How to exchange large data buffers with the coprocessor - princi

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Introduction

As explained in "Exchanging_buffers_with_the_coprocessor", the RPMsg protocol may be not efficient enough to directly exchange large buffers between the Cortexes. In this case implementing the indirect buffer exchange mode is recommended:

  • allocate contiguous buffers to store the data to exchange
  • use RPMsg to exchange references to these buffers with the remote processor.

This article gives an example mechanism that can be implemented to exchange indirect buffers between a main processor and a coprocessor.

Architecture overview

This architecture example relies on the rpmsg_sdb linux driver.

文件:Copro-sw-ipc-big-data.png

  • On Cortex-A:
  • The rpmsg_sdb Linux driver implements the service to allocate and share buffers with the Cortex-M.
  • The Linux application requests and memory-maps (mmap) the buffers needed to access the associated memory.
  • On Cortex-M:
  • The application has to implement the "rpmsg-sdb-channel" RPMsg service to manage the buffer information.
  • A DMA can be used to transfer data to/from DDR.

Refer to How to exchange large data buffers with the coprocessor - example for an example.

rpmsg_sdb driver

The RPMsg shared data buffer driver example is in charge of:

  • Allocating large buffers in contiguous memory (DDR) and memory mapping them (mmap) for use by an application.
  • implementing the RPMsg service to share buffer information (address, size) with the coprocessor.
  • Sending events to a Linux application (relying on the eventfd interface) when buffers are available (on RPMsg message reception).
Info.png This driver is provided as example. It implements only the transfer from Cortex-M to cortex-A

Configuration

Kernel configuration

No kernel configuration is needed. The rpmsg_sdb Linux driver is proposed as module and can be installed using the associated Yocto recipe.

Device tree

No device tree declaration is needed. The rpmsg_sdb driver is registered as an RPMsg driver. it is probed when the remote processor creates the "rpmsg-sdb-channel" service.

Source code

The source code is available in the rpsmg-sdb-mod Yocto recipe.

How to use

User space interface

The rpmsg_sdb driver exposes a "/dev/rpmsg_sdb" sysfs that offers an interface to allocate and manage the shared buffers.

  • open/close: get/release file descriptor.
  int fd;
  fd= open('/dev/rpmsg_sdb');
  close(fd);
  • mmap: allocate and map memories
  void *buff0_id, *buff1_id;
 
  buff0_id = mmap(NULL, size,  PROT_READ | PROT_WRITE, 	MAP_PRIVATE, fd, 0);
  buff1_id = mmap(NULL, size,  PROT_READ | PROT_WRITE, 	MAP_PRIVATE, fd, 0);
  • RPMSG_SDB_IOCTL_SET_EFD ioctl: register event for a buffer
  typedef struct
  {
  	int bufferId, eventfd;
  } rpmsg_sdb_ioctl_set_efd;
  
  int efd[NB_BUF];
  rpmsg_sdb_ioctl_set_efd q_set_efd;

  for (i=0;i<NB_BUF;i++){
	/* Create the evenfd, and sent it to kernel driver, for notification of buffer full */
	efd[i] = eventfd(0, 0);
  }
  q_set_efd.bufferId = i;  /* i is the index of the buffer */
  q_set_efd.eventfd = efd[i];
  
  ioctl(fd, RPMSG_SDB_IOCTL_SET_EFD, buff0_id, &q_set_efd);
  • RPMSG_SDB_IOCTL_GET_DATA_SIZE ioctl : get the size of a buffer
  typedef struct
  {
  	int bufferId;
  	uint32_t size;
  } rpmsg_sdb_ioctl_get_data_size;
  
  rpmsg_sdb_ioctl_get_data_size q_get_data_size;

  ioctl(fd, RPMSG_SDB_IOCTL_GET_DATA_SIZE, buff0_id, eventfd);

p*manage event

  while (1) {
	ret = poll(fds, NB_BUF, TIMEOUT * 1000);
	if (ret < 0) {
		perror("poll()");
		break;
	} else if (ret) {
		printf("Data is available now.\n");
	} else if (ret == 0) {
		printf("No data within five seconds.\n");
		break;
	}
	for (j=0;j<NB_BUF;j++){
		if (fds[j].revents & POLLIN) {
			/* Event received for the buffer j: New data is available for buffer j */
		}
	}
}

RPMsg messaging

The RPMsg protocol is used for communication with the Cortex-M:

  • Information about the buffer allocated and mmaped is sent to the Cortex-M.
The message is structured in a string with following format: "BxAyyyyyyyyLzzzzzzzz"
  • x: buffer index (32 bits, decimal format, no leading zero)
  • yyyyyyyy: physical address of the buffer in DDR (32 bits, 8-digit hexadecimal format, leading zero)
  • zzzzzzzz: length of the buffer (32 bits, 8-digit hexadecimal format, leading zero).
  • Buffer filled event received from the Cortex-M:
When the Cortex-M4 has filled a buffer it can inform the Linux application by sending an RPMsg with following string format : "BxLzzzzzzzz"'.
  • x: buffer index (32 bits, decimal format, no leading zero)
  • zzzzzzzz: length of the buffer (32 bits, 8-digit hexadecimal format, leading zero).
On reception of this message the rpmsg_sdb driver sends an event to the application.


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