picorv32/README.md

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PicoRV32 - A Size-Optimized RISC-V CPU
======================================
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PicoRV32 is a CPU core that implements the [RISC-V RV32IMC Instruction Set](http://riscv.org/).
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It can be configured as RV32E, RV32I, RV32IC, RV32IM, or RV32IMC core, and optionally
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contains a built-in interrupt controller.
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Tools (gcc, binutils, etc..) can be obtained via the [RISC-V Website](http://riscv.org/download.html#tab_tools).
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The examples bundled with PicoRV32 expect various RV32 toolchains to be installed in `/opt/riscv32i[m][c]`. See
the [build instructions below](#building-a-pure-rv32i-toolchain) for details.
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PicoRV32 is free and open hardware licensed under the [ISC license](http://en.wikipedia.org/wiki/ISC_license)
(a license that is similar in terms to the MIT license or the 2-clause BSD license).
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#### Table of Contents
- [Features and Typical Applications](#features-and-typical-applications)
- [Files in this Repository](#files-in-this-repository)
- [Verilog Module Parameters](#verilog-module-parameters)
- [Cycles per Instruction Performance](#cycles-per-instruction-performance)
- [PicoRV32 Native Memory Interface](#picorv32-native-memory-interface)
- [Pico Co-Processor Interface (PCPI)](#pico-co-processor-interface-pcpi)
- [Custom Instructions for IRQ Handling](#custom-instructions-for-irq-handling)
- [Building a pure RV32I Toolchain](#building-a-pure-rv32i-toolchain)
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- [Linking binaries with newlib for PicoRV32](#linking-binaries-with-newlib-for-picorv32)
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- [Evaluation: Timing and Utilization on Xilinx 7-Series FPGAs](#evaluation-timing-and-utilization-on-xilinx-7-series-fpgas)
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Features and Typical Applications
---------------------------------
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- Small (750-2000 LUTs in 7-Series Xilinx Architecture)
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- High f<sub>max</sub> (250-450 MHz on 7-Series Xilinx FPGAs)
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- Selectable native memory interface or AXI4-Lite master
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- Optional IRQ support (using a simple custom ISA)
- Optional Co-Processor Interface
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This CPU is meant to be used as auxiliary processor in FPGA designs and ASICs. Due
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to its high f<sub>max</sub> it can be integrated in most existing designs without crossing
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clock domains. When operated on a lower frequency, it will have a lot of timing
slack and thus can be added to a design without compromising timing closure.
For even smaller size it is possible disable support for registers `x16`..`x31` as
well as `RDCYCLE[H]`, `RDTIME[H]`, and `RDINSTRET[H]` instructions, turning the
processor into an RV32E core.
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Furthermore it is possible to choose between a dual-port and a single-port
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register file implementation. The former provides better performance while
the latter results in a smaller core.
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*Note: In architectures that implement the register file in dedicated memory
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resources, such as many FPGAs, disabling the 16 upper registers and/or
disabling the dual-port register file may not further reduce the core size.*
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The core exists in two variations: `picorv32` and `picorv32_axi`. The former
provides a simple native memory interface, that is easy to use in simple
environments, and the latter provides an AXI-4 Lite Master interface that can
easily be integrated with existing systems that are already using the AXI
standard.
A separate core `picorv32_axi_adapter` is provided to bridge between the native
memory interface and AXI4. This core can be used to create custom cores that
include one or more PicoRV32 cores together with local RAM, ROM, and
memory-mapped peripherals, communicating with each other using the native
interface, and communicating with the outside world via AXI4.
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The optional IRQ feature can be used to react to events from the outside, implement
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fault handlers, or catch instructions from a larger ISA and emulate them in
software.
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The optional Pico Co-Processor Interface (PCPI) can be used to implement
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non-branching instructions in an external coprocessor. Implementations
of PCPI cores that implement the M Standard Extension instructions
`MUL[H[SU|U]]` and `DIV[U]/REM[U]` are included in this package.
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Files in this Repository
------------------------
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#### README.md
You are reading it right now.
#### picorv32.v
This Verilog file contains the following Verilog modules:
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| Module | Description |
| ------------------------ | --------------------------------------------------------------------- |
| `picorv32` | The PicoRV32 CPU |
| `picorv32_axi` | The version of the CPU with AXI4-Lite interface |
| `picorv32_axi_adapter` | Adapter from PicoRV32 Memory Interface to AXI4-Lite |
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| `picorv32_wb` | The version of the CPU with Wishbone Master interface |
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| `picorv32_pcpi_mul` | A PCPI core that implements the `MUL[H[SU|U]]` instructions |
| `picorv32_pcpi_fast_mul` | A version of `picorv32_pcpi_fast_mul` using a single cycle multiplier |
| `picorv32_pcpi_div` | A PCPI core that implements the `DIV[U]/REM[U]` instructions |
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Simply copy this file into your project.
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#### Makefile and testbenches
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A basic test environment. Run `make test` to run the standard test bench (`testbench.v`)
in the standard configurations. There are other test benches and configurations. See
the `test_*` make target in the Makefile for details.
Run `make test_ez` to run `testbench_ez.v`, a very simple test bench that does
not require an external firmware .hex file. This can be useful in environments
where the RISC-V compiler toolchain is not available.
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*Note: The test bench is using Icarus Verilog. However, Icarus Verilog 0.9.7
(the latest release at the time of writing) has a few bugs that prevent the
test bench from running. Upgrade to the latest github master of Icarus Verilog
to run the test bench.*
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#### firmware/
A simple test firmware. This runs the basic tests from `tests/`, some C code, tests IRQ
handling and the multiply PCPI core.
All the code in `firmware/` is in the public domain. Simply copy whatever you can use.
#### tests/
Simple instruction-level tests from [riscv-tests](https://github.com/riscv/riscv-tests).
#### dhrystone/
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Another simple test firmware that runs the Dhrystone benchmark.
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#### picosoc/
A simple example SoC using PicoRV32 that can execute code directly from a
memory mapped SPI flash.
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#### scripts/
Various scripts and examples for different (synthesis) tools and hardware architectures.
Verilog Module Parameters
-------------------------
The following Verilog module parameters can be used to configure the PicoRV32
core.
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#### ENABLE_COUNTERS (default = 1)
This parameter enables support for the `RDCYCLE[H]`, `RDTIME[H]`, and
`RDINSTRET[H]` instructions. This instructions will cause a hardware
trap (like any other unsupported instruction) if `ENABLE_COUNTERS` is set to zero.
*Note: Strictly speaking the `RDCYCLE[H]`, `RDTIME[H]`, and `RDINSTRET[H]`
instructions are not optional for an RV32I core. But chances are they are not
going to be missed after the application code has been debugged and profiled.
This instructions are optional for an RV32E core.*
#### ENABLE_COUNTERS64 (default = 1)
This parameter enables support for the `RDCYCLEH`, `RDTIMEH`, and `RDINSTRETH`
instructions. If this parameter is set to 0, and `ENABLE_COUNTERS` is set to 1,
then only the `RDCYCLE`, `RDTIME`, and `RDINSTRET` instructions are available.
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#### ENABLE_REGS_16_31 (default = 1)
This parameter enables support for registers the `x16`..`x31`. The RV32E ISA
excludes this registers. However, the RV32E ISA spec requires a hardware trap
for when code tries to access this registers. This is not implemented in PicoRV32.
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#### ENABLE_REGS_DUALPORT (default = 1)
The register file can be implemented with two or one read ports. A dual ported
register file improves performance a bit, but can also increase the size of
the core.
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#### LATCHED_MEM_RDATA (default = 0)
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Set this to 1 if the `mem_rdata` is kept stable by the external circuit after a
transaction. In the default configuration the PicoRV32 core only expects the
`mem_rdata` input to be valid in the cycle with `mem_valid && mem_ready` and
latches the value internally.
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This parameter is only available for the `picorv32` core. In the
`picorv32_axi` core this is implicitly set to 0.
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#### TWO_STAGE_SHIFT (default = 1)
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By default shift operations are performed in two stages: first shifts in units
of 4 bits and then shifts in units of 1 bit. This speeds up shift operations,
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but adds additional hardware. Set this parameter to 0 to disable the two-stage
shift to further reduce the size of the core.
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#### BARREL_SHIFTER (default = 0)
By default shift operations are performed by successively shifting by a
small amount (see `TWO_STAGE_SHIFT` above). With this option set, a barrel
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shifter is used instead.
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#### TWO_CYCLE_COMPARE (default = 0)
This relaxes the longest data path a bit by adding an additional FF stage
at the cost of adding an additional clock cycle delay to the conditional
branch instructions.
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*Note: Enabling this parameter will be most effective when retiming (aka
"register balancing") is enabled in the synthesis flow.*
#### TWO_CYCLE_ALU (default = 0)
This adds an additional FF stage in the ALU data path, improving timing
at the cost of an additional clock cycle for all instructions that use
the ALU.
*Note: Enabling this parameter will be most effective when retiming (aka
"register balancing") is enabled in the synthesis flow.*
#### COMPRESSED_ISA (default = 0)
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This enables support for the RISC-V Compressed Instruction Set.
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#### CATCH_MISALIGN (default = 1)
Set this to 0 to disable the circuitry for catching misaligned memory
accesses.
#### CATCH_ILLINSN (default = 1)
Set this to 0 to disable the circuitry for catching illegal instructions.
The core will still trap on `EBREAK` instructions with this option
set to 0. With IRQs enabled, an `EBREAK` normally triggers an IRQ 1. With
this option set to 0, an `EBREAK` will trap the processor without
triggering an interrupt.
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#### ENABLE_PCPI (default = 0)
Set this to 1 to enable the Pico Co-Processor Interface (PCPI).
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#### ENABLE_MUL (default = 0)
This parameter internally enables PCPI and instantiates the `picorv32_pcpi_mul`
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core that implements the `MUL[H[SU|U]]` instructions. The external PCPI
interface only becomes functional when ENABLE_PCPI is set as well.
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#### ENABLE_FAST_MUL (default = 0)
This parameter internally enables PCPI and instantiates the `picorv32_pcpi_fast_mul`
core that implements the `MUL[H[SU|U]]` instructions. The external PCPI
interface only becomes functional when ENABLE_PCPI is set as well.
If both ENABLE_MUL and ENABLE_FAST_MUL are set then the ENABLE_MUL setting
will be ignored and the fast multiplier core will be instantiated.
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#### ENABLE_DIV (default = 0)
This parameter internally enables PCPI and instantiates the `picorv32_pcpi_div`
core that implements the `DIV[U]/REM[U]` instructions. The external PCPI
interface only becomes functional when ENABLE_PCPI is set as well.
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#### ENABLE_IRQ (default = 0)
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Set this to 1 to enable IRQs. (see "Custom Instructions for IRQ Handling" below
for a discussion of IRQs)
#### ENABLE_IRQ_QREGS (default = 1)
Set this to 0 to disable support for the `getq` and `setq` instructions. Without
the q-registers, the irq return address will be stored in x3 (gp) and the IRQ
bitmask in x4 (tp), the global pointer and thread pointer registers according
to the RISC-V ABI. Code generated from ordinary C code will not interact with
those registers.
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Support for q-registers is always disabled when ENABLE_IRQ is set to 0.
#### ENABLE_IRQ_TIMER (default = 1)
Set this to 0 to disable support for the `timer` instruction.
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Support for the timer is always disabled when ENABLE_IRQ is set to 0.
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#### ENABLE_TRACE (default = 0)
Produce an execution trace using the `trace_valid` and `trace_data` output ports.
For a demontration of this feature run `make test_vcd` to create a trace file
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and then run `python3 showtrace.py testbench.trace firmware/firmware.elf` to decode
it.
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#### REGS_INIT_ZERO (default = 0)
Set this to 1 to initialize all registers to zero (using a Verilog `initial` block).
This can be useful for simulation or formal verification.
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#### MASKED_IRQ (default = 32'h 0000_0000)
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A 1 bit in this bitmask corresponds to a permanently disabled IRQ.
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#### LATCHED_IRQ (default = 32'h ffff_ffff)
A 1 bit in this bitmask indicates that the corresponding IRQ is "latched", i.e.
when the IRQ line is high for only one cycle, the interrupt will be marked as
pending and stay pending until the interrupt handler is called (aka "pulse
interrupts" or "edge-triggered interrupts").
Set a bit in this bitmask to 0 to convert an interrupt line to operate
as "level sensitive" interrupt.
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#### PROGADDR_RESET (default = 32'h 0000_0000)
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The start address of the program.
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#### PROGADDR_IRQ (default = 32'h 0000_0010)
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The start address of the interrupt handler.
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#### STACKADDR (default = 32'h ffff_ffff)
When this parameter has a value different from 0xffffffff, then register `x2` (the
stack pointer) is initialized to this value on reset. (All other registers remain
uninitialized.) Note that the RISC-V calling convention requires the stack pointer
to be aligned on 16 bytes boundaries (4 bytes for the RV32I soft float calling
convention).
Cycles per Instruction Performance
----------------------------------
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*A short reminder: This core is optimized for size and f<sub>max</sub>, not performance.*
Unless stated otherwise, the following numbers apply to a PicoRV32 with
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ENABLE_REGS_DUALPORT active and connected to a memory that can accommodate
requests within one clock cycle.
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The average Cycles per Instruction (CPI) is approximately 4, depending on the mix of
instructions in the code. The CPI numbers for the individual instructions can
be found in the table below. The column "CPI (SP)" contains the CPI numbers for
a core built without ENABLE_REGS_DUALPORT.
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| Instruction | CPI | CPI (SP) |
| ---------------------| ----:| --------:|
| direct jump (jal) | 3 | 3 |
| ALU reg + immediate | 3 | 3 |
| ALU reg + reg | 3 | 4 |
| branch (not taken) | 3 | 4 |
| memory load | 5 | 5 |
| memory store | 5 | 6 |
| branch (taken) | 5 | 6 |
| indirect jump (jalr) | 6 | 6 |
| shift operations | 4-14 | 4-15 |
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When `ENABLE_MUL` is activated, then a `MUL` instruction will execute
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in 40 cycles and a `MULH[SU|U]` instruction will execute in 72 cycles.
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When `ENABLE_DIV` is activated, then a `DIV[U]/REM[U]` instruction will
execute in 40 cycles.
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When `BARREL_SHIFTER` is activated, a shift operation takes as long as
any other ALU operation.
The following dhrystone benchmark results are for a core with enabled
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`ENABLE_FAST_MUL`, `ENABLE_DIV`, and `BARREL_SHIFTER` options.
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Dhrystone benchmark results: 0.516 DMIPS/MHz (908 Dhrystones/Second/MHz)
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For the Dhrystone benchmark the average CPI is 4.100.
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Without using the look-ahead memory interface (usually required for max
clock speed), this results drop to 0.305 DMIPS/MHz and 5.232 CPI.
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PicoRV32 Native Memory Interface
--------------------------------
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The native memory interface of PicoRV32 is a simple valid-ready interface
that can run one memory transfer at a time:
output mem_valid
output mem_instr
input mem_ready
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output [31:0] mem_addr
output [31:0] mem_wdata
output [ 3:0] mem_wstrb
input [31:0] mem_rdata
The core initiates a memory transfer by asserting `mem_valid`. The valid
signal stays high until the peer asserts `mem_ready`. All core outputs
are stable over the `mem_valid` period. If the memory transfer is an
instruction fetch, the core asserts `mem_instr`.
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#### Read Transfer
In a read transfer `mem_wstrb` has the value 0 and `mem_wdata` is unused.
The memory reads the address `mem_addr` and makes the read value available on
`mem_rdata` in the cycle `mem_ready` is high.
There is no need for an external wait cycle. The memory read can be implemented
asynchronously with `mem_ready` going high in the same cycle as `mem_valid`, or
`mem_ready` being tied to constant 1.
#### Write Transfer
In a write transfer `mem_wstrb` is not 0 and `mem_rdata` is unused. The memory
write the data at `mem_wdata` to the address `mem_addr` and acknowledges the
transfer by asserting `mem_ready`.
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The 4 bits of `mem_wstrb` are write enables for the four bytes in the addressed
word. Only the 8 values `0000`, `1111`, `1100`, `0011`, `1000`, `0100`, `0010`,
and `0001` are possible, i.e. no write, write 32 bits, write upper 16 bits,
write lower 16, or write a single byte respectively.
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There is no need for an external wait cycle. The memory can acknowledge the
write immediately with `mem_ready` going high in the same cycle as
`mem_valid`, or `mem_ready` being tied to constant 1.
#### Look-Ahead Interface
The PicoRV32 core also provides a "Look-Ahead Memory Interface" that provides
all information about the next memory transfer one clock cycle earlier than the
normal interface.
output mem_la_read
output mem_la_write
output [31:0] mem_la_addr
output [31:0] mem_la_wdata
output [ 3:0] mem_la_wstrb
In the clock cycle before `mem_valid` goes high, this interface will output a
pulse on `mem_la_read` or `mem_la_write` to indicate the start of a read or
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write transaction in the next clock cycle.
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*Note: The signals `mem_la_read`, `mem_la_write`, and `mem_la_addr` are driven
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by combinatorial circuits within the PicoRV32 core. It might be harder to
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achieve timing closure with the look-ahead interface than with the normal
memory interface described above.*
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Pico Co-Processor Interface (PCPI)
----------------------------------
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The Pico Co-Processor Interface (PCPI) can be used to implement non-branching
instructions in external cores:
output pcpi_valid
output [31:0] pcpi_insn
output [31:0] pcpi_rs1
output [31:0] pcpi_rs2
input pcpi_wr
input [31:0] pcpi_rd
input pcpi_wait
input pcpi_ready
When an unsupported instruction is encountered and the PCPI feature is
activated (see ENABLE_PCPI above), then `pcpi_valid` is asserted, the
instruction word itself is output on `pcpi_insn`, the `rs1` and `rs2`
fields are decoded and the values in those registers are output
on `pcpi_rs1` and `pcpi_rs2`.
An external PCPI core can then decode the instruction, execute it, and assert
`pcpi_ready` when execution of the instruction is finished. Optionally a
result value can be written to `pcpi_rd` and `pcpi_wr` asserted. The
PicoRV32 core will then decode the `rd` field of the instruction and
write the value from `pcpi_rd` to the respective register.
When no external PCPI core acknowledges the instruction within 16 clock
cycles, then an illegal instruction exception is raised and the respective
interrupt handler is called. A PCPI core that needs more than a couple of
cycles to execute an instruction, should assert `pcpi_wait` as soon as
the instruction has been decoded successfully and keep it asserted until
it asserts `pcpi_ready`. This will prevent the PicoRV32 core from raising
an illegal instruction exception.
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Custom Instructions for IRQ Handling
------------------------------------
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*Note: The IRQ handling features in PicoRV32 do not follow the RISC-V
Privileged ISA specification. Instead a small set of very simple custom
instructions is used to implement IRQ handling with minimal hardware
overhead.*
The following custom instructions are only supported when IRQs are enabled
via the `ENABLE_IRQ` parameter (see above).
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The PicoRV32 core has a built-in interrupt controller with 32 interrupt inputs. An
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interrupt can be triggered by asserting the corresponding bit in the `irq`
input of the core.
When the interrupt handler is started, the `eoi` End Of Interrupt (EOI) signals
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for the handled interrupts go high. The `eoi` signals go low again when the
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interrupt handler returns.
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The IRQs 0-2 can be triggered internally by the following built-in interrupt sources:
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| IRQ | Interrupt Source |
| ---:| ------------------------------------|
| 0 | Timer Interrupt |
| 1 | EBREAK/ECALL or Illegal Instruction |
| 2 | BUS Error (Unalign Memory Access) |
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This interrupts can also be triggered by external sources, such as co-processors
connected via PCPI.
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The core has 4 additional 32-bit registers `q0 .. q3` that are used for IRQ
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handling. When the IRQ handler is called, the register `q0` contains the return
address and `q1` contains a bitmask of all IRQs to be handled. This means one
call to the interrupt handler needs to service more than one IRQ when more than
one bit is set in `q1`.
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When support for compressed instructions is enabled, then the LSB of q0 is set
when the interrupted instruction is a compressed instruction. This can be used if
the IRQ handler wants to decode the interrupted instruction.
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Registers `q2` and `q3` are uninitialized and can be used as temporary storage
when saving/restoring register values in the IRQ handler.
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All of the following instructions are encoded under the `custom0` opcode. The f3
and rs2 fields are ignored in all this instructions.
See [firmware/custom_ops.S](firmware/custom_ops.S) for GNU assembler macros that
implement mnemonics for this instructions.
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See [firmware/start.S](firmware/start.S) for an example implementation of an
interrupt handler assembler wrapper, and [firmware/irq.c](firmware/irq.c) for
the actual interrupt handler.
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#### getq rd, qs
This instruction copies the value from a q-register to a general-purpose
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register.
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0000000 ----- 000XX --- XXXXX 0001011
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f7 rs2 qs f3 rd opcode
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Example:
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getq x5, q2
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#### setq qd, rs
This instruction copies the value from a general-purpose register to a
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q-register.
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0000001 ----- XXXXX --- 000XX 0001011
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f7 rs2 rs f3 qd opcode
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Example:
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setq q2, x5
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#### retirq
Return from interrupt. This instruction copies the value from `q0`
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to the program counter and re-enables interrupts.
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0000010 ----- 00000 --- 00000 0001011
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f7 rs2 rs f3 rd opcode
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Example:
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retirq
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#### maskirq
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The "IRQ Mask" register contains a bitmask of masked (disabled) interrupts.
This instruction writes a new value to the irq mask register and reads the old
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value.
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0000011 ----- XXXXX --- XXXXX 0001011
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f7 rs2 rs f3 rd opcode
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Example:
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maskirq x1, x2
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The processor starts with all interrupts disabled.
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An illegal instruction or bus error while the illegal instruction or bus error
interrupt is disabled will cause the processor to halt.
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#### waitirq
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Pause execution until an interrupt becomes pending. The bitmask of pending IRQs
is written to `rd`.
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0000100 ----- 00000 --- XXXXX 0001011
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f7 rs2 rs f3 rd opcode
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Example:
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waitirq x1
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#### timer
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Reset the timer counter to a new value. The counter counts down clock cycles and
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triggers the timer interrupt when transitioning from 1 to 0. Setting the
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counter to zero disables the timer. The old value of the counter is written to
`rd`.
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0000101 ----- XXXXX --- XXXXX 0001011
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f7 rs2 rs f3 rd opcode
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Example:
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timer x1, x2
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Building a pure RV32I Toolchain
-------------------------------
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TL;DR: Run the following commands to build the complete toolchain:
make download-tools
make -j$(nproc) build-tools
The default settings in the [riscv-tools](https://github.com/riscv/riscv-tools) build
scripts will build a compiler, assembler and linker that can target any RISC-V ISA,
but the libraries are built for RV32G and RV64G targets. Follow the instructions
below to build a complete toolchain (including libraries) that target a pure RV32I
CPU.
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The following commands will build the RISC-V GNU toolchain and libraries for a
pure RV32I target, and install it in `/opt/riscv32i`:
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# Ubuntu packages needed:
sudo apt-get install autoconf automake autotools-dev curl libmpc-dev \
libmpfr-dev libgmp-dev gawk build-essential bison flex texinfo \
gperf libtool patchutils bc zlib1g-dev git
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sudo mkdir /opt/riscv32i
sudo chown $USER /opt/riscv32i
git clone https://github.com/riscv/riscv-gnu-toolchain riscv-gnu-toolchain-rv32i
cd riscv-gnu-toolchain-rv32i
git checkout c3ad555
git submodule update --init --recursive
mkdir build; cd build
../configure --with-arch=rv32i --prefix=/opt/riscv32i
make -j$(nproc)
The commands will all be named using the prefix `riscv32-unknown-elf-`, which
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makes it easy to install them side-by-side with the regular riscv-tools (those
are using the name prefix `riscv64-unknown-elf-` by default).
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Alternatively you can simply use one of the following make targets from PicoRV32's
Makefile to build a `RV32I[M][C]` toolchain. You still need to install all
prerequisites, as described above. Then run any of the following commands in the
PicoRV32 source directory:
| Command | Install Directory | ISA |
|:---------------------------------------- |:------------------ |:-------- |
| `make -j$(nproc) build-riscv32i-tools` | `/opt/riscv32i/` | `RV32I` |
| `make -j$(nproc) build-riscv32ic-tools` | `/opt/riscv32ic/` | `RV32IC` |
| `make -j$(nproc) build-riscv32im-tools` | `/opt/riscv32im/` | `RV32IM` |
| `make -j$(nproc) build-riscv32imc-tools` | `/opt/riscv32imc/` | `RV32IMC` |
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Or simply run `make -j$(nproc) build-tools` to build and install all four tool chains.
By default calling any of those make targets will (re-)download the toolchain
sources. Run `make download-tools` to download the sources to `/var/cache/distfiles/`
once in advance.
*Note: These instructions are for git rev c3ad555 (2018-08-13) of riscv-gnu-toolchain.*
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Linking binaries with newlib for PicoRV32
-----------------------------------------
The tool chains (see last section for install instructions) come with a version of
the newlib C standard library.
Use the linker script [firmware/riscv.ld](firmware/riscv.ld) for linking binaries
against the newlib library. Using this linker script will create a binary that
has its entry point at 0x10000. (The default linker script does not have a static
entry point, thus a proper ELF loader would be needed that can determine the
entry point at runtime while loading the program.)
Newlib comes with a few syscall stubs. You need to provide your own implementation
of those syscalls and link your program with this implementation, overwriting the
default stubs from newlib. See `syscalls.c` in [scripts/cxxdemo/](scripts/cxxdemo/)
for an example of how to do that.
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Evaluation: Timing and Utilization on Xilinx 7-Series FPGAs
-----------------------------------------------------------
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The following evaluations have been performed with Vivado 2017.3.
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#### Timing on Xilinx 7-Series FPGAs
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The `picorv32_axi` module with enabled `TWO_CYCLE_ALU` has been placed and
routed for Xilinx Artix-7T, Kintex-7T, Virtex-7T, Kintex UltraScale, and Virtex
UltraScale devices in all speed grades. A binary search is used to find the
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shortest clock period for which the design meets timing.
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See `make table.txt` in [scripts/vivado/](scripts/vivado/).
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| Device | Device | Speedgrade | Clock Period (Freq.) |
|:------------------------- |:---------------------|:----------:| --------------------:|
| Xilinx Kintex-7T | xc7k70t-fbg676-2 | -2 | 2.4 ns (416 MHz) |
| Xilinx Kintex-7T | xc7k70t-fbg676-3 | -3 | 2.2 ns (454 MHz) |
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| Xilinx Virtex-7T | xc7v585t-ffg1761-2 | -2 | 2.3 ns (434 MHz) |
| Xilinx Virtex-7T | xc7v585t-ffg1761-3 | -3 | 2.2 ns (454 MHz) |
| Xilinx Kintex UltraScale | xcku035-fbva676-2-e | -2 | 2.0 ns (500 MHz) |
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| Xilinx Kintex UltraScale | xcku035-fbva676-3-e | -3 | 1.8 ns (555 MHz) |
| Xilinx Virtex UltraScale | xcvu065-ffvc1517-2-e | -2 | 2.1 ns (476 MHz) |
| Xilinx Virtex UltraScale | xcvu065-ffvc1517-3-e | -3 | 2.0 ns (500 MHz) |
| Xilinx Kintex UltraScale+ | xcku3p-ffva676-2-e | -2 | 1.4 ns (714 MHz) |
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| Xilinx Kintex UltraScale+ | xcku3p-ffva676-3-e | -3 | 1.3 ns (769 MHz) |
| Xilinx Virtex UltraScale+ | xcvu3p-ffvc1517-2-e | -2 | 1.5 ns (666 MHz) |
| Xilinx Virtex UltraScale+ | xcvu3p-ffvc1517-3-e | -3 | 1.4 ns (714 MHz) |
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#### Utilization on Xilinx 7-Series FPGAs
The following table lists the resource utilization in area-optimized synthesis
for the following three cores:
- **PicoRV32 (small):** The `picorv32` module without counter instructions,
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without two-stage shifts, with externally latched `mem_rdata`, and without
catching of misaligned memory accesses and illegal instructions.
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- **PicoRV32 (regular):** The `picorv32` module in its default configuration.
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- **PicoRV32 (large):** The `picorv32` module with enabled PCPI, IRQ, MUL,
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DIV, BARREL_SHIFTER, and COMPRESSED_ISA features.
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See `make area` in [scripts/vivado/](scripts/vivado/).
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| Core Variant | Slice LUTs | LUTs as Memory | Slice Registers |
|:------------------ | ----------:| --------------:| ---------------:|
| PicoRV32 (small) | 761 | 48 | 442 |
| PicoRV32 (regular) | 917 | 48 | 583 |
| PicoRV32 (large) | 2019 | 88 | 1085 |
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