blob: 40e0efc01c714b09a483af0948b58c5e66c365a1 (
plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
|
module channel_ram
( // System
input txclk,
input reset,
// USB side
input [31:0] datain,
input WR,
input WR_done,
output have_space,
// Reader side
output [31:0] dataout,
input RD,
input RD_done,
output packet_waiting);
reg [6:0] wr_addr, rd_addr;
reg [1:0] which_ram_wr, which_ram_rd;
reg [2:0] nb_packets;
reg [31:0] ram0 [0:127];
reg [31:0] ram1 [0:127];
reg [31:0] ram2 [0:127];
reg [31:0] ram3 [0:127];
reg [31:0] dataout0;
reg [31:0] dataout1;
reg [31:0] dataout2;
reg [31:0] dataout3;
wire wr_done_int;
wire rd_done_int;
wire [6:0] rd_addr_final;
wire [1:0] which_ram_rd_final;
// USB side
always @(posedge txclk)
if(WR & (which_ram_wr == 2'd0)) ram0[wr_addr] <= datain;
always @(posedge txclk)
if(WR & (which_ram_wr == 2'd1)) ram1[wr_addr] <= datain;
always @(posedge txclk)
if(WR & (which_ram_wr == 2'd2)) ram2[wr_addr] <= datain;
always @(posedge txclk)
if(WR & (which_ram_wr == 2'd3)) ram3[wr_addr] <= datain;
assign wr_done_int = ((WR && (wr_addr == 7'd127)) || WR_done);
always @(posedge txclk)
if(reset)
wr_addr <= 0;
else if (WR_done)
wr_addr <= 0;
else if (WR)
wr_addr <= wr_addr + 7'd1;
always @(posedge txclk)
if(reset)
which_ram_wr <= 0;
else if (wr_done_int)
which_ram_wr <= which_ram_wr + 2'd1;
assign have_space = (nb_packets < 3'd3);
// Reader side
// short hand fifo
// rd_addr_final is what rd_addr is going to be next clock cycle
// which_ram_rd_final is what which_ram_rd is going to be next clock cycle
always @(posedge txclk) dataout0 <= ram0[rd_addr_final];
always @(posedge txclk) dataout1 <= ram1[rd_addr_final];
always @(posedge txclk) dataout2 <= ram2[rd_addr_final];
always @(posedge txclk) dataout3 <= ram3[rd_addr_final];
assign dataout = (which_ram_rd_final[1]) ?
(which_ram_rd_final[0] ? dataout3 : dataout2) :
(which_ram_rd_final[0] ? dataout1 : dataout0);
//RD_done is the only way to signal the end of one packet
assign rd_done_int = RD_done;
always @(posedge txclk)
if (reset)
rd_addr <= 0;
else if (RD_done)
rd_addr <= 0;
else if (RD) rd_addr <= rd_addr + 7'd1;
assign rd_addr_final = (reset|RD_done) ? (6'd0) :
((RD)?(rd_addr+7'd1):rd_addr);
always @(posedge txclk)
if (reset)
which_ram_rd <= 0;
else if (rd_done_int)
which_ram_rd <= which_ram_rd + 2'd1;
assign which_ram_rd_final = (reset) ? (2'd0):
((rd_done_int) ? (which_ram_rd + 2'd1) : which_ram_rd);
//packet_waiting is set to zero if rd_done_int is high
//because there is no guarantee that nb_packets will be pos.
assign packet_waiting = (nb_packets != 0) & (~rd_done_int);
always @(posedge txclk)
if (reset)
nb_packets <= 0;
else if (wr_done_int & ~rd_done_int)
nb_packets <= nb_packets + 3'd1;
else if (rd_done_int & ~wr_done_int)
nb_packets <= nb_packets - 3'd1;
endmodule
|