OPAE C API Programming Guide

Overview

The OPAE C library (libopae-c) is a lightweight user-space library that provides abstractions for FPGA resources in a compute environment. The OPAE C library builds on the driver stack that supports the FPGA device, abstracting hardware- and OS-specific details. It provides access to the underlying FPGA resources as a set of features available to software programs running on the host. These features include the acceleration logic preconfigured on the FPGA and functions to manage and reconfigure the FPGA. The library enables your applications to transparently and seamlessly benefit from FPGA-based acceleration.

Layered

By providing a unified C API, the library supports different FPGA integration and deployment models, ranging from single-node systems with one or a few FPGA devices to large-scale FPGA deployments in a data center. At one end of the spectrum, the API supports a simple application using a PCIe link to reconfigure the FPGA with different accelerator functions. At the other end of the spectrum, resource management and orchestration services in a data center can use this API to discover and select FPGA resources and then allocate them for use by acceleration workloads.

OPAE Role

The OPAE provides a common base layer for a wide range of applications without sacrificing performance or efficiency. The abstraction layer limits the details of the FPGA hardware that software applications must handle.

The OPAE provides consistent interfaces to crucial components of the platform. The OPAE does not constrain frameworks and applications by making optimizations with limited applicability. When the OPAE does provide convenience functions or optimizations, they are optional.

For example, the OPAE provides an interface to allocate physically contiguous buffers in system memory that user-space software and an accelerator can share. This interface enables the most basic feature set of allocating and sharing a large page of memory in one API call. However, it does not provide a malloc()-like interface backed by a memory pool or slab allocator. Higher layers of the software stack can make such domain-specific optimizations.

Intel Accelerator Stack Hardware Terminology

The following terms define the hardware and hardware processes involved in creating an accelerator function.

  • FPGA: Field Programmable Gate Array is a discrete or integrated device connecting to a host CPU via PCIe or other type of interconnects.
  • Accelerator Function Unit (AFU): The AFU is the supplied implementation of an accelerator, typically in HDL. AFUs implement a function such as compression, encryption, or mathematical operations. The Quartus Prime Pro software synthesizes the RTL logic into a bitstream.
  • Accelerator Function (AF): The AF is the compiled binary for an AFU. An AF is a raw binary file (.rbf) bitstream. A tool (fpgaconf) reconfigures the FPGA using an AF bitstream.
  • Reconfiguration: The process of reprogramming the FPGA with a different AF.

OPAE Software Concepts Reflected in the C API

The following OPAE data structures and functions integrate AFUs into the OPAE environment. The OPAE C API models these data structures and functions. For more information on the object models refer to the Object model section.

  • Accelerator: An accelerator is an allocable accelerator function implemented in an FPGA. An accelerator tracks the ownership of an AFU (or part of it) for a process that uses it. Multiple processes can share an accelerator.
  • Device: The OPAE enumerates and models two device types: the FPGA and the AFU.
  • Events: Events are asynchronous notifications. The FPGA driver triggers particular events to indicate error conditions. Accelerator logic can also define its own events. User applications can choose to be notified when particular events occur and respond appropriately.
  • Shared memory buffers: Software allocates shared memory buffers in user process memory on the host. Shared memory buffers facilitate data transfers between the user process and the accelerator that it owns.

OPAE Library

Linking with this library is straightforward. Code using the OPAE library should include the header file fpga.h. Taking the GCC compiler on Linux as an example, here is the simplest compile and link command:

gcc myprog.c -I</path/to/fpga.h> -L</path/to/libopae-c.so> -lopae-c -luuid -ljson-c -lpthread

The OPAE library uses the third-party `libuuid` and `libjson-c` libraries that are not distributed with
the OPAE library. Make sure to install these libraries.

Sample Code

The library source includes two code samples. Use these samples to learn how to call functions in the library. Build and run these samples to determine if your installation and environment are set up properly.

Refer to the Running the Hello FPGA Example chapter in the Intel® Acceleration Stack Quick Start Guide for for Intel Programmable Acceleration Card with Intel Arria® 10 GX FPGA for more information about using the sample code.

High-Level Directory Structure

Building and installing the OPAE library results in the following directory structure on the Linux OS. Windows and MacOS have similar directories and files.

Directory & Files Contents
include/opae Directory containing all header files
include/opae/fpga.h Top-level header for user code to include
include/opae/access.h Header file for accelerator acquire/release, MMIO, memory management, event handling, and so on
include/opae/bitstream.h Header file for bitstream manipulation functions
include/opae/common.h Header file for error reporting functions
include/opae/enum.h Header file for AFU enumeration functions
include/opae/manage.h Header file for FPGA management functions
include/opae/types.h Various type definitions
lib Directory containing shared library files
lib/libopae-c.so The shared dynamic library for linking with the user application
doc Directory containing API documentation
doc/html Directory for documentation of HTML format
doc/latex Directory for documentation of LaTex format
doc/man Directory for documentation of Unix man page format

Basic Application Flow

The figure below shows the basic application flow from the viewpoint of a user-process.

Basic

API Components

The API object model abstracts the physical FPGA device and available functions. It is a generalized model and extends to describe any FPGA type.

Object Models

  • fpga_objtype: An enum type that represents the type of an FPGA resource, either FPGA_DEVICE or FPGA_ACCELERATOR. An FPGA_DEVICE object corresponds to a physical FPGA device. Only FPGA_DEVICE objects can invoke management functions. The FPGA_ACCELERATOR represents an instance of an AFU.
  • fpga_token: An opaque type that represents a resource known to, but not necessarily owned by, the calling process. The calling process must own a resource before it can invoke functions of the resource.
  • fpga_handle: An opaque type that represents a resource owned by the calling process. The API functions fpgaOpen() and fpgaClose() acquire and release ownership of a resource that an fpga_handle represents. (Refer to the Functions section for more information.)
  • fpga_properties: An opaque type for a properties object. Your applications use these properties to query and search for appropriate resources. The FPGA Resource Properties section documents properties visible to your applications.
  • fpga_event_handle: An opaque handle the FPGA driver uses to notify your application about an event.
  • fpga_event_type: An enum type that represents the types of events. The following are valid values: FPGA_EVENT_INTERRUPT, FPGA_EVENT_ERROR, and FPGA_EVENT_POWER_THERMAL. (The Intel Programmable Acceleration Card (PAC) with Intel Arria 10 GX FPGA does not handle thermal and power events.)
  • fpga_result: An enum type to represent the result of an API function. If the function returns successfully the result is FPGA_OK. Otherwise, the result is the appropriate error codes. Function fpgaErrStr() translates an error code into human-readable strings.

Functions

The table below groups important API calls by their functionality. For more information about each of the functions, refer to the OPAE C API reference manual.

FPGA Resource Properties

Applications query resource properties by specifying the property name for Prop in the fpgaPropertiesGet[Prop]() and fpgaPropertiesSet[Prop]() functions. The FPGA and Accelerator columns state whether or not the Property is available for the FPGA or Accelerator objects.

Property FPGA Accelerator Description
Parent No Yes fpga_toke n of the parent object
ObjectType Yes Yes The type of the resource: either FPGA_DEVI CE or FPGA_ACCE LERATOR
Bus Yes Yes The bus number
Device Yes Yes The PCI device number
Function Yes Yes The PCI function number
SocketId Yes Yes The socket ID
DeviceId Yes Yes The device ID
NumSlots Yes No Number of AFU slots available on an FPGA_DEVI CE resource
BBSID Yes No The FPGA Interface Manager (FIM) ID of an FPGA_DEVI CE resource
BBSVersion Yes No The FIM version of an FPGA_DEVI CE resource
VendorId Yes No The vendor ID of an FPGA_DEVI CE resource
Model Yes No The model of an FPGA_DEVI CE resource
LocalMemorySize Yes No The local memory size of an FPGA_DEVI CE resource
Capabilities Yes No The capabilitie s of an FPGA_DEVI CE resource
GUID Yes Yes The GUID of an FPGA_DEVI CE or FPGA_ACCE LERATOR resource
NumMMIO No Yes The number of MMIO space of an FPGA_ACCE LERATOR resource
NumInterrupts No Yes The number of interrupts of an FPGA_ACCE LERATOR resource
AcceleratorState No Yes The state of an FPGA_ACCE LERATOR resource: either FPGA_ACCE LERATOR_ASS IGNED or FPGA_ACCE LERATOR_UNA SSIGNED

OPAE C API Return Codes

The OPAE C library returns a code for every exported public API function. FPGA_OK indicates successful completion of the requested operation. Any return code other than FPGA_OK indicates an error or unexpected behavior. When using the OPAE C API, always check the API return codes.

Error Code Description
FPGA_OK Operation completed successfully
FPGA_INVALID_PARAM Invalid parameter supplied
FPGA_BUSY Resource is busy
FPGA_EXCEPTION An exception occurred
FPGA_NOT_FOUND A required resource was not found
FPGA_NO_MEMORY Not enough memory to complete operation
FPGA_NOT_SUPPORTED Requested operation is not supported
FPGA_NO_DRIVER Driver is not loaded
FPGA_NO_DAEMON FPGA Daemon (fpgad) is not running
FPGA_NO_ACCESS Insufficient privileges or permissions
FPGA_RECONF_ERROR Error while reconfiguring FPGA

Usage Models

Query and Search for a Resource

The user-code first populates an fpga_properties object with the required properties. Then, fpgaEnumerate() searches for matching resources. fpgaEnumerate() may return more than one matching resource.

#include "fpga/fpga.h"

fpga_guid               guid;
fpga_properties         filter = NULL;
fpga_result             res;
fpga_token              tokens[MAX_NUM_TOKENS];
uint32_t                num_matches = 0;

/* Start with an empty properties object */
res = fpgaGetProperties(NULL, &filter);

/* Populate the properties object with required values.
   In this case, search for accelerators that matches
   the specified GUID.
*/
uuid_parse(GUID, guid);
res = fpgaPropertiesSetObjectType(filter, FPGA_ACCELERATOR);
res = fpgaPropertiesSetGuid(filter, guid);

/* Query the number of matching resources */
res = fpgaEnumerate(&filter, 1, NULL, 1, &num_matches);

/* Return tokens for all matching resources */
res = fpgaEnumerate(&filter, 1, tokens, num_matches, &num_matches);

/* Destroy the properties object */
res = fpgaDestroyProperties(&filter);

/* More code */
......

/* Destroy tokens */
for (uint32_t i = 0; i < num_matches; ++i) {
    res = fpgaDestroyToken(tokens[i]);
}

The fpgaEnumerate() function can take multiple fpga_propertiesobjects in an array. In such cases, the function performs a logical OR of the properties object and returns resources that match any of the multiple properties. The fpga_token objects that fpgaEnumerate() returns, do not signify ownership. To acquire ownership of a resource represented by a token, pass the token to fpgaOpen().

Acquire and Release a Resource

Use fpgaOpen() and fpgaClose() to acquire and release ownership of a resource. The calling process must own the resource before it can initiate MMIO, access share memory buffers, and use functions offered by the resource.

#include "fpga/fpga.h"

fpga_handle             handle;
fpga_result             res;

/* Acquire ownership of a resource that
`fpgaEnumerate()` previously returned as a token */

res = fpgaOpen(token, &handle);

/* More code */
......

/* Release the ownership */
res = fpgaClose(handle);

Shared Memory Buffer

This code snippet shows how to prepare a memory buffer to be shared between the calling process and an accelerator.

#include "fpga/fpga.h"

fpga_handle             handle;
fpga_result             res;

/* Hint for the virtual address of the buffer */
volatile uint64_t       *addr_hint;
/* An ID we can use to reference the buffer later */
uint32_t                bufid;
/* Flag to indicate whether or not the buffer is preallocated */
int                     flag = 0;

/* Allocate (if necessary), pin, and map a buffer to be accessible
   by an accelerator
*/
res = fpgaPrepareBuffer(handle, BUF_SIZE, (void **) &addr_hint,
                        &bufid, flag);

/* The actual address mapped to the buffer */
uint64_t                iova;
/* Get the IO virtual address for the buffer */
res = fpgaGetIOVA(handle, bufid, &iova);

/* Inform the accelerator about the virtual address by writing to its mapped
   register file
*/
......

/* More code */
......

/* Release the shared buffer */
res = fpgaReleaseBuffer(handle, bufid);
The `flag` variable can take a constant `FPGA_BUF_PREALLOCATED` to
indicate that the calling process has already allocated the address space
that `addr_hint` points to.

MMIO

This code snippet shows how to map and unmap the register file of an accelerator into the calling process’s virtual memory space.

#include "fpga/fpga.h"

fpga_handle             handle;
fpga_result             res;

/* Index of the MMIO space. There might be multiple spaces on an accelerator */
uint32_t                mmio_num = 0;
/* Mapped address */
uint64_t                mmio_addr;

/* Map MMIO */
res = fpgaMapMMIO(handle, mmio_num, &mmio_addr);

/* Write to a 32-bit value to the mapped register file at a certain byte
   offset.

   CSR_CTL is the offset in the mapped space to where the value will be
   written. It's defined elsewhere.
*/
res = fpgaWriteMMIO32(handle, mmio_num, CSR_CTL, value);

/* More code */
......

/* Unmap MMIO */
res = fpgaUnmapMMIO(handle, mmio_num);
Every AFU has its own register adress space and its own protocol to control operation through
the registers.