srdl2sv/examples/interrupt_hierarchy/srdl2sv_out/interrupt_hierarchy.sv

2800 lines
97 KiB
Systemverilog
Raw Normal View History

/*****************************************************************
*
*
*
*
*
*
*
*
* The present RTL was generated by srdl2sv v0.01. The RTL and all
* templates the RTL is derived from are licensed under the MIT
* license. The license is shown below.
*
* srdl2sv itself is licensed under GPLv3.
*
* Maintainer : Dennis Potter <dennis@dennispotter.eu>
* Report Bugs: https://github.com/Silicon1602/srdl2sv/issues
*
* ===GENERATION INFORMATION======================================
*
* Generation information:
* - User: : dpotter
* - Time : October 30 2021 23:34:49
* - Path : /home/dpotter/srdl2sv/examples/interrupt_hierarchy
* - RDL file : ['interrupt_hierarchy.rdl']
* - Hostname : ArchXPS
*
* RDL include directories:
* -
*
* Commandline arguments to srdl2sv:
* - Ouput Directory : ./srdl2sv_out
* - Stream Log Level : INFO
* - File Log Level : NONE
* - Use Real Tabs : False
* - Tab Width : 4
* - Enums Enabled : True
* - Register Bus Type: amba3ahblite
* - Address width : 32
* - Byte enables : True
* - Descriptions : {'AddrMap': False, 'RegFile': False, 'Memory': False, 'Register': False, 'Field': False}
*
* ===LICENSE OF INTERRUPT_HIERARCHY.SV=====================================
*
* Copyright 2021 Dennis Potter <dennis@dennispotter.eu>
*
* Permission is hereby granted, free of charge, to any person
* obtaining a copy of this software and associated documentation
* files (the "Software"), to deal in the Software without
* restriction, including without limitation the rights to use,
* copy, modify, merge, publish, distribute, sublicense, and/or
* sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following
* conditions:
*
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES
* OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT
* HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
* WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
* OTHER DEALINGS IN THE SOFTWARE.
****************************************************************/
module interrupt_hierarchy
(
// Resets
input field_reset_n,
// Inputs
input clk ,
input HRESETn ,
input [31:0] HADDR ,
input HWRITE ,
input [2:0] HSIZE ,
input [3:0] HPROT ,
input [1:0] HTRANS ,
input [32-1:0] HWDATA ,
input HSEL ,
input logic [0:0] block_a_int__crc_error_in ,
input logic [0:0] block_a_int__len_error_in ,
input logic [0:0] block_a_int__multi_bit_ecc_error_in,
input logic [3:0] block_a_int__active_ecc_master_in ,
input logic [0:0] block_b_int__crc_error_in ,
input logic [0:0] block_b_int__len_error_in ,
input logic [0:0] block_b_int__multi_bit_ecc_error_in,
input logic [3:0] block_b_int__active_ecc_master_in ,
input logic [0:0] block_c_int__crc_error_in ,
input logic [0:0] block_c_int__len_error_in ,
input logic [0:0] block_c_int__multi_bit_ecc_error_in,
input logic [3:0] block_c_int__active_ecc_master_in ,
input logic [0:0] block_d_int__crc_error_in ,
input logic [0:0] block_d_int__len_error_in ,
input logic [0:0] block_d_int__multi_bit_ecc_error_in,
input logic [3:0] block_d_int__active_ecc_master_in ,
// Outputs
output HREADYOUT ,
output HRESP ,
output [32-1:0] HRDATA ,
output logic block_a_int_intr,
output logic block_a_int_halt,
output logic block_b_int_intr,
output logic block_b_int_halt,
output logic block_c_int_intr,
output logic block_c_int_halt,
output logic block_d_int_intr,
output logic block_d_int_halt,
output logic master_int_intr ,
output logic master_halt_intr,
output logic master_halt_halt,
output logic global_int_intr ,
output logic global_int_halt
);
// Internal signals
srdl2sv_widget_if #(.ADDR_W (32), .DATA_W(32)) widget_if;
/*******************************************************************
* AMBA 3 AHB Lite Widget
* ======================
* Naming conventions
* - widget_if -> SystemVerilog interface to between widgets
* and the internal srdl2sv registers.
* - H* -> Signals as defined in AMBA3 AHB Lite
* specification
* - clk -> Clock that drives registers and the bus
*******************************************************************/
srdl2sv_amba3ahblite
#(.FLOP_REGISTER_IF (0),
.BUS_BITS (32),
.NO_BYTE_ENABLE (0))
srdl2sv_amba3ahblite_inst
(// Bus protocol
.HRESETn,
.HCLK (clk),
.HADDR,
.HWRITE,
.HSIZE,
.HPROT,
.HTRANS,
.HWDATA,
.HSEL,
.HREADYOUT,
.HRESP,
.HRDATA,
// Interface to internal logic
.widget_if);
/*******************************************************************
/*******************************************************************
/* REGISTER : block_a_int
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_a_int_active ;
logic block_a_int_sw_wr ;
logic [31:0] block_a_int_data_mux_in ;
logic block_a_int_rdy_mux_in ;
logic block_a_int_err_mux_in ;
logic [0:0] block_a_int__crc_error_q ;
logic [0:0] block_a_int__crc_error_sticky_latch ;
logic [0:0] block_a_int__len_error_q ;
logic [0:0] block_a_int__len_error_sticky_latch ;
logic [0:0] block_a_int__multi_bit_ecc_error_q ;
logic [0:0] block_a_int__multi_bit_ecc_error_sticky_latch;
logic [3:0] block_a_int__active_ecc_master_q ;
logic [3:0] block_a_int__active_ecc_master_sticky_latch;
// Register-activation for 'block_a_int'
assign block_a_int_active = widget_if.addr == 0;
assign block_a_int_sw_wr = block_a_int_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_a_int[0:0])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_int__crc_error_q <= 1'd0;
end
else
begin
if (block_a_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_a_int__crc_error_q[0:0] <= block_a_int__crc_error_q[0:0] & ~widget_if.w_data[0:0];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_a_int__crc_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_a_int__crc_error_q[i] <= 1'b1;
end
end
end
end // of block_a_int__crc_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_a_int__crc_error_sticky_latch = block_a_int__crc_error_in;
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_a_int[1:1])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_int__len_error_q <= 1'd0;
end
else
begin
if (block_a_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_a_int__len_error_q[0:0] <= block_a_int__len_error_q[0:0] & ~widget_if.w_data[1:1];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_a_int__len_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_a_int__len_error_q[i] <= 1'b1;
end
end
end
end // of block_a_int__len_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_a_int__len_error_sticky_latch = block_a_int__len_error_in;
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_a_int[2:2])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_int__multi_bit_ecc_error_q <= 1'd0;
end
else
begin
if (block_a_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_a_int__multi_bit_ecc_error_q[0:0] <= block_a_int__multi_bit_ecc_error_q[0:0] & ~widget_if.w_data[2:2];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_a_int__multi_bit_ecc_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_a_int__multi_bit_ecc_error_q[i] <= 1'b1;
end
end
end
end // of block_a_int__multi_bit_ecc_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_a_int__multi_bit_ecc_error_sticky_latch = block_a_int__multi_bit_ecc_error_in;
//-----------------FIELD SUMMARY-----------------
// name : active_ecc_master (block_a_int[7:4])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'sticky']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_int__active_ecc_master_q <= 4'd0;
end
else
begin
if (block_a_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_a_int__active_ecc_master_q[3:0] <= block_a_int__active_ecc_master_q[3:0] & ~widget_if.w_data[7:4];
end
end
else
if (|block_a_int__active_ecc_master_sticky_latch && !(|block_a_int__active_ecc_master_q))
begin
// Sticky. Keep value until software clears it
block_a_int__active_ecc_master_q <= block_a_int__active_ecc_master_in;
end
end // of block_a_int__active_ecc_master's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_a_int__active_ecc_master_sticky_latch = block_a_int__active_ecc_master_in;
/**************************************
* Register contains interrupts *
**************************************/
// Register has at least one interrupt field
assign block_a_int_intr = |(block_a_int__crc_error_q & block_a_int_en__crc_error_q) || |(block_a_int__len_error_q & block_a_int_en__len_error_q) || |(block_a_int__multi_bit_ecc_error_q & block_a_int_en__multi_bit_ecc_error_q);
// Register has at least one interrupt field with halt property set
assign block_a_int_halt = |(block_a_int__crc_error_q & ~block_a_halt_en__crc_error_q) || |(block_a_int__len_error_q & ~block_a_halt_en__len_error_q) || |(block_a_int__multi_bit_ecc_error_q & ~block_a_halt_en__multi_bit_ecc_error_q);
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_a_int_data_mux_in = {{24{1'b0}}, block_a_int__active_ecc_master_q, {1{1'b0}}, block_a_int__multi_bit_ecc_error_q, block_a_int__len_error_q, block_a_int__crc_error_q};
// Internal registers are ready immediately
assign block_a_int_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_a_int_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_a_int_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_a_int_en_active ;
logic block_a_int_en_sw_wr ;
logic [31:0] block_a_int_en_data_mux_in ;
logic block_a_int_en_rdy_mux_in ;
logic block_a_int_en_err_mux_in ;
logic [0:0] block_a_int_en__crc_error_q ;
logic [0:0] block_a_int_en__len_error_q ;
logic [0:0] block_a_int_en__multi_bit_ecc_error_q;
// Register-activation for 'block_a_int_en'
assign block_a_int_en_active = widget_if.addr == 4;
assign block_a_int_en_sw_wr = block_a_int_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_a_int_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_int_en__crc_error_q <= 1'd1;
end
else
begin
if (block_a_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_a_int_en__crc_error_q[0:0] <= widget_if.w_data[0:0];
end
end // of block_a_int_en__crc_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_a_int_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_int_en__len_error_q <= 1'd1;
end
else
begin
if (block_a_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_a_int_en__len_error_q[0:0] <= widget_if.w_data[1:1];
end
end // of block_a_int_en__len_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_a_int_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_int_en__multi_bit_ecc_error_q <= 1'd0;
end
else
begin
if (block_a_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_a_int_en__multi_bit_ecc_error_q[0:0] <= widget_if.w_data[2:2];
end
end // of block_a_int_en__multi_bit_ecc_error's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_a_int_en_data_mux_in = {{29{1'b0}}, block_a_int_en__multi_bit_ecc_error_q, block_a_int_en__len_error_q, block_a_int_en__crc_error_q};
// Internal registers are ready immediately
assign block_a_int_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_a_int_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_a_halt_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_a_halt_en_active ;
logic block_a_halt_en_sw_wr ;
logic [31:0] block_a_halt_en_data_mux_in ;
logic block_a_halt_en_rdy_mux_in ;
logic block_a_halt_en_err_mux_in ;
logic [0:0] block_a_halt_en__crc_error_q ;
logic [0:0] block_a_halt_en__len_error_q ;
logic [0:0] block_a_halt_en__multi_bit_ecc_error_q;
// Register-activation for 'block_a_halt_en'
assign block_a_halt_en_active = widget_if.addr == 8;
assign block_a_halt_en_sw_wr = block_a_halt_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_a_halt_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_halt_en__crc_error_q <= 1'd0;
end
else
begin
if (block_a_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_a_halt_en__crc_error_q[0:0] <= widget_if.w_data[0:0];
end
end // of block_a_halt_en__crc_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_a_halt_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_halt_en__len_error_q <= 1'd0;
end
else
begin
if (block_a_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_a_halt_en__len_error_q[0:0] <= widget_if.w_data[1:1];
end
end // of block_a_halt_en__len_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_a_halt_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_a_halt_en__multi_bit_ecc_error_q <= 1'd1;
end
else
begin
if (block_a_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_a_halt_en__multi_bit_ecc_error_q[0:0] <= widget_if.w_data[2:2];
end
end // of block_a_halt_en__multi_bit_ecc_error's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_a_halt_en_data_mux_in = {{29{1'b0}}, block_a_halt_en__multi_bit_ecc_error_q, block_a_halt_en__len_error_q, block_a_halt_en__crc_error_q};
// Internal registers are ready immediately
assign block_a_halt_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_a_halt_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_b_int
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_b_int_active ;
logic block_b_int_sw_wr ;
logic [31:0] block_b_int_data_mux_in ;
logic block_b_int_rdy_mux_in ;
logic block_b_int_err_mux_in ;
logic [0:0] block_b_int__crc_error_q ;
logic [0:0] block_b_int__crc_error_sticky_latch ;
logic [0:0] block_b_int__len_error_q ;
logic [0:0] block_b_int__len_error_sticky_latch ;
logic [0:0] block_b_int__multi_bit_ecc_error_q ;
logic [0:0] block_b_int__multi_bit_ecc_error_sticky_latch;
logic [3:0] block_b_int__active_ecc_master_q ;
logic [3:0] block_b_int__active_ecc_master_sticky_latch;
// Register-activation for 'block_b_int'
assign block_b_int_active = widget_if.addr == 256;
assign block_b_int_sw_wr = block_b_int_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_b_int[0:0])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_int__crc_error_q <= 1'd0;
end
else
begin
if (block_b_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_b_int__crc_error_q[0:0] <= block_b_int__crc_error_q[0:0] & ~widget_if.w_data[0:0];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_b_int__crc_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_b_int__crc_error_q[i] <= 1'b1;
end
end
end
end // of block_b_int__crc_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_b_int__crc_error_sticky_latch = block_b_int__crc_error_in;
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_b_int[1:1])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_int__len_error_q <= 1'd0;
end
else
begin
if (block_b_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_b_int__len_error_q[0:0] <= block_b_int__len_error_q[0:0] & ~widget_if.w_data[1:1];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_b_int__len_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_b_int__len_error_q[i] <= 1'b1;
end
end
end
end // of block_b_int__len_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_b_int__len_error_sticky_latch = block_b_int__len_error_in;
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_b_int[2:2])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_int__multi_bit_ecc_error_q <= 1'd0;
end
else
begin
if (block_b_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_b_int__multi_bit_ecc_error_q[0:0] <= block_b_int__multi_bit_ecc_error_q[0:0] & ~widget_if.w_data[2:2];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_b_int__multi_bit_ecc_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_b_int__multi_bit_ecc_error_q[i] <= 1'b1;
end
end
end
end // of block_b_int__multi_bit_ecc_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_b_int__multi_bit_ecc_error_sticky_latch = block_b_int__multi_bit_ecc_error_in;
//-----------------FIELD SUMMARY-----------------
// name : active_ecc_master (block_b_int[7:4])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'sticky']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_int__active_ecc_master_q <= 4'd0;
end
else
begin
if (block_b_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_b_int__active_ecc_master_q[3:0] <= block_b_int__active_ecc_master_q[3:0] & ~widget_if.w_data[7:4];
end
end
else
if (|block_b_int__active_ecc_master_sticky_latch && !(|block_b_int__active_ecc_master_q))
begin
// Sticky. Keep value until software clears it
block_b_int__active_ecc_master_q <= block_b_int__active_ecc_master_in;
end
end // of block_b_int__active_ecc_master's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_b_int__active_ecc_master_sticky_latch = block_b_int__active_ecc_master_in;
/**************************************
* Register contains interrupts *
**************************************/
// Register has at least one interrupt field
assign block_b_int_intr = |(block_b_int__crc_error_q & block_b_int_en__crc_error_q) || |(block_b_int__len_error_q & block_b_int_en__len_error_q) || |(block_b_int__multi_bit_ecc_error_q & block_b_int_en__multi_bit_ecc_error_q);
// Register has at least one interrupt field with halt property set
assign block_b_int_halt = |(block_b_int__crc_error_q & ~block_b_halt_en__crc_error_q) || |(block_b_int__len_error_q & ~block_b_halt_en__len_error_q) || |(block_b_int__multi_bit_ecc_error_q & ~block_b_halt_en__multi_bit_ecc_error_q);
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_b_int_data_mux_in = {{24{1'b0}}, block_b_int__active_ecc_master_q, {1{1'b0}}, block_b_int__multi_bit_ecc_error_q, block_b_int__len_error_q, block_b_int__crc_error_q};
// Internal registers are ready immediately
assign block_b_int_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_b_int_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_b_int_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_b_int_en_active ;
logic block_b_int_en_sw_wr ;
logic [31:0] block_b_int_en_data_mux_in ;
logic block_b_int_en_rdy_mux_in ;
logic block_b_int_en_err_mux_in ;
logic [0:0] block_b_int_en__crc_error_q ;
logic [0:0] block_b_int_en__len_error_q ;
logic [0:0] block_b_int_en__multi_bit_ecc_error_q;
// Register-activation for 'block_b_int_en'
assign block_b_int_en_active = widget_if.addr == 260;
assign block_b_int_en_sw_wr = block_b_int_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_b_int_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_int_en__crc_error_q <= 1'd1;
end
else
begin
if (block_b_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_b_int_en__crc_error_q[0:0] <= widget_if.w_data[0:0];
end
end // of block_b_int_en__crc_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_b_int_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_int_en__len_error_q <= 1'd1;
end
else
begin
if (block_b_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_b_int_en__len_error_q[0:0] <= widget_if.w_data[1:1];
end
end // of block_b_int_en__len_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_b_int_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_int_en__multi_bit_ecc_error_q <= 1'd0;
end
else
begin
if (block_b_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_b_int_en__multi_bit_ecc_error_q[0:0] <= widget_if.w_data[2:2];
end
end // of block_b_int_en__multi_bit_ecc_error's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_b_int_en_data_mux_in = {{29{1'b0}}, block_b_int_en__multi_bit_ecc_error_q, block_b_int_en__len_error_q, block_b_int_en__crc_error_q};
// Internal registers are ready immediately
assign block_b_int_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_b_int_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_b_halt_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_b_halt_en_active ;
logic block_b_halt_en_sw_wr ;
logic [31:0] block_b_halt_en_data_mux_in ;
logic block_b_halt_en_rdy_mux_in ;
logic block_b_halt_en_err_mux_in ;
logic [0:0] block_b_halt_en__crc_error_q ;
logic [0:0] block_b_halt_en__len_error_q ;
logic [0:0] block_b_halt_en__multi_bit_ecc_error_q;
// Register-activation for 'block_b_halt_en'
assign block_b_halt_en_active = widget_if.addr == 264;
assign block_b_halt_en_sw_wr = block_b_halt_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_b_halt_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_halt_en__crc_error_q <= 1'd0;
end
else
begin
if (block_b_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_b_halt_en__crc_error_q[0:0] <= widget_if.w_data[0:0];
end
end // of block_b_halt_en__crc_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_b_halt_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_halt_en__len_error_q <= 1'd0;
end
else
begin
if (block_b_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_b_halt_en__len_error_q[0:0] <= widget_if.w_data[1:1];
end
end // of block_b_halt_en__len_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_b_halt_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_b_halt_en__multi_bit_ecc_error_q <= 1'd1;
end
else
begin
if (block_b_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_b_halt_en__multi_bit_ecc_error_q[0:0] <= widget_if.w_data[2:2];
end
end // of block_b_halt_en__multi_bit_ecc_error's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_b_halt_en_data_mux_in = {{29{1'b0}}, block_b_halt_en__multi_bit_ecc_error_q, block_b_halt_en__len_error_q, block_b_halt_en__crc_error_q};
// Internal registers are ready immediately
assign block_b_halt_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_b_halt_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_c_int
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_c_int_active ;
logic block_c_int_sw_wr ;
logic [31:0] block_c_int_data_mux_in ;
logic block_c_int_rdy_mux_in ;
logic block_c_int_err_mux_in ;
logic [0:0] block_c_int__crc_error_q ;
logic [0:0] block_c_int__crc_error_sticky_latch ;
logic [0:0] block_c_int__len_error_q ;
logic [0:0] block_c_int__len_error_sticky_latch ;
logic [0:0] block_c_int__multi_bit_ecc_error_q ;
logic [0:0] block_c_int__multi_bit_ecc_error_sticky_latch;
logic [3:0] block_c_int__active_ecc_master_q ;
logic [3:0] block_c_int__active_ecc_master_sticky_latch;
// Register-activation for 'block_c_int'
assign block_c_int_active = widget_if.addr == 512;
assign block_c_int_sw_wr = block_c_int_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_c_int[0:0])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_int__crc_error_q <= 1'd0;
end
else
begin
if (block_c_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_c_int__crc_error_q[0:0] <= block_c_int__crc_error_q[0:0] & ~widget_if.w_data[0:0];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_c_int__crc_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_c_int__crc_error_q[i] <= 1'b1;
end
end
end
end // of block_c_int__crc_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_c_int__crc_error_sticky_latch = block_c_int__crc_error_in;
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_c_int[1:1])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_int__len_error_q <= 1'd0;
end
else
begin
if (block_c_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_c_int__len_error_q[0:0] <= block_c_int__len_error_q[0:0] & ~widget_if.w_data[1:1];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_c_int__len_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_c_int__len_error_q[i] <= 1'b1;
end
end
end
end // of block_c_int__len_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_c_int__len_error_sticky_latch = block_c_int__len_error_in;
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_c_int[2:2])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_int__multi_bit_ecc_error_q <= 1'd0;
end
else
begin
if (block_c_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_c_int__multi_bit_ecc_error_q[0:0] <= block_c_int__multi_bit_ecc_error_q[0:0] & ~widget_if.w_data[2:2];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_c_int__multi_bit_ecc_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_c_int__multi_bit_ecc_error_q[i] <= 1'b1;
end
end
end
end // of block_c_int__multi_bit_ecc_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_c_int__multi_bit_ecc_error_sticky_latch = block_c_int__multi_bit_ecc_error_in;
//-----------------FIELD SUMMARY-----------------
// name : active_ecc_master (block_c_int[7:4])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'sticky']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_int__active_ecc_master_q <= 4'd0;
end
else
begin
if (block_c_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_c_int__active_ecc_master_q[3:0] <= block_c_int__active_ecc_master_q[3:0] & ~widget_if.w_data[7:4];
end
end
else
if (|block_c_int__active_ecc_master_sticky_latch && !(|block_c_int__active_ecc_master_q))
begin
// Sticky. Keep value until software clears it
block_c_int__active_ecc_master_q <= block_c_int__active_ecc_master_in;
end
end // of block_c_int__active_ecc_master's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_c_int__active_ecc_master_sticky_latch = block_c_int__active_ecc_master_in;
/**************************************
* Register contains interrupts *
**************************************/
// Register has at least one interrupt field
assign block_c_int_intr = |(block_c_int__crc_error_q & block_c_int_en__crc_error_q) || |(block_c_int__len_error_q & block_c_int_en__len_error_q) || |(block_c_int__multi_bit_ecc_error_q & block_c_int_en__multi_bit_ecc_error_q);
// Register has at least one interrupt field with halt property set
assign block_c_int_halt = |(block_c_int__crc_error_q & ~block_c_halt_en__crc_error_q) || |(block_c_int__len_error_q & ~block_c_halt_en__len_error_q) || |(block_c_int__multi_bit_ecc_error_q & ~block_c_halt_en__multi_bit_ecc_error_q);
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_c_int_data_mux_in = {{24{1'b0}}, block_c_int__active_ecc_master_q, {1{1'b0}}, block_c_int__multi_bit_ecc_error_q, block_c_int__len_error_q, block_c_int__crc_error_q};
// Internal registers are ready immediately
assign block_c_int_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_c_int_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_c_int_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_c_int_en_active ;
logic block_c_int_en_sw_wr ;
logic [31:0] block_c_int_en_data_mux_in ;
logic block_c_int_en_rdy_mux_in ;
logic block_c_int_en_err_mux_in ;
logic [0:0] block_c_int_en__crc_error_q ;
logic [0:0] block_c_int_en__len_error_q ;
logic [0:0] block_c_int_en__multi_bit_ecc_error_q;
// Register-activation for 'block_c_int_en'
assign block_c_int_en_active = widget_if.addr == 516;
assign block_c_int_en_sw_wr = block_c_int_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_c_int_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_int_en__crc_error_q <= 1'd1;
end
else
begin
if (block_c_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_c_int_en__crc_error_q[0:0] <= widget_if.w_data[0:0];
end
end // of block_c_int_en__crc_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_c_int_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_int_en__len_error_q <= 1'd1;
end
else
begin
if (block_c_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_c_int_en__len_error_q[0:0] <= widget_if.w_data[1:1];
end
end // of block_c_int_en__len_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_c_int_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_int_en__multi_bit_ecc_error_q <= 1'd0;
end
else
begin
if (block_c_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_c_int_en__multi_bit_ecc_error_q[0:0] <= widget_if.w_data[2:2];
end
end // of block_c_int_en__multi_bit_ecc_error's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_c_int_en_data_mux_in = {{29{1'b0}}, block_c_int_en__multi_bit_ecc_error_q, block_c_int_en__len_error_q, block_c_int_en__crc_error_q};
// Internal registers are ready immediately
assign block_c_int_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_c_int_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_c_halt_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_c_halt_en_active ;
logic block_c_halt_en_sw_wr ;
logic [31:0] block_c_halt_en_data_mux_in ;
logic block_c_halt_en_rdy_mux_in ;
logic block_c_halt_en_err_mux_in ;
logic [0:0] block_c_halt_en__crc_error_q ;
logic [0:0] block_c_halt_en__len_error_q ;
logic [0:0] block_c_halt_en__multi_bit_ecc_error_q;
// Register-activation for 'block_c_halt_en'
assign block_c_halt_en_active = widget_if.addr == 520;
assign block_c_halt_en_sw_wr = block_c_halt_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_c_halt_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_halt_en__crc_error_q <= 1'd0;
end
else
begin
if (block_c_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_c_halt_en__crc_error_q[0:0] <= widget_if.w_data[0:0];
end
end // of block_c_halt_en__crc_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_c_halt_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_halt_en__len_error_q <= 1'd0;
end
else
begin
if (block_c_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_c_halt_en__len_error_q[0:0] <= widget_if.w_data[1:1];
end
end // of block_c_halt_en__len_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_c_halt_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_c_halt_en__multi_bit_ecc_error_q <= 1'd1;
end
else
begin
if (block_c_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_c_halt_en__multi_bit_ecc_error_q[0:0] <= widget_if.w_data[2:2];
end
end // of block_c_halt_en__multi_bit_ecc_error's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_c_halt_en_data_mux_in = {{29{1'b0}}, block_c_halt_en__multi_bit_ecc_error_q, block_c_halt_en__len_error_q, block_c_halt_en__crc_error_q};
// Internal registers are ready immediately
assign block_c_halt_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_c_halt_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_d_int
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_d_int_active ;
logic block_d_int_sw_wr ;
logic [31:0] block_d_int_data_mux_in ;
logic block_d_int_rdy_mux_in ;
logic block_d_int_err_mux_in ;
logic [0:0] block_d_int__crc_error_q ;
logic [0:0] block_d_int__crc_error_sticky_latch ;
logic [0:0] block_d_int__len_error_q ;
logic [0:0] block_d_int__len_error_sticky_latch ;
logic [0:0] block_d_int__multi_bit_ecc_error_q ;
logic [0:0] block_d_int__multi_bit_ecc_error_sticky_latch;
logic [3:0] block_d_int__active_ecc_master_q ;
logic [3:0] block_d_int__active_ecc_master_sticky_latch;
// Register-activation for 'block_d_int'
assign block_d_int_active = widget_if.addr == 768;
assign block_d_int_sw_wr = block_d_int_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_d_int[0:0])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_int__crc_error_q <= 1'd0;
end
else
begin
if (block_d_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_d_int__crc_error_q[0:0] <= block_d_int__crc_error_q[0:0] & ~widget_if.w_data[0:0];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_d_int__crc_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_d_int__crc_error_q[i] <= 1'b1;
end
end
end
end // of block_d_int__crc_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_d_int__crc_error_sticky_latch = block_d_int__crc_error_in;
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_d_int[1:1])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_int__len_error_q <= 1'd0;
end
else
begin
if (block_d_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_d_int__len_error_q[0:0] <= block_d_int__len_error_q[0:0] & ~widget_if.w_data[1:1];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_d_int__len_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_d_int__len_error_q[i] <= 1'b1;
end
end
end
end // of block_d_int__len_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_d_int__len_error_sticky_latch = block_d_int__len_error_in;
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_d_int[2:2])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'intr', 'intr type', 'enable', 'haltenable']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_int__multi_bit_ecc_error_q <= 1'd0;
end
else
begin
if (block_d_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_d_int__multi_bit_ecc_error_q[0:0] <= block_d_int__multi_bit_ecc_error_q[0:0] & ~widget_if.w_data[2:2];
end
end
else
begin
for (int i = 0; i < 1; i++)
begin
if (block_d_int__multi_bit_ecc_error_sticky_latch[i])
begin
// Stickybit. Keep value until software clears it
block_d_int__multi_bit_ecc_error_q[i] <= 1'b1;
end
end
end
end // of block_d_int__multi_bit_ecc_error's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_d_int__multi_bit_ecc_error_sticky_latch = block_d_int__multi_bit_ecc_error_in;
//-----------------FIELD SUMMARY-----------------
// name : active_ecc_master (block_d_int[7:4])
// access : hw = w
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'woclr', 'desc', 'sticky']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_int__active_ecc_master_q <= 4'd0;
end
else
begin
if (block_d_int_sw_wr)
begin
if (widget_if.byte_en[0]) // woclr property
begin
block_d_int__active_ecc_master_q[3:0] <= block_d_int__active_ecc_master_q[3:0] & ~widget_if.w_data[7:4];
end
end
else
if (|block_d_int__active_ecc_master_sticky_latch && !(|block_d_int__active_ecc_master_q))
begin
// Sticky. Keep value until software clears it
block_d_int__active_ecc_master_q <= block_d_int__active_ecc_master_in;
end
end // of block_d_int__active_ecc_master's always_ff
// Define signal that causes the interrupt to be set (level-type interrupt)
assign block_d_int__active_ecc_master_sticky_latch = block_d_int__active_ecc_master_in;
/**************************************
* Register contains interrupts *
**************************************/
// Register has at least one interrupt field
assign block_d_int_intr = |(block_d_int__crc_error_q & block_d_int_en__crc_error_q) || |(block_d_int__len_error_q & block_d_int_en__len_error_q) || |(block_d_int__multi_bit_ecc_error_q & block_d_int_en__multi_bit_ecc_error_q);
// Register has at least one interrupt field with halt property set
assign block_d_int_halt = |(block_d_int__crc_error_q & ~block_d_halt_en__crc_error_q) || |(block_d_int__len_error_q & ~block_d_halt_en__len_error_q) || |(block_d_int__multi_bit_ecc_error_q & ~block_d_halt_en__multi_bit_ecc_error_q);
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_d_int_data_mux_in = {{24{1'b0}}, block_d_int__active_ecc_master_q, {1{1'b0}}, block_d_int__multi_bit_ecc_error_q, block_d_int__len_error_q, block_d_int__crc_error_q};
// Internal registers are ready immediately
assign block_d_int_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_d_int_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_d_int_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_d_int_en_active ;
logic block_d_int_en_sw_wr ;
logic [31:0] block_d_int_en_data_mux_in ;
logic block_d_int_en_rdy_mux_in ;
logic block_d_int_en_err_mux_in ;
logic [0:0] block_d_int_en__crc_error_q ;
logic [0:0] block_d_int_en__len_error_q ;
logic [0:0] block_d_int_en__multi_bit_ecc_error_q;
// Register-activation for 'block_d_int_en'
assign block_d_int_en_active = widget_if.addr == 772;
assign block_d_int_en_sw_wr = block_d_int_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_d_int_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_int_en__crc_error_q <= 1'd1;
end
else
begin
if (block_d_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_d_int_en__crc_error_q[0:0] <= widget_if.w_data[0:0];
end
end // of block_d_int_en__crc_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_d_int_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_int_en__len_error_q <= 1'd1;
end
else
begin
if (block_d_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_d_int_en__len_error_q[0:0] <= widget_if.w_data[1:1];
end
end // of block_d_int_en__len_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_d_int_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_int_en__multi_bit_ecc_error_q <= 1'd0;
end
else
begin
if (block_d_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_d_int_en__multi_bit_ecc_error_q[0:0] <= widget_if.w_data[2:2];
end
end // of block_d_int_en__multi_bit_ecc_error's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_d_int_en_data_mux_in = {{29{1'b0}}, block_d_int_en__multi_bit_ecc_error_q, block_d_int_en__len_error_q, block_d_int_en__crc_error_q};
// Internal registers are ready immediately
assign block_d_int_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_d_int_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : block_d_halt_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic block_d_halt_en_active ;
logic block_d_halt_en_sw_wr ;
logic [31:0] block_d_halt_en_data_mux_in ;
logic block_d_halt_en_rdy_mux_in ;
logic block_d_halt_en_err_mux_in ;
logic [0:0] block_d_halt_en__crc_error_q ;
logic [0:0] block_d_halt_en__len_error_q ;
logic [0:0] block_d_halt_en__multi_bit_ecc_error_q;
// Register-activation for 'block_d_halt_en'
assign block_d_halt_en_active = widget_if.addr == 776;
assign block_d_halt_en_sw_wr = block_d_halt_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : crc_error (block_d_halt_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_halt_en__crc_error_q <= 1'd0;
end
else
begin
if (block_d_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_d_halt_en__crc_error_q[0:0] <= widget_if.w_data[0:0];
end
end // of block_d_halt_en__crc_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : len_error (block_d_halt_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_halt_en__len_error_q <= 1'd0;
end
else
begin
if (block_d_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_d_halt_en__len_error_q[0:0] <= widget_if.w_data[1:1];
end
end // of block_d_halt_en__len_error's always_ff
//-----------------FIELD SUMMARY-----------------
// name : multi_bit_ecc_error (block_d_halt_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
block_d_halt_en__multi_bit_ecc_error_q <= 1'd1;
end
else
begin
if (block_d_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
block_d_halt_en__multi_bit_ecc_error_q[0:0] <= widget_if.w_data[2:2];
end
end // of block_d_halt_en__multi_bit_ecc_error's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign block_d_halt_en_data_mux_in = {{29{1'b0}}, block_d_halt_en__multi_bit_ecc_error_q, block_d_halt_en__len_error_q, block_d_halt_en__crc_error_q};
// Internal registers are ready immediately
assign block_d_halt_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign block_d_halt_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : master_int
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic master_int_active ;
logic [31:0] master_int_data_mux_in ;
logic master_int_rdy_mux_in ;
logic master_int_err_mux_in ;
logic [0:0] master_int__module_a_int_q;
logic [0:0] master_int__module_b_int_q;
logic [0:0] master_int__module_c_int_q;
logic [0:0] master_int__module_d_int_q;
// Register-activation for 'master_int'
assign master_int_active = widget_if.addr == 4096;
//-----------------FIELD SUMMARY-----------------
// name : module_a_int (master_int[0:0])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['intr', 'stickybit', 'sw', 'desc', 'enable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_int__module_a_int_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
master_int__module_a_int_q <= block_a_int_intr;
end
end // of master_int__module_a_int's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_b_int (master_int[1:1])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['intr', 'stickybit', 'sw', 'desc', 'enable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_int__module_b_int_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
master_int__module_b_int_q <= block_b_int_intr;
end
end // of master_int__module_b_int's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_c_int (master_int[2:2])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['intr', 'stickybit', 'sw', 'desc', 'enable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_int__module_c_int_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
master_int__module_c_int_q <= block_c_int_intr;
end
end // of master_int__module_c_int's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_d_int (master_int[3:3])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['intr', 'stickybit', 'sw', 'desc', 'enable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_int__module_d_int_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
master_int__module_d_int_q <= block_d_int_intr;
end
end // of master_int__module_d_int's always_ff
/**************************************
* Register contains interrupts *
**************************************/
// Register has at least one interrupt field
assign master_int_intr = |(master_int__module_a_int_q & master_int_en__module_a_int_en_q) || |(master_int__module_b_int_q & master_int_en__module_b_int_en_q) || |(master_int__module_c_int_q & master_int_en__module_c_int_en_q) || |(master_int__module_d_int_q & master_int_en__module_d_int_en_q);
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign master_int_data_mux_in = {{28{1'b0}}, master_int__module_d_int_q, master_int__module_c_int_q, master_int__module_b_int_q, master_int__module_a_int_q};
// Internal registers are ready immediately
assign master_int_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign master_int_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (1'b0)));
/*******************************************************************
/*******************************************************************
/* REGISTER : master_halt
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic master_halt_active ;
logic [31:0] master_halt_data_mux_in ;
logic master_halt_rdy_mux_in ;
logic master_halt_err_mux_in ;
logic [0:0] master_halt__module_a_int_q;
logic [0:0] master_halt__module_b_int_q;
logic [0:0] master_halt__module_c_int_q;
logic [0:0] master_halt__module_d_int_q;
// Register-activation for 'master_halt'
assign master_halt_active = widget_if.addr == 4100;
//-----------------FIELD SUMMARY-----------------
// name : module_a_int (master_halt[0:0])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['intr', 'stickybit', 'sw', 'desc', 'haltenable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_halt__module_a_int_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
master_halt__module_a_int_q <= block_a_int_halt;
end
end // of master_halt__module_a_int's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_b_int (master_halt[1:1])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['intr', 'stickybit', 'sw', 'desc', 'haltenable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_halt__module_b_int_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
master_halt__module_b_int_q <= block_b_int_halt;
end
end // of master_halt__module_b_int's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_c_int (master_halt[2:2])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['intr', 'stickybit', 'sw', 'desc', 'haltenable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_halt__module_c_int_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
master_halt__module_c_int_q <= block_c_int_halt;
end
end // of master_halt__module_c_int's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_d_int (master_halt[3:3])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['intr', 'stickybit', 'sw', 'desc', 'haltenable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_halt__module_d_int_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
master_halt__module_d_int_q <= block_d_int_halt;
end
end // of master_halt__module_d_int's always_ff
/**************************************
* Register contains interrupts *
**************************************/
// Register has at least one interrupt field
assign master_halt_intr = |(master_halt__module_a_int_q) || |(master_halt__module_b_int_q) || |(master_halt__module_c_int_q) || |(master_halt__module_d_int_q);
// Register has at least one interrupt field with halt property set
assign master_halt_halt = |(master_halt__module_a_int_q & ~master_halt_en__module_a_halt_en_q) || |(master_halt__module_b_int_q & ~master_halt_en__module_b_halt_en_q) || |(master_halt__module_c_int_q & ~master_halt_en__module_c_halt_en_q) || |(master_halt__module_d_int_q & ~master_halt_en__module_d_halt_en_q);
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign master_halt_data_mux_in = {{28{1'b0}}, master_halt__module_d_int_q, master_halt__module_c_int_q, master_halt__module_b_int_q, master_halt__module_a_int_q};
// Internal registers are ready immediately
assign master_halt_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign master_halt_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (1'b0)));
/*******************************************************************
/*******************************************************************
/* REGISTER : master_int_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic master_int_en_active ;
logic master_int_en_sw_wr ;
logic [31:0] master_int_en_data_mux_in ;
logic master_int_en_rdy_mux_in ;
logic master_int_en_err_mux_in ;
logic [0:0] master_int_en__module_a_int_en_q;
logic [0:0] master_int_en__module_b_int_en_q;
logic [0:0] master_int_en__module_c_int_en_q;
logic [0:0] master_int_en__module_d_int_en_q;
// Register-activation for 'master_int_en'
assign master_int_en_active = widget_if.addr == 4104;
assign master_int_en_sw_wr = master_int_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : module_a_int_en (master_int_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_int_en__module_a_int_en_q <= 1'd0;
end
else
begin
if (master_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
master_int_en__module_a_int_en_q[0:0] <= widget_if.w_data[0:0];
end
end // of master_int_en__module_a_int_en's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_b_int_en (master_int_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_int_en__module_b_int_en_q <= 1'd0;
end
else
begin
if (master_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
master_int_en__module_b_int_en_q[0:0] <= widget_if.w_data[1:1];
end
end // of master_int_en__module_b_int_en's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_c_int_en (master_int_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_int_en__module_c_int_en_q <= 1'd0;
end
else
begin
if (master_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
master_int_en__module_c_int_en_q[0:0] <= widget_if.w_data[2:2];
end
end // of master_int_en__module_c_int_en's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_d_int_en (master_int_en[3:3])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_int_en__module_d_int_en_q <= 1'd0;
end
else
begin
if (master_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
master_int_en__module_d_int_en_q[0:0] <= widget_if.w_data[3:3];
end
end // of master_int_en__module_d_int_en's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign master_int_en_data_mux_in = {{28{1'b0}}, master_int_en__module_d_int_en_q, master_int_en__module_c_int_en_q, master_int_en__module_b_int_en_q, master_int_en__module_a_int_en_q};
// Internal registers are ready immediately
assign master_int_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign master_int_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : master_halt_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic master_halt_en_active ;
logic master_halt_en_sw_wr ;
logic [31:0] master_halt_en_data_mux_in ;
logic master_halt_en_rdy_mux_in ;
logic master_halt_en_err_mux_in ;
logic [0:0] master_halt_en__module_a_halt_en_q;
logic [0:0] master_halt_en__module_b_halt_en_q;
logic [0:0] master_halt_en__module_c_halt_en_q;
logic [0:0] master_halt_en__module_d_halt_en_q;
// Register-activation for 'master_halt_en'
assign master_halt_en_active = widget_if.addr == 4108;
assign master_halt_en_sw_wr = master_halt_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : module_a_halt_en (master_halt_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_halt_en__module_a_halt_en_q <= 1'd0;
end
else
begin
if (master_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
master_halt_en__module_a_halt_en_q[0:0] <= widget_if.w_data[0:0];
end
end // of master_halt_en__module_a_halt_en's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_b_halt_en (master_halt_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_halt_en__module_b_halt_en_q <= 1'd0;
end
else
begin
if (master_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
master_halt_en__module_b_halt_en_q[0:0] <= widget_if.w_data[1:1];
end
end // of master_halt_en__module_b_halt_en's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_c_halt_en (master_halt_en[2:2])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_halt_en__module_c_halt_en_q <= 1'd0;
end
else
begin
if (master_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
master_halt_en__module_c_halt_en_q[0:0] <= widget_if.w_data[2:2];
end
end // of master_halt_en__module_c_halt_en's always_ff
//-----------------FIELD SUMMARY-----------------
// name : module_d_halt_en (master_halt_en[3:3])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
master_halt_en__module_d_halt_en_q <= 1'd0;
end
else
begin
if (master_halt_en_sw_wr)
begin
if (widget_if.byte_en[0])
master_halt_en__module_d_halt_en_q[0:0] <= widget_if.w_data[3:3];
end
end // of master_halt_en__module_d_halt_en's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign master_halt_en_data_mux_in = {{28{1'b0}}, master_halt_en__module_d_halt_en_q, master_halt_en__module_c_halt_en_q, master_halt_en__module_b_halt_en_q, master_halt_en__module_a_halt_en_q};
// Internal registers are ready immediately
assign master_halt_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign master_halt_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
/*******************************************************************
/*******************************************************************
/* REGISTER : global_int
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic global_int_active ;
logic [31:0] global_int_data_mux_in ;
logic global_int_rdy_mux_in ;
logic global_int_err_mux_in ;
logic [0:0] global_int__global_int_q ;
logic [0:0] global_int__global_halt_q;
// Register-activation for 'global_int'
assign global_int_active = widget_if.addr == 4112;
//-----------------FIELD SUMMARY-----------------
// name : global_int (global_int[0:0])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'intr', 'stickybit', 'desc', 'enable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
global_int__global_int_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
global_int__global_int_q <= master_int_intr;
end
end // of global_int__global_int's always_ff
//-----------------FIELD SUMMARY-----------------
// name : global_halt (global_int[1:1])
// access : hw = w
// sw = r (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'intr', 'stickybit', 'desc', 'haltenable', 'next']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
global_int__global_halt_q <= 1'd0;
end
else
begin
begin
// Non-sticky interrupt. Only keep value high if source keeps up
global_int__global_halt_q <= master_halt_halt;
end
end // of global_int__global_halt's always_ff
/**************************************
* Register contains interrupts *
**************************************/
// Register has at least one interrupt field
assign global_int_intr = |(global_int__global_int_q & global_int_en__global_int_en_q) || |(global_int__global_halt_q);
// Register has at least one interrupt field with halt property set
assign global_int_halt = |(global_int__global_int_q) || |(global_int__global_halt_q & ~global_int_en__global_halt_en_q);
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign global_int_data_mux_in = {{30{1'b0}}, global_int__global_halt_q, global_int__global_int_q};
// Internal registers are ready immediately
assign global_int_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign global_int_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (1'b0)));
/*******************************************************************
/*******************************************************************
/* REGISTER : global_int_en
/* DIMENSION : 0
/* DEPTHS (per dimension): []
/*******************************************************************
/*******************************************************************/
logic global_int_en_active ;
logic global_int_en_sw_wr ;
logic [31:0] global_int_en_data_mux_in ;
logic global_int_en_rdy_mux_in ;
logic global_int_en_err_mux_in ;
logic [0:0] global_int_en__global_int_en_q ;
logic [0:0] global_int_en__global_halt_en_q;
// Register-activation for 'global_int_en'
assign global_int_en_active = widget_if.addr == 4116;
assign global_int_en_sw_wr = global_int_en_active && widget_if.w_vld;
//-----------------FIELD SUMMARY-----------------
// name : global_int_en (global_int_en[0:0])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
global_int_en__global_int_en_q <= 1'd0;
end
else
begin
if (global_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
global_int_en__global_int_en_q[0:0] <= widget_if.w_data[0:0];
end
end // of global_int_en__global_int_en's always_ff
//-----------------FIELD SUMMARY-----------------
// name : global_halt_en (global_int_en[1:1])
// access : hw = na
// sw = rw (precedence)
// reset : active_low / asynchronous
// flags : ['sw', 'desc']
// external : False
// storage type : StorageType.FLOPS
//-----------------------------------------------
always_ff @(posedge clk or negedge field_reset_n)
if (!field_reset_n)
begin
global_int_en__global_halt_en_q <= 1'd0;
end
else
begin
if (global_int_en_sw_wr)
begin
if (widget_if.byte_en[0])
global_int_en__global_halt_en_q[0:0] <= widget_if.w_data[1:1];
end
end // of global_int_en__global_halt_en's always_ff
/**************************************
* Assign all fields to signal to Mux *
**************************************/
// Assign all fields. Fields that are not readable are tied to 0.
assign global_int_en_data_mux_in = {{30{1'b0}}, global_int_en__global_halt_en_q, global_int_en__global_int_en_q};
// Internal registers are ready immediately
assign global_int_en_rdy_mux_in = 1'b1;
// Return an error if *no* read and *no* write was succesful. If some bits
// cannot be read/written but others are succesful, don't return and error
// Hence, as long as one action can be succesful, no error will be returned.
assign global_int_en_err_mux_in = !((widget_if.r_vld && (widget_if.byte_en[0])) || (widget_if.w_vld && (widget_if.byte_en[0])));
// Read multiplexer
always_comb
begin
unique case (1'b1)
block_a_int_active:
begin
widget_if.r_data = block_a_int_data_mux_in;
widget_if.err = block_a_int_err_mux_in;
widget_if.rdy = block_a_int_rdy_mux_in;
end
block_a_int_en_active:
begin
widget_if.r_data = block_a_int_en_data_mux_in;
widget_if.err = block_a_int_en_err_mux_in;
widget_if.rdy = block_a_int_en_rdy_mux_in;
end
block_a_halt_en_active:
begin
widget_if.r_data = block_a_halt_en_data_mux_in;
widget_if.err = block_a_halt_en_err_mux_in;
widget_if.rdy = block_a_halt_en_rdy_mux_in;
end
block_b_int_active:
begin
widget_if.r_data = block_b_int_data_mux_in;
widget_if.err = block_b_int_err_mux_in;
widget_if.rdy = block_b_int_rdy_mux_in;
end
block_b_int_en_active:
begin
widget_if.r_data = block_b_int_en_data_mux_in;
widget_if.err = block_b_int_en_err_mux_in;
widget_if.rdy = block_b_int_en_rdy_mux_in;
end
block_b_halt_en_active:
begin
widget_if.r_data = block_b_halt_en_data_mux_in;
widget_if.err = block_b_halt_en_err_mux_in;
widget_if.rdy = block_b_halt_en_rdy_mux_in;
end
block_c_int_active:
begin
widget_if.r_data = block_c_int_data_mux_in;
widget_if.err = block_c_int_err_mux_in;
widget_if.rdy = block_c_int_rdy_mux_in;
end
block_c_int_en_active:
begin
widget_if.r_data = block_c_int_en_data_mux_in;
widget_if.err = block_c_int_en_err_mux_in;
widget_if.rdy = block_c_int_en_rdy_mux_in;
end
block_c_halt_en_active:
begin
widget_if.r_data = block_c_halt_en_data_mux_in;
widget_if.err = block_c_halt_en_err_mux_in;
widget_if.rdy = block_c_halt_en_rdy_mux_in;
end
block_d_int_active:
begin
widget_if.r_data = block_d_int_data_mux_in;
widget_if.err = block_d_int_err_mux_in;
widget_if.rdy = block_d_int_rdy_mux_in;
end
block_d_int_en_active:
begin
widget_if.r_data = block_d_int_en_data_mux_in;
widget_if.err = block_d_int_en_err_mux_in;
widget_if.rdy = block_d_int_en_rdy_mux_in;
end
block_d_halt_en_active:
begin
widget_if.r_data = block_d_halt_en_data_mux_in;
widget_if.err = block_d_halt_en_err_mux_in;
widget_if.rdy = block_d_halt_en_rdy_mux_in;
end
master_int_active:
begin
widget_if.r_data = master_int_data_mux_in;
widget_if.err = master_int_err_mux_in;
widget_if.rdy = master_int_rdy_mux_in;
end
master_halt_active:
begin
widget_if.r_data = master_halt_data_mux_in;
widget_if.err = master_halt_err_mux_in;
widget_if.rdy = master_halt_rdy_mux_in;
end
master_int_en_active:
begin
widget_if.r_data = master_int_en_data_mux_in;
widget_if.err = master_int_en_err_mux_in;
widget_if.rdy = master_int_en_rdy_mux_in;
end
master_halt_en_active:
begin
widget_if.r_data = master_halt_en_data_mux_in;
widget_if.err = master_halt_en_err_mux_in;
widget_if.rdy = master_halt_en_rdy_mux_in;
end
global_int_active:
begin
widget_if.r_data = global_int_data_mux_in;
widget_if.err = global_int_err_mux_in;
widget_if.rdy = global_int_rdy_mux_in;
end
global_int_en_active:
begin
widget_if.r_data = global_int_en_data_mux_in;
widget_if.err = global_int_en_err_mux_in;
widget_if.rdy = global_int_en_rdy_mux_in;
end
default:
begin
// If the address is not found, return an error
widget_if.r_data = 0;
widget_if.err = 1;
widget_if.rdy = widget_if.r_vld || widget_if.w_vld;
end
endcase
end
endmodule