fpga-lab-2/Top/niosII/synthesis/submodules/altera_avalon_sc_fifo.v

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// -----------------------------------------------------------
// Legal Notice: (C)2007 Altera Corporation. All rights reserved. Your
// use of Altera Corporation's design tools, logic functions and other
// software and tools, and its AMPP partner logic functions, and any
// output files any of the foregoing (including device programming or
// simulation files), and any associated documentation or information are
// expressly subject to the terms and conditions of the Altera Program
// License Subscription Agreement or other applicable license agreement,
// including, without limitation, that your use is for the sole purpose
// of programming logic devices manufactured by Altera and sold by Altera
// or its authorized distributors. Please refer to the applicable
// agreement for further details.
//
// Description: Single clock Avalon-ST FIFO.
// -----------------------------------------------------------
`timescale 1 ns / 1 ns
//altera message_off 10036
module altera_avalon_sc_fifo
#(
// --------------------------------------------------
// Parameters
// --------------------------------------------------
parameter SYMBOLS_PER_BEAT = 1,
parameter BITS_PER_SYMBOL = 8,
parameter FIFO_DEPTH = 16,
parameter CHANNEL_WIDTH = 0,
parameter ERROR_WIDTH = 0,
parameter USE_PACKETS = 0,
parameter USE_FILL_LEVEL = 0,
parameter USE_STORE_FORWARD = 0,
parameter USE_ALMOST_FULL_IF = 0,
parameter USE_ALMOST_EMPTY_IF = 0,
// --------------------------------------------------
// Empty latency is defined as the number of cycles
// required for a write to deassert the empty flag.
// For example, a latency of 1 means that the empty
// flag is deasserted on the cycle after a write.
//
// Another way to think of it is the latency for a
// write to propagate to the output.
//
// An empty latency of 0 implies lookahead, which is
// only implemented for the register-based FIFO.
// --------------------------------------------------
parameter EMPTY_LATENCY = 3,
parameter USE_MEMORY_BLOCKS = 1,
// --------------------------------------------------
// Internal Parameters
// --------------------------------------------------
parameter DATA_WIDTH = SYMBOLS_PER_BEAT * BITS_PER_SYMBOL,
parameter EMPTY_WIDTH = log2ceil(SYMBOLS_PER_BEAT)
)
(
// --------------------------------------------------
// Ports
// --------------------------------------------------
input clk,
input reset,
input [DATA_WIDTH-1: 0] in_data,
input in_valid,
input in_startofpacket,
input in_endofpacket,
input [((EMPTY_WIDTH>0) ? (EMPTY_WIDTH-1):0) : 0] in_empty,
input [((ERROR_WIDTH>0) ? (ERROR_WIDTH-1):0) : 0] in_error,
input [((CHANNEL_WIDTH>0) ? (CHANNEL_WIDTH-1):0): 0] in_channel,
output in_ready,
output [DATA_WIDTH-1 : 0] out_data,
output reg out_valid,
output out_startofpacket,
output out_endofpacket,
output [((EMPTY_WIDTH>0) ? (EMPTY_WIDTH-1):0) : 0] out_empty,
output [((ERROR_WIDTH>0) ? (ERROR_WIDTH-1):0) : 0] out_error,
output [((CHANNEL_WIDTH>0) ? (CHANNEL_WIDTH-1):0): 0] out_channel,
input out_ready,
input [(USE_STORE_FORWARD ? 2 : 1) : 0] csr_address,
input csr_write,
input csr_read,
input [31 : 0] csr_writedata,
output reg [31 : 0] csr_readdata,
output wire almost_full_data,
output wire almost_empty_data
);
// --------------------------------------------------
// Local Parameters
// --------------------------------------------------
localparam ADDR_WIDTH = log2ceil(FIFO_DEPTH);
localparam DEPTH = FIFO_DEPTH;
localparam PKT_SIGNALS_WIDTH = 2 + EMPTY_WIDTH;
localparam PAYLOAD_WIDTH = (USE_PACKETS == 1) ?
2 + EMPTY_WIDTH + DATA_WIDTH + ERROR_WIDTH + CHANNEL_WIDTH:
DATA_WIDTH + ERROR_WIDTH + CHANNEL_WIDTH;
// --------------------------------------------------
// Internal Signals
// --------------------------------------------------
genvar i;
reg [PAYLOAD_WIDTH-1 : 0] mem [DEPTH-1 : 0];
reg [ADDR_WIDTH-1 : 0] wr_ptr;
reg [ADDR_WIDTH-1 : 0] rd_ptr;
reg [DEPTH-1 : 0] mem_used;
wire [ADDR_WIDTH-1 : 0] next_wr_ptr;
wire [ADDR_WIDTH-1 : 0] next_rd_ptr;
wire [ADDR_WIDTH-1 : 0] incremented_wr_ptr;
wire [ADDR_WIDTH-1 : 0] incremented_rd_ptr;
wire [ADDR_WIDTH-1 : 0] mem_rd_ptr;
wire read;
wire write;
reg empty;
reg next_empty;
reg full;
reg next_full;
wire [PKT_SIGNALS_WIDTH-1 : 0] in_packet_signals;
wire [PKT_SIGNALS_WIDTH-1 : 0] out_packet_signals;
wire [PAYLOAD_WIDTH-1 : 0] in_payload;
reg [PAYLOAD_WIDTH-1 : 0] internal_out_payload;
reg [PAYLOAD_WIDTH-1 : 0] out_payload;
reg internal_out_valid;
wire internal_out_ready;
reg [ADDR_WIDTH : 0] fifo_fill_level;
reg [ADDR_WIDTH : 0] fill_level;
reg [ADDR_WIDTH-1 : 0] sop_ptr = 0;
wire [ADDR_WIDTH-1 : 0] curr_sop_ptr;
reg [23:0] almost_full_threshold;
reg [23:0] almost_empty_threshold;
reg [23:0] cut_through_threshold;
reg [15:0] pkt_cnt;
reg drop_on_error_en;
reg error_in_pkt;
reg pkt_has_started;
reg sop_has_left_fifo;
reg fifo_too_small_r;
reg pkt_cnt_eq_zero;
reg pkt_cnt_eq_one;
wire wait_for_threshold;
reg pkt_mode;
wire wait_for_pkt;
wire ok_to_forward;
wire in_pkt_eop_arrive;
wire out_pkt_leave;
wire in_pkt_start;
wire in_pkt_error;
wire drop_on_error;
wire fifo_too_small;
wire out_pkt_sop_leave;
wire [31:0] max_fifo_size;
reg fifo_fill_level_lt_cut_through_threshold;
// --------------------------------------------------
// Define Payload
//
// Icky part where we decide which signals form the
// payload to the FIFO with generate blocks.
// --------------------------------------------------
generate
if (EMPTY_WIDTH > 0) begin : gen_blk1
assign in_packet_signals = {in_startofpacket, in_endofpacket, in_empty};
assign {out_startofpacket, out_endofpacket, out_empty} = out_packet_signals;
end
else begin : gen_blk1_else
assign out_empty = in_error;
assign in_packet_signals = {in_startofpacket, in_endofpacket};
assign {out_startofpacket, out_endofpacket} = out_packet_signals;
end
endgenerate
generate
if (USE_PACKETS) begin : gen_blk2
if (ERROR_WIDTH > 0) begin : gen_blk3
if (CHANNEL_WIDTH > 0) begin : gen_blk4
assign in_payload = {in_packet_signals, in_data, in_error, in_channel};
assign {out_packet_signals, out_data, out_error, out_channel} = out_payload;
end
else begin : gen_blk4_else
assign out_channel = in_channel;
assign in_payload = {in_packet_signals, in_data, in_error};
assign {out_packet_signals, out_data, out_error} = out_payload;
end
end
else begin : gen_blk3_else
assign out_error = in_error;
if (CHANNEL_WIDTH > 0) begin : gen_blk5
assign in_payload = {in_packet_signals, in_data, in_channel};
assign {out_packet_signals, out_data, out_channel} = out_payload;
end
else begin : gen_blk5_else
assign out_channel = in_channel;
assign in_payload = {in_packet_signals, in_data};
assign {out_packet_signals, out_data} = out_payload;
end
end
end
else begin : gen_blk2_else
assign out_packet_signals = 0;
if (ERROR_WIDTH > 0) begin : gen_blk6
if (CHANNEL_WIDTH > 0) begin : gen_blk7
assign in_payload = {in_data, in_error, in_channel};
assign {out_data, out_error, out_channel} = out_payload;
end
else begin : gen_blk7_else
assign out_channel = in_channel;
assign in_payload = {in_data, in_error};
assign {out_data, out_error} = out_payload;
end
end
else begin : gen_blk6_else
assign out_error = in_error;
if (CHANNEL_WIDTH > 0) begin : gen_blk8
assign in_payload = {in_data, in_channel};
assign {out_data, out_channel} = out_payload;
end
else begin : gen_blk8_else
assign out_channel = in_channel;
assign in_payload = in_data;
assign out_data = out_payload;
end
end
end
endgenerate
// --------------------------------------------------
// Memory-based FIFO storage
//
// To allow a ready latency of 0, the read index is
// obtained from the next read pointer and memory
// outputs are unregistered.
//
// If the empty latency is 1, we infer bypass logic
// around the memory so writes propagate to the
// outputs on the next cycle.
//
// Do not change the way this is coded: Quartus needs
// a perfect match to the template, and any attempt to
// refactor the two always blocks into one will break
// memory inference.
// --------------------------------------------------
generate if (USE_MEMORY_BLOCKS == 1) begin : gen_blk9
if (EMPTY_LATENCY == 1) begin : gen_blk10
always @(posedge clk) begin
if (in_valid && in_ready)
mem[wr_ptr] = in_payload;
internal_out_payload = mem[mem_rd_ptr];
end
end else begin : gen_blk10_else
always @(posedge clk) begin
if (in_valid && in_ready)
mem[wr_ptr] <= in_payload;
internal_out_payload <= mem[mem_rd_ptr];
end
end
assign mem_rd_ptr = next_rd_ptr;
end else begin : gen_blk9_else
// --------------------------------------------------
// Register-based FIFO storage
//
// Uses a shift register as the storage element. Each
// shift register slot has a bit which indicates if
// the slot is occupied (credit to Sam H for the idea).
// The occupancy bits are contiguous and start from the
// lsb, so 0000, 0001, 0011, 0111, 1111 for a 4-deep
// FIFO.
//
// Each slot is enabled during a read or when it
// is unoccupied. New data is always written to every
// going-to-be-empty slot (we keep track of which ones
// are actually useful with the occupancy bits). On a
// read we shift occupied slots.
//
// The exception is the last slot, which always gets
// new data when it is unoccupied.
// --------------------------------------------------
for (i = 0; i < DEPTH-1; i = i + 1) begin : shift_reg
always @(posedge clk or posedge reset) begin
if (reset) begin
mem[i] <= 0;
end
else if (read || !mem_used[i]) begin
if (!mem_used[i+1])
mem[i] <= in_payload;
else
mem[i] <= mem[i+1];
end
end
end
always @(posedge clk, posedge reset) begin
if (reset) begin
mem[DEPTH-1] <= 0;
end
else begin
if (DEPTH == 1) begin
if (write)
mem[DEPTH-1] <= in_payload;
end
else if (!mem_used[DEPTH-1])
mem[DEPTH-1] <= in_payload;
end
end
end
endgenerate
assign read = internal_out_ready && internal_out_valid && ok_to_forward;
assign write = in_ready && in_valid;
// --------------------------------------------------
// Pointer Management
// --------------------------------------------------
generate if (USE_MEMORY_BLOCKS == 1) begin : gen_blk11
assign incremented_wr_ptr = wr_ptr + 1'b1;
assign incremented_rd_ptr = rd_ptr + 1'b1;
assign next_wr_ptr = drop_on_error ? curr_sop_ptr : write ? incremented_wr_ptr : wr_ptr;
assign next_rd_ptr = (read) ? incremented_rd_ptr : rd_ptr;
always @(posedge clk or posedge reset) begin
if (reset) begin
wr_ptr <= 0;
rd_ptr <= 0;
end
else begin
wr_ptr <= next_wr_ptr;
rd_ptr <= next_rd_ptr;
end
end
end else begin : gen_blk11_else
// --------------------------------------------------
// Shift Register Occupancy Bits
//
// Consider a 4-deep FIFO with 2 entries: 0011
// On a read and write, do not modify the bits.
// On a write, left-shift the bits to get 0111.
// On a read, right-shift the bits to get 0001.
//
// Also, on a write we set bit0 (the head), while
// clearing the tail on a read.
// --------------------------------------------------
always @(posedge clk or posedge reset) begin
if (reset) begin
mem_used[0] <= 0;
end
else begin
if (write ^ read) begin
if (write)
mem_used[0] <= 1;
else if (read) begin
if (DEPTH > 1)
mem_used[0] <= mem_used[1];
else
mem_used[0] <= 0;
end
end
end
end
if (DEPTH > 1) begin : gen_blk12
always @(posedge clk or posedge reset) begin
if (reset) begin
mem_used[DEPTH-1] <= 0;
end
else begin
if (write ^ read) begin
mem_used[DEPTH-1] <= 0;
if (write)
mem_used[DEPTH-1] <= mem_used[DEPTH-2];
end
end
end
end
for (i = 1; i < DEPTH-1; i = i + 1) begin : storage_logic
always @(posedge clk, posedge reset) begin
if (reset) begin
mem_used[i] <= 0;
end
else begin
if (write ^ read) begin
if (write)
mem_used[i] <= mem_used[i-1];
else if (read)
mem_used[i] <= mem_used[i+1];
end
end
end
end
end
endgenerate
// --------------------------------------------------
// Memory FIFO Status Management
//
// Generates the full and empty signals from the
// pointers. The FIFO is full when the next write
// pointer will be equal to the read pointer after
// a write. Reading from a FIFO clears full.
//
// The FIFO is empty when the next read pointer will
// be equal to the write pointer after a read. Writing
// to a FIFO clears empty.
//
// A simultaneous read and write must not change any of
// the empty or full flags unless there is a drop on error event.
// --------------------------------------------------
generate if (USE_MEMORY_BLOCKS == 1) begin : gen_blk13
always @* begin
next_full = full;
next_empty = empty;
if (read && !write) begin
next_full = 1'b0;
if (incremented_rd_ptr == wr_ptr)
next_empty = 1'b1;
end
if (write && !read) begin
if (!drop_on_error)
next_empty = 1'b0;
else if (curr_sop_ptr == rd_ptr) // drop on error and only 1 pkt in fifo
next_empty = 1'b1;
if (incremented_wr_ptr == rd_ptr && !drop_on_error)
next_full = 1'b1;
end
if (write && read && drop_on_error) begin
if (curr_sop_ptr == next_rd_ptr)
next_empty = 1'b1;
end
end
always @(posedge clk or posedge reset) begin
if (reset) begin
empty <= 1;
full <= 0;
end
else begin
empty <= next_empty;
full <= next_full;
end
end
end else begin : gen_blk13_else
// --------------------------------------------------
// Register FIFO Status Management
//
// Full when the tail occupancy bit is 1. Empty when
// the head occupancy bit is 0.
// --------------------------------------------------
always @* begin
full = mem_used[DEPTH-1];
empty = !mem_used[0];
// ------------------------------------------
// For a single slot FIFO, reading clears the
// full status immediately.
// ------------------------------------------
if (DEPTH == 1)
full = mem_used[0] && !read;
internal_out_payload = mem[0];
// ------------------------------------------
// Writes clear empty immediately for lookahead modes.
// Note that we use in_valid instead of write to avoid
// combinational loops (in lookahead mode, qualifying
// with in_ready is meaningless).
//
// In a 1-deep FIFO, a possible combinational loop runs
// from write -> out_valid -> out_ready -> write
// ------------------------------------------
if (EMPTY_LATENCY == 0) begin
empty = !mem_used[0] && !in_valid;
if (!mem_used[0] && in_valid)
internal_out_payload = in_payload;
end
end
end
endgenerate
// --------------------------------------------------
// Avalon-ST Signals
//
// The in_ready signal is straightforward.
//
// To match memory latency when empty latency > 1,
// out_valid assertions must be delayed by one clock
// cycle.
//
// Note: out_valid deassertions must not be delayed or
// the FIFO will underflow.
// --------------------------------------------------
assign in_ready = !full;
assign internal_out_ready = out_ready || !out_valid;
generate if (EMPTY_LATENCY > 1) begin : gen_blk14
always @(posedge clk or posedge reset) begin
if (reset)
internal_out_valid <= 0;
else begin
internal_out_valid <= !empty & ok_to_forward & ~drop_on_error;
if (read) begin
if (incremented_rd_ptr == wr_ptr)
internal_out_valid <= 1'b0;
end
end
end
end else begin : gen_blk14_else
always @* begin
internal_out_valid = !empty & ok_to_forward;
end
end
endgenerate
// --------------------------------------------------
// Single Output Pipeline Stage
//
// This output pipeline stage is enabled if the FIFO's
// empty latency is set to 3 (default). It is disabled
// for all other allowed latencies.
//
// Reason: The memory outputs are unregistered, so we have to
// register the output or fmax will drop if combinatorial
// logic is present on the output datapath.
//
// Q: The Avalon-ST spec says that I have to register my outputs
// But isn't the memory counted as a register?
// A: The path from the address lookup to the memory output is
// slow. Registering the memory outputs is a good idea.
//
// The registers get packed into the memory by the fitter
// which means minimal resources are consumed (the result
// is a altsyncram with registered outputs, available on
// all modern Altera devices).
//
// This output stage acts as an extra slot in the FIFO,
// and complicates the fill level.
// --------------------------------------------------
generate if (EMPTY_LATENCY == 3) begin : gen_blk15
always @(posedge clk or posedge reset) begin
if (reset) begin
out_valid <= 0;
out_payload <= 0;
end
else begin
if (internal_out_ready) begin
out_valid <= internal_out_valid & ok_to_forward;
out_payload <= internal_out_payload;
end
end
end
end
else begin : gen_blk15_else
always @* begin
out_valid = internal_out_valid;
out_payload = internal_out_payload;
end
end
endgenerate
// --------------------------------------------------
// Fill Level
//
// The fill level is calculated from the next write
// and read pointers to avoid unnecessary latency
// and logic.
//
// However, if the store-and-forward mode of the FIFO
// is enabled, the fill level is an up-down counter
// for fmax optimization reasons.
//
// If the output pipeline is enabled, the fill level
// must account for it, or we'll always be off by one.
// This may, or may not be important depending on the
// application.
//
// For now, we'll always calculate the exact fill level
// at the cost of an extra adder when the output stage
// is enabled.
// --------------------------------------------------
generate if (USE_FILL_LEVEL) begin : gen_blk16
wire [31:0] depth32;
assign depth32 = DEPTH;
if (USE_STORE_FORWARD) begin
reg [ADDR_WIDTH : 0] curr_packet_len_less_one;
// --------------------------------------------------
// We only drop on endofpacket. As long as we don't add to the fill
// level on the dropped endofpacket cycle, we can simply subtract
// (packet length - 1) from the fill level for dropped packets.
// --------------------------------------------------
always @(posedge clk or posedge reset) begin
if (reset) begin
curr_packet_len_less_one <= 0;
end else begin
if (write) begin
curr_packet_len_less_one <= curr_packet_len_less_one + 1'b1;
if (in_endofpacket)
curr_packet_len_less_one <= 0;
end
end
end
always @(posedge clk or posedge reset) begin
if (reset) begin
fifo_fill_level <= 0;
end else if (drop_on_error) begin
fifo_fill_level <= fifo_fill_level - curr_packet_len_less_one;
if (read)
fifo_fill_level <= fifo_fill_level - curr_packet_len_less_one - 1'b1;
end else if (write && !read) begin
fifo_fill_level <= fifo_fill_level + 1'b1;
end else if (read && !write) begin
fifo_fill_level <= fifo_fill_level - 1'b1;
end
end
end else begin
always @(posedge clk or posedge reset) begin
if (reset)
fifo_fill_level <= 0;
else if (next_full & !drop_on_error)
fifo_fill_level <= depth32[ADDR_WIDTH:0];
else begin
fifo_fill_level[ADDR_WIDTH] <= 1'b0;
fifo_fill_level[ADDR_WIDTH-1 : 0] <= next_wr_ptr - next_rd_ptr;
end
end
end
always @* begin
fill_level = fifo_fill_level;
if (EMPTY_LATENCY == 3)
fill_level = fifo_fill_level + {{ADDR_WIDTH{1'b0}}, out_valid};
end
end
else begin : gen_blk16_else
always @* begin
fill_level = 0;
end
end
endgenerate
generate if (USE_ALMOST_FULL_IF) begin : gen_blk17
assign almost_full_data = (fill_level >= almost_full_threshold);
end
else
assign almost_full_data = 0;
endgenerate
generate if (USE_ALMOST_EMPTY_IF) begin : gen_blk18
assign almost_empty_data = (fill_level <= almost_empty_threshold);
end
else
assign almost_empty_data = 0;
endgenerate
// --------------------------------------------------
// Avalon-MM Status & Control Connection Point
//
// Register map:
//
// | Addr | RW | 31 - 0 |
// | 0 | R | Fill level |
//
// The registering of this connection point means
// that there is a cycle of latency between
// reads/writes and the updating of the fill level.
// --------------------------------------------------
generate if (USE_STORE_FORWARD) begin : gen_blk19
assign max_fifo_size = FIFO_DEPTH - 1;
always @(posedge clk or posedge reset) begin
if (reset) begin
almost_full_threshold <= max_fifo_size[23 : 0];
almost_empty_threshold <= 0;
cut_through_threshold <= 0;
drop_on_error_en <= 0;
csr_readdata <= 0;
pkt_mode <= 1'b1;
end
else begin
if (csr_read) begin
csr_readdata <= 32'b0;
if (csr_address == 5)
csr_readdata <= {31'b0, drop_on_error_en};
else if (csr_address == 4)
csr_readdata <= {8'b0, cut_through_threshold};
else if (csr_address == 3)
csr_readdata <= {8'b0, almost_empty_threshold};
else if (csr_address == 2)
csr_readdata <= {8'b0, almost_full_threshold};
else if (csr_address == 0)
csr_readdata <= {{(31 - ADDR_WIDTH){1'b0}}, fill_level};
end
else if (csr_write) begin
if(csr_address == 3'b101)
drop_on_error_en <= csr_writedata[0];
else if(csr_address == 3'b100) begin
cut_through_threshold <= csr_writedata[23:0];
pkt_mode <= (csr_writedata[23:0] == 0);
end
else if(csr_address == 3'b011)
almost_empty_threshold <= csr_writedata[23:0];
else if(csr_address == 3'b010)
almost_full_threshold <= csr_writedata[23:0];
end
end
end
end
else if (USE_ALMOST_FULL_IF || USE_ALMOST_EMPTY_IF) begin : gen_blk19_else1
assign max_fifo_size = FIFO_DEPTH - 1;
always @(posedge clk or posedge reset) begin
if (reset) begin
almost_full_threshold <= max_fifo_size[23 : 0];
almost_empty_threshold <= 0;
csr_readdata <= 0;
end
else begin
if (csr_read) begin
csr_readdata <= 32'b0;
if (csr_address == 3)
csr_readdata <= {8'b0, almost_empty_threshold};
else if (csr_address == 2)
csr_readdata <= {8'b0, almost_full_threshold};
else if (csr_address == 0)
csr_readdata <= {{(31 - ADDR_WIDTH){1'b0}}, fill_level};
end
else if (csr_write) begin
if(csr_address == 3'b011)
almost_empty_threshold <= csr_writedata[23:0];
else if(csr_address == 3'b010)
almost_full_threshold <= csr_writedata[23:0];
end
end
end
end
else begin : gen_blk19_else2
always @(posedge clk or posedge reset) begin
if (reset) begin
csr_readdata <= 0;
end
else if (csr_read) begin
csr_readdata <= 0;
if (csr_address == 0)
csr_readdata <= {{(31 - ADDR_WIDTH){1'b0}}, fill_level};
end
end
end
endgenerate
// --------------------------------------------------
// Store and forward logic
// --------------------------------------------------
// if the fifo gets full before the entire packet or the
// cut-threshold condition is met then start sending out
// data in order to avoid dead-lock situation
generate if (USE_STORE_FORWARD) begin : gen_blk20
assign wait_for_threshold = (fifo_fill_level_lt_cut_through_threshold) & wait_for_pkt ;
assign wait_for_pkt = pkt_cnt_eq_zero | (pkt_cnt_eq_one & out_pkt_leave);
assign ok_to_forward = (pkt_mode ? (~wait_for_pkt | ~pkt_has_started) :
~wait_for_threshold) | fifo_too_small_r;
assign in_pkt_eop_arrive = in_valid & in_ready & in_endofpacket;
assign in_pkt_start = in_valid & in_ready & in_startofpacket;
assign in_pkt_error = in_valid & in_ready & |in_error;
assign out_pkt_sop_leave = out_valid & out_ready & out_startofpacket;
assign out_pkt_leave = out_valid & out_ready & out_endofpacket;
assign fifo_too_small = (pkt_mode ? wait_for_pkt : wait_for_threshold) & full & out_ready;
// count packets coming and going into the fifo
always @(posedge clk or posedge reset) begin
if (reset) begin
pkt_cnt <= 0;
pkt_has_started <= 0;
sop_has_left_fifo <= 0;
fifo_too_small_r <= 0;
pkt_cnt_eq_zero <= 1'b1;
pkt_cnt_eq_one <= 1'b0;
fifo_fill_level_lt_cut_through_threshold <= 1'b1;
end
else begin
fifo_fill_level_lt_cut_through_threshold <= fifo_fill_level < cut_through_threshold;
fifo_too_small_r <= fifo_too_small;
if( in_pkt_eop_arrive )
sop_has_left_fifo <= 1'b0;
else if (out_pkt_sop_leave & pkt_cnt_eq_zero )
sop_has_left_fifo <= 1'b1;
if (in_pkt_eop_arrive & ~out_pkt_leave & ~drop_on_error ) begin
pkt_cnt <= pkt_cnt + 1'b1;
pkt_cnt_eq_zero <= 0;
if (pkt_cnt == 0)
pkt_cnt_eq_one <= 1'b1;
else
pkt_cnt_eq_one <= 1'b0;
end
else if((~in_pkt_eop_arrive | drop_on_error) & out_pkt_leave) begin
pkt_cnt <= pkt_cnt - 1'b1;
if (pkt_cnt == 1)
pkt_cnt_eq_zero <= 1'b1;
else
pkt_cnt_eq_zero <= 1'b0;
if (pkt_cnt == 2)
pkt_cnt_eq_one <= 1'b1;
else
pkt_cnt_eq_one <= 1'b0;
end
if (in_pkt_start)
pkt_has_started <= 1'b1;
else if (in_pkt_eop_arrive)
pkt_has_started <= 1'b0;
end
end
// drop on error logic
always @(posedge clk or posedge reset) begin
if (reset) begin
sop_ptr <= 0;
error_in_pkt <= 0;
end
else begin
// save the location of the SOP
if ( in_pkt_start )
sop_ptr <= wr_ptr;
// remember if error in pkt
// log error only if packet has already started
if (in_pkt_eop_arrive)
error_in_pkt <= 1'b0;
else if ( in_pkt_error & (pkt_has_started | in_pkt_start))
error_in_pkt <= 1'b1;
end
end
assign drop_on_error = drop_on_error_en & (error_in_pkt | in_pkt_error) & in_pkt_eop_arrive &
~sop_has_left_fifo & ~(out_pkt_sop_leave & pkt_cnt_eq_zero);
assign curr_sop_ptr = (write && in_startofpacket && in_endofpacket) ? wr_ptr : sop_ptr;
end
else begin : gen_blk20_else
assign ok_to_forward = 1'b1;
assign drop_on_error = 1'b0;
if (ADDR_WIDTH <= 1)
assign curr_sop_ptr = 1'b0;
else
assign curr_sop_ptr = {ADDR_WIDTH - 1 { 1'b0 }};
end
endgenerate
// --------------------------------------------------
// Calculates the log2ceil of the input value
// --------------------------------------------------
function integer log2ceil;
input integer val;
reg[31:0] i;
begin
i = 1;
log2ceil = 0;
while (i < val) begin
log2ceil = log2ceil + 1;
i = i[30:0] << 1;
end
end
endfunction
endmodule