-- #################################################################################################
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-- #################################################################################################
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-- # << NEORV32 - Processor Top Entity with AXI4-Lite Compatible Master Interface >> #
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-- # << NEORV32 - Processor Top Entity with AXI4-Lite Compatible Master Interface >> #
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-- # ********************************************************************************************* #
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-- # ********************************************************************************************* #
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-- # (c) "AXI", "AXI4" and "AXI4-Lite" are trademarks of Arm Holdings plc. #
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-- # (c) "AXI", "AXI4" and "AXI4-Lite" are trademarks of Arm Holdings plc. #
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-- # Note: External MTIME is not supported. #
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-- # Note: External MTIME is not supported. #
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-- # ********************************************************************************************* #
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-- # ********************************************************************************************* #
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-- # BSD 3-Clause License #
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-- # BSD 3-Clause License #
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-- # #
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-- # #
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-- # Copyright (c) 2021, Stephan Nolting. All rights reserved. #
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-- # Copyright (c) 2021, Stephan Nolting. All rights reserved. #
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-- # #
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-- # #
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-- # Redistribution and use in source and binary forms, with or without modification, are #
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-- # Redistribution and use in source and binary forms, with or without modification, are #
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-- # permitted provided that the following conditions are met: #
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-- # permitted provided that the following conditions are met: #
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-- # #
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-- # #
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-- # 1. Redistributions of source code must retain the above copyright notice, this list of #
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-- # 1. Redistributions of source code must retain the above copyright notice, this list of #
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-- # conditions and the following disclaimer. #
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-- # conditions and the following disclaimer. #
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-- # #
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-- # #
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-- # 2. Redistributions in binary form must reproduce the above copyright notice, this list of #
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-- # 2. Redistributions in binary form must reproduce the above copyright notice, this list of #
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-- # conditions and the following disclaimer in the documentation and/or other materials #
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-- # conditions and the following disclaimer in the documentation and/or other materials #
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-- # provided with the distribution. #
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-- # provided with the distribution. #
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-- # #
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-- # #
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-- # 3. Neither the name of the copyright holder nor the names of its contributors may be used to #
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-- # 3. Neither the name of the copyright holder nor the names of its contributors may be used to #
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-- # endorse or promote products derived from this software without specific prior written #
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-- # endorse or promote products derived from this software without specific prior written #
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-- # permission. #
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-- # permission. #
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-- # #
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-- # #
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-- # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS #
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-- # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS #
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-- # OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF #
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-- # OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF #
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-- # MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE #
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-- # MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE #
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-- # COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, #
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-- # COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, #
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-- # EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE #
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-- # EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE #
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-- # GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED #
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-- # GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED #
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-- # AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING #
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-- # AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING #
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-- # NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED #
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-- # NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED #
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-- # OF THE POSSIBILITY OF SUCH DAMAGE. #
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-- # OF THE POSSIBILITY OF SUCH DAMAGE. #
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-- # ********************************************************************************************* #
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-- # ********************************************************************************************* #
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-- # The NEORV32 Processor - https://github.com/stnolting/neorv32 (c) Stephan Nolting #
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-- # The NEORV32 Processor - https://github.com/stnolting/neorv32 (c) Stephan Nolting #
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-- #################################################################################################
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-- #################################################################################################
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library ieee;
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library ieee;
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use ieee.std_logic_1164.all;
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use ieee.std_logic_1164.all;
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use ieee.numeric_std.all;
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use ieee.numeric_std.all;
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library neorv32;
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library neorv32;
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use neorv32.neorv32_package.all;
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use neorv32.neorv32_package.all;
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entity neorv32_SystemTop_axi4lite is
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entity neorv32_SystemTop_axi4lite is
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generic (
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generic (
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-- ------------------------------------------------------------
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-- ------------------------------------------------------------
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-- Configuration Generics --
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-- Configuration Generics --
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-- ------------------------------------------------------------
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-- ------------------------------------------------------------
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-- General --
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-- General --
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CLOCK_FREQUENCY : natural := 0; -- clock frequency of clk_i in Hz
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CLOCK_FREQUENCY : natural := 0; -- clock frequency of clk_i in Hz
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INT_BOOTLOADER_EN : boolean := true; -- boot configuration: true = boot explicit bootloader; false = boot from int/ext (I)MEM
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INT_BOOTLOADER_EN : boolean := true; -- boot configuration: true = boot explicit bootloader; false = boot from int/ext (I)MEM
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HW_THREAD_ID : natural := 0; -- hardware thread id (32-bit)
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HW_THREAD_ID : natural := 0; -- hardware thread id (32-bit)
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-- On-Chip Debugger (OCD) --
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-- On-Chip Debugger (OCD) --
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ON_CHIP_DEBUGGER_EN : boolean := false; -- implement on-chip debugger
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ON_CHIP_DEBUGGER_EN : boolean := false; -- implement on-chip debugger
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-- RISC-V CPU Extensions --
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-- RISC-V CPU Extensions --
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CPU_EXTENSION_RISCV_A : boolean := false; -- implement atomic extension?
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CPU_EXTENSION_RISCV_A : boolean := false; -- implement atomic extension?
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CPU_EXTENSION_RISCV_C : boolean := false; -- implement compressed extension?
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CPU_EXTENSION_RISCV_C : boolean := false; -- implement compressed extension?
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CPU_EXTENSION_RISCV_E : boolean := false; -- implement embedded RF extension?
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CPU_EXTENSION_RISCV_E : boolean := false; -- implement embedded RF extension?
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CPU_EXTENSION_RISCV_M : boolean := false; -- implement muld/div extension?
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CPU_EXTENSION_RISCV_M : boolean := false; -- implement muld/div extension?
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CPU_EXTENSION_RISCV_U : boolean := false; -- implement user mode extension?
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CPU_EXTENSION_RISCV_U : boolean := false; -- implement user mode extension?
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CPU_EXTENSION_RISCV_Zbb : boolean := false; -- implement basic bit-manipulation sub-extension?
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CPU_EXTENSION_RISCV_Zbb : boolean := false; -- implement basic bit-manipulation sub-extension?
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CPU_EXTENSION_RISCV_Zfinx : boolean := false; -- implement 32-bit floating-point extension (using INT reg!)
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CPU_EXTENSION_RISCV_Zfinx : boolean := false; -- implement 32-bit floating-point extension (using INT reg!)
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CPU_EXTENSION_RISCV_Zicsr : boolean := true; -- implement CSR system?
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CPU_EXTENSION_RISCV_Zicsr : boolean := true; -- implement CSR system?
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CPU_EXTENSION_RISCV_Zifencei : boolean := false; -- implement instruction stream sync.?
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CPU_EXTENSION_RISCV_Zifencei : boolean := false; -- implement instruction stream sync.?
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-- Extension Options --
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-- Extension Options --
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FAST_MUL_EN : boolean := false; -- use DSPs for M extension's multiplier
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FAST_MUL_EN : boolean := false; -- use DSPs for M extension's multiplier
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FAST_SHIFT_EN : boolean := false; -- use barrel shifter for shift operations
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FAST_SHIFT_EN : boolean := false; -- use barrel shifter for shift operations
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CPU_CNT_WIDTH : natural := 64; -- total width of CPU cycle and instret counters (0..64)
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CPU_CNT_WIDTH : natural := 64; -- total width of CPU cycle and instret counters (0..64)
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-- Physical Memory Protection (PMP) --
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-- Physical Memory Protection (PMP) --
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PMP_NUM_REGIONS : natural := 0; -- number of regions (0..64)
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PMP_NUM_REGIONS : natural := 0; -- number of regions (0..64)
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PMP_MIN_GRANULARITY : natural := 64*1024; -- minimal region granularity in bytes, has to be a power of 2, min 8 bytes
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PMP_MIN_GRANULARITY : natural := 64*1024; -- minimal region granularity in bytes, has to be a power of 2, min 8 bytes
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-- Hardware Performance Monitors (HPM) --
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-- Hardware Performance Monitors (HPM) --
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HPM_NUM_CNTS : natural := 0; -- number of implemented HPM counters (0..29)
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HPM_NUM_CNTS : natural := 0; -- number of implemented HPM counters (0..29)
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HPM_CNT_WIDTH : natural := 40; -- total size of HPM counters (0..64)
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HPM_CNT_WIDTH : natural := 40; -- total size of HPM counters (0..64)
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-- Internal Instruction memory --
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-- Internal Instruction memory --
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MEM_INT_IMEM_EN : boolean := true; -- implement processor-internal instruction memory
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MEM_INT_IMEM_EN : boolean := true; -- implement processor-internal instruction memory
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MEM_INT_IMEM_SIZE : natural := 16*1024; -- size of processor-internal instruction memory in bytes
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MEM_INT_IMEM_SIZE : natural := 16*1024; -- size of processor-internal instruction memory in bytes
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-- Internal Data memory --
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-- Internal Data memory --
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MEM_INT_DMEM_EN : boolean := true; -- implement processor-internal data memory
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MEM_INT_DMEM_EN : boolean := true; -- implement processor-internal data memory
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MEM_INT_DMEM_SIZE : natural := 8*1024; -- size of processor-internal data memory in bytes
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MEM_INT_DMEM_SIZE : natural := 8*1024; -- size of processor-internal data memory in bytes
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-- Internal Cache memory --
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-- Internal Cache memory --
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ICACHE_EN : boolean := false; -- implement instruction cache
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ICACHE_EN : boolean := false; -- implement instruction cache
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ICACHE_NUM_BLOCKS : natural := 4; -- i-cache: number of blocks (min 1), has to be a power of 2
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ICACHE_NUM_BLOCKS : natural := 4; -- i-cache: number of blocks (min 1), has to be a power of 2
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ICACHE_BLOCK_SIZE : natural := 64; -- i-cache: block size in bytes (min 4), has to be a power of 2
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ICACHE_BLOCK_SIZE : natural := 64; -- i-cache: block size in bytes (min 4), has to be a power of 2
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ICACHE_ASSOCIATIVITY : natural := 1; -- i-cache: associativity / number of sets (1=direct_mapped), has to be a power of 2
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ICACHE_ASSOCIATIVITY : natural := 1; -- i-cache: associativity / number of sets (1=direct_mapped), has to be a power of 2
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-- External Interrupts Controller (XIRQ) --
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-- External Interrupts Controller (XIRQ) --
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XIRQ_NUM_CH : natural := 0; -- number of external IRQ channels (0..32)
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XIRQ_NUM_CH : natural := 0; -- number of external IRQ channels (0..32)
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XIRQ_TRIGGER_TYPE : std_logic_vector(31 downto 0) := x"FFFFFFFF"; -- trigger type: 0=level, 1=edge
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XIRQ_TRIGGER_TYPE : std_logic_vector(31 downto 0) := x"FFFFFFFF"; -- trigger type: 0=level, 1=edge
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XIRQ_TRIGGER_POLARITY : std_logic_vector(31 downto 0) := x"FFFFFFFF"; -- trigger polarity: 0=low-level/falling-edge, 1=high-level/rising-edge
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XIRQ_TRIGGER_POLARITY : std_logic_vector(31 downto 0) := x"FFFFFFFF"; -- trigger polarity: 0=low-level/falling-edge, 1=high-level/rising-edge
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-- Processor peripherals --
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-- Processor peripherals --
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IO_GPIO_EN : boolean := true; -- implement general purpose input/output port unit (GPIO)?
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IO_GPIO_EN : boolean := true; -- implement general purpose input/output port unit (GPIO)?
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IO_MTIME_EN : boolean := true; -- implement machine system timer (MTIME)?
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IO_MTIME_EN : boolean := true; -- implement machine system timer (MTIME)?
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IO_UART0_EN : boolean := true; -- implement primary universal asynchronous receiver/transmitter (UART0)?
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IO_UART0_EN : boolean := true; -- implement primary universal asynchronous receiver/transmitter (UART0)?
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IO_UART1_EN : boolean := true; -- implement secondary universal asynchronous receiver/transmitter (UART1)?
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IO_UART1_EN : boolean := true; -- implement secondary universal asynchronous receiver/transmitter (UART1)?
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IO_SPI_EN : boolean := true; -- implement serial peripheral interface (SPI)?
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IO_SPI_EN : boolean := true; -- implement serial peripheral interface (SPI)?
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IO_TWI_EN : boolean := true; -- implement two-wire interface (TWI)?
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IO_TWI_EN : boolean := true; -- implement two-wire interface (TWI)?
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IO_PWM_NUM_CH : natural := 4; -- number of PWM channels to implement (0..60); 0 = disabled
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IO_PWM_NUM_CH : natural := 4; -- number of PWM channels to implement (0..60); 0 = disabled
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IO_WDT_EN : boolean := true; -- implement watch dog timer (WDT)?
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IO_WDT_EN : boolean := true; -- implement watch dog timer (WDT)?
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IO_TRNG_EN : boolean := false; -- implement true random number generator (TRNG)?
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IO_TRNG_EN : boolean := false; -- implement true random number generator (TRNG)?
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IO_CFS_EN : boolean := false; -- implement custom functions subsystem (CFS)?
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IO_CFS_EN : boolean := false; -- implement custom functions subsystem (CFS)?
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IO_CFS_CONFIG : std_logic_vector(31 downto 0) := x"00000000"; -- custom CFS configuration generic
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IO_CFS_CONFIG : std_logic_vector(31 downto 0) := x"00000000"; -- custom CFS configuration generic
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IO_CFS_IN_SIZE : positive := 32; -- size of CFS input conduit in bits
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IO_CFS_IN_SIZE : positive := 32; -- size of CFS input conduit in bits
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IO_CFS_OUT_SIZE : positive := 32; -- size of CFS output conduit in bits
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IO_CFS_OUT_SIZE : positive := 32; -- size of CFS output conduit in bits
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IO_NEOLED_EN : boolean := true -- implement NeoPixel-compatible smart LED interface (NEOLED)?
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IO_NEOLED_EN : boolean := true -- implement NeoPixel-compatible smart LED interface (NEOLED)?
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);
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);
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port (
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port (
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-- ------------------------------------------------------------
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-- ------------------------------------------------------------
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-- AXI4-Lite-Compatible Master Interface --
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-- AXI4-Lite-Compatible Master Interface --
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-- ------------------------------------------------------------
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-- ------------------------------------------------------------
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-- Clock and Reset --
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-- Clock and Reset --
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m_axi_aclk : in std_logic;
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m_axi_aclk : in std_logic;
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m_axi_aresetn : in std_logic;
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m_axi_aresetn : in std_logic;
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-- Write Address Channel --
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-- Write Address Channel --
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m_axi_awaddr : out std_logic_vector(31 downto 0);
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m_axi_awaddr : out std_logic_vector(31 downto 0);
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m_axi_awprot : out std_logic_vector(2 downto 0);
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m_axi_awprot : out std_logic_vector(2 downto 0);
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m_axi_awvalid : out std_logic;
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m_axi_awvalid : out std_logic;
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m_axi_awready : in std_logic;
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m_axi_awready : in std_logic;
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-- Write Data Channel --
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-- Write Data Channel --
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m_axi_wdata : out std_logic_vector(31 downto 0);
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m_axi_wdata : out std_logic_vector(31 downto 0);
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m_axi_wstrb : out std_logic_vector(3 downto 0);
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m_axi_wstrb : out std_logic_vector(3 downto 0);
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m_axi_wvalid : out std_logic;
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m_axi_wvalid : out std_logic;
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m_axi_wready : in std_logic;
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m_axi_wready : in std_logic;
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-- Read Address Channel --
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-- Read Address Channel --
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m_axi_araddr : out std_logic_vector(31 downto 0);
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m_axi_araddr : out std_logic_vector(31 downto 0);
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m_axi_arprot : out std_logic_vector(2 downto 0);
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m_axi_arprot : out std_logic_vector(2 downto 0);
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m_axi_arvalid : out std_logic;
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m_axi_arvalid : out std_logic;
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m_axi_arready : in std_logic;
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m_axi_arready : in std_logic;
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-- Read Data Channel --
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-- Read Data Channel --
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m_axi_rdata : in std_logic_vector(31 downto 0);
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m_axi_rdata : in std_logic_vector(31 downto 0);
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m_axi_rresp : in std_logic_vector(1 downto 0);
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m_axi_rresp : in std_logic_vector(1 downto 0);
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m_axi_rvalid : in std_logic;
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m_axi_rvalid : in std_logic;
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m_axi_rready : out std_logic;
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m_axi_rready : out std_logic;
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-- Write Response Channel --
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-- Write Response Channel --
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m_axi_bresp : in std_logic_vector(1 downto 0);
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m_axi_bresp : in std_logic_vector(1 downto 0);
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m_axi_bvalid : in std_logic;
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m_axi_bvalid : in std_logic;
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m_axi_bready : out std_logic;
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m_axi_bready : out std_logic;
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-- ------------------------------------------------------------
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-- ------------------------------------------------------------
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-- JTAG on-chip debugger interface (available if ON_CHIP_DEBUGGER_EN = true) --
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-- JTAG on-chip debugger interface (available if ON_CHIP_DEBUGGER_EN = true) --
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-- ------------------------------------------------------------
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-- ------------------------------------------------------------
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jtag_trst_i : in std_logic := '0'; -- low-active TAP reset (optional)
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jtag_trst_i : in std_logic := '0'; -- low-active TAP reset (optional)
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jtag_tck_i : in std_logic := '0'; -- serial clock
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jtag_tck_i : in std_logic := '0'; -- serial clock
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jtag_tdi_i : in std_logic := '0'; -- serial data input
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jtag_tdi_i : in std_logic := '0'; -- serial data input
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jtag_tdo_o : out std_logic; -- serial data output
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jtag_tdo_o : out std_logic; -- serial data output
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jtag_tms_i : in std_logic := '0'; -- mode select
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jtag_tms_i : in std_logic := '0'; -- mode select
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-- ------------------------------------------------------------
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-- ------------------------------------------------------------
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-- Processor IO --
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-- Processor IO --
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-- ------------------------------------------------------------
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-- ------------------------------------------------------------
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-- GPIO (available if IO_GPIO_EN = true) --
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-- GPIO (available if IO_GPIO_EN = true) --
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gpio_o : out std_logic_vector(63 downto 0); -- parallel output
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gpio_o : out std_logic_vector(63 downto 0); -- parallel output
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gpio_i : in std_logic_vector(63 downto 0) := (others => '0'); -- parallel input
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gpio_i : in std_logic_vector(63 downto 0) := (others => '0'); -- parallel input
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-- primary UART0 (available if IO_UART0_EN = true) --
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-- primary UART0 (available if IO_UART0_EN = true) --
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uart0_txd_o : out std_logic; -- UART0 send data
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uart0_txd_o : out std_logic; -- UART0 send data
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uart0_rxd_i : in std_logic := '0'; -- UART0 receive data
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uart0_rxd_i : in std_logic := '0'; -- UART0 receive data
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uart0_rts_o : out std_logic; -- hw flow control: UART0.RX ready to receive ("RTR"), low-active, optional
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uart0_rts_o : out std_logic; -- hw flow control: UART0.RX ready to receive ("RTR"), low-active, optional
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uart0_cts_i : in std_logic := '0'; -- hw flow control: UART0.TX allowed to transmit, low-active, optional
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uart0_cts_i : in std_logic := '0'; -- hw flow control: UART0.TX allowed to transmit, low-active, optional
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-- secondary UART1 (available if IO_UART1_EN = true) --
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-- secondary UART1 (available if IO_UART1_EN = true) --
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uart1_txd_o : out std_logic; -- UART1 send data
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uart1_txd_o : out std_logic; -- UART1 send data
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uart1_rxd_i : in std_logic := '0'; -- UART1 receive data
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uart1_rxd_i : in std_logic := '0'; -- UART1 receive data
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uart1_rts_o : out std_logic; -- hw flow control: UART1.RX ready to receive ("RTR"), low-active, optional
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uart1_rts_o : out std_logic; -- hw flow control: UART1.RX ready to receive ("RTR"), low-active, optional
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uart1_cts_i : in std_logic := '0'; -- hw flow control: UART1.TX allowed to transmit, low-active, optional
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uart1_cts_i : in std_logic := '0'; -- hw flow control: UART1.TX allowed to transmit, low-active, optional
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-- SPI (available if IO_SPI_EN = true) --
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-- SPI (available if IO_SPI_EN = true) --
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spi_sck_o : out std_logic; -- SPI serial clock
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spi_sck_o : out std_logic; -- SPI serial clock
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spi_sdo_o : out std_logic; -- controller data out, peripheral data in
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spi_sdo_o : out std_logic; -- controller data out, peripheral data in
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spi_sdi_i : in std_logic := '0'; -- controller data in, peripheral data out
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spi_sdi_i : in std_logic := '0'; -- controller data in, peripheral data out
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spi_csn_o : out std_logic_vector(07 downto 0); -- SPI CS
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spi_csn_o : out std_logic_vector(07 downto 0); -- SPI CS
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-- TWI (available if IO_TWI_EN = true) --
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-- TWI (available if IO_TWI_EN = true) --
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twi_sda_io : inout std_logic; -- twi serial data line
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twi_sda_io : inout std_logic; -- twi serial data line
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twi_scl_io : inout std_logic; -- twi serial clock line
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twi_scl_io : inout std_logic; -- twi serial clock line
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-- PWM (available if IO_PWM_NUM_CH > 0) --
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-- PWM (available if IO_PWM_NUM_CH > 0) --
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pwm_o : out std_logic_vector(IO_PWM_NUM_CH-1 downto 0); -- pwm channels
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pwm_o : out std_logic_vector(IO_PWM_NUM_CH-1 downto 0); -- pwm channels
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-- Custom Functions Subsystem IO (available if IO_CFS_EN = true) --
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-- Custom Functions Subsystem IO (available if IO_CFS_EN = true) --
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cfs_in_i : in std_logic_vector(IO_CFS_IN_SIZE-1 downto 0); -- custom inputs
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cfs_in_i : in std_logic_vector(IO_CFS_IN_SIZE-1 downto 0); -- custom inputs
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cfs_out_o : out std_logic_vector(IO_CFS_OUT_SIZE-1 downto 0); -- custom outputs
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cfs_out_o : out std_logic_vector(IO_CFS_OUT_SIZE-1 downto 0); -- custom outputs
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-- NeoPixel-compatible smart LED interface (available if IO_NEOLED_EN = true) --
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-- NeoPixel-compatible smart LED interface (available if IO_NEOLED_EN = true) --
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neoled_o : out std_logic; -- async serial data line
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neoled_o : out std_logic; -- async serial data line
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-- External platform interrupts (available if XIRQ_NUM_CH > 0) --
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-- External platform interrupts (available if XIRQ_NUM_CH > 0) --
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xirq_i : in std_logic_vector(XIRQ_NUM_CH-1 downto 0) := (others => '0'); -- IRQ channels
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xirq_i : in std_logic_vector(XIRQ_NUM_CH-1 downto 0) := (others => '0'); -- IRQ channels
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-- CPU Interrupts --
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-- CPU Interrupts --
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nm_irq_i : in std_logic := '0'; -- non-maskable interrupt
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msw_irq_i : in std_logic := '0'; -- machine software interrupt
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msw_irq_i : in std_logic := '0'; -- machine software interrupt
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mext_irq_i : in std_logic := '0' -- machine external interrupt
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mext_irq_i : in std_logic := '0' -- machine external interrupt
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);
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);
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end entity;
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end entity;
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architecture neorv32_SystemTop_axi4lite_rtl of neorv32_SystemTop_axi4lite is
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architecture neorv32_SystemTop_axi4lite_rtl of neorv32_SystemTop_axi4lite is
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|
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-- type conversion --
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-- type conversion --
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constant IO_CFS_CONFIG_INT : std_ulogic_vector(31 downto 0) := std_ulogic_vector(IO_CFS_CONFIG);
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constant IO_CFS_CONFIG_INT : std_ulogic_vector(31 downto 0) := std_ulogic_vector(IO_CFS_CONFIG);
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constant XIRQ_TRIGGER_TYPE_INT : std_ulogic_vector(31 downto 0) := std_ulogic_vector(XIRQ_TRIGGER_TYPE);
|
constant XIRQ_TRIGGER_TYPE_INT : std_ulogic_vector(31 downto 0) := std_ulogic_vector(XIRQ_TRIGGER_TYPE);
|
constant XIRQ_TRIGGER_POLARITY_INT : std_ulogic_vector(31 downto 0) := std_ulogic_vector(XIRQ_TRIGGER_POLARITY);
|
constant XIRQ_TRIGGER_POLARITY_INT : std_ulogic_vector(31 downto 0) := std_ulogic_vector(XIRQ_TRIGGER_POLARITY);
|
--
|
--
|
signal clk_i_int : std_ulogic;
|
signal clk_i_int : std_ulogic;
|
signal rstn_i_int : std_ulogic;
|
signal rstn_i_int : std_ulogic;
|
--
|
--
|
signal jtag_trst_i_int :std_ulogic;
|
signal jtag_trst_i_int :std_ulogic;
|
signal jtag_tck_i_int :std_ulogic;
|
signal jtag_tck_i_int :std_ulogic;
|
signal jtag_tdi_i_int :std_ulogic;
|
signal jtag_tdi_i_int :std_ulogic;
|
signal jtag_tdo_o_int :std_ulogic;
|
signal jtag_tdo_o_int :std_ulogic;
|
signal jtag_tms_i_int :std_ulogic;
|
signal jtag_tms_i_int :std_ulogic;
|
--
|
--
|
signal gpio_o_int : std_ulogic_vector(63 downto 0);
|
signal gpio_o_int : std_ulogic_vector(63 downto 0);
|
signal gpio_i_int : std_ulogic_vector(63 downto 0);
|
signal gpio_i_int : std_ulogic_vector(63 downto 0);
|
--
|
--
|
signal uart0_txd_o_int : std_ulogic;
|
signal uart0_txd_o_int : std_ulogic;
|
signal uart0_rxd_i_int : std_ulogic;
|
signal uart0_rxd_i_int : std_ulogic;
|
signal uart0_rts_o_int : std_ulogic;
|
signal uart0_rts_o_int : std_ulogic;
|
signal uart0_cts_i_int : std_ulogic;
|
signal uart0_cts_i_int : std_ulogic;
|
--
|
--
|
signal uart1_txd_o_int : std_ulogic;
|
signal uart1_txd_o_int : std_ulogic;
|
signal uart1_rxd_i_int : std_ulogic;
|
signal uart1_rxd_i_int : std_ulogic;
|
signal uart1_rts_o_int : std_ulogic;
|
signal uart1_rts_o_int : std_ulogic;
|
signal uart1_cts_i_int : std_ulogic;
|
signal uart1_cts_i_int : std_ulogic;
|
--
|
--
|
signal spi_sck_o_int : std_ulogic;
|
signal spi_sck_o_int : std_ulogic;
|
signal spi_sdo_o_int : std_ulogic;
|
signal spi_sdo_o_int : std_ulogic;
|
signal spi_sdi_i_int : std_ulogic;
|
signal spi_sdi_i_int : std_ulogic;
|
signal spi_csn_o_int : std_ulogic_vector(07 downto 0);
|
signal spi_csn_o_int : std_ulogic_vector(07 downto 0);
|
--
|
--
|
signal pwm_o_int : std_ulogic_vector(IO_PWM_NUM_CH-1 downto 0);
|
signal pwm_o_int : std_ulogic_vector(IO_PWM_NUM_CH-1 downto 0);
|
--
|
--
|
signal cfs_in_i_int : std_ulogic_vector(IO_CFS_IN_SIZE-1 downto 0);
|
signal cfs_in_i_int : std_ulogic_vector(IO_CFS_IN_SIZE-1 downto 0);
|
signal cfs_out_o_int : std_ulogic_vector(IO_CFS_OUT_SIZE-1 downto 0);
|
signal cfs_out_o_int : std_ulogic_vector(IO_CFS_OUT_SIZE-1 downto 0);
|
--
|
--
|
signal neoled_o_int : std_ulogic;
|
signal neoled_o_int : std_ulogic;
|
--
|
--
|
signal xirq_i_int : std_ulogic_vector(XIRQ_NUM_CH-1 downto 0);
|
signal xirq_i_int : std_ulogic_vector(XIRQ_NUM_CH-1 downto 0);
|
--
|
--
|
signal nm_irq_i_int : std_ulogic;
|
|
signal msw_irq_i_int : std_ulogic;
|
signal msw_irq_i_int : std_ulogic;
|
signal mext_irq_i_int : std_ulogic;
|
signal mext_irq_i_int : std_ulogic;
|
|
|
-- internal wishbone bus --
|
-- internal wishbone bus --
|
type wb_bus_t is record
|
type wb_bus_t is record
|
adr : std_ulogic_vector(31 downto 0); -- address
|
adr : std_ulogic_vector(31 downto 0); -- address
|
di : std_ulogic_vector(31 downto 0); -- processor input data
|
di : std_ulogic_vector(31 downto 0); -- processor input data
|
do : std_ulogic_vector(31 downto 0); -- processor output data
|
do : std_ulogic_vector(31 downto 0); -- processor output data
|
we : std_ulogic; -- write enable
|
we : std_ulogic; -- write enable
|
sel : std_ulogic_vector(03 downto 0); -- byte enable
|
sel : std_ulogic_vector(03 downto 0); -- byte enable
|
stb : std_ulogic; -- strobe
|
stb : std_ulogic; -- strobe
|
cyc : std_ulogic; -- valid cycle
|
cyc : std_ulogic; -- valid cycle
|
ack : std_ulogic; -- transfer acknowledge
|
ack : std_ulogic; -- transfer acknowledge
|
err : std_ulogic; -- transfer error
|
err : std_ulogic; -- transfer error
|
tag : std_ulogic_vector(02 downto 0); -- tag
|
tag : std_ulogic_vector(02 downto 0); -- tag
|
lock : std_ulogic; -- exclusive access request
|
lock : std_ulogic; -- exclusive access request
|
end record;
|
end record;
|
signal wb_core : wb_bus_t;
|
signal wb_core : wb_bus_t;
|
|
|
-- AXI bridge control --
|
-- AXI bridge control --
|
type ctrl_t is record
|
type ctrl_t is record
|
radr_received : std_ulogic;
|
radr_received : std_ulogic;
|
wadr_received : std_ulogic;
|
wadr_received : std_ulogic;
|
wdat_received : std_ulogic;
|
wdat_received : std_ulogic;
|
end record;
|
end record;
|
signal ctrl : ctrl_t;
|
signal ctrl : ctrl_t;
|
|
|
signal ack_read, ack_write : std_ulogic; -- normal transfer termination
|
signal ack_read, ack_write : std_ulogic; -- normal transfer termination
|
signal err_read, err_write : std_ulogic; -- error transfer termination
|
signal err_read, err_write : std_ulogic; -- error transfer termination
|
|
|
begin
|
begin
|
|
|
-- Sanity Checks --------------------------------------------------------------------------
|
-- Sanity Checks --------------------------------------------------------------------------
|
-- -------------------------------------------------------------------------------------------
|
-- -------------------------------------------------------------------------------------------
|
assert not (CPU_EXTENSION_RISCV_A = true) report "NEORV32 PROCESSOR CONFIG WARNING: AXI4-Lite provides NO support for atomic memory operations. LR/SC access via AXI will raise a bus exception." severity warning;
|
assert not (CPU_EXTENSION_RISCV_A = true) report "NEORV32 PROCESSOR CONFIG WARNING: AXI4-Lite provides NO support for atomic memory operations. LR/SC access via AXI will raise a bus exception." severity warning;
|
|
|
|
|
-- The Core Of The Problem ----------------------------------------------------------------
|
-- The Core Of The Problem ----------------------------------------------------------------
|
-- -------------------------------------------------------------------------------------------
|
-- -------------------------------------------------------------------------------------------
|
neorv32_top_inst: neorv32_top
|
neorv32_top_inst: neorv32_top
|
generic map (
|
generic map (
|
-- General --
|
-- General --
|
CLOCK_FREQUENCY => CLOCK_FREQUENCY, -- clock frequency of clk_i in Hz
|
CLOCK_FREQUENCY => CLOCK_FREQUENCY, -- clock frequency of clk_i in Hz
|
INT_BOOTLOADER_EN => INT_BOOTLOADER_EN, -- boot configuration: true = boot explicit bootloader; false = boot from int/ext (I)MEM
|
INT_BOOTLOADER_EN => INT_BOOTLOADER_EN, -- boot configuration: true = boot explicit bootloader; false = boot from int/ext (I)MEM
|
HW_THREAD_ID => HW_THREAD_ID, -- hardware thread id (hartid)
|
HW_THREAD_ID => HW_THREAD_ID, -- hardware thread id (hartid)
|
-- On-Chip Debugger (OCD) --
|
-- On-Chip Debugger (OCD) --
|
ON_CHIP_DEBUGGER_EN => ON_CHIP_DEBUGGER_EN, -- implement on-chip debugger
|
ON_CHIP_DEBUGGER_EN => ON_CHIP_DEBUGGER_EN, -- implement on-chip debugger
|
-- RISC-V CPU Extensions --
|
-- RISC-V CPU Extensions --
|
CPU_EXTENSION_RISCV_A => CPU_EXTENSION_RISCV_A, -- implement atomic extension?
|
CPU_EXTENSION_RISCV_A => CPU_EXTENSION_RISCV_A, -- implement atomic extension?
|
CPU_EXTENSION_RISCV_C => CPU_EXTENSION_RISCV_C, -- implement compressed extension?
|
CPU_EXTENSION_RISCV_C => CPU_EXTENSION_RISCV_C, -- implement compressed extension?
|
CPU_EXTENSION_RISCV_E => CPU_EXTENSION_RISCV_E, -- implement embedded RF extension?
|
CPU_EXTENSION_RISCV_E => CPU_EXTENSION_RISCV_E, -- implement embedded RF extension?
|
CPU_EXTENSION_RISCV_M => CPU_EXTENSION_RISCV_M, -- implement muld/div extension?
|
CPU_EXTENSION_RISCV_M => CPU_EXTENSION_RISCV_M, -- implement muld/div extension?
|
CPU_EXTENSION_RISCV_U => CPU_EXTENSION_RISCV_U, -- implement user mode extension?
|
CPU_EXTENSION_RISCV_U => CPU_EXTENSION_RISCV_U, -- implement user mode extension?
|
CPU_EXTENSION_RISCV_Zbb => CPU_EXTENSION_RISCV_Zbb, -- implement basic bit-manipulation sub-extension?
|
CPU_EXTENSION_RISCV_Zbb => CPU_EXTENSION_RISCV_Zbb, -- implement basic bit-manipulation sub-extension?
|
CPU_EXTENSION_RISCV_Zfinx => CPU_EXTENSION_RISCV_Zfinx, -- implement 32-bit floating-point extension (using INT reg!)
|
CPU_EXTENSION_RISCV_Zfinx => CPU_EXTENSION_RISCV_Zfinx, -- implement 32-bit floating-point extension (using INT reg!)
|
CPU_EXTENSION_RISCV_Zicsr => CPU_EXTENSION_RISCV_Zicsr, -- implement CSR system?
|
CPU_EXTENSION_RISCV_Zicsr => CPU_EXTENSION_RISCV_Zicsr, -- implement CSR system?
|
CPU_EXTENSION_RISCV_Zifencei => CPU_EXTENSION_RISCV_Zifencei, -- implement instruction stream sync.?
|
CPU_EXTENSION_RISCV_Zifencei => CPU_EXTENSION_RISCV_Zifencei, -- implement instruction stream sync.?
|
-- Extension Options --
|
-- Extension Options --
|
FAST_MUL_EN => FAST_MUL_EN, -- use DSPs for M extension's multiplier
|
FAST_MUL_EN => FAST_MUL_EN, -- use DSPs for M extension's multiplier
|
FAST_SHIFT_EN => FAST_SHIFT_EN, -- use barrel shifter for shift operations
|
FAST_SHIFT_EN => FAST_SHIFT_EN, -- use barrel shifter for shift operations
|
CPU_CNT_WIDTH => CPU_CNT_WIDTH, -- total width of CPU cycle and instret counters (0..64)
|
CPU_CNT_WIDTH => CPU_CNT_WIDTH, -- total width of CPU cycle and instret counters (0..64)
|
-- Physical Memory Protection (PMP) --
|
-- Physical Memory Protection (PMP) --
|
PMP_NUM_REGIONS => PMP_NUM_REGIONS, -- number of regions (0..64)
|
PMP_NUM_REGIONS => PMP_NUM_REGIONS, -- number of regions (0..64)
|
PMP_MIN_GRANULARITY => PMP_MIN_GRANULARITY, -- minimal region granularity in bytes, has to be a power of 2, min 8 bytes
|
PMP_MIN_GRANULARITY => PMP_MIN_GRANULARITY, -- minimal region granularity in bytes, has to be a power of 2, min 8 bytes
|
-- Hardware Performance Monitors (HPM) --
|
-- Hardware Performance Monitors (HPM) --
|
HPM_NUM_CNTS => HPM_NUM_CNTS, -- number of implemented HPM counters (0..29)
|
HPM_NUM_CNTS => HPM_NUM_CNTS, -- number of implemented HPM counters (0..29)
|
HPM_CNT_WIDTH => HPM_CNT_WIDTH, -- total size of HPM counters (0..64)
|
HPM_CNT_WIDTH => HPM_CNT_WIDTH, -- total size of HPM counters (0..64)
|
-- Internal Instruction memory --
|
-- Internal Instruction memory --
|
MEM_INT_IMEM_EN => MEM_INT_IMEM_EN, -- implement processor-internal instruction memory
|
MEM_INT_IMEM_EN => MEM_INT_IMEM_EN, -- implement processor-internal instruction memory
|
MEM_INT_IMEM_SIZE => MEM_INT_IMEM_SIZE, -- size of processor-internal instruction memory in bytes
|
MEM_INT_IMEM_SIZE => MEM_INT_IMEM_SIZE, -- size of processor-internal instruction memory in bytes
|
-- Internal Data memory --
|
-- Internal Data memory --
|
MEM_INT_DMEM_EN => MEM_INT_DMEM_EN, -- implement processor-internal data memory
|
MEM_INT_DMEM_EN => MEM_INT_DMEM_EN, -- implement processor-internal data memory
|
MEM_INT_DMEM_SIZE => MEM_INT_DMEM_SIZE, -- size of processor-internal data memory in bytes
|
MEM_INT_DMEM_SIZE => MEM_INT_DMEM_SIZE, -- size of processor-internal data memory in bytes
|
-- Internal Cache memory --
|
-- Internal Cache memory --
|
ICACHE_EN => ICACHE_EN, -- implement instruction cache
|
ICACHE_EN => ICACHE_EN, -- implement instruction cache
|
ICACHE_NUM_BLOCKS => ICACHE_NUM_BLOCKS, -- i-cache: number of blocks (min 1), has to be a power of 2
|
ICACHE_NUM_BLOCKS => ICACHE_NUM_BLOCKS, -- i-cache: number of blocks (min 1), has to be a power of 2
|
ICACHE_BLOCK_SIZE => ICACHE_BLOCK_SIZE, -- i-cache: block size in bytes (min 4), has to be a power of 2
|
ICACHE_BLOCK_SIZE => ICACHE_BLOCK_SIZE, -- i-cache: block size in bytes (min 4), has to be a power of 2
|
ICACHE_ASSOCIATIVITY => ICACHE_ASSOCIATIVITY, -- i-cache: associativity / number of sets (1=direct_mapped), has to be a power of 2
|
ICACHE_ASSOCIATIVITY => ICACHE_ASSOCIATIVITY, -- i-cache: associativity / number of sets (1=direct_mapped), has to be a power of 2
|
-- External memory interface --
|
-- External memory interface --
|
MEM_EXT_EN => true, -- implement external memory bus interface?
|
MEM_EXT_EN => true, -- implement external memory bus interface?
|
MEM_EXT_TIMEOUT => 0, -- cycles after a pending bus access auto-terminates (0 = disabled)
|
MEM_EXT_TIMEOUT => 0, -- cycles after a pending bus access auto-terminates (0 = disabled)
|
MEM_EXT_PIPE_MODE => false, -- protocol: false=classic/standard wishbone mode, true=pipelined wishbone mode
|
MEM_EXT_PIPE_MODE => false, -- protocol: false=classic/standard wishbone mode, true=pipelined wishbone mode
|
MEM_EXT_BIG_ENDIAN => false, -- byte order: true=big-endian, false=little-endian
|
MEM_EXT_BIG_ENDIAN => false, -- byte order: true=big-endian, false=little-endian
|
MEM_EXT_ASYNC_RX => false, -- use register buffer for RX data when false
|
MEM_EXT_ASYNC_RX => false, -- use register buffer for RX data when false
|
-- External Interrupts Controller (XIRQ) --
|
-- External Interrupts Controller (XIRQ) --
|
XIRQ_NUM_CH => XIRQ_NUM_CH, -- number of external IRQ channels (0..32)
|
XIRQ_NUM_CH => XIRQ_NUM_CH, -- number of external IRQ channels (0..32)
|
XIRQ_TRIGGER_TYPE => XIRQ_TRIGGER_TYPE_INT, -- trigger type: 0=level, 1=edge
|
XIRQ_TRIGGER_TYPE => XIRQ_TRIGGER_TYPE_INT, -- trigger type: 0=level, 1=edge
|
XIRQ_TRIGGER_POLARITY => XIRQ_TRIGGER_POLARITY_INT, -- trigger polarity: 0=low-level/falling-edge, 1=high-level/rising-edge
|
XIRQ_TRIGGER_POLARITY => XIRQ_TRIGGER_POLARITY_INT, -- trigger polarity: 0=low-level/falling-edge, 1=high-level/rising-edge
|
-- Processor peripherals --
|
-- Processor peripherals --
|
IO_GPIO_EN => IO_GPIO_EN, -- implement general purpose input/output port unit (GPIO)?
|
IO_GPIO_EN => IO_GPIO_EN, -- implement general purpose input/output port unit (GPIO)?
|
IO_MTIME_EN => IO_MTIME_EN, -- implement machine system timer (MTIME)?
|
IO_MTIME_EN => IO_MTIME_EN, -- implement machine system timer (MTIME)?
|
IO_UART0_EN => IO_UART0_EN, -- implement primary universal asynchronous receiver/transmitter (UART0)?
|
IO_UART0_EN => IO_UART0_EN, -- implement primary universal asynchronous receiver/transmitter (UART0)?
|
IO_UART1_EN => IO_UART1_EN, -- implement secondary universal asynchronous receiver/transmitter (UART1)?
|
IO_UART1_EN => IO_UART1_EN, -- implement secondary universal asynchronous receiver/transmitter (UART1)?
|
IO_SPI_EN => IO_SPI_EN, -- implement serial peripheral interface (SPI)?
|
IO_SPI_EN => IO_SPI_EN, -- implement serial peripheral interface (SPI)?
|
IO_TWI_EN => IO_TWI_EN, -- implement two-wire interface (TWI)?
|
IO_TWI_EN => IO_TWI_EN, -- implement two-wire interface (TWI)?
|
IO_PWM_NUM_CH => IO_PWM_NUM_CH, -- number of PWM channels to implement (0..60); 0 = disabled
|
IO_PWM_NUM_CH => IO_PWM_NUM_CH, -- number of PWM channels to implement (0..60); 0 = disabled
|
IO_WDT_EN => IO_WDT_EN, -- implement watch dog timer (WDT)?
|
IO_WDT_EN => IO_WDT_EN, -- implement watch dog timer (WDT)?
|
IO_TRNG_EN => IO_TRNG_EN, -- implement true random number generator (TRNG)?
|
IO_TRNG_EN => IO_TRNG_EN, -- implement true random number generator (TRNG)?
|
IO_CFS_EN => IO_CFS_EN, -- implement custom functions subsystem (CFS)?
|
IO_CFS_EN => IO_CFS_EN, -- implement custom functions subsystem (CFS)?
|
IO_CFS_CONFIG => IO_CFS_CONFIG_INT, -- custom CFS configuration generic
|
IO_CFS_CONFIG => IO_CFS_CONFIG_INT, -- custom CFS configuration generic
|
IO_CFS_IN_SIZE => IO_CFS_IN_SIZE, -- size of CFS input conduit in bits
|
IO_CFS_IN_SIZE => IO_CFS_IN_SIZE, -- size of CFS input conduit in bits
|
IO_CFS_OUT_SIZE => IO_CFS_OUT_SIZE, -- size of CFS output conduit in bits
|
IO_CFS_OUT_SIZE => IO_CFS_OUT_SIZE, -- size of CFS output conduit in bits
|
IO_NEOLED_EN => IO_NEOLED_EN -- implement NeoPixel-compatible smart LED interface (NEOLED)?
|
IO_NEOLED_EN => IO_NEOLED_EN -- implement NeoPixel-compatible smart LED interface (NEOLED)?
|
)
|
)
|
port map (
|
port map (
|
-- Global control --
|
-- Global control --
|
clk_i => clk_i_int, -- global clock, rising edge
|
clk_i => clk_i_int, -- global clock, rising edge
|
rstn_i => rstn_i_int, -- global reset, low-active, async
|
rstn_i => rstn_i_int, -- global reset, low-active, async
|
-- JTAG on-chip debugger interface (available if ON_CHIP_DEBUGGER_EN = true) --
|
-- JTAG on-chip debugger interface (available if ON_CHIP_DEBUGGER_EN = true) --
|
jtag_trst_i => jtag_trst_i_int, -- low-active TAP reset (optional)
|
jtag_trst_i => jtag_trst_i_int, -- low-active TAP reset (optional)
|
jtag_tck_i => jtag_tck_i_int, -- serial clock
|
jtag_tck_i => jtag_tck_i_int, -- serial clock
|
jtag_tdi_i => jtag_tdi_i_int, -- serial data input
|
jtag_tdi_i => jtag_tdi_i_int, -- serial data input
|
jtag_tdo_o => jtag_tdo_o_int, -- serial data output
|
jtag_tdo_o => jtag_tdo_o_int, -- serial data output
|
jtag_tms_i => jtag_tms_i_int, -- mode select
|
jtag_tms_i => jtag_tms_i_int, -- mode select
|
-- Wishbone bus interface (available if MEM_EXT_EN = true) --
|
-- Wishbone bus interface (available if MEM_EXT_EN = true) --
|
wb_tag_o => wb_core.tag, -- tag
|
wb_tag_o => wb_core.tag, -- tag
|
wb_adr_o => wb_core.adr, -- address
|
wb_adr_o => wb_core.adr, -- address
|
wb_dat_i => wb_core.di, -- read data
|
wb_dat_i => wb_core.di, -- read data
|
wb_dat_o => wb_core.do, -- write data
|
wb_dat_o => wb_core.do, -- write data
|
wb_we_o => wb_core.we, -- read/write
|
wb_we_o => wb_core.we, -- read/write
|
wb_sel_o => wb_core.sel, -- byte enable
|
wb_sel_o => wb_core.sel, -- byte enable
|
wb_stb_o => wb_core.stb, -- strobe
|
wb_stb_o => wb_core.stb, -- strobe
|
wb_cyc_o => wb_core.cyc, -- valid cycle
|
wb_cyc_o => wb_core.cyc, -- valid cycle
|
wb_lock_o => wb_core.lock, -- exclusive access request
|
wb_lock_o => wb_core.lock, -- exclusive access request
|
wb_ack_i => wb_core.ack, -- transfer acknowledge
|
wb_ack_i => wb_core.ack, -- transfer acknowledge
|
wb_err_i => wb_core.err, -- transfer error
|
wb_err_i => wb_core.err, -- transfer error
|
-- Advanced memory control signals (available if MEM_EXT_EN = true) --
|
-- Advanced memory control signals (available if MEM_EXT_EN = true) --
|
fence_o => open, -- indicates an executed FENCE operation
|
fence_o => open, -- indicates an executed FENCE operation
|
fencei_o => open, -- indicates an executed FENCEI operation
|
fencei_o => open, -- indicates an executed FENCEI operation
|
-- GPIO (available if IO_GPIO_EN = true) --
|
-- GPIO (available if IO_GPIO_EN = true) --
|
gpio_o => gpio_o_int, -- parallel output
|
gpio_o => gpio_o_int, -- parallel output
|
gpio_i => gpio_i_int, -- parallel input
|
gpio_i => gpio_i_int, -- parallel input
|
-- primary UART0 (available if IO_UART0_EN = true) --
|
-- primary UART0 (available if IO_UART0_EN = true) --
|
uart0_txd_o => uart0_txd_o_int, -- UART0 send data
|
uart0_txd_o => uart0_txd_o_int, -- UART0 send data
|
uart0_rxd_i => uart0_rxd_i_int, -- UART0 receive data
|
uart0_rxd_i => uart0_rxd_i_int, -- UART0 receive data
|
uart0_rts_o => uart0_rts_o_int, -- hw flow control: UART0.RX ready to receive ("RTR"), low-active, optional
|
uart0_rts_o => uart0_rts_o_int, -- hw flow control: UART0.RX ready to receive ("RTR"), low-active, optional
|
uart0_cts_i => uart0_cts_i_int, -- hw flow control: UART0.TX allowed to transmit, low-active, optional
|
uart0_cts_i => uart0_cts_i_int, -- hw flow control: UART0.TX allowed to transmit, low-active, optional
|
-- secondary UART1 (available if IO_UART1_EN = true) --
|
-- secondary UART1 (available if IO_UART1_EN = true) --
|
uart1_txd_o => uart1_txd_o_int, -- UART1 send data
|
uart1_txd_o => uart1_txd_o_int, -- UART1 send data
|
uart1_rxd_i => uart1_rxd_i_int, -- UART1 receive data
|
uart1_rxd_i => uart1_rxd_i_int, -- UART1 receive data
|
uart1_rts_o => uart1_rts_o_int, -- hw flow control: UART1.RX ready to receive ("RTR"), low-active, optional
|
uart1_rts_o => uart1_rts_o_int, -- hw flow control: UART1.RX ready to receive ("RTR"), low-active, optional
|
uart1_cts_i => uart1_cts_i_int, -- hw flow control: UART1.TX allowed to transmit, low-active, optional
|
uart1_cts_i => uart1_cts_i_int, -- hw flow control: UART1.TX allowed to transmit, low-active, optional
|
-- SPI (available if IO_SPI_EN = true) --
|
-- SPI (available if IO_SPI_EN = true) --
|
spi_sck_o => spi_sck_o_int, -- SPI serial clock
|
spi_sck_o => spi_sck_o_int, -- SPI serial clock
|
spi_sdo_o => spi_sdo_o_int, -- controller data out, peripheral data in
|
spi_sdo_o => spi_sdo_o_int, -- controller data out, peripheral data in
|
spi_sdi_i => spi_sdi_i_int, -- controller data in, peripheral data out
|
spi_sdi_i => spi_sdi_i_int, -- controller data in, peripheral data out
|
spi_csn_o => spi_csn_o_int, -- SPI CS
|
spi_csn_o => spi_csn_o_int, -- SPI CS
|
-- TWI (available if IO_TWI_EN = true) --
|
-- TWI (available if IO_TWI_EN = true) --
|
twi_sda_io => twi_sda_io, -- twi serial data line
|
twi_sda_io => twi_sda_io, -- twi serial data line
|
twi_scl_io => twi_scl_io, -- twi serial clock line
|
twi_scl_io => twi_scl_io, -- twi serial clock line
|
-- PWM available if IO_PWM_NUM_CH > 0) --
|
-- PWM available if IO_PWM_NUM_CH > 0) --
|
pwm_o => pwm_o_int, -- pwm channels
|
pwm_o => pwm_o_int, -- pwm channels
|
-- Custom Functions Subsystem IO (available if IO_CFS_EN = true) --
|
-- Custom Functions Subsystem IO (available if IO_CFS_EN = true) --
|
cfs_in_i => cfs_in_i_int, -- custom inputs
|
cfs_in_i => cfs_in_i_int, -- custom inputs
|
cfs_out_o => cfs_out_o_int, -- custom outputs
|
cfs_out_o => cfs_out_o_int, -- custom outputs
|
-- NeoPixel-compatible smart LED interface (available if IO_NEOLED_EN = true) --
|
-- NeoPixel-compatible smart LED interface (available if IO_NEOLED_EN = true) --
|
neoled_o => neoled_o_int, -- async serial data line
|
neoled_o => neoled_o_int, -- async serial data line
|
-- System time --
|
-- System time --
|
mtime_i => (others => '0'), -- current system time from ext. MTIME (if IO_MTIME_EN = false)
|
mtime_i => (others => '0'), -- current system time from ext. MTIME (if IO_MTIME_EN = false)
|
mtime_o => open, -- current system time from int. MTIME (if IO_MTIME_EN = true)
|
mtime_o => open, -- current system time from int. MTIME (if IO_MTIME_EN = true)
|
-- External platform interrupts (available if XIRQ_NUM_CH > 0) --
|
-- External platform interrupts (available if XIRQ_NUM_CH > 0) --
|
xirq_i => xirq_i_int, -- IRQ channels
|
xirq_i => xirq_i_int, -- IRQ channels
|
-- CPU Interrupts --
|
-- CPU Interrupts --
|
nm_irq_i => nm_irq_i_int, -- non-maskable interrupt
|
|
mtime_irq_i => '0', -- machine timer interrupt, available if IO_MTIME_EN = false
|
mtime_irq_i => '0', -- machine timer interrupt, available if IO_MTIME_EN = false
|
msw_irq_i => msw_irq_i_int, -- machine software interrupt
|
msw_irq_i => msw_irq_i_int, -- machine software interrupt
|
mext_irq_i => mext_irq_i_int -- machine external interrupt
|
mext_irq_i => mext_irq_i_int -- machine external interrupt
|
);
|
);
|
|
|
-- type conversion --
|
-- type conversion --
|
gpio_o <= std_logic_vector(gpio_o_int);
|
gpio_o <= std_logic_vector(gpio_o_int);
|
gpio_i_int <= std_ulogic_vector(gpio_i);
|
gpio_i_int <= std_ulogic_vector(gpio_i);
|
|
|
jtag_trst_i_int <= std_ulogic(jtag_trst_i);
|
jtag_trst_i_int <= std_ulogic(jtag_trst_i);
|
jtag_tck_i_int <= std_ulogic(jtag_tck_i);
|
jtag_tck_i_int <= std_ulogic(jtag_tck_i);
|
jtag_tdi_i_int <= std_ulogic(jtag_tdi_i);
|
jtag_tdi_i_int <= std_ulogic(jtag_tdi_i);
|
jtag_tdo_o <= std_logic(jtag_tdo_o_int);
|
jtag_tdo_o <= std_logic(jtag_tdo_o_int);
|
jtag_tms_i_int <= std_ulogic(jtag_tms_i);
|
jtag_tms_i_int <= std_ulogic(jtag_tms_i);
|
|
|
uart0_txd_o <= std_logic(uart0_txd_o_int);
|
uart0_txd_o <= std_logic(uart0_txd_o_int);
|
uart0_rxd_i_int <= std_ulogic(uart0_rxd_i);
|
uart0_rxd_i_int <= std_ulogic(uart0_rxd_i);
|
uart1_txd_o <= std_logic(uart0_txd_o_int);
|
uart1_txd_o <= std_logic(uart0_txd_o_int);
|
uart1_rxd_i_int <= std_ulogic(uart0_rxd_i);
|
uart1_rxd_i_int <= std_ulogic(uart0_rxd_i);
|
|
|
spi_sck_o <= std_logic(spi_sck_o_int);
|
spi_sck_o <= std_logic(spi_sck_o_int);
|
spi_sdo_o <= std_logic(spi_sdo_o_int);
|
spi_sdo_o <= std_logic(spi_sdo_o_int);
|
spi_sdi_i_int <= std_ulogic(spi_sdi_i);
|
spi_sdi_i_int <= std_ulogic(spi_sdi_i);
|
spi_csn_o <= std_logic_vector(spi_csn_o_int);
|
spi_csn_o <= std_logic_vector(spi_csn_o_int);
|
|
|
pwm_o <= std_logic_vector(pwm_o_int);
|
pwm_o <= std_logic_vector(pwm_o_int);
|
|
|
cfs_in_i_int <= std_ulogic_vector(cfs_in_i);
|
cfs_in_i_int <= std_ulogic_vector(cfs_in_i);
|
cfs_out_o <= std_logic_vector(cfs_out_o_int);
|
cfs_out_o <= std_logic_vector(cfs_out_o_int);
|
|
|
neoled_o <= std_logic(neoled_o_int);
|
neoled_o <= std_logic(neoled_o_int);
|
|
|
|
xirq_i_int <= std_ulogic_vector(xirq_i);
|
|
|
|
msw_irq_i_int <= std_ulogic(msw_irq_i);
|
mext_irq_i_int <= std_ulogic(mext_irq_i);
|
mext_irq_i_int <= std_ulogic(mext_irq_i);
|
|
|
|
|
-- Wishbone to AXI4-Lite Bridge -----------------------------------------------------------
|
-- Wishbone to AXI4-Lite Bridge -----------------------------------------------------------
|
-- -------------------------------------------------------------------------------------------
|
-- -------------------------------------------------------------------------------------------
|
|
|
-- access arbiter --
|
-- access arbiter --
|
axi_access_arbiter: process(rstn_i_int, clk_i_int)
|
axi_access_arbiter: process(rstn_i_int, clk_i_int)
|
begin
|
begin
|
if (rstn_i_int = '0') then
|
if (rstn_i_int = '0') then
|
ctrl.radr_received <= '0';
|
ctrl.radr_received <= '0';
|
ctrl.wadr_received <= '0';
|
ctrl.wadr_received <= '0';
|
ctrl.wdat_received <= '0';
|
ctrl.wdat_received <= '0';
|
elsif rising_edge(clk_i_int) then
|
elsif rising_edge(clk_i_int) then
|
if (wb_core.cyc = '0') then -- idle
|
if (wb_core.cyc = '0') then -- idle
|
ctrl.radr_received <= '0';
|
ctrl.radr_received <= '0';
|
ctrl.wadr_received <= '0';
|
ctrl.wadr_received <= '0';
|
ctrl.wdat_received <= '0';
|
ctrl.wdat_received <= '0';
|
else -- busy
|
else -- busy
|
-- "read address received" flag --
|
-- "read address received" flag --
|
if (wb_core.we = '0') then -- pending READ
|
if (wb_core.we = '0') then -- pending READ
|
if (m_axi_arready = '1') then -- read address received by interconnect?
|
if (m_axi_arready = '1') then -- read address received by interconnect?
|
ctrl.radr_received <= '1';
|
ctrl.radr_received <= '1';
|
end if;
|
end if;
|
end if;
|
end if;
|
-- "write address received" flag --
|
-- "write address received" flag --
|
if (wb_core.we = '1') then -- pending WRITE
|
if (wb_core.we = '1') then -- pending WRITE
|
if (m_axi_awready = '1') then -- write address received by interconnect?
|
if (m_axi_awready = '1') then -- write address received by interconnect?
|
ctrl.wadr_received <= '1';
|
ctrl.wadr_received <= '1';
|
end if;
|
end if;
|
end if;
|
end if;
|
-- "write data received" flag --
|
-- "write data received" flag --
|
if (wb_core.we = '1') then -- pending WRITE
|
if (wb_core.we = '1') then -- pending WRITE
|
if (m_axi_wready = '1') then -- write data received by interconnect?
|
if (m_axi_wready = '1') then -- write data received by interconnect?
|
ctrl.wdat_received <= '1';
|
ctrl.wdat_received <= '1';
|
end if;
|
end if;
|
end if;
|
end if;
|
end if;
|
end if;
|
end if;
|
end if;
|
end process axi_access_arbiter;
|
end process axi_access_arbiter;
|
|
|
|
|
-- AXI4-Lite Global Signals --
|
-- AXI4-Lite Global Signals --
|
clk_i_int <= std_ulogic(m_axi_aclk);
|
clk_i_int <= std_ulogic(m_axi_aclk);
|
rstn_i_int <= std_ulogic(m_axi_aresetn);
|
rstn_i_int <= std_ulogic(m_axi_aresetn);
|
|
|
|
|
-- AXI4-Lite Read Address Channel --
|
-- AXI4-Lite Read Address Channel --
|
m_axi_araddr <= std_logic_vector(wb_core.adr);
|
m_axi_araddr <= std_logic_vector(wb_core.adr);
|
m_axi_arvalid <= std_logic((wb_core.cyc and (not wb_core.we)) and (not ctrl.radr_received));
|
m_axi_arvalid <= std_logic((wb_core.cyc and (not wb_core.we)) and (not ctrl.radr_received));
|
--m_axi_arprot <= "000"; -- recommended by Xilinx
|
--m_axi_arprot <= "000"; -- recommended by Xilinx
|
m_axi_arprot(0) <= wb_core.tag(0); -- 0:unprivileged access, 1:privileged access
|
m_axi_arprot(0) <= wb_core.tag(0); -- 0:unprivileged access, 1:privileged access
|
m_axi_arprot(1) <= wb_core.tag(1); -- 0:secure access, 1:non-secure access
|
m_axi_arprot(1) <= wb_core.tag(1); -- 0:secure access, 1:non-secure access
|
m_axi_arprot(2) <= wb_core.tag(2); -- 0:data access, 1:instruction access
|
m_axi_arprot(2) <= wb_core.tag(2); -- 0:data access, 1:instruction access
|
|
|
-- AXI4-Lite Read Data Channel --
|
-- AXI4-Lite Read Data Channel --
|
m_axi_rready <= std_logic(wb_core.cyc and (not wb_core.we));
|
m_axi_rready <= std_logic(wb_core.cyc and (not wb_core.we));
|
wb_core.di <= std_ulogic_vector(m_axi_rdata);
|
wb_core.di <= std_ulogic_vector(m_axi_rdata);
|
ack_read <= std_ulogic(m_axi_rvalid);
|
ack_read <= std_ulogic(m_axi_rvalid);
|
err_read <= '0' when (m_axi_rresp = "00") else '1'; -- read response = ok? check this signal only when m_axi_rvalid = '1'
|
err_read <= '0' when (m_axi_rresp = "00") else '1'; -- read response = ok? check this signal only when m_axi_rvalid = '1'
|
|
|
|
|
-- AXI4-Lite Write Address Channel --
|
-- AXI4-Lite Write Address Channel --
|
m_axi_awaddr <= std_logic_vector(wb_core.adr);
|
m_axi_awaddr <= std_logic_vector(wb_core.adr);
|
m_axi_awvalid <= std_logic((wb_core.cyc and wb_core.we) and (not ctrl.wadr_received));
|
m_axi_awvalid <= std_logic((wb_core.cyc and wb_core.we) and (not ctrl.wadr_received));
|
--m_axi_awprot <= "000"; -- recommended by Xilinx
|
--m_axi_awprot <= "000"; -- recommended by Xilinx
|
m_axi_awprot(0) <= wb_core.tag(0); -- 0:unprivileged access, 1:privileged access
|
m_axi_awprot(0) <= wb_core.tag(0); -- 0:unprivileged access, 1:privileged access
|
m_axi_awprot(1) <= wb_core.tag(1); -- 0:secure access, 1:non-secure access
|
m_axi_awprot(1) <= wb_core.tag(1); -- 0:secure access, 1:non-secure access
|
m_axi_awprot(2) <= wb_core.tag(2); -- 0:data access, 1:instruction access
|
m_axi_awprot(2) <= wb_core.tag(2); -- 0:data access, 1:instruction access
|
|
|
-- AXI4-Lite Write Data Channel --
|
-- AXI4-Lite Write Data Channel --
|
m_axi_wdata <= std_logic_vector(wb_core.do);
|
m_axi_wdata <= std_logic_vector(wb_core.do);
|
m_axi_wvalid <= std_logic((wb_core.cyc and wb_core.we) and (not ctrl.wdat_received));
|
m_axi_wvalid <= std_logic((wb_core.cyc and wb_core.we) and (not ctrl.wdat_received));
|
m_axi_wstrb <= std_logic_vector(wb_core.sel); -- byte-enable
|
m_axi_wstrb <= std_logic_vector(wb_core.sel); -- byte-enable
|
|
|
-- AXI4-Lite Write Response Channel --
|
-- AXI4-Lite Write Response Channel --
|
m_axi_bready <= std_logic(wb_core.cyc and wb_core.we);
|
m_axi_bready <= std_logic(wb_core.cyc and wb_core.we);
|
ack_write <= std_ulogic(m_axi_bvalid);
|
ack_write <= std_ulogic(m_axi_bvalid);
|
err_write <= '0' when (m_axi_bresp = "00") else '1'; -- write response = ok? check this signal only when m_axi_bvalid = '1'
|
err_write <= '0' when (m_axi_bresp = "00") else '1'; -- write response = ok? check this signal only when m_axi_bvalid = '1'
|
|
|
|
|
-- Wishbone transfer termination --
|
-- Wishbone transfer termination --
|
wb_core.ack <= ack_read or ack_write;
|
wb_core.ack <= ack_read or ack_write;
|
wb_core.err <= (ack_read and err_read) or (ack_write and err_write) or wb_core.lock;
|
wb_core.err <= (ack_read and err_read) or (ack_write and err_write) or wb_core.lock;
|
|
|
|
|
end architecture;
|
end architecture;
|
|
|