pluto_hdl_adi/library/axi_dmac/request_arb.v

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// ***************************************************************************
// ***************************************************************************
// Copyright 2014 - 2017 (c) Analog Devices, Inc. All rights reserved.
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
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//
// In this HDL repository, there are many different and unique modules, consisting
// of various HDL (Verilog or VHDL) components. The individual modules are
// developed independently, and may be accompanied by separate and unique license
// terms.
//
// The user should read each of these license terms, and understand the
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// freedoms and responsibilities that he or she has by using this source/core.
//
// This core is distributed in the hope that it will be useful, but WITHOUT ANY
// WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
// A PARTICULAR PURPOSE.
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
//
// Redistribution and use of source or resulting binaries, with or without modification
// of this file, are permitted under one of the following two license terms:
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
//
// 1. The GNU General Public License version 2 as published by the
// Free Software Foundation, which can be found in the top level directory
// of this repository (LICENSE_GPL2), and also online at:
// <https://www.gnu.org/licenses/old-licenses/gpl-2.0.html>
//
// OR
//
// 2. An ADI specific BSD license, which can be found in the top level directory
// of this repository (LICENSE_ADIBSD), and also on-line at:
// https://github.com/analogdevicesinc/hdl/blob/master/LICENSE_ADIBSD
// This will allow to generate bit files and not release the source code,
// as long as it attaches to an ADI device.
//
// ***************************************************************************
// ***************************************************************************
module dmac_request_arb #(
parameter DMA_DATA_WIDTH_SRC = 64,
parameter DMA_DATA_WIDTH_DEST = 64,
parameter DMA_LENGTH_WIDTH = 24,
parameter BYTES_PER_BEAT_WIDTH_DEST = $clog2(DMA_DATA_WIDTH_DEST/8),
parameter BYTES_PER_BEAT_WIDTH_SRC = $clog2(DMA_DATA_WIDTH_SRC/8),
parameter DMA_TYPE_DEST = 0,
parameter DMA_TYPE_SRC = 2,
parameter DMA_AXI_ADDR_WIDTH = 32,
parameter ASYNC_CLK_REQ_SRC = 1,
parameter ASYNC_CLK_SRC_DEST = 1,
parameter ASYNC_CLK_DEST_REQ = 1,
parameter AXI_SLICE_DEST = 0,
parameter AXI_SLICE_SRC = 0,
parameter MAX_BYTES_PER_BURST = 128,
parameter BYTES_PER_BURST_WIDTH = 7,
parameter FIFO_SIZE = 8,
parameter ID_WIDTH = $clog2(FIFO_SIZE*2),
parameter AXI_LENGTH_WIDTH_SRC = 8,
parameter AXI_LENGTH_WIDTH_DEST = 8,
parameter ENABLE_DIAGNOSTICS_IF = 0)(
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
input req_clk,
input req_resetn,
input req_valid,
output req_ready,
input [DMA_AXI_ADDR_WIDTH-1:BYTES_PER_BEAT_WIDTH_DEST] req_dest_address,
input [DMA_AXI_ADDR_WIDTH-1:BYTES_PER_BEAT_WIDTH_SRC] req_src_address,
input [DMA_LENGTH_WIDTH-1:0] req_length,
input req_xlast,
input req_sync_transfer_start,
output eot,
output [BYTES_PER_BURST_WIDTH-1:0] measured_burst_length,
output response_partial,
output response_valid,
input response_ready,
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output abort_req,
// Master AXI interface
input m_dest_axi_aclk,
input m_dest_axi_aresetn,
input m_src_axi_aclk,
input m_src_axi_aresetn,
// Write address
output [DMA_AXI_ADDR_WIDTH-1:0] m_axi_awaddr,
output [AXI_LENGTH_WIDTH_DEST-1:0] m_axi_awlen,
output [ 2:0] m_axi_awsize,
output [ 1:0] m_axi_awburst,
output [ 2:0] m_axi_awprot,
output [ 3:0] m_axi_awcache,
output m_axi_awvalid,
input m_axi_awready,
// Write data
output [DMA_DATA_WIDTH_DEST-1:0] m_axi_wdata,
output [(DMA_DATA_WIDTH_DEST/8)-1:0] m_axi_wstrb,
input m_axi_wready,
output m_axi_wvalid,
output m_axi_wlast,
// Write response
input m_axi_bvalid,
input [ 1:0] m_axi_bresp,
output m_axi_bready,
// Read address
input m_axi_arready,
output m_axi_arvalid,
output [DMA_AXI_ADDR_WIDTH-1:0] m_axi_araddr,
output [AXI_LENGTH_WIDTH_SRC-1:0] m_axi_arlen,
output [ 2:0] m_axi_arsize,
output [ 1:0] m_axi_arburst,
output [ 2:0] m_axi_arprot,
output [ 3:0] m_axi_arcache,
// Read data and response
input [DMA_DATA_WIDTH_SRC-1:0] m_axi_rdata,
output m_axi_rready,
input m_axi_rvalid,
input m_axi_rlast,
input [ 1:0] m_axi_rresp,
// Slave streaming AXI interface
input s_axis_aclk,
output s_axis_ready,
input s_axis_valid,
input [DMA_DATA_WIDTH_SRC-1:0] s_axis_data,
input s_axis_last,
input [0:0] s_axis_user,
output s_axis_xfer_req,
// Master streaming AXI interface
input m_axis_aclk,
input m_axis_ready,
output m_axis_valid,
output [DMA_DATA_WIDTH_DEST-1:0] m_axis_data,
output m_axis_last,
output m_axis_xfer_req,
// Input FIFO interface
input fifo_wr_clk,
input fifo_wr_en,
input [DMA_DATA_WIDTH_SRC-1:0] fifo_wr_din,
output fifo_wr_overflow,
input fifo_wr_sync,
output fifo_wr_xfer_req,
// Input FIFO interface
input fifo_rd_clk,
input fifo_rd_en,
output fifo_rd_valid,
output [DMA_DATA_WIDTH_DEST-1:0] fifo_rd_dout,
output fifo_rd_underflow,
output fifo_rd_xfer_req,
output [ID_WIDTH-1:0] dbg_dest_request_id,
output [ID_WIDTH-1:0] dbg_dest_address_id,
output [ID_WIDTH-1:0] dbg_dest_data_id,
output [ID_WIDTH-1:0] dbg_dest_response_id,
output [ID_WIDTH-1:0] dbg_src_request_id,
output [ID_WIDTH-1:0] dbg_src_address_id,
output [ID_WIDTH-1:0] dbg_src_data_id,
output [ID_WIDTH-1:0] dbg_src_response_id,
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
input req_enable,
output dest_clk,
input dest_resetn,
output dest_ext_resetn,
input dest_enable,
output dest_enabled,
output src_clk,
input src_resetn,
output src_ext_resetn,
input src_enable,
output src_enabled,
// Diagnostics interface
output [7:0] dest_diag_level_bursts
);
localparam DMA_TYPE_MM_AXI = 0;
localparam DMA_TYPE_STREAM_AXI = 1;
localparam DMA_TYPE_FIFO = 2;
localparam DMA_ADDRESS_WIDTH_DEST = DMA_AXI_ADDR_WIDTH - BYTES_PER_BEAT_WIDTH_DEST;
localparam DMA_ADDRESS_WIDTH_SRC = DMA_AXI_ADDR_WIDTH - BYTES_PER_BEAT_WIDTH_SRC;
// Bytes per burst is the same for both dest and src, but bytes per beat may
// differ, so beats per burst may also differ
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
localparam BEATS_PER_BURST_WIDTH_SRC = BYTES_PER_BURST_WIDTH - BYTES_PER_BEAT_WIDTH_SRC;
localparam BEATS_PER_BURST_WIDTH_DEST = BYTES_PER_BURST_WIDTH - BYTES_PER_BEAT_WIDTH_DEST;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
localparam BURSTS_PER_TRANSFER_WIDTH = DMA_LENGTH_WIDTH - BYTES_PER_BURST_WIDTH;
reg eot_mem_src[0:2**ID_WIDTH-1];
reg eot_mem_dest[0:2**ID_WIDTH-1];
wire request_eot;
wire source_eot;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [ID_WIDTH-1:0] request_id;
wire [ID_WIDTH-1:0] source_id;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [ID_WIDTH-1:0] response_id;
wire enabled_src;
wire enabled_dest;
wire req_gen_valid;
wire req_gen_ready;
wire src_dest_valid;
wire src_dest_ready;
wire req_src_valid;
wire req_src_ready;
wire dest_req_valid;
wire dest_req_ready;
wire [DMA_ADDRESS_WIDTH_DEST-1:0] dest_req_dest_address;
wire dest_req_xlast;
wire dest_response_valid;
wire dest_response_ready;
wire [1:0] dest_response_resp;
wire dest_response_resp_eot;
wire [BYTES_PER_BURST_WIDTH-1:0] dest_response_data_burst_length;
wire dest_response_partial;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [ID_WIDTH-1:0] dest_request_id;
wire [ID_WIDTH-1:0] dest_data_request_id;
wire [ID_WIDTH-1:0] dest_data_response_id;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [ID_WIDTH-1:0] dest_response_id;
wire dest_valid;
wire dest_ready;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [DMA_DATA_WIDTH_DEST-1:0] dest_data;
wire dest_last;
wire dest_fifo_valid;
wire dest_fifo_ready;
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
wire [DMA_DATA_WIDTH_DEST-1:0] dest_fifo_data;
wire dest_fifo_last;
wire src_req_valid;
wire src_req_ready;
wire [DMA_ADDRESS_WIDTH_DEST-1:0] src_req_dest_address;
wire [DMA_ADDRESS_WIDTH_SRC-1:0] src_req_src_address;
wire [BEATS_PER_BURST_WIDTH_SRC-1:0] src_req_last_burst_length;
wire src_req_sync_transfer_start;
wire src_req_xlast;
reg [DMA_ADDRESS_WIDTH_DEST-1:0] src_req_dest_address_cur = 'h0;
reg src_req_xlast_cur = 1'b0;
/* TODO
wire src_response_valid;
wire src_response_ready;
wire src_response_empty;
wire [1:0] src_response_resp;
*/
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [ID_WIDTH-1:0] src_request_id;
reg [ID_WIDTH-1:0] src_throttled_request_id;
wire [ID_WIDTH-1:0] src_data_request_id;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [ID_WIDTH-1:0] src_response_id;
wire src_valid;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [DMA_DATA_WIDTH_SRC-1:0] src_data;
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
wire src_last;
wire src_partial_burst;
wire block_descr_to_dst;
wire src_fifo_valid;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [DMA_DATA_WIDTH_SRC-1:0] src_fifo_data;
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
wire src_fifo_last;
wire src_fifo_partial_burst;
wire src_bl_valid;
wire src_bl_ready;
wire [BEATS_PER_BURST_WIDTH_SRC-1:0] src_burst_length;
wire [BYTES_PER_BURST_WIDTH-1:0] dest_burst_info_length;
wire dest_burst_info_partial;
wire [ID_WIDTH-1:0] dest_burst_info_id;
wire dest_burst_info_write;
reg src_dest_valid_hs = 1'b0;
wire src_dest_valid_hs_masked;
wire src_dest_ready_hs;
wire req_rewind_req_valid;
wire [ID_WIDTH+3-1:0] req_rewind_req_data;
wire completion_req_valid;
wire completion_req_last;
wire [1:0] completion_transfer_id;
wire rewind_req_valid;
wire rewind_req_ready;
wire [ID_WIDTH+3-1:0] rewind_req_data;
reg src_throttler_enabled = 1'b1;
wire src_throttler_enable;
wire rewind_state;
/* Unused for now
wire response_src_valid;
wire response_src_ready = 1'b1;
wire [1:0] response_src_resp;
*/
assign dbg_dest_request_id = dest_request_id;
assign dbg_dest_response_id = dest_response_id;
assign dbg_src_request_id = src_request_id;
assign dbg_src_response_id = src_response_id;
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
always @(posedge req_clk)
begin
eot_mem_src[request_id] <= request_eot;
end
always @(posedge src_clk)
begin
eot_mem_dest[source_id] <= source_eot;
end
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
generate if (DMA_TYPE_DEST == DMA_TYPE_MM_AXI) begin
wire dest_bl_valid;
wire dest_bl_ready;
wire [BEATS_PER_BURST_WIDTH_DEST-1:0] dest_burst_length;
wire [BEATS_PER_BURST_WIDTH_SRC-1:0] dest_src_burst_length;
assign dest_clk = m_dest_axi_aclk;
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
assign dest_ext_resetn = m_dest_axi_aresetn;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [ID_WIDTH-1:0] dest_address_id;
wire dest_address_eot = eot_mem_dest[dest_address_id];
wire dest_response_eot = eot_mem_dest[dest_response_id];
assign dbg_dest_address_id = dest_address_id;
assign dbg_dest_data_id = dest_data_response_id;
assign dest_data_request_id = dest_address_id;
dmac_dest_mm_axi #(
.ID_WIDTH(ID_WIDTH),
.DMA_DATA_WIDTH(DMA_DATA_WIDTH_DEST),
.DMA_ADDR_WIDTH(DMA_AXI_ADDR_WIDTH),
.BEATS_PER_BURST_WIDTH(BEATS_PER_BURST_WIDTH_DEST),
.BYTES_PER_BEAT_WIDTH(BYTES_PER_BEAT_WIDTH_DEST),
.MAX_BYTES_PER_BURST(MAX_BYTES_PER_BURST),
.BYTES_PER_BURST_WIDTH(BYTES_PER_BURST_WIDTH),
.AXI_LENGTH_WIDTH(AXI_LENGTH_WIDTH_DEST)
) i_dest_dma_mm (
.m_axi_aclk(m_dest_axi_aclk),
.m_axi_aresetn(dest_resetn),
.enable(dest_enable),
.enabled(dest_enabled),
.req_valid(dest_req_valid),
.req_ready(dest_req_ready),
.req_address(dest_req_dest_address),
.bl_valid(dest_bl_valid),
.bl_ready(dest_bl_ready),
.measured_last_burst_length(dest_burst_length),
.response_valid(dest_response_valid),
.response_ready(dest_response_ready),
.response_resp(dest_response_resp),
.response_resp_eot(dest_response_resp_eot),
.response_resp_partial(dest_response_partial),
.response_data_burst_length(dest_response_data_burst_length),
.request_id(dest_request_id),
.response_id(dest_response_id),
.address_id(dest_address_id),
.address_eot(dest_address_eot),
.response_eot(dest_response_eot),
.fifo_valid(dest_valid),
.fifo_ready(dest_ready),
.fifo_data(dest_data),
.fifo_last(dest_last),
.dest_burst_info_length(dest_burst_info_length),
.dest_burst_info_partial(dest_burst_info_partial),
.dest_burst_info_id(dest_burst_info_id),
.dest_burst_info_write(dest_burst_info_write),
.m_axi_awready(m_axi_awready),
.m_axi_awvalid(m_axi_awvalid),
.m_axi_awaddr(m_axi_awaddr),
.m_axi_awlen(m_axi_awlen),
.m_axi_awsize(m_axi_awsize),
.m_axi_awburst(m_axi_awburst),
.m_axi_awprot(m_axi_awprot),
.m_axi_awcache(m_axi_awcache),
.m_axi_wready(m_axi_wready),
.m_axi_wvalid(m_axi_wvalid),
.m_axi_wdata(m_axi_wdata),
.m_axi_wstrb(m_axi_wstrb),
.m_axi_wlast(m_axi_wlast),
.m_axi_bvalid(m_axi_bvalid),
.m_axi_bresp(m_axi_bresp),
.m_axi_bready(m_axi_bready)
);
util_axis_fifo #(
.DATA_WIDTH(BEATS_PER_BURST_WIDTH_SRC),
.ADDRESS_WIDTH(0),
.ASYNC_CLK(ASYNC_CLK_SRC_DEST)
) i_src_dest_bl_fifo (
.s_axis_aclk(src_clk),
.s_axis_aresetn(src_resetn),
.s_axis_valid(src_bl_valid),
.s_axis_ready(src_bl_ready),
.s_axis_empty(),
.s_axis_data(src_burst_length),
.s_axis_room(),
.m_axis_aclk(dest_clk),
.m_axis_aresetn(dest_resetn),
.m_axis_valid(dest_bl_valid),
.m_axis_ready(dest_bl_ready),
.m_axis_data(dest_src_burst_length),
.m_axis_level()
);
// Adapt burst length from source width to destination width by either
// truncation or completion with ones.
if (BEATS_PER_BURST_WIDTH_SRC == BEATS_PER_BURST_WIDTH_DEST) begin
assign dest_burst_length = dest_src_burst_length;
end
if (BEATS_PER_BURST_WIDTH_SRC < BEATS_PER_BURST_WIDTH_DEST) begin
assign dest_burst_length = {dest_src_burst_length,
{BEATS_PER_BURST_WIDTH_DEST - BEATS_PER_BURST_WIDTH_SRC{1'b1}}};
end
if (BEATS_PER_BURST_WIDTH_SRC > BEATS_PER_BURST_WIDTH_DEST) begin
assign dest_burst_length = dest_src_burst_length[BEATS_PER_BURST_WIDTH_SRC-1 -: BEATS_PER_BURST_WIDTH_DEST];
end
end else begin
assign m_axi_awvalid = 1'b0;
assign m_axi_awaddr = 'h00;
assign m_axi_awlen = 'h00;
assign m_axi_awsize = 'h00;
assign m_axi_awburst = 'h00;
assign m_axi_awprot = 'h00;
assign m_axi_awcache = 'h00;
assign m_axi_wvalid = 1'b0;
assign m_axi_wdata = 'h00;
assign m_axi_wstrb = 'h00;
assign m_axi_wlast = 1'b0;
assign m_axi_bready = 1'b0;
assign src_bl_ready = 1'b1;
assign dest_response_partial = 1'b0;
assign dest_response_data_burst_length = 'h0;
end
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
if (DMA_TYPE_DEST == DMA_TYPE_STREAM_AXI) begin
assign dest_clk = m_axis_aclk;
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
assign dest_ext_resetn = 1'b1;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [ID_WIDTH-1:0] data_id;
wire data_eot = eot_mem_dest[data_id];
wire response_eot = eot_mem_dest[dest_response_id];
assign dest_data_request_id = dest_request_id;
assign dbg_dest_address_id = 'h00;
assign dbg_dest_data_id = data_id;
dmac_dest_axi_stream #(
.ID_WIDTH(ID_WIDTH),
.S_AXIS_DATA_WIDTH(DMA_DATA_WIDTH_DEST),
.BEATS_PER_BURST_WIDTH(BEATS_PER_BURST_WIDTH_DEST)
) i_dest_dma_stream (
.s_axis_aclk(m_axis_aclk),
.s_axis_aresetn(dest_resetn),
.enable(dest_enable),
.enabled(dest_enabled),
.req_valid(dest_req_valid),
.req_ready(dest_req_ready),
.req_xlast(dest_req_xlast),
.response_valid(dest_response_valid),
.response_ready(dest_response_ready),
.response_resp(dest_response_resp),
.response_resp_eot(dest_response_resp_eot),
.response_id(dest_response_id),
.data_id(data_id),
.xfer_req(m_axis_xfer_req),
.data_eot(data_eot),
.response_eot(response_eot),
.fifo_valid(dest_valid),
.fifo_ready(dest_ready),
.fifo_data(dest_data),
.fifo_last(dest_last),
.m_axis_valid(m_axis_valid),
.m_axis_ready(m_axis_ready),
.m_axis_data(m_axis_data),
.m_axis_last(m_axis_last)
);
end else begin
assign m_axis_valid = 1'b0;
assign m_axis_last = 1'b0;
assign m_axis_xfer_req = 1'b0;
assign m_axis_data = 'h00;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
end
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
if (DMA_TYPE_DEST == DMA_TYPE_FIFO) begin
assign dest_clk = fifo_rd_clk;
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
assign dest_ext_resetn = 1'b1;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
wire [ID_WIDTH-1:0] data_id;
wire data_eot = eot_mem_dest[data_id];
wire response_eot = eot_mem_dest[dest_response_id];
assign dest_data_request_id = dest_request_id;
assign dbg_dest_address_id = 'h00;
assign dbg_dest_data_id = data_id;
dmac_dest_fifo_inf #(
.ID_WIDTH(ID_WIDTH),
.DATA_WIDTH(DMA_DATA_WIDTH_DEST),
.BEATS_PER_BURST_WIDTH(BEATS_PER_BURST_WIDTH_DEST)
) i_dest_dma_fifo (
.clk(fifo_rd_clk),
.resetn(dest_resetn),
.enable(dest_enable),
.enabled(dest_enabled),
.req_valid(dest_req_valid),
.req_ready(dest_req_ready),
.response_valid(dest_response_valid),
.response_ready(dest_response_ready),
.response_resp(dest_response_resp),
.response_resp_eot(dest_response_resp_eot),
.response_id(dest_response_id),
.data_id(data_id),
.data_eot(data_eot),
.response_eot(response_eot),
.fifo_valid(dest_valid),
.fifo_ready(dest_ready),
.fifo_data(dest_data),
.fifo_last(dest_last),
.en(fifo_rd_en),
.valid(fifo_rd_valid),
.dout(fifo_rd_dout),
.underflow(fifo_rd_underflow),
.xfer_req(fifo_rd_xfer_req)
);
end else begin
assign fifo_rd_valid = 1'b0;
assign fifo_rd_dout = 'h0;
assign fifo_rd_underflow = 1'b0;
assign fifo_rd_xfer_req = 1'b0;
end endgenerate
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
generate if (DMA_TYPE_SRC == DMA_TYPE_MM_AXI) begin
wire [ID_WIDTH-1:0] src_data_id;
wire [ID_WIDTH-1:0] src_address_id;
wire src_address_eot = eot_mem_src[src_address_id];
assign source_id = src_address_id;
assign source_eot = src_address_eot;
assign src_clk = m_src_axi_aclk;
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
assign src_ext_resetn = m_src_axi_aresetn;
assign dbg_src_address_id = src_address_id;
assign dbg_src_data_id = src_data_id;
dmac_src_mm_axi #(
.ID_WIDTH(ID_WIDTH),
.DMA_DATA_WIDTH(DMA_DATA_WIDTH_SRC),
.DMA_ADDR_WIDTH(DMA_AXI_ADDR_WIDTH),
.BEATS_PER_BURST_WIDTH(BEATS_PER_BURST_WIDTH_SRC),
.BYTES_PER_BEAT_WIDTH(BYTES_PER_BEAT_WIDTH_SRC),
.AXI_LENGTH_WIDTH(AXI_LENGTH_WIDTH_SRC)
) i_src_dma_mm (
.m_axi_aclk(m_src_axi_aclk),
.m_axi_aresetn(src_resetn),
.enable(src_enable),
.enabled(src_enabled),
.req_valid(src_req_valid),
.req_ready(src_req_ready),
.req_address(src_req_src_address),
.req_last_burst_length(src_req_last_burst_length),
.bl_valid(src_bl_valid),
.bl_ready(src_bl_ready),
.measured_last_burst_length(src_burst_length),
/* TODO
.response_valid(src_response_valid),
.response_ready(src_response_ready),
.response_resp(src_response_resp),
*/
.request_id(src_throttled_request_id),
.response_id(src_response_id),
.address_id(src_address_id),
.data_id(src_data_id),
.address_eot(src_address_eot),
.fifo_valid(src_valid),
.fifo_data(src_data),
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
.fifo_last(src_last),
.m_axi_arready(m_axi_arready),
.m_axi_arvalid(m_axi_arvalid),
.m_axi_araddr(m_axi_araddr),
.m_axi_arlen(m_axi_arlen),
.m_axi_arsize(m_axi_arsize),
.m_axi_arburst(m_axi_arburst),
.m_axi_arprot(m_axi_arprot),
.m_axi_arcache(m_axi_arcache),
.m_axi_rready(m_axi_rready),
.m_axi_rvalid(m_axi_rvalid),
.m_axi_rdata(m_axi_rdata),
.m_axi_rlast(m_axi_rlast),
.m_axi_rresp(m_axi_rresp)
);
end else begin
assign m_axi_arvalid = 1'b0;
assign m_axi_araddr = 'h00;
assign m_axi_arlen = 'h00;
assign m_axi_arsize = 'h00;
assign m_axi_arburst = 'h00;
assign m_axi_arcache = 'h00;
assign m_axi_arprot = 'h00;
assign m_axi_rready = 1'b0;
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
end
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
if (DMA_TYPE_SRC == DMA_TYPE_STREAM_AXI) begin
assign src_clk = s_axis_aclk;
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
assign src_ext_resetn = 1'b1;
wire src_eot = eot_mem_src[src_response_id];
assign dbg_src_address_id = 'h00;
assign dbg_src_data_id = 'h00;
/* TODO
assign src_response_valid = 1'b0;
assign src_response_resp = 2'b0;
*/
dmac_src_axi_stream #(
.ID_WIDTH(ID_WIDTH),
.S_AXIS_DATA_WIDTH(DMA_DATA_WIDTH_SRC),
.BEATS_PER_BURST_WIDTH(BEATS_PER_BURST_WIDTH_SRC)
) i_src_dma_stream (
.s_axis_aclk(s_axis_aclk),
.s_axis_aresetn(src_resetn),
.enable(src_enable),
.enabled(src_enabled),
.req_valid(src_req_valid),
.req_ready(src_req_ready),
.req_last_burst_length(src_req_last_burst_length),
.req_sync_transfer_start(src_req_sync_transfer_start),
.req_xlast(src_req_xlast),
.request_id(src_throttled_request_id),
.response_id(src_response_id),
.eot(src_eot),
.rewind_req_valid(rewind_req_valid),
.rewind_req_ready(rewind_req_ready),
.rewind_req_data(rewind_req_data),
.bl_valid(src_bl_valid),
.bl_ready(src_bl_ready),
.measured_last_burst_length(src_burst_length),
.block_descr_to_dst(block_descr_to_dst),
.source_id(source_id),
.source_eot(source_eot),
.fifo_valid(src_valid),
.fifo_data(src_data),
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
.fifo_last(src_last),
.fifo_partial_burst(src_partial_burst),
.s_axis_valid(s_axis_valid),
.s_axis_ready(s_axis_ready),
.s_axis_data(s_axis_data),
.s_axis_last(s_axis_last),
.s_axis_user(s_axis_user),
.s_axis_xfer_req(s_axis_xfer_req)
);
util_axis_fifo #(
.DATA_WIDTH(ID_WIDTH + 3),
.ADDRESS_WIDTH(0),
.ASYNC_CLK(ASYNC_CLK_REQ_SRC)
) i_rewind_req_fifo (
.s_axis_aclk(src_clk),
.s_axis_aresetn(src_resetn),
.s_axis_valid(rewind_req_valid),
.s_axis_ready(rewind_req_ready),
.s_axis_empty(),
.s_axis_data(rewind_req_data),
.s_axis_room(),
.m_axis_aclk(req_clk),
.m_axis_aresetn(req_resetn),
.m_axis_valid(req_rewind_req_valid),
.m_axis_ready(1'b1),
.m_axis_data(req_rewind_req_data),
.m_axis_level()
);
end else begin
assign s_axis_ready = 1'b0;
assign s_axis_xfer_req = 1'b0;
assign rewind_req_valid = 1'b0;
assign rewind_req_data = 'h0;
assign req_rewind_req_valid = 'b0;
assign req_rewind_req_data = 'h0;
assign src_partial_burst = 1'b0;
assign block_descr_to_dst = 1'b0;
end
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
2015-08-19 11:11:47 +00:00
if (DMA_TYPE_SRC == DMA_TYPE_FIFO) begin
wire src_eot = eot_mem_src[src_response_id];
assign source_id = src_response_id;
assign source_eot = src_eot;
assign src_clk = fifo_wr_clk;
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
assign src_ext_resetn = 1'b1;
assign dbg_src_address_id = 'h00;
assign dbg_src_data_id = 'h00;
/* TODO
assign src_response_valid = 1'b0;
assign src_response_resp = 2'b0;
*/
dmac_src_fifo_inf #(
.ID_WIDTH(ID_WIDTH),
.DATA_WIDTH(DMA_DATA_WIDTH_SRC),
.BEATS_PER_BURST_WIDTH(BEATS_PER_BURST_WIDTH_SRC)
) i_src_dma_fifo (
.clk(fifo_wr_clk),
.resetn(src_resetn),
.enable(src_enable),
.enabled(src_enabled),
.req_valid(src_req_valid),
.req_ready(src_req_ready),
.req_last_burst_length(src_req_last_burst_length),
.req_sync_transfer_start(src_req_sync_transfer_start),
.request_id(src_throttled_request_id),
.response_id(src_response_id),
.eot(src_eot),
.bl_valid(src_bl_valid),
.bl_ready(src_bl_ready),
.measured_last_burst_length(src_burst_length),
.fifo_valid(src_valid),
.fifo_data(src_data),
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
.fifo_last(src_last),
.en(fifo_wr_en),
.din(fifo_wr_din),
.overflow(fifo_wr_overflow),
.sync(fifo_wr_sync),
.xfer_req(fifo_wr_xfer_req)
);
end else begin
assign fifo_wr_overflow = 1'b0;
assign fifo_wr_xfer_req = 1'b0;
end endgenerate
sync_bits #(
.NUM_OF_BITS(ID_WIDTH),
.ASYNC_CLK(ASYNC_CLK_REQ_SRC)
) i_sync_src_request_id (
.out_clk(src_clk),
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
.out_resetn(1'b1),
.in(request_id),
.out(src_request_id)
);
`include "inc_id.vh"
function compare_id;
input [ID_WIDTH-1:0] a;
input [ID_WIDTH-1:0] b;
begin
compare_id = a[ID_WIDTH-1] == b[ID_WIDTH-1];
if (ID_WIDTH >= 2) begin
if (a[ID_WIDTH-2] == b[ID_WIDTH-2]) begin
compare_id = 1'b1;
end
end
if (ID_WIDTH >= 3) begin
if (a[ID_WIDTH-3:0] != b[ID_WIDTH-3:0]) begin
compare_id = 1'b1;
end
end
end
endfunction
sync_event #(.ASYNC_CLK(ASYNC_CLK_REQ_SRC)) sync_rewind (
.in_clk(req_clk),
.in_event(rewind_state),
.out_clk(src_clk),
.out_event(src_throttler_enable)
);
always @(posedge src_clk) begin
if (src_resetn == 1'b0) begin
src_throttler_enabled <= 'b1;
end else if (rewind_req_valid) begin
src_throttler_enabled <= 'b0;
end else if (src_throttler_enable) begin
src_throttler_enabled <= 'b1;
end
end
/*
* Make sure that we do not request more data than what fits into the
* store-and-forward burst memory.
* Throttler must be blocked during rewind since it does not tolerate
* a decrement of the request ID.
*/
always @(posedge src_clk) begin
if (src_resetn == 1'b0) begin
src_throttled_request_id <= 'h00;
end else if (rewind_req_valid) begin
src_throttled_request_id <= rewind_req_data[ID_WIDTH-1:0];
end else if (src_throttled_request_id != src_request_id &&
compare_id(src_throttled_request_id, src_data_request_id) &&
src_throttler_enabled) begin
src_throttled_request_id <= inc_id(src_throttled_request_id);
end
end
sync_bits #(
.NUM_OF_BITS(ID_WIDTH),
.ASYNC_CLK(ASYNC_CLK_DEST_REQ)
) i_sync_req_response_id (
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
.out_clk(req_clk),
.out_resetn(1'b1),
.in(dest_response_id),
.out(response_id)
);
axi_register_slice #(
.DATA_WIDTH(DMA_DATA_WIDTH_SRC + 2),
.FORWARD_REGISTERED(AXI_SLICE_SRC),
.BACKWARD_REGISTERED(0)
) i_src_slice (
.clk(src_clk),
.resetn(src_resetn),
.s_axi_valid(src_valid),
.s_axi_ready(),
.s_axi_data({src_data,src_last,src_partial_burst}),
.m_axi_valid(src_fifo_valid),
.m_axi_ready(1'b1), /* No backpressure */
.m_axi_data({src_fifo_data,src_fifo_last,src_fifo_partial_burst})
);
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
axi_dmac_burst_memory #(
.DATA_WIDTH_SRC(DMA_DATA_WIDTH_SRC),
.DATA_WIDTH_DEST(DMA_DATA_WIDTH_DEST),
.ID_WIDTH(ID_WIDTH),
.MAX_BYTES_PER_BURST(MAX_BYTES_PER_BURST),
.ASYNC_CLK(ASYNC_CLK_SRC_DEST),
.BYTES_PER_BEAT_WIDTH_SRC(BYTES_PER_BEAT_WIDTH_SRC),
.BYTES_PER_BURST_WIDTH(BYTES_PER_BURST_WIDTH),
.ENABLE_DIAGNOSTICS_IF(ENABLE_DIAGNOSTICS_IF)
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
) i_store_and_forward (
.src_clk(src_clk),
.src_reset(~src_resetn),
.src_data_valid(src_fifo_valid),
.src_data(src_fifo_data),
.src_data_last(src_fifo_last),
.src_data_valid_bytes({BYTES_PER_BEAT_WIDTH_SRC{1'b1}}),
.src_data_partial_burst(src_fifo_partial_burst),
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
.src_data_request_id(src_data_request_id),
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
.dest_clk(dest_clk),
.dest_reset(~dest_resetn),
.dest_data_valid(dest_fifo_valid),
.dest_data_ready(dest_fifo_ready),
.dest_data(dest_fifo_data),
.dest_data_last(dest_fifo_last),
.dest_burst_info_length(dest_burst_info_length),
.dest_burst_info_partial(dest_burst_info_partial),
.dest_burst_info_id(dest_burst_info_id),
.dest_burst_info_write(dest_burst_info_write),
.dest_request_id(dest_request_id),
.dest_data_request_id(dest_data_request_id),
.dest_data_response_id(dest_data_response_id),
.dest_diag_level_bursts(dest_diag_level_bursts)
);
axi_register_slice #(
.DATA_WIDTH(DMA_DATA_WIDTH_DEST + 1),
.FORWARD_REGISTERED(AXI_SLICE_DEST),
.BACKWARD_REGISTERED(AXI_SLICE_DEST)
) i_dest_slice (
.clk(dest_clk),
.resetn(dest_resetn),
axi_dmac: Rework data store-and-forward buffer Currently the DMAC uses a simple FIFO as the store-and-forward buffer. The FIFO handshaking is beat based whereas the remainder of the DMAC is burst based. This means that additional control signals have to be combined with the FIFO handshaking signal to generate the external handshaking signals. Re-work the store-and-forward buffer to utilize a BRAM that is subdivided into N segments. Where N is the maximum number of bursts that can be stored in the buffer and each segment has the size of the maximum burst length. Each segment stores the data associated with one burst and even when the burst is shorter than the maximum burst length the next burst will be stored in the next segment. The new store-and-forward buffer takes care of generating all the handshaking signals. This means handshaking is generated in a central place and does not have to be combined from multiple data-paths simplifying the overall logic. The new store-and-forward buffer also takes care of data width up- and down-sizing in case that the source and sink modules have a different data width. This tighter integration will allow future enhancements like using asymmetric memory. This re-work lays the foundation of future enhancements to the DMA like support for un-aligned transfers and early transfer abort which would have been much more difficult to implement with the previous architecture. In addition it significantly reduces the resource utilization of the store-and-forward buffer and allows for better timing due to reduced combinatorial path lengths. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2018-05-09 16:02:41 +00:00
.s_axi_valid(dest_fifo_valid),
.s_axi_ready(dest_fifo_ready),
.s_axi_data({
dest_fifo_last,
dest_fifo_data
}),
.m_axi_valid(dest_valid),
.m_axi_ready(dest_ready),
.m_axi_data({
dest_last,
dest_data
})
);
// Don't let the request generator run in advance more than one descriptor
// The descriptor FIFO should not block the start of the request generator
// since it becomes ready earlier.
assign req_gen_valid = req_valid & req_ready;
assign req_src_valid = req_valid & req_ready;
assign req_ready = req_gen_ready & req_src_ready;
util_axis_fifo #(
.DATA_WIDTH(DMA_ADDRESS_WIDTH_DEST + 1),
.ADDRESS_WIDTH(0),
.ASYNC_CLK(ASYNC_CLK_SRC_DEST)
) i_dest_req_fifo (
.s_axis_aclk(src_clk),
.s_axis_aresetn(src_resetn),
.s_axis_valid(src_dest_valid_hs_masked),
.s_axis_ready(src_dest_ready_hs),
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
.s_axis_empty(),
.s_axis_data({
src_req_dest_address_cur,
src_req_xlast_cur
}),
.s_axis_room(),
.m_axis_aclk(dest_clk),
.m_axis_aresetn(dest_resetn),
.m_axis_valid(dest_req_valid),
.m_axis_ready(dest_req_ready),
.m_axis_data({
dest_req_dest_address,
dest_req_xlast
}),
.m_axis_level()
);
util_axis_fifo #(
.DATA_WIDTH(DMA_ADDRESS_WIDTH_DEST + DMA_ADDRESS_WIDTH_SRC + BEATS_PER_BURST_WIDTH_SRC + 2),
.ADDRESS_WIDTH(0),
.ASYNC_CLK(ASYNC_CLK_REQ_SRC)
) i_src_req_fifo (
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
.s_axis_aclk(req_clk),
.s_axis_aresetn(req_resetn),
.s_axis_valid(req_src_valid),
.s_axis_ready(req_src_ready),
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
.s_axis_empty(),
.s_axis_data({
req_dest_address,
req_src_address,
req_length[BYTES_PER_BURST_WIDTH-1:BYTES_PER_BEAT_WIDTH_SRC],
req_sync_transfer_start,
req_xlast
}),
.s_axis_room(),
.m_axis_aclk(src_clk),
.m_axis_aresetn(src_resetn),
.m_axis_valid(src_req_spltr_valid),
.m_axis_ready(src_req_spltr_ready),
.m_axis_data({
src_req_dest_address,
src_req_src_address,
src_req_last_burst_length,
src_req_sync_transfer_start,
src_req_xlast
}),
.m_axis_level()
);
// Save the descriptor in the source clock domain since the submission to
// destination is delayed.
always @(posedge src_clk) begin
if (src_req_valid == 1'b1 && src_req_ready == 1'b1) begin
src_req_dest_address_cur <= src_req_dest_address;
src_req_xlast_cur <= src_req_xlast;
end
end
always @(posedge src_clk) begin
if (src_resetn == 1'b0) begin
src_dest_valid_hs <= 1'b0;
end else if (src_req_valid == 1'b1 && src_req_ready == 1'b1) begin
src_dest_valid_hs <= 1'b1;
end else if (src_dest_ready_hs == 1'b1) begin
src_dest_valid_hs <= 1'b0;
end
end
// Forward the descriptor to the destination only after the source decided to
// do so
assign src_dest_valid_hs_masked = src_dest_valid_hs == 1'b1 && block_descr_to_dst == 1'b0;
assign src_req_spltr_ready = src_req_ready && src_dest_ready_hs;
assign src_req_valid = src_req_spltr_valid && src_req_spltr_ready;
/* Unused for now
util_axis_fifo #(
.DATA_WIDTH(2),
.ADDRESS_WIDTH(0),
.ASYNC_CLK(ASYNC_CLK_REQ_SRC)
) i_src_response_fifo (
.s_axis_aclk(src_clk),
.s_axis_aresetn(src_resetn),
.s_axis_valid(src_response_valid),
.s_axis_ready(src_response_ready),
.s_axis_empty(src_response_empty),
.s_axis_data(src_response_resp),
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
.m_axis_aclk(req_clk),
.m_axis_aresetn(req_resetn),
.m_axis_valid(response_src_valid),
.m_axis_ready(response_src_ready),
.m_axis_data(response_src_resp)
);
assign src_response_empty = 1'b1;
assign src_response_ready = 1'b1;
*/
dmac_request_generator #(
.ID_WIDTH(ID_WIDTH),
.BURSTS_PER_TRANSFER_WIDTH(BURSTS_PER_TRANSFER_WIDTH)
) i_req_gen (
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
.clk(req_clk),
.resetn(req_resetn),
.request_id(request_id),
.response_id(response_id),
.rewind_req_valid(req_rewind_req_valid),
.rewind_req_data(req_rewind_req_data),
.rewind_state(rewind_state),
2018-08-30 13:29:24 +00:00
.abort_req(abort_req),
.completion_req_valid(completion_req_valid),
.completion_req_last(completion_req_last),
.completion_transfer_id(completion_transfer_id),
.req_valid(req_gen_valid),
.req_ready(req_gen_ready),
.req_burst_count(req_length[DMA_LENGTH_WIDTH-1:BYTES_PER_BURST_WIDTH]),
.req_xlast(req_xlast),
axi_dmac: Rework transfer shutdown The DMAC allows a transfer to be aborted. When a transfer is aborted the DMAC shuts down as fast as possible while still completing any pending transactions as required by the protocol specifications of the port. E.g. for AXI-MM this means to complete all outstanding bursts. Once the DMAC has entered an idle state a special synchronization signal is send to all modules. This synchronization signal instructs them to flush the pipeline and remove any stale data and metadata associated with the aborted transfer. Once all data has been flushed the DMAC enters the shutdown state and is ready for the next transfer. In addition each module has a reset that resets the modules state and is used at system startup to bring them into a consistent state. Re-work the shutdown process to instead of flushing the pipeline re-use the startup reset signal also for shutdown. To manage the reset signal generation introduce the reset manager module. It contains a state machine that will assert the reset signals in the correct order and for the appropriate duration in case of a transfer shutdown. The reset signal is asserted in all domains until it has been asserted for at least 4 clock cycles in the slowest domain. This ensures that the reset signal is not de-asserted in the faster domains before the slower domains have had a chance to process the reset signal. In addition the reset signal is de-asserted in the opposite direction of the data flow. This ensures that the data sink is ready to receive data before the data source can start sending data. This simplifies the internal handshaking. This approach has multiple advantages. * Issuing a reset and removing all state takes less time than explicitly flushing one sample per clock cycle at a time. * It simplifies the logic in the faster clock domains at the expense of more complicated logic in the slower control clock domain. This allows for higher fMax on the data paths. * Less signals to synchronize from the control domain to the data domains The implementation of the pause mode has also slightly changed. Pause is now a simple disable of the data domains. When the transfer is resumed after a pause the data domains are re-enabled and continue at their previous state. Signed-off-by: Lars-Peter Clausen <lars@metafoo.de>
2017-09-21 14:02:44 +00:00
.enable(req_enable),
.eot(request_eot)
);
axi_dmac_response_manager #(
.DMA_DATA_WIDTH_SRC(DMA_DATA_WIDTH_SRC),
.DMA_DATA_WIDTH_DEST(DMA_DATA_WIDTH_DEST),
.DMA_LENGTH_WIDTH(DMA_LENGTH_WIDTH),
.BYTES_PER_BURST_WIDTH(BYTES_PER_BURST_WIDTH),
.BYTES_PER_BEAT_WIDTH_SRC(BYTES_PER_BEAT_WIDTH_SRC),
.ASYNC_CLK_DEST_REQ(ASYNC_CLK_DEST_REQ)
) i_response_manager(
.dest_clk(dest_clk),
.dest_resetn(dest_resetn),
.dest_response_valid(dest_response_valid),
.dest_response_ready(dest_response_ready),
.dest_response_resp(dest_response_resp),
.dest_response_partial(dest_response_partial),
.dest_response_resp_eot(dest_response_resp_eot),
.dest_response_data_burst_length(dest_response_data_burst_length),
.req_clk(req_clk),
.req_resetn(req_resetn),
.response_eot(eot),
.measured_burst_length(measured_burst_length),
.response_partial(response_partial),
.response_valid(response_valid),
.response_ready(response_ready),
.completion_req_valid(completion_req_valid),
.completion_req_last(completion_req_last),
.completion_transfer_id(completion_transfer_id)
);
endmodule