libtracefs(3) ============= NAME ---- tracefs_cpu_open_mapped, tracefs_cpu_is_mapped, tracefs_mapped_is_supported, tracefs_cpu_map, tracefs_cpu_unmap - Memory mapping of the ring buffer SYNOPSIS -------- [verse] -- *#include * bool *tracefs_cpu_is_mapped*(struct tracefs_cpu pass:[*]tcpu); bool *tracefs_mapped_is_supported*(void); int *tracefs_cpu_map*(struct tracefs_cpu pass:[*]tcpu); void *tracefs_cpu_unmap*(struct tracefs_cpu pass:[*]tcpu); struct tracefs_cpu pass:[*]*tracefs_cpu_open_mapped*(struct tracefs_instance pass:[*]instance, int cpu, bool nonblock); -- DESCRIPTION ----------- If the trace_pipe_raw supports memory mapping, this is usually a more efficient method to stream data from the kernel ring buffer than by reading it, as it does not require copying the memory that is being read. If memory mapping is supported by the kernel and the application asks to use the memory mapping via either *tracefs_cpu_map()* or by *tracefs_cpu_open_mapped()* then the functions *tracefs_cpu_read*(3) and *tracefs_cpu_read_buf*(3) will use the mapping directly instead of calling the read system call. Note, mapping will cause *tracefs_cpu_buffered_read*(3) and *tracefs_cpu_buffered_read_buf*(3) to act just like *tracefs_cpu_read*(3) and *tracefs_cpu_read_buf*(3) respectively as it doesn't make sense to use a splice pipe when mapped. The kernel will do a copy for splice reads on mapping, and then another copy in the function when it can avoid the copying if the ring buffer is memory mapped. If the _tcpu_ is memory mapped it will also force *tracefs_cpu_write*(3) and *tracefs_cpu_pipe*(3) to copy from the mapping instead of using splice. Thus care must be used when determining to map the ring buffer or not, and why it does not get mapped by default. The *tracefs_cpu_is_mapped()* function will return true if _tcpu_ currently has its ring buffer memory mapped and false otherwise. This does not return whether or not that the kernel supports memory mapping, but that can usually be determined by calling *tracefs_cpu_map()*. The *tracefs_mapped_is_supported()* returns true if the ring buffer can be memory mapped. The *tracefs_cpu_map()* function will attempt to map the ring buffer associated to _tcpu_ if it is not already mapped. The *tracefs_cpu_unmap()* function will unmap the ring buffer associated to _tcpu_ if it is mapped. The *tracefs_cpu_open_mapped()* is equivalent to calling *tracefs_cpu_open*(3) followed by *tracefs_cpu_map()* on the returned _tcpu_ of *tracefs_cpu_open*(3). Note, this will still succeed if the mapping fails, in which case it acts the same as *tracefs_cpu_open*(3). If knowing if the mapping succeed or not, *tracefs_cpu_is_mapped()* should be called on the return _tcpu_. RETURN VALUE ------------ *tracefs_cpu_is_mapped()* returns true if the given _tcpu_ has its ring buffer memory mapped or false otherwise. *tracefs_mapped_is_supported()* returns true if the tracing ring buffer can be memory mapped or false if it cannot be or an error occurred. *tracefs_cpu_map()* returns 0 on success and -1 on error in mapping. If 0 is returned then *tracefs_cpu_is_mapped()* will return true afterward, or false if the mapping failed. *tracefs_cpu_open_mapped()* returns an allocated tracefs_cpu on success of creation regardless if it succeed in mapping the ring buffer or not. It returns NULL for the same reasons *tracefs_cpu_open*(3) returns NULL. If success of mapping is to be known, then calling *tracefs_cpu_is_mapped()* afterward is required. EXAMPLE ------- [source,c] -- #include #include #include static void read_subbuf(struct tep_handle *tep, struct kbuffer *kbuf) { static struct trace_seq seq; struct tep_record record; int missed_events; if (seq.buffer) trace_seq_reset(&seq); else trace_seq_init(&seq); while ((record.data = kbuffer_read_event(kbuf, &record.ts))) { record.size = kbuffer_event_size(kbuf); missed_events = kbuffer_missed_events(kbuf); if (missed_events) { printf("[MISSED EVENTS"); if (missed_events > 0) printf(": %d]\n", missed_events); else printf("]\n"); } kbuffer_next_event(kbuf, NULL); tep_print_event(tep, &seq, &record, "%s-%d %6.1000d\t%s: %s\n", TEP_PRINT_COMM, TEP_PRINT_PID, TEP_PRINT_TIME, TEP_PRINT_NAME, TEP_PRINT_INFO); trace_seq_do_printf(&seq); trace_seq_reset(&seq); } } int main (int argc, char **argv) { struct tracefs_cpu *tcpu; struct tep_handle *tep; struct kbuffer *kbuf; bool mapped; int cpu; if (argc < 2 || !isdigit(argv[1][0])) { printf("usage: %s cpu\n\n", argv[0]); exit(-1); } cpu = atoi(argv[1]); tep = tracefs_local_events(NULL); if (!tep) { perror("Reading trace event formats"); exit(-1); } tcpu = tracefs_cpu_open_mapped(NULL, cpu, 0); if (!tcpu) { perror("Open CPU 0 file"); exit(-1); } /* * If this kernel supports mapping, use normal read, * otherwise use the piped buffer read, although if * the mapping succeeded, tracefs_cpu_buffered_read_buf() * acts the same as tracefs_cpu_read_buf(). But this is just * an example on how to use tracefs_cpu_is_mapped(). */ mapped = tracefs_cpu_is_mapped(tcpu); if (!mapped) printf("Was not able to map, falling back to buffered read\n"); while ((kbuf = mapped ? tracefs_cpu_read_buf(tcpu, true) : tracefs_cpu_buffered_read_buf(tcpu, true))) { read_subbuf(tep, kbuf); } kbuf = tracefs_cpu_flush_buf(tcpu); if (kbuf) read_subbuf(tep, kbuf); tracefs_cpu_close(tcpu); tep_free(tep); return 0; } -- FILES ----- [verse] -- *tracefs.h* Header file to include in order to have access to the library APIs. *-ltracefs* Linker switch to add when building a program that uses the library. -- SEE ALSO -------- *tracefs_cpu_open*(3), *tracefs_cpu_read*(3), *tracefs_cpu_read_buf*(3), *tracefs_cpu_buffered_read*(3), *tracefs_cpu_buffered_read_buf*(3), *libtracefs*(3), *libtraceevent*(3), *trace-cmd*(1) AUTHOR ------ [verse] -- *Steven Rostedt* -- REPORTING BUGS -------------- Report bugs to LICENSE ------- libtracefs is Free Software licensed under the GNU LGPL 2.1 RESOURCES --------- https://git.kernel.org/pub/scm/libs/libtrace/libtracefs.git/ COPYING ------- Copyright \(C) 2022 Google, Inc. Free use of this software is granted under the terms of the GNU Public License (GPL).