PicoBlaze is the designation of a series of three free soft processor cores from Xilinx for use in their FPGA and CPLD products. They are based on a RISC architecture of 8 bits and can reach speeds up to 100 MIPS on the Virtex 4 FPGA's family. The processors have an 8-bit address and data port for access to a wide range of peripherals. The license of the cores allows their free use, albeit only on Xilinx devices, and they come with development tools. Third party tools are available from Mediatronix and others. Also PacoBlaze, a behavioral and device independent implementation of the cores exists and is released under the BSD License.
The PicoBlaze design was originally named KCPSM which stands for "Constant(K) Coded Programmable State Machine" (formerly "Ken Chapman's PSM"). Ken Chapman was the Xilinx systems designer who devised and implemented the microcontroller.
component kcpsm3 is port ( address : out std_logic_vector(9 downto 0); instruction : in std_logic_vector(17 downto 0); port_id : out std_logic_vector(7 downto 0); write_strobe : out std_logic; out_port : out std_logic_vector(7 downto 0); read_strobe : out std_logic; in_port : in std_logic_vector(7 downto 0); interrupt : in std_logic; interrupt_ack : out std_logic; reset : in std_logic; clk : in std_logic ); end component;
All instructions execute in two clock cycles, making performance of the core instruction set deterministic. Interrupt response is not more than five clock cycles. As a resource optimization, it is possible for two PicoBlaze cores to share the same 1k x 18 instruction PROM, taking advantage of the dual-ported implementation of this block on Xilinx FPGAs.
Xilinx documents the PicoBlaze as requiring just 96 FPGA slices. The small implementation size is achieved in part through a fairly rigid separation of the instruction sequencing side (program counter, call-return stack, implied stack pointer, and interrupt enable bit) from the execution side (ALU, register file, scratchpad RAM, Z/C status bits). The only information which flows from the compute side to the sequencing side are the zero and carry ALU status bits, when tested by the conditional JUMP and CALL instructions. It is not possible to implement computed jumps or function pointers. The only information which flows from the sequencing side to the execution side are operand fields: destination register (4 bits), ALU opcode (six bits), optional source register (4 bits), optional 8-bit immediate value/port-address, optional 6-bit scratchpad address. There is no mechanism to inspect the value of the stack pointer, the contents of the 31-entry stack, the interrupt enable bit, or the contents of program memory.
The instruction sequencing side does not contain an adder, so relative branches and position independent code are not possible. All jump and call addresses are absolute.
The PicoBlaze is poorly suited to programming in compiled languages such as C. In addition to the lack of support for function pointers, there are no instructions or addressing modes to expedite a stack-based calling convention. For PicoBlaze it takes two instructions to implement PUSH or POP and two instructions to implement relative addressing off a software-designated stack pointer. The PicoBlaze is better suited to a hand-optimized register-based calling convention. This does not preclude the use of a Forth-like data stack, and in fact the PicoBlaze is well suited to this approach, if the 64-byte scratchpad memory offers sufficient space.
- PicoBlaze on the Xilinx website
- PicoBlaze product brief
- PicoBlaze user manual
- TechXclusives: Creating Embedded Microcontrollers (Programmable State Machines) PDF
- PicoBlaze user resources
- PicoBlaze Debugger, Software and RTL Hardware development with ModelSim
- Open source Picoblaze assembler
- pBlazASM, an open source assembler and simulator for Windows
- pBlazIDE, an assembler IDE for Windows
- kpicosim, an open source assembler IDE for Linux
- openPICIDE, an open source assembler IDE for Linux, MAC and Windows
- PacoBlaze: an open source synthesizable and behavioral Verilog clone of PicoBlaze
- Implementation of picoblaze in LabVIEW FPGA on the Xilinx Spartan 3E Starter board
- "PicoBlaze 8-bit Microcontroller". Xilinx, Inc. Retrieved 2007-06-25.
- "PicoBlaze 8-bit Embedded Microcontroller User Guide". Xilinx, Inc. Retrieved 2007-06-25.
- Pong P. Chu (2008). FPGA Prototyping by VHDL Examples: Xilinx Spartan-3 Version. Wiley & Sons. ISBN 978-0-470-18531-5.