Maxeler Technology. Maximum Performance Computing (MPC) changes the classical computer science optimization from ease-of-programming to maximizing performance and minimizing total cost of computing. Performance is optimized by constructing compute engines to generate one result per clock cycle, wherever possible. Ease-of-programming is still important but takes second place to performance, computational density and power consumption. As such, MPC focuses on mission critical, long running computations with large datasets and complex numerical and intense statistical content. Maxeler drives MPC via „Multiscale Dataflow Computing‟. This section summarises the components of MPC, illustrates how MPC dataflow computers are programmed and how the resulting tools are presented to the users. An overview of MPC, along with detailed examples of applications, is available in [27, 28]. One Maxeler Dataflow Engine (DFE) combines 10^4 arithmetic units with 10^7 bytes of local fast SRAM and 10^11 bytes of 6-channel large DRAM. MaxelerOS allows the DFEs and CPU to run in parallel, so while the DFEs are processing the data, the CPU typically performs the non-time- critical parts of an application. Maxeler's MPC programming environment comprises of several components: ● MaxCompiler, a meta-programming library used to produce DFE configurations by way of the MaxJ programming language, which is an extended form of Java with operator overloading. The compute kernels handling the data-intensive part of the application and the associated manager, which orchestrates data movement within the DFE, are written using this language. MaxJ is a Hardware Description language which produces the computational intensive part of the design configuration. ● the SLiC (Simple Live CPU) interface, which is Maxeler's application programming interface for CPU-DFE integration; ● MaxelerOS, a software layer between the SLiC interface, operating system and hardware, which manages DFE hardware and CPU-DFE communication in a way transparent to the user; ● MaxIDE, a specialised integrated development environment for MaxJ and DFE design, a fast DFE software simulator and a comprehensive debug environment used during development. These components and their use are described in details in [29, 30]. In such an MPC system, the CPUs are in control and drive the computations on the DFEs. The data-intensive parts of the computations are typically confined to the DFE configuration and are made available through the SLiC interface. A...
