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[/] [qaz_libs/] [trunk/] [coaxpress/] [cx_bit_align.v] - Rev 3
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// // // module cx_bit_align ( input data_in, output reg [9:0] data_out, output clock, output strobe, input data_sent_lsb, input reset ); // using big endian as presented in US4,486,739 localparam K27_7_10b = 10'b110110_1000; // K27.7 Start of data packet indication localparam K28_0_10b = 10'b001111_0100; // K28.0 GPIO indication localparam K28_6_10b = 10'b001111_0110; // K28.6 I/O acknowledgement localparam K28_1_10b = 10'b001111_1001; // K28.1 Used for alignment localparam K28_2_10b = 10'b001111_0101; // K28.2 Rising trigger indication localparam K28_3_10b = 10'b001111_0011; // K28.3 Stream marker – see section 7.2 localparam K28_4_10b = 10'b001111_0010; // K28.4 Falling trigger indication localparam K28_5_10b = 10'b001111_1010; // K28.5 Used for alignment localparam K28_7_10b = 10'b001111_1000; // K29.7 End of data packet indication localparam D21_5_10b = 10'b101010_1010; // wire clock_n; // assign clock = clock_n; // -------------------------------------------------------------------- // recover_clock i_recover_clock ( .in(data_in), .clock(clock) ); // -------------------------------------------------------------------- // four word shift register reg [39:0] data_in_r; always @( negedge clock ) if( data_sent_lsb ) data_in_r <= { data_in_r[38:0], data_in }; else data_in_r <= { data_in, data_in_r[39:1] }; // -------------------------------------------------------------------- // integer bit_count = 0; always @( negedge clock ) if( bit_count == 9 ) bit_count <= 0; else bit_count <= bit_count + 1; // -------------------------------------------------------------------- // wire p3_is_D21_5_msb = (data_in_r[39:30] == D21_5_10b) | (data_in_r[39:30] == ~D21_5_10b); wire p2_is_K28_1_msb = (data_in_r[29:20] == K28_1_10b) | (data_in_r[29:20] == ~K28_1_10b); wire p1_is_K28_1_msb = (data_in_r[19:10] == K28_1_10b) | (data_in_r[19:10] == ~K28_1_10b); wire p0_is_K28_5_msb = (data_in_r[9:0] == K28_5_10b) | (data_in_r[9:0] == ~K28_5_10b); wire p3_is_D21_5_lsb = (data_in_r[9:0] == D21_5_10b) | (data_in_r[9:0] == ~D21_5_10b); wire p2_is_K28_1_lsb = (data_in_r[19:10] == K28_1_10b) | (data_in_r[19:10] == ~K28_1_10b); wire p1_is_K28_1_lsb = (data_in_r[29:20] == K28_1_10b) | (data_in_r[29:20] == ~K28_1_10b); wire p0_is_K28_5_lsb = (data_in_r[39:30] == K28_5_10b) | (data_in_r[39:30] == ~K28_5_10b); wire found_idle_word = data_sent_lsb ? (p0_is_K28_5_lsb & p1_is_K28_1_lsb & p2_is_K28_1_lsb & p3_is_D21_5_lsb) : (p0_is_K28_5_msb & p1_is_K28_1_msb & p2_is_K28_1_msb & p3_is_D21_5_msb); integer bit_select = 'hx; always @( posedge clock ) if( reset ) bit_select <= 'hx; else if( found_idle_word ) bit_select <= bit_count; // -------------------------------------------------------------------- // register parallel outputs in litle endian bit order integer i; always @( posedge clock ) if( bit_count == bit_select ) for( i = 0; i < 10; i = i + 1 ) data_out[i] <= data_in_r[9-i]; // -------------------------------------------------------------------- // debug -- look for control codes `ifdef DEBUG_COAXPRESS wire dbg_p0_is_K27_7 = (data_in_r[9:0] == K27_7_10b) | (data_in_r[9:0] == ~K27_7_10b); wire dbg_p0_is_K28_0 = (data_in_r[9:0] == K28_0_10b) | (data_in_r[9:0] == ~K28_0_10b); wire dbg_p0_is_K28_6 = (data_in_r[9:0] == K28_6_10b) | (data_in_r[9:0] == ~K28_6_10b); wire dbg_p0_is_K28_1 = (data_in_r[9:0] == K28_1_10b) | (data_in_r[9:0] == ~K28_1_10b); wire dbg_p0_is_K28_2 = (data_in_r[9:0] == K28_2_10b) | (data_in_r[9:0] == ~K28_2_10b); wire dbg_p0_is_K28_3 = (data_in_r[9:0] == K28_3_10b) | (data_in_r[9:0] == ~K28_3_10b); wire dbg_p0_is_K28_4 = (data_in_r[9:0] == K28_4_10b) | (data_in_r[9:0] == ~K28_4_10b); wire dbg_p0_is_K28_5 = (data_in_r[9:0] == K28_5_10b) | (data_in_r[9:0] == ~K28_5_10b); wire dbg_p0_is_K28_7 = (data_in_r[9:0] == K28_7_10b) | (data_in_r[9:0] == ~K28_7_10b); wire dbg_p0_is_D21_5 = (data_in_r[9:0] == D21_5_10b) | (data_in_r[9:0] == ~D21_5_10b); // debug -- four word shift register, reverse bit order reg [39:0] dbg_data_in_n_r; always @( negedge clock ) dbg_data_in_n_r <= { data_in, dbg_data_in_n_r[39:1] }; wire dbg_p0_is_K27_7_n = (dbg_data_in_n_r[9:0] == K27_7_10b) | (dbg_data_in_n_r[9:0] == ~K27_7_10b); wire dbg_p0_is_K28_0_n = (dbg_data_in_n_r[9:0] == K28_0_10b) | (dbg_data_in_n_r[9:0] == ~K28_0_10b); wire dbg_p0_is_K28_6_n = (dbg_data_in_n_r[9:0] == K28_6_10b) | (dbg_data_in_n_r[9:0] == ~K28_6_10b); wire dbg_p0_is_K28_1_n = (dbg_data_in_n_r[9:0] == K28_1_10b) | (dbg_data_in_n_r[9:0] == ~K28_1_10b); wire dbg_p0_is_K28_2_n = (dbg_data_in_n_r[9:0] == K28_2_10b) | (dbg_data_in_n_r[9:0] == ~K28_2_10b); wire dbg_p0_is_K28_3_n = (dbg_data_in_n_r[9:0] == K28_3_10b) | (dbg_data_in_n_r[9:0] == ~K28_3_10b); wire dbg_p0_is_K28_4_n = (dbg_data_in_n_r[9:0] == K28_4_10b) | (dbg_data_in_n_r[9:0] == ~K28_4_10b); wire dbg_p0_is_K28_5_n = (dbg_data_in_n_r[9:0] == K28_5_10b) | (dbg_data_in_n_r[9:0] == ~K28_5_10b); wire dbg_p0_is_K28_7_n = (dbg_data_in_n_r[9:0] == K28_7_10b) | (dbg_data_in_n_r[9:0] == ~K28_7_10b); // debug -- assume bit select reg [9:0] dbg_data_out; always @( posedge clock ) if( bit_count == 2 ) dbg_data_out <= data_in_r[9:0]; wire dbg_data_out_K28_5 = (dbg_data_out == K28_5_10b) | (dbg_data_out == ~K28_5_10b); wire dbg_data_out_K28_1 = (dbg_data_out == K28_1_10b) | (dbg_data_out == ~K28_1_10b); wire dbg_data_out_D21_5 = (dbg_data_out == D21_5_10b) | (dbg_data_out == ~D21_5_10b); `endif // -------------------------------------------------------------------- // register parallel outputs in litle endian bit order assign strobe = (bit_count === bit_select); endmodule
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