s %s\n", ip, method, uri);
util_snprintf, util_vsnprintf, util_vsprintf
The util_strcasecmp function performs a comparison of two alphanumeric strings and returns a -1, 0, or 1 to signal which is larger or that they are identical.
The comparison is not case-sensitive.
int util_strcasecmp(const char *s1, const char *s2);
1 if s1 is greater than s2.
0 if s1 is equal to s2.
-1 if s1 is less than s2.
char *s1 is the first string.
char *s2 is the second string.
The util_strftime function translates a tm structure, which is a structure describing a system time, into a textual representation. It is a thread-safe version of the standard strftime function
int util_strftime(char *s, const char *format, const struct tm *t);
The number of characters placed into s, not counting the terminating NULL character.
char *s is the string buffer to put the text into. There is no bounds checking, so you must make sure that your buffer is large enough for the text of the date.
const char *format is a format string, a bit like a printf string in that it consists of text with certain %x substrings. You may use the constant HTTP_DATE_FMT to create date strings in the standard Internet format. For more information, see the documentation on the printf function for the runtime library of your compiler. Refer toChapter 10, Time Formats for details on time formats.
const struct tm *t is a pointer to a calendar time (tm) structure, usually created by the function system_localtime or system_gmtime.
system_localtime, system_gmtime
The util_strncasecmp function performs a comparison of the first n characters in the alphanumeric strings and returns a -1, 0, or 1 to signal which is larger or that they are identical.
The function’s comparison is not case-sensitive.
int util_strncasecmp(const char *s1, const char *s2, int n);
1 if s1 is greater than s2.
0 if s1 is equal to s2.
-1 if s1 is less than s2.
char *s1 is the first string.
char *s2 is the second string.
int n is the number of initial characters to compare.
util_strcasecmp
The util_uri_escape function converts any special characters in the URI into the URI format (%XX, where XX is the hexadecimal equivalent of the ASCII character), and returns the escaped string. The special characters are %?#:+&*"<>, space, carriage return, and line feed.
Use util_uri_escape before sending a URI back to the client.
char *util_uri_escape(char *d, char *s);
The string (possibly newly allocated) with escaped characters replaced.
char *d is a string. If d is not NULL, the function copies the formatted string into d and returns d. If d is NULL, the function allocates a properly sized string and copies the formatted special characters into the new string, then returns d.
The util_uri_escape function does not check bounds for the parameter d. Therefore, if d is not NULL, it should be at least three times as large as the string s.
char *s is the string containing the original unescaped URI.
util_uri_is_evil, util_uri_parse, util_uri_unescape
The util_uri_is_evil function checks a specified URI for insecure path characters. Insecure path characters include //, /./, /../ and/., /.. (also for Windows./) at the end of the URI. Use this function to see if a URI requested by the client is insecure.
int util_uri_is_evil(char *t);
1 if the URI is insecure, or 0 if the URI is OK.
char *t is the URI to be checked.
util_uri_escape, util_uri_parse
The util_uri_parse function converts //, /./, and /*/../ into / in the specified URI (where * is any character other than /). You can use this function to convert a URI’s bad sequences into valid ones. First use the function util_uri_is_evil to determine whether the function has a bad sequence.
void util_uri_parse(char *uri);
void
char *uri is the URI to be converted.
util_uri_is_evil, util_uri_unescape
The util_uri_unescape function converts the encoded characters of a URI into their ASCII equivalents. Encoded characters appear as %XX, where XX is a hexadecimal equivalent of the character.
You cannot use an embedded NULL in a string, because NSAPI functions assume that a NULL is the end of the string. Therefore, passing unicode-encoded content through an NSAPI plug-in doesn’t work.
void util_uri_unescape(char *uri);
void
char *uri is the URI to be converted.
util_uri_escape, util_uri_is_evil, util_uri_parse
The util_vsnprintf function formats a specified string, using a specified format, into a specified buffer using the vprintf-style syntax. The function performs bounds checking and returns the number of characters in the formatted buffer.
For more information, see the documentation on the printf function for the runtime library of your compiler.
int util_vsnprintf(char *s, int n, register char *fmt, va_list args);
The number of characters formatted into the buffer.
char *s is the buffer to receive the formatted string.
int n is the maximum number of bytes allowed to be copied.
register char *fmt is the format string. The function handles only %d and %s strings; it does not handle any width or precision strings.
va_list args is an STD argument variable obtained from a previous call to va_start.
util_sprintf, util_vsprintf
The util_vsprintf function formats a specified string, using a specified format, into a specified buffer using the vprintf-style syntax without bounds checking. It returns the number of characters in the formatted buffer.
For more information, see the documentation on the printf function for the runtime library of your compiler.
int util_vsprintf(char *s, register char *fmt, va_list args);
The number of characters formatted into the buffer.
char *s is the buffer to receive the formatted string.
register char *fmt is the format string. The function handles only %d and %s strings. It does not handle any width or precision strings.
va_list args is an STD argument variable obtained from a previous call to va_start.
util_snprintf, util_vsnprintf
The vs_alloc_slot function allocates a new slot for storing a pointer to data specific to a certain VirtualServer*. The returned slot number may be used in subsequent vs_set_data and vs_get_data calls. The returned slot number is valid for any VirtualServer*.
The value of the pointer (which may be returned by a call to vs_set_data) defaults to NULL for every VirtualServer*.
int vs_alloc_slot(void);
A slot number on success, or -1 on failure.
The vs_get_data function finds the value of a pointer to data for a given VirtualServer* and slot. The slot must be a slot number returned from vs_alloc_slot or vs_set_data.
void* vs_get_data(const VirtualServer* vs, int slot);
The value of the pointer previously stored via vs_set_data, or NULL on failure.
const VirtualServer* vs represents the virtual server to query the pointer for.
int slot is the slot number to retrieve the pointer from.
The vs_get_default_httpd_object function obtains a pointer to the default (or root) httpd_object from the virtual server's httpd_objset (in the configuration defined by the obj.conf file of the virtual server class). The default object is typically named default. Plug-ins may only modify the httpd_object at VSInitFunc time (see vs_register_cb for an explanation of VSInitFunc time).
Do not FREE the returned object.
httpd_object* vs_get_default_httpd_object(VirtualServer* vs);
A pointer the default httpd_object, or NULL on failure. Do not FREE this object.
VirtualServer* vs represents the virtual server for which to find the default object.
vs_get_httpd_objset, vs_register_cb
The vs_get_doc_root function finds the document root for a virtual server. The returned string is the full operating system path to the document root.
The caller should FREE the returned string when done with it.
char* vs_get_doc_root(const VirtualServer* vs);
A pointer to a string representing the full operating system path to the document root. It is the caller's responsibility to FREE this string.
const VirtualServer* vs represents the virtual server for which to find the document root.
The vs_get_httpd_objset function obtains a pointer to the httpd_objset (the configuration defined by the obj.conf file of the virtual server class) for a given virtual server. Plugins may only modify the httpd_objset at VSInitFunc time (see vs_register_cb for an explanation of VSInitFunc time).
Do not FREE the returned objset.
httpd_objset* vs_get_httpd_objset(VirtualServer* vs);
A pointer to the httpd_objset, or NULL on failure. Do not FREE this objset.
VirtualServer* vs represents the virtual server for which to find the objset.
vs_get_default_httpd_object, vs_register_cb
The vs_get_id function finds the ID of a VirtualServer*.
The ID of a virtual server is a unique NULL-terminated string that remains constant across configurations. Note that while IDs remain constant across configurations, the value of VirtualServer* pointers do not.
Do not FREE the virtual server ID string. If called during request processing, the string will remain valid for the duration of the current request. If called during VSInitFunc processing, the string will remain valid until after the corresponding VSDestroyFunc function has returned (see vs_register_cb).
To retrieve a VirtualServer* that is valid only for the current request, use request_get_vs.
const char* vs_get_id(const VirtualServer* vs);
A pointer to a string representing the virtual server ID. Do not FREE this string.
const VirtualServer* vs represents the virtual server of interest.
vs_register_cb, request_get_vs
The vs_get_mime_type function determines the MIME type that would be returned in the content-type: header for the given URI.
The caller should FREE the returned string when done with it.
char* vs_get_mime_type(const VirtualServer* vs, const char* uri);
A pointer to a string representing the MIME type. It is the caller's responsibility to FREE this string.
const VirtualServer* vs represents the virtual server of interest.
const char* uri is the URI whose MIME type is of interest.
The vs_lookup_config_var function finds the value of a configuration variable for a given virtual server.
Do not FREE the returned string.
const char* vs_lookup_config_var(const VirtualServer* vs, const char* name);
A pointer to a string representing the value of variable name on success, or NULL if variable name was not found. Do not FREE this string.
const VirtualServer* vs represents the virtual server of interest.
const char* name is the name of the configuration variable.
The vs_register_cb function allows a plug-in to register functions that will receive notifications of virtual server initialization and destruction events. The vs_register_cb function would typically be called from an Init SAF in magnus.conf.
When a new configuration is loaded, all registered VSInitFunc (virtual server initialization) callbacks are called for each of the virtual servers before any requests are served from the new configuration. VSInitFunc callbacks are called in the same order they were registered; that is, the first callback registered is the first called.
When the last request has been served from an old configuration, all registered VSDestroyFunc (virtual server destruction) callbacks are called for each of the virtual servers before any virtual servers are destroyed. VSDestroyFunc callbacks are called in reverse order; that is, the first callback registered is the last called.
Either initfn or destroyfn may be NULL if the caller is not interested in callbacks for initialization or destruction, respectively.
int vs_register_cb(VSInitFunc* initfn, VSDestroyFunc* destroyfn);
The constant REQ_PROCEED if the operation succeeded.
The constant REQ_ABORTED if the operation failed.
VSInitFunc* initfn is a pointer to the function to call at virtual server initialization time, or NULL if the caller is not interested in virtual server initialization events.
VSDestroyFunc* destroyfn is a pointer to the function to call at virtual server destruction time, or NULL if the caller is not interested in virtual server destruction events.
The vs_set_data function sets the value of a pointer to data for a given virtual server and slot. The *slot must be -1 or a slot number returned from vs_alloc_slot. If *slot is -1, vs_set_data calls vs_alloc_slot implicitly and returns the new slot number in *slot.
Note that the stored pointer is maintained on a per-VirtualServer* basis, not a per-ID basis. Distinct VirtualServer*s from different configurations may exist simultaneously with the same virtual server IDs. However, since these are distinct VirtualServer*s, they each have their own VirtualServer*-specific data. As a result, vs_set_data should generally not be called outside of VSInitFunc processing (see vs_register_cb for an explanation of VSInitFunc processing).
void* vs_set_data(const VirtualServer* vs, int* slot, void* data);
Data on success, or NULL on failure.
const VirtualServer* vs represents the virtual server to set the pointer for.
int* slot is the slot number to store the pointer at.
void* data is the pointer to store.
vs_get_data, vs_alloc_slot, vs_register_cb
The vs_translate_uri function translates a URI as though it were part of a request for a specific virtual server. The returned string is the full operating system path.
The caller should FREE the returned string when done with it.
char* vs_translate_uri(const VirtualServer* vs, const char* uri);
A pointer to a string representing the full operating system path for the given URI. It is the caller's responsibility to FREE this string.
const VirtualServer* vs represents the virtual server for which to translate the URI.
const char* uri is the URI to translate to an operating system path.
The write filter method is called when output data is to be sent. Filters that modify or consume outgoing data should implement the write filter method.
Upon receiving control, a write implementation should first process the data as necessary, and then pass it on to the next filter layer; for example, by calling net_write(layer->lower, ...,). If the filter buffers outgoing data, it should implement the flush filter method.
int write(FilterLayer *layer, const void *buf, int amount);
The number of bytes consumed, which may be less than the requested amount if an error occurred.
FilterLayer *layer is the filter layer in which the filter is installed.
const void *buf is the buffer that contains the outgoing data.
int amount is the number of bytes in the buffer.
int myfilter_write(FilterLayer *layer, const void *buf, int amount) { return net_write(layer->lower, buf, amount); } See Also
The writev filter method is called when multiple buffers of output data are to be sent. Filters that modify or consume outgoing data may choose to implement the writev filter method.
If a filter implements the write filter method but not the writev filter method, the server automatically translates net_writev calls to net_write calls. As a result, filters interested in the outgoing data stream do not need to implement the writev filter method. However, for performance reasons, it is beneficial for filters that implement the write filter method to also implement the writev filter method.
int writev(FilterLayer *layer, const struct iovec *iov, int iov_size);
The number of bytes consumed, which may be less than the requested amount if an error occurred.
FilterLayer *layer is the filter layer the filter is installed in.
const struct iovec *iov is an array of iovec structures, each of which contains outgoing data.
int iov_size is the number of iovec structures in the iov array.
int myfilter_writev(FilterLayer *layer, const struct iovec *iov, int iov_size) { return net_writev(layer->lower, iov, iov_size); }