Commit de641880 authored by Andrey Filippov's avatar Andrey Filippov

continiuing co-simulation with 353 code, verified martching data to the compressor input

parent 947d1d99
...@@ -153,6 +153,8 @@ module cmprs_cmd_decode#( ...@@ -153,6 +153,8 @@ module cmprs_cmd_decode#(
// cr_w, // data written to cr (1 cycle long) - just to reset legacy IRQ // cr_w, // data written to cr (1 cycle long) - just to reset legacy IRQ
// ntiles,//[17:0] - number of tiles in a frame to process // ntiles,//[17:0] - number of tiles in a frame to process
input frame_start, // @mclk input frame_start, // @mclk
output frame_start_xclk, // frame start, parameters are copied at this pulse
// outputs sync @ posedge mclk: // outputs sync @ posedge mclk:
output cmprs_en_mclk, // @mclk 0 resets immediately output cmprs_en_mclk, // @mclk 0 resets immediately
input cmprs_en_extend, // @mclk keep compressor enabled for graceful shutdown input cmprs_en_extend, // @mclk keep compressor enabled for graceful shutdown
...@@ -162,7 +164,7 @@ module cmprs_cmd_decode#( ...@@ -162,7 +164,7 @@ module cmprs_cmd_decode#(
// cmprs_run should be off // cmprs_run should be off
output reg sigle_frame_buf, // memory controller uses a single frame buffer (frame_number_* == 0), use other sync output reg sigle_frame_buf, // memory controller uses a single frame buffer (frame_number_* == 0), use other sync
// outputs sync @ posedge xclk: // outputs sync @ posedge xclk:
output reg cmprs_en_xclk, // enable compressor, turne off immedaitely output reg cmprs_en_xclk, // enable compressor, turn off immedaitely
output reg cmprs_en_late_xclk, // enable stuffer, extends control fields for graceful shutdown output reg cmprs_en_late_xclk, // enable stuffer, extends control fields for graceful shutdown
// cmprs_start, // single cycle when single or constant compression is turned on // cmprs_start, // single cycle when single or constant compression is turned on
// cmprs_repeat,// high in repetitive mode // cmprs_repeat,// high in repetitive mode
...@@ -283,7 +285,7 @@ module cmprs_cmd_decode#( ...@@ -283,7 +285,7 @@ module cmprs_cmd_decode#(
if (mrst) format_mclk <= 0; if (mrst) format_mclk <= 0;
else if (format_we_r) format_mclk <= di_r[30:0]; else if (format_we_r) format_mclk <= di_r[30:0];
if (mrst) color_sat_mclk <= 0; if (mrst) color_sat_mclk <= 'h0b6090; // 'h16c120 - saturation = 2
else if (color_sat_we_r) color_sat_mclk <= di_r[23:0]; else if (color_sat_we_r) color_sat_mclk <= di_r[23:0];
if (mrst) coring_mclk <= 0; if (mrst) coring_mclk <= 0;
...@@ -292,10 +294,12 @@ module cmprs_cmd_decode#( ...@@ -292,10 +294,12 @@ module cmprs_cmd_decode#(
end end
// re-clock to compressor clock // re-clock to compressor clock
always @ (posedge xclk) begin
always @ (posedge xclk) if (ctrl_we_xclk) begin
cmprs_en_xclk <= cmprs_en_mclk_r; cmprs_en_xclk <= cmprs_en_mclk_r;
cmprs_en_late_xclk <= cmprs_en_mclk_r || cmprs_en_extend; cmprs_en_late_xclk <= cmprs_en_mclk_r || cmprs_en_extend;
end
always @ (posedge xclk) if (ctrl_we_xclk) begin
// cmprs_en_late_xclk <= cmprs_en_mclk_r || cmprs_en_extend;
cmprs_qpage_xclk <= cmprs_qpage_mclk; cmprs_qpage_xclk <= cmprs_qpage_mclk;
cmprs_dcsub_xclk <= cmprs_dcsub_mclk; cmprs_dcsub_xclk <= cmprs_dcsub_mclk;
cmprs_mode_xclk <= cmprs_mode_mclk; cmprs_mode_xclk <= cmprs_mode_mclk;
......
...@@ -40,7 +40,7 @@ module cmprs_frame_sync#( ...@@ -40,7 +40,7 @@ module cmprs_frame_sync#(
input cmprs_standalone, // @mclk single-cycle: generate a single frame_start_dst in unbonded (not synchronized) mode. input cmprs_standalone, // @mclk single-cycle: generate a single frame_start_dst in unbonded (not synchronized) mode.
// cmprs_run should be off // cmprs_run should be off
input sigle_frame_buf, // memory controller uses a single frame buffer (frame_number_* == 0), use other sync input sigle_frame_buf, // memory controller uses a single frame buffer (frame_number_* == 0), use other sync
input vsync_late, // @xclk delayed start of frame, @xclk. In 353 it was 16 lines after VACT active input vsync_late, // @mclk delayed start of frame, @xclk. In 353 it was 16 lines after VACT active
// source channel should already start, some delay give time for sequencer commands // source channel should already start, some delay give time for sequencer commands
// that should arrive before it // that should arrive before it
input frame_started, // @xclk started first macroblock (checking for broken frames) input frame_started, // @xclk started first macroblock (checking for broken frames)
...@@ -71,7 +71,7 @@ module cmprs_frame_sync#( ...@@ -71,7 +71,7 @@ module cmprs_frame_sync#(
b) turned off enable while frame was being compressed b) turned off enable while frame was being compressed
Abort frame lasts until flush end or timeout expire Abort frame lasts until flush end or timeout expire
*/ */
wire vsync_late_mclk; // single mclk cycle, reclocked from vsync_late // wire vsync_late_mclk; // single mclk cycle, reclocked from vsync_late
wire frame_started_mclk; wire frame_started_mclk;
reg bonded_mode; reg bonded_mode;
reg frame_start_dst_r; reg frame_start_dst_r;
...@@ -86,12 +86,16 @@ module cmprs_frame_sync#( ...@@ -86,12 +86,16 @@ module cmprs_frame_sync#(
reg [CMPRS_TIMEOUT_BITS-1:0] timeout; reg [CMPRS_TIMEOUT_BITS-1:0] timeout;
reg cmprs_en_extend_r=0; reg cmprs_en_extend_r=0;
reg cmprs_en_d; reg cmprs_en_d;
// reg cmprs_en_xclk;
assign frame_start_dst = frame_start_dst_r; assign frame_start_dst = frame_start_dst_r;
assign cmprs_en_extend = cmprs_en_extend_r; assign cmprs_en_extend = cmprs_en_extend_r;
assign stuffer_running_mclk = stuffer_running_mclk_r; assign stuffer_running_mclk = stuffer_running_mclk_r;
assign reading_frame = reading_frame_r; assign reading_frame = reading_frame_r;
// always @ (posedge xclk) begin
// cmprs_en_xclk <=cmprs_en;
// end
always @ (posedge mclk) begin always @ (posedge mclk) begin
if (mrst) cmprs_en_extend_r <= 0; if (mrst) cmprs_en_extend_r <= 0;
else if (cmprs_en) cmprs_en_extend_r <= 1; else if (cmprs_en) cmprs_en_extend_r <= 1;
...@@ -107,34 +111,35 @@ module cmprs_frame_sync#( ...@@ -107,34 +111,35 @@ module cmprs_frame_sync#(
cmprs_en_d <= cmprs_en; cmprs_en_d <= cmprs_en;
broken_frame <= cmprs_en && cmprs_run && vsync_late_mclk && reading_frame_r; // single xclk pulse broken_frame <= cmprs_en && cmprs_run && vsync_late && reading_frame_r; // single xclk pulse
aborted_frame <= cmprs_en_d && !cmprs_en && stuffer_running_mclk_r; aborted_frame <= cmprs_en_d && !cmprs_en && stuffer_running_mclk_r;
if (!stuffer_running_mclk_r ||!cmprs_en_extend_r) force_flush_long <= 0; if (!stuffer_running_mclk_r ||!cmprs_en_extend_r) force_flush_long <= 0;
else if (broken_frame || aborted_frame) force_flush_long <= 1; else if (broken_frame || aborted_frame) force_flush_long <= 1;
if (!cmprs_en || frame_done || (cmprs_run && vsync_late_mclk)) reading_frame_r <= 0; if (!cmprs_en || frame_done || (cmprs_run && vsync_late)) reading_frame_r <= 0;
else if (frame_started_mclk) reading_frame_r <= 1; else if (frame_started_mclk) reading_frame_r <= 1;
frame_start_dst_r <= cmprs_en && (cmprs_run ? (vsync_late_mclk && !reading_frame_r) : cmprs_standalone); frame_start_dst_r <= cmprs_en && (cmprs_run ? (vsync_late && !reading_frame_r) : cmprs_standalone);
if (!cmprs_en) bonded_mode <= 0; if (!cmprs_en) bonded_mode <= 0;
else if (cmprs_run) bonded_mode <= 1; else if (cmprs_run) bonded_mode <= 1;
else if (cmprs_standalone) bonded_mode <= 0; else if (cmprs_standalone) bonded_mode <= 0;
if (!cmprs_en || !cmprs_run || vsync_late_mclk) frames_differ <= 0; if (!cmprs_en || !cmprs_run || vsync_late) frames_differ <= 0;
else if (frame_done_src) frames_differ <= 1'b1; else if (frame_done_src) frames_differ <= 1'b1;
frames_numbers_differ <= frame_number_src != frame_number; frames_numbers_differ <= frame_number_src != frame_number;
line_numbers_sync <= (line_unfinished_src > line_unfinished); line_numbers_sync <= (line_unfinished_src > line_unfinished);
suspend <= !bonded_mode && ((sigle_frame_buf ? frames_differ : frames_numbers_differ) || line_numbers_sync); // suspend <= !bonded_mode && ((sigle_frame_buf ? frames_differ : frames_numbers_differ) || line_numbers_sync);
suspend <= bonded_mode && ((sigle_frame_buf ? frames_differ : frames_numbers_differ) || !line_numbers_sync);
end end
pulse_cross_clock vsync_late_mclk_i (.rst(xrst), .src_clk(xclk), .dst_clk(mclk), .in_pulse(vsync_late), .out_pulse(vsync_late_mclk),.busy()); // pulse_cross_clock vsync_late_mclk_i (.rst(xrst), .src_clk(xclk), .dst_clk(mclk), .in_pulse(cmprs_en_xclk && vsync_late), .out_pulse(vsync_late_mclk),.busy());
pulse_cross_clock frame_started_i (.rst(xrst), .src_clk(xclk), .dst_clk(mclk), .in_pulse(frame_started), .out_pulse(frame_started_mclk),.busy()); pulse_cross_clock frame_started_i (.rst(xrst), .src_clk(xclk), .dst_clk(mclk), .in_pulse(frame_started), .out_pulse(frame_started_mclk),.busy());
endmodule endmodule
......
...@@ -36,6 +36,7 @@ module cmprs_macroblock_buf_iface ( ...@@ -36,6 +36,7 @@ module cmprs_macroblock_buf_iface (
output next_page_chn, // single mclk (posedge): Done with the page in the buffer, memory controller may read more data output next_page_chn, // single mclk (posedge): Done with the page in the buffer, memory controller may read more data
input frame_en, // if 0 - will reset logic immediately (but not page number) input frame_en, // if 0 - will reset logic immediately (but not page number)
input frame_start_xclk, // frame parameters are valid after this pulse
input frame_go, // start frame: if idle, will start reading data (if available), input frame_go, // start frame: if idle, will start reading data (if available),
// if running - will not restart a new frame if 0. // if running - will not restart a new frame if 0.
input [ 4:0] left_marg, // left margin (for not-yet-implemented) mono JPEG (8 lines tile row) can need 7 bits (mod 32 - tile) input [ 4:0] left_marg, // left margin (for not-yet-implemented) mono JPEG (8 lines tile row) can need 7 bits (mod 32 - tile)
...@@ -93,6 +94,7 @@ module cmprs_macroblock_buf_iface ( ...@@ -93,6 +94,7 @@ module cmprs_macroblock_buf_iface (
// reg first_mb; // from mb_pre_start[2] to mb_pre_start[1] // reg first_mb; // from mb_pre_start[2] to mb_pre_start[1]
wire starting; wire starting;
reg frame_pre_run; reg frame_pre_run;
reg [1:0] frame_may_start;
assign frame_en_w = frame_en && frame_go; assign frame_en_w = frame_en && frame_go;
...@@ -106,14 +108,20 @@ module cmprs_macroblock_buf_iface ( ...@@ -106,14 +108,20 @@ module cmprs_macroblock_buf_iface (
assign last_mb = mb_last_row && mb_last_in_row; assign last_mb = mb_last_row && mb_last_in_row;
assign starting = |mb_pre_start; assign starting = |mb_pre_start;
assign mb_pre_start_w = (mb_pre_end_in && (!last_mb || frame_en_w)) || (!frame_pre_run && frame_en_w && !frame_en_r && !starting); // assign mb_pre_start_w = (mb_pre_end_in && (!last_mb || frame_en_w)) || (!frame_pre_run && frame_en_w && !frame_en_r && !starting);
assign frame_pre_start_w = frame_en_w && ((mb_pre_end_in && last_mb) || (!frame_pre_run && !frame_en_r && !starting)); // assign frame_pre_start_w = frame_en_w && ((mb_pre_end_in && last_mb) || (!frame_pre_run && !frame_en_r && !starting));
assign mb_pre_start_w = (mb_pre_end_in && (!last_mb || frame_may_start)) || ((frame_may_start==2'b1) && !frame_pre_run && !starting);
assign frame_pre_start_w = frame_may_start[0] && ((mb_pre_end_in && last_mb) || (!frame_pre_run && !frame_may_start[1] && !starting));
assign start_page = next_invalid[1:0]; // oldest page needed for this macroblock assign start_page = next_invalid[1:0]; // oldest page needed for this macroblock
always @ (posedge xclk) begin always @ (posedge xclk) begin
if (!frame_en) frame_en_r <= 0; if (!frame_en) frame_en_r <= 0;
else frame_en_r <= frame_en_w; else frame_en_r <= frame_en_w;
if (!frame_en_w || starting) frame_may_start[0] <= 0;
else if (frame_start_xclk) frame_may_start[0] <= 1;
frame_may_start[1] <= frame_may_start[0];
frame_pre_start_r <= frame_pre_start_w; // same time as mb_pre_start frame_pre_start_r <= frame_pre_start_w; // same time as mb_pre_start
if (!frame_en) mb_first_in_row <= 0; if (!frame_en) mb_first_in_row <= 0;
...@@ -147,8 +155,10 @@ module cmprs_macroblock_buf_iface ( ...@@ -147,8 +155,10 @@ module cmprs_macroblock_buf_iface (
// calculate before starting each macroblock (will wait if buffer is not ready) (TODO: align mb_pre_start[0] to mb_pre_end[2] - same) // calculate before starting each macroblock (will wait if buffer is not ready) (TODO: align mb_pre_start[0] to mb_pre_end[2] - same)
//mb_pre_start_w //mb_pre_start_w
if (!frame_en_r) mb_pre_start <= 0;
if (mb_pre_start_w) mb_pre_start <= 1; if (mb_pre_start_w) mb_pre_start <= 1;
else if (!mb_pre_start[4] || buf_ready_w) mb_pre_start <= mb_pre_start << 1; else if (!mb_pre_start[4] || buf_ready_w) mb_pre_start <= mb_pre_start << 1;
if (mb_pre_start[1]) mbl_x_r[6:3] <= mb_first_in_row? {2'b0,left_marg[4:3]} : mbl_x_next_r[6:3]; if (mb_pre_start[1]) mbl_x_r[6:3] <= mb_first_in_row? {2'b0,left_marg[4:3]} : mbl_x_next_r[6:3];
if (mb_pre_start[2]) mbl_x_last_r[7:3] <= {1'b0,mbl_x_r[6:3]} + {2'b0,mb_w_m1[5:3]}; if (mb_pre_start[2]) mbl_x_last_r[7:3] <= {1'b0,mbl_x_r[6:3]} + {2'b0,mb_w_m1[5:3]};
if (mb_pre_start[3]) begin if (mb_pre_start[3]) begin
...@@ -163,7 +173,7 @@ module cmprs_macroblock_buf_iface ( ...@@ -163,7 +173,7 @@ module cmprs_macroblock_buf_iface (
// at the end of each macroblock - calculate start page increment (and after delay - advance invalidate_next) // at the end of each macroblock - calculate start page increment (and after delay - advance invalidate_next)
// changed to after started: // changed to after started:
// calculate next start X in page (regardless of emd of macroblock row - selection will be at macroblock start) // calculate next start X in page (regardless of end of macroblock row - selection will be at macroblock start)
if (mb_pre_start[5]) mbl_x_inc_r[7:3] <= {1'b0,mbl_x_r[6:3]} + {3'b0,mb_hper[4:3]}; if (mb_pre_start[5]) mbl_x_inc_r[7:3] <= {1'b0,mbl_x_r[6:3]} + {3'b0,mb_hper[4:3]};
if (mb_pre_start[6]) begin if (mb_pre_start[6]) begin
......
...@@ -44,8 +44,8 @@ module cmprs_pixel_buf_iface #( ...@@ -44,8 +44,8 @@ module cmprs_pixel_buf_iface #(
output [ 1:0] buf_rd, // buf {regen, re} output [ 1:0] buf_rd, // buf {regen, re}
// if running - will not restart a new frame if 0. // if running - will not restart a new frame if 0.
input [ 2:0] converter_type, // 0 - color18, 1 - color20, 2 - mono, 3 - jp4, 4 - jp4-diff, 7 - mono8 (not yet implemented) input [ 2:0] converter_type, // 0 - color18, 1 - color20, 2 - mono, 3 - jp4, 4 - jp4-diff, 7 - mono8 (not yet implemented)
input [ 5:0] mb_w_m1, // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 input [ 5:0] mb_w_m1, // macroblock width minus 1
input [ 5:0] mb_h_m1, // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 input [ 5:0] mb_h_m1, // macroblock height minus 1
input [ 1:0] tile_width, // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 input [ 1:0] tile_width, // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
input tile_col_width, // 0 - 16 pixels, 1 -32 pixels input tile_col_width, // 0 - 16 pixels, 1 -32 pixels
// Tiles/macroblocks level (from cmprs_macroblock_buf_iface) // Tiles/macroblocks level (from cmprs_macroblock_buf_iface)
...@@ -55,9 +55,9 @@ module cmprs_pixel_buf_iface #( ...@@ -55,9 +55,9 @@ module cmprs_pixel_buf_iface #(
input mb_pre_start, // 1 clock cycle before stream of addresses to the buffer input mb_pre_start, // 1 clock cycle before stream of addresses to the buffer
input [ 1:0] start_page, // page to read next tile from (or first of several pages) input [ 1:0] start_page, // page to read next tile from (or first of several pages)
input [ 6:0] macroblock_x, // macroblock left pixel x relative to a tile (page) Maximal page - 128 bytes wide input [ 6:0] macroblock_x, // macroblock left pixel x relative to a tile (page) Maximal page - 128 bytes wide
output [ 7:0] data_out, // output reg [ 7:0] data_out, //
output pre_first_out, // For each macroblock in a frame output pre_first_out, // For each macroblock in a frame
output data_valid // output reg data_valid //
); );
localparam PERIOD_COLOR18 = 384; // >18*18, limited by 6*64 (macroblocks) localparam PERIOD_COLOR18 = 384; // >18*18, limited by 6*64 (macroblocks)
localparam PERIOD_COLOR20 = 400; // limited by the 20x20 padded macroblock localparam PERIOD_COLOR20 = 400; // limited by the 20x20 padded macroblock
...@@ -68,7 +68,7 @@ module cmprs_pixel_buf_iface #( ...@@ -68,7 +68,7 @@ module cmprs_pixel_buf_iface #(
reg [CMPRS_BUF_EXTRA_LATENCY+3:0] buf_re=0; reg [CMPRS_BUF_EXTRA_LATENCY+3:0] buf_re=0;
reg [ 7:0] do_r; // reg [ 7:0] do_r;
reg [11:0] bufa_r; // buffer read address (2 MSB - page number) reg [11:0] bufa_r; // buffer read address (2 MSB - page number)
reg [11:0] row_sa; // row start address reg [11:0] row_sa; // row start address
reg [ 9:0] tile_sa; // tile start address for the same row (w/o page number) for continuing row reg [ 9:0] tile_sa; // tile start address for the same row (w/o page number) for continuing row
...@@ -79,9 +79,9 @@ module cmprs_pixel_buf_iface #( ...@@ -79,9 +79,9 @@ module cmprs_pixel_buf_iface #(
reg [ 5:0] rows_left; reg [ 5:0] rows_left;
reg [ 6:0] tile_x; // horizontal position in a tile reg [ 6:0] tile_x; // horizontal position in a tile
reg [ 4:0] column_x; // horizontal position in a column (0..31 or 0..15) reg [ 4:0] column_x; // horizontal position in a column (0..31 or 0..15)
reg last_col; reg last_col; // macroblock last column
reg first_col; reg first_col; // macroblock first column
reg last_row; reg last_row; // macroblock last row
wire addr_run_end; // generate last cycle of address run wire addr_run_end; // generate last cycle of address run
wire [ 6:0] tile_width_or; // set unused msb to all 1 wire [ 6:0] tile_width_or; // set unused msb to all 1
...@@ -105,9 +105,8 @@ module cmprs_pixel_buf_iface #( ...@@ -105,9 +105,8 @@ module cmprs_pixel_buf_iface #(
assign mb_pre_end = mb_pre_end_r; assign mb_pre_end = mb_pre_end_r;
assign mb_release_buf = mb_release_buf_r; assign mb_release_buf = mb_release_buf_r;
assign buf_rd = buf_re[1:0]; assign buf_rd = buf_re[1:0];
assign data_out = do_r; // assign data_out = do_r;
assign pre_first_out = pre_first_out_r; assign pre_first_out = pre_first_out_r;
assign data_valid = buf_re[CMPRS_BUF_EXTRA_LATENCY+2];
always @(posedge xclk) begin always @(posedge xclk) begin
if (!frame_en) buf_re[0] <= 0; if (!frame_en) buf_re[0] <= 0;
...@@ -118,7 +117,7 @@ module cmprs_pixel_buf_iface #( ...@@ -118,7 +117,7 @@ module cmprs_pixel_buf_iface #(
else buf_re[CMPRS_BUF_EXTRA_LATENCY+3:1] <= {buf_re[CMPRS_BUF_EXTRA_LATENCY+2:0]}; else buf_re[CMPRS_BUF_EXTRA_LATENCY+3:1] <= {buf_re[CMPRS_BUF_EXTRA_LATENCY+2:0]};
// Buffer data read: // Buffer data read:
if (buf_re[CMPRS_BUF_EXTRA_LATENCY+2]) do_r <= buf_di; if (buf_re[CMPRS_BUF_EXTRA_LATENCY+2]) data_out <= buf_di;
if (!frame_en) pre_first_out_r <= 0; if (!frame_en) pre_first_out_r <= 0;
else pre_first_out_r <= buf_re[CMPRS_BUF_EXTRA_LATENCY+1] && ! buf_re[CMPRS_BUF_EXTRA_LATENCY+2]; else pre_first_out_r <= buf_re[CMPRS_BUF_EXTRA_LATENCY+1] && ! buf_re[CMPRS_BUF_EXTRA_LATENCY+2];
...@@ -131,10 +130,12 @@ module cmprs_pixel_buf_iface #( ...@@ -131,10 +130,12 @@ module cmprs_pixel_buf_iface #(
if (!frame_en) buf_re[CMPRS_BUF_EXTRA_LATENCY+2:1] <= 0; if (!frame_en) buf_re[CMPRS_BUF_EXTRA_LATENCY+2:1] <= 0;
if (buf_re[0]) last_col <= 0; // if (buf_re[0]) last_col <= 0; // ????
if (!buf_re[0]) last_col <= 0;
else last_col <= (cols_left == 1); else last_col <= (cols_left == 1);
if (buf_re[0]) last_row <= 0; // if (buf_re[0]) last_row <= 0;
if (!buf_re[0]) last_row <= 0;
else if (last_col) last_row <= (rows_left == 1); else if (last_col) last_row <= (rows_left == 1);
first_col <= (mb_pre_start || (last_col && !last_row)); first_col <= (mb_pre_start || (last_col && !last_row));
...@@ -153,12 +154,13 @@ module cmprs_pixel_buf_iface #( ...@@ -153,12 +154,13 @@ module cmprs_pixel_buf_iface #(
if (mb_pre_start || last_col) tile_x <= {2'b0,macroblock_x[4:0]} | tile_width_or; if (mb_pre_start || last_col) tile_x <= {2'b0,macroblock_x[4:0]} | tile_width_or;
else if (buf_re[0]) tile_x <= (tile_x+1) | tile_width_or; else if (buf_re[0]) tile_x <= (tile_x+1) | tile_width_or;
if (mb_pre_start || last_col) bufa_r[11:10] <= start_page; if (mb_pre_start) bufa_r[11:10] <= start_page;
else if (last_col) bufa_r[11:10] <= row_sa[11:10]; // start_page;
else if (last_in_tile) bufa_r[11:10] <= bufa_r[11:10] + 1; else if (last_in_tile) bufa_r[11:10] <= bufa_r[11:10] + 1;
// Most time critical - calculation of the buffer address // Most time critical - calculation of the buffer address
if (mb_pre_start) bufa_r[9:0] <= {3'b0,macroblock_x}; if (mb_pre_start) bufa_r[9:0] <= {3'b0,macroblock_x};
else if (last_col) bufa_r[9:0] <= row_sa[9:0]; else if (last_col) bufa_r[9:0] <= row_sa[9:0]; // 'bx next cycle after AFTER mb_pre_start
else if (last_in_tile) bufa_r[9:0] <= tile_sa; else if (last_in_tile) bufa_r[9:0] <= tile_sa;
else if (buf_re[0]) bufa_r[9:0] <= bufa_r[9:0] + {last_in_col?col_inc[9:4]:6'b0,4'b1}; else if (buf_re[0]) bufa_r[9:0] <= bufa_r[9:0] + {last_in_col?col_inc[9:4]:6'b0,4'b1};
...@@ -166,7 +168,7 @@ module cmprs_pixel_buf_iface #( ...@@ -166,7 +168,7 @@ module cmprs_pixel_buf_iface #(
if (!frame_en) period_cntr <= 0; if (!frame_en) period_cntr <= 0;
else if (mb_pre_start) begin else if (mb_pre_start) begin
case (converter_type[2:0]) case (converter_type[2:0])
CMPRS_COLOR18: period_cntr <= PERIOD_COLOR18 - 1; CMPRS_COLOR18: period_cntr <= PERIOD_COLOR18 - 1; // period = 384 - limited by 6*64, not by 18x18
CMPRS_COLOR20: period_cntr <= PERIOD_COLOR20 - 1; CMPRS_COLOR20: period_cntr <= PERIOD_COLOR20 - 1;
CMPRS_MONO16: period_cntr <= PERIOD_MONO16 - 1; CMPRS_MONO16: period_cntr <= PERIOD_MONO16 - 1;
CMPRS_JP4: period_cntr <= PERIOD_JP4 - 1; CMPRS_JP4: period_cntr <= PERIOD_JP4 - 1;
...@@ -182,6 +184,18 @@ module cmprs_pixel_buf_iface #( ...@@ -182,6 +184,18 @@ module cmprs_pixel_buf_iface #(
if (!frame_en) mb_release_buf_r <= 0; if (!frame_en) mb_release_buf_r <= 0;
else mb_release_buf_r <= (period_cntr == (CMPRS_RELEASE_EARLY+1)); else mb_release_buf_r <= (period_cntr == (CMPRS_RELEASE_EARLY+1));
data_valid <= buf_re[CMPRS_BUF_EXTRA_LATENCY+2];
end
`ifdef SIMULATION
reg [8:0] sim_dout_cntr;
always @(posedge xclk) begin
if (!data_valid) sim_dout_cntr <= 0;
else sim_dout_cntr <= sim_dout_cntr + 1;
if (data_valid) begin
$display("CMPRS INPUT %x:%x @ %t",sim_dout_cntr, data_out, $time);
end
end end
`endif
endmodule endmodule
...@@ -29,9 +29,9 @@ module cmprs_tile_mode_decode #( ...@@ -29,9 +29,9 @@ module cmprs_tile_mode_decode #(
parameter CMPRS_MONO8 = 7 // Regular JPEG monochrome with 8x8 macroblocks (not yet implemented) parameter CMPRS_MONO8 = 7 // Regular JPEG monochrome with 8x8 macroblocks (not yet implemented)
)( )(
input [2:0] converter_type, input [2:0] converter_type,
output reg [ 5:0] mb_w_m1, // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 output reg [ 5:0] mb_w_m1, // macroblock width minus 1
output reg [ 5:0] mb_h_m1, // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 output reg [ 5:0] mb_h_m1, // macroblock height minus 1
output reg [ 4:0] mb_hper, // macroblock horizontal period (8/16) // 3 LSB not used TODO: assign from converter_type[2:0] output reg [ 4:0] mb_hper, // macroblock horizontal period (8/16) // 3 LSB not used
output reg [ 1:0] tile_width, // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 output reg [ 1:0] tile_width, // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
output reg tile_col_width // 0 - 16 pixels, 1 -32 pixels output reg tile_col_width // 0 - 16 pixels, 1 -32 pixels
); );
...@@ -40,51 +40,51 @@ module cmprs_tile_mode_decode #( ...@@ -40,51 +40,51 @@ module cmprs_tile_mode_decode #(
always @(converter_type) begin always @(converter_type) begin
case (converter_type) case (converter_type)
CMPRS_COLOR18: begin CMPRS_COLOR18: begin
mb_w_m1 <= 17; // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 mb_w_m1 <= 17; // macroblock width minus 1
mb_h_m1 <= 17; // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 mb_h_m1 <= 17; // macroblock height minus 1
mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used TODO: assign from converter_type[2:0] mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used
tile_width <= 1; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 tile_width <= 1; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels
end end
CMPRS_COLOR20: begin CMPRS_COLOR20: begin
mb_w_m1 <= 19; // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 mb_w_m1 <= 19; // macroblock width minus 1
mb_h_m1 <= 19; // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 mb_h_m1 <= 19; // macroblock height minus 1
mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used TODO: assign from converter_type[2:0] mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used
tile_width <= 1; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 tile_width <= 1; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels
end end
CMPRS_MONO16: begin CMPRS_MONO16: begin
mb_w_m1 <= 15; // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 mb_w_m1 <= 15; // macroblock width minus 1
mb_h_m1 <= 15; // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 mb_h_m1 <= 15; // macroblock height minus 1
mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used TODO: assign from converter_type[2:0] mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used
tile_width <= 2; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 tile_width <= 2; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels
end end
CMPRS_JP4: begin CMPRS_JP4: begin
mb_w_m1 <= 15; // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 mb_w_m1 <= 15; // macroblock width minus 1
mb_h_m1 <= 15; // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 mb_h_m1 <= 15; // macroblock height minus 1
mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used TODO: assign from converter_type[2:0] mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used
tile_width <= 2; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 tile_width <= 2; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels
end end
CMPRS_JP4DIFF: begin CMPRS_JP4DIFF: begin
mb_w_m1 <= 15; // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 mb_w_m1 <= 15; // macroblock width minus 1
mb_h_m1 <= 15; // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 mb_h_m1 <= 15; // macroblock height minus 1
mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used TODO: assign from converter_type[2:0] mb_hper <= 16; // macroblock horizontal period (8/16) // 3 LSB not used
tile_width <= 2; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 tile_width <= 2; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels
end end
CMPRS_MONO8: begin CMPRS_MONO8: begin
mb_w_m1 <= 7; // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 mb_w_m1 <= 7; // macroblock width minus 1
mb_h_m1 <= 7; // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 mb_h_m1 <= 7; // macroblock height minus 1
mb_hper <= 8; // macroblock horizontal period (8/16) // 3 LSB not used TODO: assign from converter_type[2:0] mb_hper <= 8; // macroblock horizontal period (8/16) // 3 LSB not used
tile_width <= 3; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 tile_width <= 3; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels tile_col_width <= 1; // 0 - 16 pixels, 1 -32 pixels
end end
default: begin default: begin
mb_w_m1 <= 'bx; // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 mb_w_m1 <= 'bx; // macroblock width minus 1
mb_h_m1 <= 'bx; // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 mb_h_m1 <= 'bx; // macroblock height minus 1
mb_hper <= 'bx; // macroblock horizontal period (8/16) // 3 LSB not used TODO: assign from converter_type[2:0] mb_hper <= 'bx; // macroblock horizontal period (8/16) // 3 LSB not used
tile_width <= 'bx; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 tile_width <= 'bx; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
tile_col_width <= 'bx; // 0 - 16 pixels, 1 -32 pixels tile_col_width <= 'bx; // 0 - 16 pixels, 1 -32 pixels
end end
......
...@@ -167,7 +167,7 @@ module compressor393 # ( ...@@ -167,7 +167,7 @@ module compressor393 # (
output [3:0] stuffer_done_mclk, output [3:0] stuffer_done_mclk,
// frame input synchronization // frame input synchronization
input [3:0] vsync_late, // delayed start of frame, @xclk. In 353 it was 16 lines after VACT active input [3:0] vsync_late, // delayed start of frame, @mclk. In 353 it was 16 lines after VACT active
// source channel should already start, some delay give time for sequencer commands // source channel should already start, some delay give time for sequencer commands
// that should arrive before it // that should arrive before it
......
...@@ -156,7 +156,7 @@ module jp_channel#( ...@@ -156,7 +156,7 @@ module jp_channel#(
output stuffer_done_mclk, output stuffer_done_mclk,
// output [31:0] hifreq, // accumulated high frequency components in a frame sub-window // output [31:0] hifreq, // accumulated high frequency components in a frame sub-window
input vsync_late, // delayed start of frame, @xclk. In 353 it was 16 lines after VACT active input vsync_late, // delayed start of frame, @mclk. In 353 it was 16 lines after VACT active
// source channel should already start, some delay give time for sequencer commands // source channel should already start, some delay give time for sequencer commands
// that should arrive before it // that should arrive before it
...@@ -177,6 +177,7 @@ module jp_channel#( ...@@ -177,6 +177,7 @@ module jp_channel#(
// Control signals to be defined // Control signals to be defined
wire frame_en; // if 0 - will reset logic immediately (but not page number) wire frame_en; // if 0 - will reset logic immediately (but not page number)
wire frame_start_xclk; // re-clocked, parameters are copied at this pulse
wire stuffer_en; // extended enable to allow stuffer to gracefully finish wire stuffer_en; // extended enable to allow stuffer to gracefully finish
wire frame_go=frame_en; // start frame: if idle, will start reading data (if available), wire frame_go=frame_en; // start frame: if idle, will start reading data (if available),
...@@ -200,9 +201,9 @@ module jp_channel#( ...@@ -200,9 +201,9 @@ module jp_channel#(
wire [ 1:0] cmprs_fmode; // focusing/overlay mode wire [ 1:0] cmprs_fmode; // focusing/overlay mode
//TODO: assign next 5 values from converter_type[2:0] //TODO: assign next 5 values from converter_type[2:0]
wire [ 5:0] mb_w_m1; // macroblock width minus 1 // 3 LSB not used, SHOULD BE SET to 3'b111 wire [ 5:0] mb_w_m1; // macroblock width minus 1
wire [ 5:0] mb_h_m1; // macroblock horizontal period (8/16) // 3 LSB not used SHOULD BE SET to 3'b111 wire [ 5:0] mb_h_m1; // macroblock height -1
wire [ 4:0] mb_hper; // macroblock horizontal period (8/16) // 3 LSB not used TODO: assign from converter_type[2:0] wire [ 4:0] mb_hper; // macroblock horizontal period (8/16) // 3 LSB not used
wire [ 1:0] tile_width; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 wire [ 1:0] tile_width; // memory tile width (can be 128 for monochrome JPEG) Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
wire tile_col_width; // 0 - 16 pixels, 1 -32 pixels wire tile_col_width; // 0 - 16 pixels, 1 -32 pixels
...@@ -450,6 +451,7 @@ module jp_channel#( ...@@ -450,6 +451,7 @@ module jp_channel#(
.coring_we (set_coring_w), // input - write color saturation values .coring_we (set_coring_w), // input - write color saturation values
.di (cmd_data), // input[31:0] - 32-bit data to write to control register (24LSB are used) .di (cmd_data), // input[31:0] - 32-bit data to write to control register (24LSB are used)
.frame_start (frame_start_dst), // input @mclk .frame_start (frame_start_dst), // input @mclk
.frame_start_xclk (frame_start_xclk), // re-clocked, parameters are copied during this pulse
.cmprs_en_mclk (cmprs_en_mclk), // output .cmprs_en_mclk (cmprs_en_mclk), // output
.cmprs_en_extend (cmprs_en_extend), // input .cmprs_en_extend (cmprs_en_extend), // input
.cmprs_run_mclk (cmprs_run_mclk), // output reg .cmprs_run_mclk (cmprs_run_mclk), // output reg
...@@ -512,10 +514,10 @@ module jp_channel#( ...@@ -512,10 +514,10 @@ module jp_channel#(
.cmprs_standalone (cmprs_standalone), // input - @mclk single-cycle: generate a single frame_start_dst in unbonded (not synchronized) mode. .cmprs_standalone (cmprs_standalone), // input - @mclk single-cycle: generate a single frame_start_dst in unbonded (not synchronized) mode.
// cmprs_run should be off // cmprs_run should be off
.sigle_frame_buf (sigle_frame_buf), // input - memory controller uses a single frame buffer (frame_number_* == 0), use other sync .sigle_frame_buf (sigle_frame_buf), // input - memory controller uses a single frame buffer (frame_number_* == 0), use other sync
.vsync_late (vsync_late), // input - @xclk delayed start of frame, @xclk. In 353 it was 16 lines after VACT active .vsync_late (vsync_late), // input - @mclk delayed start of frame, @xclk. In 353 it was 16 lines after VACT active
// source channel should already start, some delay give time for sequencer commands // source channel should already start, some delay give time for sequencer commands
// that should arrive before it // that should arrive before it
.frame_started (first_mb && mb_pre_start), // @xclk started first macroblock (checking fro broken frames) .frame_started (first_mb && mb_pre_start), // @xclk started first macroblock (checking for broken frames)
.frame_start_dst (frame_start_dst), // output reg @mclk - trigger receive (tiled) memory channel (it will take care of .frame_start_dst (frame_start_dst), // output reg @mclk - trigger receive (tiled) memory channel (it will take care of
// single/repetitive modes itself this output either follows vsync_late (reclocks it) // single/repetitive modes itself this output either follows vsync_late (reclocks it)
// or generated in non-bonded mode (compress from memory once) // or generated in non-bonded mode (compress from memory once)
...@@ -545,11 +547,12 @@ module jp_channel#( ...@@ -545,11 +547,12 @@ module jp_channel#(
.page_ready_chn (page_ready_chn), // input .page_ready_chn (page_ready_chn), // input
.next_page_chn (next_page_chn), // output .next_page_chn (next_page_chn), // output
.frame_en (frame_en), // input .frame_en (frame_en), // input
.frame_start_xclk (frame_start_xclk), // input@posedge xclk - parameters are copied @ this pulse
.frame_go (frame_go), // input - do not use - assign to frame_en? Running frames can be controlled by other means .frame_go (frame_go), // input - do not use - assign to frame_en? Running frames can be controlled by other means
.left_marg (left_marg), // input[4:0] .left_marg (left_marg), // input[4:0]
.n_blocks_in_row_m1 (n_blocks_in_row_m1), // input[12:0] .n_blocks_in_row_m1 (n_blocks_in_row_m1), // input[12:0]
.n_block_rows_m1 (n_block_rows_m1), // input[12:0] .n_block_rows_m1 (n_block_rows_m1), // input[12:0]
.mb_w_m1 (mb_w_m1), // input[5:0] // macroblock width minus 1 // 3 LSB not used - set them to all 1 .mb_w_m1 (mb_w_m1), // input[5:0] // macroblock width minus 1 // 3 LSB not used here
.mb_hper (mb_hper), // input[4:0] // macroblock horizontal period (8/16) // 3 LSB not used (set them 0) .mb_hper (mb_hper), // input[4:0] // macroblock horizontal period (8/16) // 3 LSB not used (set them 0)
.tile_width (tile_width), // input[1:0] // memory tile width. Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128 .tile_width (tile_width), // input[1:0] // memory tile width. Can be 32/64/128: 0 - 16, 1 - 32, 2 - 64, 3 - 128
.mb_pre_end_in (mb_pre_end), // input .mb_pre_end_in (mb_pre_end), // input
......
...@@ -669,8 +669,8 @@ module ddr3 ( ...@@ -669,8 +669,8 @@ module ddr3 (
// $fseek returns 0 on success, -1 on failure // $fseek returns 0 on success, -1 on failure
if (code != 0) if (code != 0)
begin begin
$display("%m: at time %t ERROR: fseek to %d failed", $time, offset); $display("%m: at time %t ERROR: fseek to %d failed index=%d ", $time, offset, index);
$finish; // $finish;
end end
`ifdef CVC `ifdef CVC
code = $fgets(read_str, fd); code = $fgets(read_str, fd);
......
...@@ -113,7 +113,8 @@ module mcntrl_linear_rw #( ...@@ -113,7 +113,8 @@ module mcntrl_linear_rw #(
reg [FRAME_WIDTH_BITS:0] frame_full_width_r; // (14 bit) register to be absorbed by MPY reg [FRAME_WIDTH_BITS:0] frame_full_width_r; // (14 bit) register to be absorbed by MPY
reg [MPY_WIDTH-1:0] mul_rslt; reg [MPY_WIDTH-1:0] mul_rslt;
reg [NUM_RC_BURST_BITS-1:0] start_addr_r; // 22 bit - to be absorbed by DSP reg [NUM_RC_BURST_BITS-1:0] start_addr_r; // 22 bit - to be absorbed by DSP
reg [2:0] bank_reg [2:0]; // reg [2:0] bank_reg [2:0];
reg [3 * 3 - 1:0] bank_reg;
wire [FRAME_WIDTH_BITS+FRAME_HEIGHT_BITS-3:0] mul_rslt_w; wire [FRAME_WIDTH_BITS+FRAME_HEIGHT_BITS-3:0] mul_rslt_w;
reg [FRAME_WIDTH_BITS:0] row_left; // number of 8-bursts left in the current row reg [FRAME_WIDTH_BITS:0] row_left; // number of 8-bursts left in the current row
reg last_in_row; reg last_in_row;
...@@ -166,7 +167,10 @@ module mcntrl_linear_rw #( ...@@ -166,7 +167,10 @@ module mcntrl_linear_rw #(
reg last_block; reg last_block;
reg [MCNTRL_SCANLINE_PENDING_CNTR_BITS-1:0] pending_xfers; // number of requested,. but not finished block transfers reg [MCNTRL_SCANLINE_PENDING_CNTR_BITS-1:0] pending_xfers; // number of requested,. but not finished block transfers
reg [NUM_RC_BURST_BITS-1:0] row_col_r; reg [NUM_RC_BURST_BITS-1:0] row_col_r;
reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_r [1:0]; // reg [2*FRAME_HEIGHT_BITS-1:0] line_unfinished_r;
reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_relw_r;
reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_r;
wire pre_want; wire pre_want;
wire [1:0] status_data; wire [1:0] status_data;
wire [3:0] cmd_a; wire [3:0] cmd_a;
...@@ -322,10 +326,10 @@ module mcntrl_linear_rw #( ...@@ -322,10 +326,10 @@ module mcntrl_linear_rw #(
assign last_row_w= next_y==window_height; assign last_row_w= next_y==window_height;
assign xfer_want= want_r; assign xfer_want= want_r;
assign xfer_need= need_r; assign xfer_need= need_r;
assign xfer_bank= bank_reg[2]; // TODO: just a single reg layer assign xfer_bank= bank_reg[3 * 2 +: 3]; // TODO: just a single reg layer
assign xfer_row= row_col_r[NUM_RC_BURST_BITS-1:COLADDR_NUMBER-3] ; // memory row assign xfer_row= row_col_r[NUM_RC_BURST_BITS-1:COLADDR_NUMBER-3] ; // memory row
assign xfer_col= row_col_r[COLADDR_NUMBER-4:0]; // start memory column in 8-bursts assign xfer_col= row_col_r[COLADDR_NUMBER-4:0]; // start memory column in 8-bursts
assign line_unfinished=line_unfinished_r[1]; assign line_unfinished = line_unfinished_r; // [FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS];
assign chn_en = mode_reg[MCONTR_LINTILE_NRESET] & mode_reg[MCONTR_LINTILE_EN]; // enable requests by channel (continue ones in progress) assign chn_en = mode_reg[MCONTR_LINTILE_NRESET] & mode_reg[MCONTR_LINTILE_EN]; // enable requests by channel (continue ones in progress)
assign chn_rst = ~mode_reg[MCONTR_LINTILE_NRESET]; // resets command, including fifo; assign chn_rst = ~mode_reg[MCONTR_LINTILE_NRESET]; // resets command, including fifo;
assign cmd_wrmem = mode_reg[MCONTR_LINTILE_WRITE];// 0: read from memory, 1:write to memory assign cmd_wrmem = mode_reg[MCONTR_LINTILE_WRITE];// 0: read from memory, 1:write to memory
...@@ -364,9 +368,9 @@ module mcntrl_linear_rw #( ...@@ -364,9 +368,9 @@ module mcntrl_linear_rw #(
// line_start_page_left <= {COLADDR_NUMBER-3{1'b0}} - line_start_addr[COLADDR_NUMBER-4:0]; // 7 bits // line_start_page_left <= {COLADDR_NUMBER-3{1'b0}} - line_start_addr[COLADDR_NUMBER-4:0]; // 7 bits
line_start_page_left <= - line_start_addr[COLADDR_NUMBER-4:0]; // 7 bits line_start_page_left <= - line_start_addr[COLADDR_NUMBER-4:0]; // 7 bits
end end
bank_reg[0] <= frame_y[2:0]; //TODO: is it needed - a pipeline for the bank? - remove! bank_reg[0 +:3] <= frame_y[2:0]; //TODO: is it needed - a pipeline for the bank? - remove!
for (i=0;i<2; i = i+1) for (i=0;i<2; i = i+1)
bank_reg[i+1] <= bank_reg[i]; bank_reg[(i+1)*3 +:3] <= bank_reg[i * 3 +: 3];
if (recalc_r[6]) begin // cycle 7 if (recalc_r[6]) begin // cycle 7
...@@ -483,20 +487,34 @@ wire start_not_partial= xfer_start_r[0] && !xfer_limited_by_mem_page_r; ...@@ -483,20 +487,34 @@ wire start_not_partial= xfer_start_r[0] && !xfer_limited_by_mem_page_r;
else if ( xfer_start_r[0] && !xfer_done) pending_xfers <= pending_xfers + 1; else if ( xfer_start_r[0] && !xfer_done) pending_xfers <= pending_xfers + 1;
else if (!xfer_start_r[0] && xfer_done) pending_xfers <= pending_xfers - 1; else if (!xfer_start_r[0] && xfer_done) pending_xfers <= pending_xfers - 1;
/*
//line_unfinished_r cmd_wrmem //line_unfinished_r cmd_wrmem
if (mrst) line_unfinished_r[0] <= 0; //{FRAME_HEIGHT_BITS{1'b0}}; if (mrst) line_unfinished_r[0 +: FRAME_HEIGHT_BITS] <= 0; //{FRAME_HEIGHT_BITS{1'b0}};
else if (chn_rst || frame_start_r[0]) line_unfinished_r[0] <= window_y0+start_y; else if (chn_rst || frame_start_r[0]) line_unfinished_r[0 +: FRAME_HEIGHT_BITS] <= window_y0+start_y;
else if (xfer_start_r[2]) line_unfinished_r[0] <= window_y0+next_y[FRAME_HEIGHT_BITS-1:0]; // latency 2 from xfer_start else if (xfer_start_r[2]) line_unfinished_r[0 +: FRAME_HEIGHT_BITS] <= window_y0+next_y[FRAME_HEIGHT_BITS-1:0]; // latency 2 from xfer_start
if (mrst) line_unfinished_r[1] <= 0; //{FRAME_HEIGHT_BITS{1'b0}}; if (mrst) line_unfinished_r[FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS] <= 0; //{FRAME_HEIGHT_BITS{1'b0}};
// else if (chn_rst || frame_start_r[0]) line_unfinished_r[1] <= window_y0+start_y; // else if (chn_rst || frame_start_r[0]) line_unfinished_r[1] <= window_y0+start_y;
else if (chn_rst || frame_start_r[2]) line_unfinished_r[1] <= window_y0+start_y; // _r[0] -> _r[2] to make it simultaneous with frame_number else if (chn_rst || frame_start_r[2]) line_unfinished_r[FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS] <= window_y0+start_y; // _r[0] -> _r[2] to make it simultaneous with frame_number
// in read mode advance line number ASAP // in read mode advance line number ASAP
else if (xfer_start_r[2] && !cmd_wrmem) line_unfinished_r[1] <= window_y0+next_y[FRAME_HEIGHT_BITS-1:0]; // latency 2 from xfer_start else if (xfer_start_r[2] && !cmd_wrmem) line_unfinished_r[FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS] <= window_y0+next_y[FRAME_HEIGHT_BITS-1:0]; // latency 2 from xfer_start
// in write mode advance line number only when it is guaranteed it will be the first to actually access memory // in write mode advance line number only when it is guaranteed it will be the first to actually access memory
else if (xfer_grant && cmd_wrmem) line_unfinished_r[1] <= line_unfinished_r[0]; else if (xfer_grant && cmd_wrmem) line_unfinished_r[FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS] <= line_unfinished_r[0 +: FRAME_HEIGHT_BITS];
*/
/*
if (mrst) line_unfinished_relw_r <= 0;
else if (cmd_wrmem && (frame_start_r[1] || !chn_en)) line_unfinished_relw_r <= start_y;
else if ((!cmd_wrmem && recalc_r[1]) || xfer_start_r[2]) line_unfinished_relw_r <= next_y[FRAME_HEIGHT_BITS-1:0];
// xfer_start_r[2] and recalc_r[1] are at the same time
if (mrst || (frame_start || !chn_en)) line_unfinished_r <= {FRAME_HEIGHT_BITS{~cmd_wrmem}}; // lowest/highest value until valid
else if (recalc_r[2]) line_unfinished_r <= line_unfinished_relw_r + window_y0;
*/
if (recalc_r[0]) line_unfinished_relw_r <= curr_y + (cmd_wrmem ? 0: 1);
if (mrst || (frame_start || !chn_en)) line_unfinished_r <= {FRAME_HEIGHT_BITS{~cmd_wrmem}}; // lowest/highest value until valid
else if (recalc_r[2]) line_unfinished_r <= line_unfinished_relw_r + window_y0;
end end
always @ (negedge mclk) begin always @ (negedge mclk) begin
......
...@@ -129,7 +129,8 @@ module mcntrl_tiled_rw#( ...@@ -129,7 +129,8 @@ module mcntrl_tiled_rw#(
reg [FRAME_WIDTH_BITS:0] frame_full_width_r; // (14 bit) register to be absorbed by MPY reg [FRAME_WIDTH_BITS:0] frame_full_width_r; // (14 bit) register to be absorbed by MPY
reg [MPY_WIDTH-1:0] mul_rslt; reg [MPY_WIDTH-1:0] mul_rslt;
reg [NUM_RC_BURST_BITS-1:0] start_addr_r; // 22 bit - to be absorbed by DSP reg [NUM_RC_BURST_BITS-1:0] start_addr_r; // 22 bit - to be absorbed by DSP
reg [2:0] bank_reg [2:0]; // reg [2:0] bank_reg [2:0];
reg [3 * 3 - 1:0] bank_reg;
wire [FRAME_WIDTH_BITS+FRAME_HEIGHT_BITS-3:0] mul_rslt_w; wire [FRAME_WIDTH_BITS+FRAME_HEIGHT_BITS-3:0] mul_rslt_w;
// wire [2:0] cur_bank; // wire [2:0] cur_bank;
reg [FRAME_WIDTH_BITS:0] row_left; // number of 8-bursts left in the current row reg [FRAME_WIDTH_BITS:0] row_left; // number of 8-bursts left in the current row
...@@ -180,7 +181,9 @@ module mcntrl_tiled_rw#( ...@@ -180,7 +181,9 @@ module mcntrl_tiled_rw#(
reg [NUM_RC_BURST_BITS-1:0] row_col_r; reg [NUM_RC_BURST_BITS-1:0] row_col_r;
// reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_r0; // reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_r0;
// reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_r1; // reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_r1;
reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_r [1:0]; // reg [2*FRAME_HEIGHT_BITS-1:0] line_unfinished_r;
reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_relw_r;
reg [FRAME_HEIGHT_BITS-1:0] line_unfinished_r;
wire pre_want; wire pre_want;
wire [1:0] status_data; wire [1:0] status_data;
...@@ -203,7 +206,7 @@ module mcntrl_tiled_rw#( ...@@ -203,7 +206,7 @@ module mcntrl_tiled_rw#(
// wire msw13_zero=!(|cmd_data[FRAME_WIDTH_BITS+15:16]); // MSW 13 (FRAME_WIDTH_BITS) low bits are all 0 - set carry bit // wire msw13_zero=!(|cmd_data[FRAME_WIDTH_BITS+15:16]); // MSW 13 (FRAME_WIDTH_BITS) low bits are all 0 - set carry bit
wire msw_zero= !(|cmd_data[31:16]); // MSW all bits are 0 - set carry bit wire msw_zero= !(|cmd_data[31:16]); // MSW all bits are 0 - set carry bit
wire tile_width_zero= !(|cmd_data[ 0+:MAX_TILE_WIDTH]); wire tile_width_zero= !(|cmd_data[ 0+:MAX_TILE_WIDTH]);
// wire tile_height_zero=!(|cmd_data[ 8+:MAX_TILE_HEIGHT]); wire tile_height_zero=!(|cmd_data[ 8+:MAX_TILE_HEIGHT]);
wire tile_vstep_zero= !(|cmd_data[16+:MAX_TILE_HEIGHT]); wire tile_vstep_zero= !(|cmd_data[16+:MAX_TILE_HEIGHT]);
// reg [5:0] mode_reg;//mode register: {write_mode,keep_open,extra_pages[1:0],enable,!reset} // reg [5:0] mode_reg;//mode register: {write_mode,keep_open,extra_pages[1:0],enable,!reset}
...@@ -223,7 +226,8 @@ module mcntrl_tiled_rw#( ...@@ -223,7 +226,8 @@ module mcntrl_tiled_rw#(
reg [MAX_TILE_WIDTH:0] tile_cols; // full number of columns in a tile reg [MAX_TILE_WIDTH:0] tile_cols; // full number of columns in a tile
// reg [MAX_TILE_HEIGHT:0] tile_rows; // full number of rows in a tile // reg [MAX_TILE_HEIGHT:0] tile_rows; // full number of rows in a tile
reg [MAX_TILE_HEIGHT-1:0] tile_rows; // full number of rows in a tile // reg [MAX_TILE_HEIGHT-1:0] tile_rows; // full number of rows in a tile
reg [MAX_TILE_HEIGHT:0] tile_rows; // full number of rows in a tile
reg [MAX_TILE_HEIGHT:0] tile_vstep; // vertical step between rows of tiles reg [MAX_TILE_HEIGHT:0] tile_vstep; // vertical step between rows of tiles
reg [MAX_TILE_WIDTH:0] num_cols_r; // full number of columns to transfer (not minus 1) reg [MAX_TILE_WIDTH:0] num_cols_r; // full number of columns to transfer (not minus 1)
...@@ -327,7 +331,7 @@ module mcntrl_tiled_rw#( ...@@ -327,7 +331,7 @@ module mcntrl_tiled_rw#(
tile_vstep <= 0; tile_vstep <= 0;
end else if (set_tile_whs_w) begin end else if (set_tile_whs_w) begin
tile_cols <= {tile_width_zero, cmd_data[ 0+:MAX_TILE_WIDTH]}; tile_cols <= {tile_width_zero, cmd_data[ 0+:MAX_TILE_WIDTH]};
tile_rows <= { cmd_data[ 8+:MAX_TILE_HEIGHT]}; tile_rows <= {tile_height_zero, cmd_data[ 8+:MAX_TILE_HEIGHT]};
tile_vstep <= {tile_vstep_zero, cmd_data[16+:MAX_TILE_HEIGHT]}; tile_vstep <= {tile_vstep_zero, cmd_data[16+:MAX_TILE_HEIGHT]};
end end
...@@ -365,10 +369,11 @@ module mcntrl_tiled_rw#( ...@@ -365,10 +369,11 @@ module mcntrl_tiled_rw#(
//window_m_tile_height //window_m_tile_height
assign xfer_want= want_r; assign xfer_want= want_r;
assign xfer_need= need_r; assign xfer_need= need_r;
assign xfer_bank= bank_reg[2]; // TODO: just a single reg layer assign xfer_bank= bank_reg[2*3 +: 3]; // TODO: just a single reg layer
assign xfer_row= row_col_r[NUM_RC_BURST_BITS-1:COLADDR_NUMBER-3] ; // memory row assign xfer_row= row_col_r[NUM_RC_BURST_BITS-1:COLADDR_NUMBER-3] ; // memory row
assign xfer_col= row_col_r[COLADDR_NUMBER-4:0]; // start memory column in 8-bursts assign xfer_col= row_col_r[COLADDR_NUMBER-4:0]; // start memory column in 8-bursts
assign line_unfinished=line_unfinished_r[1]; // assign line_unfinished = line_unfinished_r[FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS];
assign line_unfinished = line_unfinished_r;
assign chn_en = mode_reg[MCONTR_LINTILE_NRESET] & mode_reg[MCONTR_LINTILE_EN]; // enable requests by channel (continue ones in progress) assign chn_en = mode_reg[MCONTR_LINTILE_NRESET] & mode_reg[MCONTR_LINTILE_EN]; // enable requests by channel (continue ones in progress)
assign chn_rst = ~mode_reg[MCONTR_LINTILE_NRESET]; // resets command, including fifo; assign chn_rst = ~mode_reg[MCONTR_LINTILE_NRESET]; // resets command, including fifo;
...@@ -416,9 +421,9 @@ module mcntrl_tiled_rw#( ...@@ -416,9 +421,9 @@ module mcntrl_tiled_rw#(
row_col_r <= line_start_addr+frame_x; row_col_r <= line_start_addr+frame_x;
line_start_page_left <= - line_start_addr[COLADDR_NUMBER-4:0]; // 7 bits line_start_page_left <= - line_start_addr[COLADDR_NUMBER-4:0]; // 7 bits
end end
bank_reg[0] <= frame_y[2:0]; //TODO: is it needed - a pipeline for the bank? - remove! bank_reg[0 +: 3] <= frame_y[2:0]; //TODO: is it needed - a pipeline for the bank? - remove!
for (i=0;i<2; i = i+1) for (i=0; i<2; i = i+1)
bank_reg[i+1] <= bank_reg[i]; bank_reg[(i+1)*3 +: 3] <= bank_reg[i*3 +: 3];
if (recalc_r[6]) begin // cycle 7 if (recalc_r[6]) begin // cycle 7
mem_page_left <= {1'b1,line_start_page_left} - frame_x[COLADDR_NUMBER-4:0]; mem_page_left <= {1'b1,line_start_page_left} - frame_x[COLADDR_NUMBER-4:0];
...@@ -535,18 +540,32 @@ wire start_not_partial= xfer_start_r[0] && !xfer_limited_by_mem_page_r; ...@@ -535,18 +540,32 @@ wire start_not_partial= xfer_start_r[0] && !xfer_limited_by_mem_page_r;
else if (chn_rst || frame_start_r[0]) frame_finished_r <= 0; else if (chn_rst || frame_start_r[0]) frame_finished_r <= 0;
else if (frame_done_r) frame_finished_r <= 1; else if (frame_done_r) frame_finished_r <= 1;
//line_unfinished_r cmd_wrmem //line_unfinished_r cmd_wrmem
if (mrst) line_unfinished_r[0] <= 0; //{FRAME_HEIGHT_BITS{1'b0}}; /*
else if (chn_rst || frame_start_r[0]) line_unfinished_r[0] <= window_y0+start_y; if (mrst) line_unfinished_r[0 +: FRAME_HEIGHT_BITS] <= 0; //{FRAME_HEIGHT_BITS{1'b0}};
else if (xfer_start_r[2]) line_unfinished_r[0] <= window_y0+next_y[FRAME_HEIGHT_BITS-1:0]; // latency 2 from xfer_start else if (chn_rst || frame_start_r[0]) line_unfinished_r[0 +: FRAME_HEIGHT_BITS] <= window_y0+start_y;
else if (xfer_start_r[2]) line_unfinished_r[0 +: FRAME_HEIGHT_BITS] <= window_y0+next_y[FRAME_HEIGHT_BITS-1:0]; // latency 2 from xfer_start
if (mrst) line_unfinished_r[1] <= 0; //{FRAME_HEIGHT_BITS{1'b0}}; if (mrst) line_unfinished_r[FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS] <= 0; //{FRAME_HEIGHT_BITS{1'b0}};
else if (chn_rst || frame_start_r[2]) line_unfinished_r[1] <= window_y0+start_y; // _r[0] -> _r[2] to make it simultaneous with frame_number else if (chn_rst || frame_start_r[2]) line_unfinished_r[FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS] <= window_y0+start_y; // _r[0] -> _r[2] to make it simultaneous with frame_number
// in read mode advance line number ASAP // in read mode advance line number ASAP
else if (xfer_start_r[2] && !cmd_wrmem) line_unfinished_r[1] <= window_y0+next_y[FRAME_HEIGHT_BITS-1:0]; // latency 2 from xfer_start else if (xfer_start_r[2] && !cmd_wrmem) line_unfinished_r[FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS] <= window_y0+next_y[FRAME_HEIGHT_BITS-1:0]; // latency 2 from xfer_start
// in write mode advance line number only when it is guaranteed it will be the first to actually access memory // in write mode advance line number only when it is guaranteed it will be the first to actually access memory
else if (xfer_grant && cmd_wrmem) line_unfinished_r[1] <= line_unfinished_r[0]; else if (xfer_grant && cmd_wrmem) line_unfinished_r[FRAME_HEIGHT_BITS +: FRAME_HEIGHT_BITS] <= line_unfinished_r[0 +: FRAME_HEIGHT_BITS];
*/
/*
if (mrst) line_unfinished_relw_r <= 0;
else if (cmd_wrmem && (frame_start_r[1] || !chn_en)) line_unfinished_relw_r <= start_y;
else if ((!cmd_wrmem && recalc_r[1]) || xfer_start_r[2]) line_unfinished_relw_r <= next_y[FRAME_HEIGHT_BITS-1:0];
// xfer_start_r[2] and recalc_r[1] are at the same time
if (mrst || (frame_start || !chn_en)) line_unfinished_r <= {FRAME_HEIGHT_BITS{~cmd_wrmem}}; // lowest/highest value until valid
else if (recalc_r[2]) line_unfinished_r <= line_unfinished_relw_r + window_y0;
*/
if (recalc_r[0]) line_unfinished_relw_r <= curr_y + (cmd_wrmem ? 0: tile_rows);
if (mrst || (frame_start || !chn_en)) line_unfinished_r <= {FRAME_HEIGHT_BITS{~cmd_wrmem}}; // lowest/highest value until valid
else if (recalc_r[2]) line_unfinished_r <= line_unfinished_relw_r + window_y0;
end end
always @ (negedge mclk) begin always @ (negedge mclk) begin
......
...@@ -253,13 +253,13 @@ module lens_flat393 #( ...@@ -253,13 +253,13 @@ module lens_flat393 #(
end end
// Replacing MULT18X18SIO of x353, registers on both inputs, outputs // Replacing MULT18X18SIO of x353, registers on both inputs, outputs
reg [17:0] mul1_a; reg signed [17:0] mul1_a;
reg [17:0] mul1_b; reg signed [17:0] mul1_b;
reg [35:0] mul1_p; reg signed [35:0] mul1_p;
reg [17:0] mul2_a; reg signed [17:0] mul2_a;
reg [17:0] mul2_b; reg signed [17:0] mul2_b;
// wire [17:0] mul2_b = mult_first_scaled[17:0]; // TODO - delay to have a register! // wire [17:0] mul2_b = mult_first_scaled[17:0]; // TODO - delay to have a register!
reg [35:0] mul2_p; reg signed [35:0] mul2_p;
always @ (posedge pclk) begin always @ (posedge pclk) begin
if (hact_d[7]) mul1_a <= (FXY[18]==FXY[17])?FXY[17:0]:(FXY[18]?18'h20000:18'h1ffff); if (hact_d[7]) mul1_a <= (FXY[18]==FXY[17])?FXY[17:0]:(FXY[18]?18'h20000:18'h1ffff);
if (hact_d[7]) mul1_b <= {1'b0,scales_ram[{sub_frame_late,~color[1:0]}]}; if (hact_d[7]) mul1_b <= {1'b0,scales_ram[{sub_frame_late,~color[1:0]}]};
......
...@@ -84,7 +84,7 @@ module sens_gamma #( ...@@ -84,7 +84,7 @@ module sens_gamma #(
reg [3:0] set_tdata_ram; reg [3:0] set_tdata_ram;
reg [17:0] tdata; reg [17:0] tdata;
// wire set_taddr_data_w; // wire set_taddr_data_w;
reg [12:0] taddr; // to high bits - select channnel (in buffered mode), in nion-buffered - 1 bit less, only 10 bits each table reg [12:0] taddr; // two high bits - select channnel (in buffered mode), in non-buffered - 1 bit less, only 10 bits each table
reg [SENS_GAMMA_MODE_WIDTH-1:0] mode=0; reg [SENS_GAMMA_MODE_WIDTH-1:0] mode=0;
reg [SENS_GAMMA_MODE_WIDTH-1:0] mode_mclk=0; reg [SENS_GAMMA_MODE_WIDTH-1:0] mode_mclk=0;
...@@ -336,6 +336,9 @@ module sens_gamma #( ...@@ -336,6 +336,9 @@ module sens_gamma #(
.LOG2WIDTH_WR (4), .LOG2WIDTH_WR (4),
.LOG2WIDTH_RD (4), .LOG2WIDTH_RD (4),
.DUMMY (0) .DUMMY (0)
`ifdef PRELOAD_BRAMS
`include "includes/linear1028rgb.dat.vh"
`endif
) gamma_table0_i ( ) gamma_table0_i (
.rclk (pclk), // input .rclk (pclk), // input
.raddr (table_raddr), // input[11:0] .raddr (table_raddr), // input[11:0]
...@@ -354,6 +357,9 @@ module sens_gamma #( ...@@ -354,6 +357,9 @@ module sens_gamma #(
.LOG2WIDTH_WR (4), .LOG2WIDTH_WR (4),
.LOG2WIDTH_RD (4), .LOG2WIDTH_RD (4),
.DUMMY (!((SENS_NUM_SUBCHN > 1) && ((SENS_NUM_SUBCHN > 2) || SENS_GAMMA_BUFFER))) .DUMMY (!((SENS_NUM_SUBCHN > 1) && ((SENS_NUM_SUBCHN > 2) || SENS_GAMMA_BUFFER)))
`ifdef PRELOAD_BRAMS
`include "includes/linear1028rgb.dat.vh"
`endif
) gamma_table1_i ( ) gamma_table1_i (
.rclk (pclk), // input .rclk (pclk), // input
.raddr (table_raddr), // input[11:0] .raddr (table_raddr), // input[11:0]
...@@ -372,6 +378,9 @@ module sens_gamma #( ...@@ -372,6 +378,9 @@ module sens_gamma #(
.LOG2WIDTH_WR (4), .LOG2WIDTH_WR (4),
.LOG2WIDTH_RD (4), .LOG2WIDTH_RD (4),
.DUMMY (!(SENS_GAMMA_BUFFER && (SENS_NUM_SUBCHN > 2))) .DUMMY (!(SENS_GAMMA_BUFFER && (SENS_NUM_SUBCHN > 2)))
`ifdef PRELOAD_BRAMS
`include "includes/linear1028rgb.dat.vh"
`endif
) gamma_table2_i ( ) gamma_table2_i (
.rclk (pclk), // input .rclk (pclk), // input
.raddr (table_raddr), // input[11:0] .raddr (table_raddr), // input[11:0]
...@@ -390,6 +399,9 @@ module sens_gamma #( ...@@ -390,6 +399,9 @@ module sens_gamma #(
.LOG2WIDTH_WR (4), .LOG2WIDTH_WR (4),
.LOG2WIDTH_RD (4), .LOG2WIDTH_RD (4),
.DUMMY (!(SENS_GAMMA_BUFFER && (SENS_NUM_SUBCHN > 3))) .DUMMY (!(SENS_GAMMA_BUFFER && (SENS_NUM_SUBCHN > 3)))
`ifdef PRELOAD_BRAMS
`include "includes/linear1028rgb.dat.vh"
`endif
) gamma_table3_i ( ) gamma_table3_i (
.rclk (pclk), // input .rclk (pclk), // input
.raddr (table_raddr), // input[11:0] .raddr (table_raddr), // input[11:0]
......
// This file may be used to define same pre-processor macros to be included into each parsed file // This file may be used to define same pre-processor macros to be included into each parsed file
`ifndef SYSTEM_DEFINES `ifndef SYSTEM_DEFINES
`define SYSTEM_DEFINES `define SYSTEM_DEFINES
`define PRELOAD_BRAMS
// Enviroment-dependent options // Enviroment-dependent options
`ifdef IVERILOG `ifdef IVERILOG
`define SIMULATION `define SIMULATION
......
...@@ -41,12 +41,14 @@ module multipulse_cross_clock#( ...@@ -41,12 +41,14 @@ module multipulse_cross_clock#(
wire single_rq_w; wire single_rq_w;
reg single_rq_r=0; reg single_rq_r=0;
assign busy = busy_single && (|pend_cntr); // assign busy = busy_single && (|pend_cntr);
assign single_rq_w = busy_single && (|pend_cntr); assign busy = busy_single || (|pend_cntr);
assign single_rq_w = !busy_single && (|pend_cntr);
always @(posedge src_clk) begin always @(posedge src_clk) begin
single_rq_r <= single_rq_w; single_rq_r <= single_rq_w;
pend_cntr <= pend_cntr + (we ? num_pulses : {WIDTH{1'b0}}) + (single_rq_r ? {WIDTH{1'b1}}:{WIDTH{1'b0}}); if (rst) pend_cntr <= 0;
else pend_cntr <= pend_cntr + (we ? num_pulses : {WIDTH{1'b0}}) + (single_rq_r ? {WIDTH{1'b1}}:{WIDTH{1'b0}});
end end
pulse_cross_clock #( pulse_cross_clock #(
......
...@@ -96,6 +96,9 @@ module ram18_var_w_var_r ...@@ -96,6 +96,9 @@ module ram18_var_w_var_r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [(1 << LOG2WIDTH_WR)-1:0] data_in // data out input [(1 << LOG2WIDTH_WR)-1:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
generate generate
if (DUMMY) if (DUMMY)
ram18_dummy #( ram18_dummy #(
...@@ -106,6 +109,9 @@ module ram18_var_w_var_r ...@@ -106,6 +109,9 @@ module ram18_var_w_var_r
else if ((LOG2WIDTH_WR == 5) && (LOG2WIDTH_RD == 5)) else if ((LOG2WIDTH_WR == 5) && (LOG2WIDTH_RD == 5))
ram18_32w_32r #( ram18_32w_32r #(
.REGISTERS (REGISTERS) .REGISTERS (REGISTERS)
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[8:0] .raddr (raddr), // input[8:0]
...@@ -122,6 +128,9 @@ module ram18_var_w_var_r ...@@ -122,6 +128,9 @@ module ram18_var_w_var_r
ram18_32w_lt32r #( ram18_32w_lt32r #(
.REGISTERS (REGISTERS), .REGISTERS (REGISTERS),
.LOG2WIDTH_RD (LOG2WIDTH_RD) .LOG2WIDTH_RD (LOG2WIDTH_RD)
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[(>8):0] .raddr (raddr), // input[(>8):0]
...@@ -138,6 +147,9 @@ module ram18_var_w_var_r ...@@ -138,6 +147,9 @@ module ram18_var_w_var_r
ram18_lt32w_32r #( ram18_lt32w_32r #(
.REGISTERS (REGISTERS), .REGISTERS (REGISTERS),
.LOG2WIDTH_WR (LOG2WIDTH_WR) .LOG2WIDTH_WR (LOG2WIDTH_WR)
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[8:0] .raddr (raddr), // input[8:0]
...@@ -155,6 +167,9 @@ module ram18_var_w_var_r ...@@ -155,6 +167,9 @@ module ram18_var_w_var_r
.REGISTERS (REGISTERS), .REGISTERS (REGISTERS),
.LOG2WIDTH_WR (LOG2WIDTH_WR), .LOG2WIDTH_WR (LOG2WIDTH_WR),
.LOG2WIDTH_RD (LOG2WIDTH_RD) .LOG2WIDTH_RD (LOG2WIDTH_RD)
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[(>8):0] .raddr (raddr), // input[(>8):0]
...@@ -189,6 +204,9 @@ module ram18_32w_32r ...@@ -189,6 +204,9 @@ module ram18_32w_32r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [31:0] data_in // data out input [31:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
localparam PWIDTH_WR=36; localparam PWIDTH_WR=36;
localparam PWIDTH_RD=36; localparam PWIDTH_RD=36;
...@@ -209,6 +227,9 @@ module ram18_32w_32r ...@@ -209,6 +227,9 @@ module ram18_32w_32r
.SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY" .SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY"
.INIT_FILE ("NONE"), // "NONE" or filename with initialization data .INIT_FILE ("NONE"), // "NONE" or filename with initialization data
.SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES" .SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES"
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
...@@ -260,6 +281,9 @@ module ram18_lt32w_lt32r ...@@ -260,6 +281,9 @@ module ram18_lt32w_lt32r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [(1 << LOG2WIDTH_WR)-1:0] data_in // data out input [(1 << LOG2WIDTH_WR)-1:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR); localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR);
localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD); localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD);
localparam WIDTH_WR = 1 << LOG2WIDTH_WR; localparam WIDTH_WR = 1 << LOG2WIDTH_WR;
...@@ -288,7 +312,9 @@ module ram18_lt32w_lt32r ...@@ -288,7 +312,9 @@ module ram18_lt32w_lt32r
.SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY" .SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY"
.INIT_FILE ("NONE"), // "NONE" or filename with initialization data .INIT_FILE ("NONE"), // "NONE" or filename with initialization data
.SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES" .SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES"
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
...@@ -338,6 +364,9 @@ module ram18_lt32w_32r ...@@ -338,6 +364,9 @@ module ram18_lt32w_32r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [(1 << LOG2WIDTH_WR)-1:0] data_in // data out input [(1 << LOG2WIDTH_WR)-1:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR); localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR);
localparam PWIDTH_RD = 36; localparam PWIDTH_RD = 36;
localparam WIDTH_WR = 1 << LOG2WIDTH_WR; localparam WIDTH_WR = 1 << LOG2WIDTH_WR;
...@@ -362,6 +391,9 @@ module ram18_lt32w_32r ...@@ -362,6 +391,9 @@ module ram18_lt32w_32r
.SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY" .SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY"
.INIT_FILE ("NONE"), // "NONE" or filename with initialization data .INIT_FILE ("NONE"), // "NONE" or filename with initialization data
.SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES" .SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES"
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
...@@ -412,6 +444,9 @@ module ram18_32w_lt32r ...@@ -412,6 +444,9 @@ module ram18_32w_lt32r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [31:0] data_in // data out input [31:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
localparam PWIDTH_WR = 36; localparam PWIDTH_WR = 36;
localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD); localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD);
localparam WIDTH_RD = 1 << LOG2WIDTH_RD; localparam WIDTH_RD = 1 << LOG2WIDTH_RD;
...@@ -434,6 +469,9 @@ module ram18_32w_lt32r ...@@ -434,6 +469,9 @@ module ram18_32w_lt32r
.SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY" .SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY"
.INIT_FILE ("NONE"), // "NONE" or filename with initialization data .INIT_FILE ("NONE"), // "NONE" or filename with initialization data
.SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES" .SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES"
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
......
...@@ -92,6 +92,9 @@ module ram18p_var_w_var_r ...@@ -92,6 +92,9 @@ module ram18p_var_w_var_r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
generate generate
if (DUMMY) if (DUMMY)
ram18p_dummy #( ram18p_dummy #(
...@@ -102,6 +105,9 @@ module ram18p_var_w_var_r ...@@ -102,6 +105,9 @@ module ram18p_var_w_var_r
else if ((LOG2WIDTH_WR == 5) && (LOG2WIDTH_RD == 5)) else if ((LOG2WIDTH_WR == 5) && (LOG2WIDTH_RD == 5))
ram18p_32w_32r #( ram18p_32w_32r #(
.REGISTERS (REGISTERS) .REGISTERS (REGISTERS)
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[8:0] .raddr (raddr), // input[8:0]
...@@ -118,6 +124,9 @@ module ram18p_var_w_var_r ...@@ -118,6 +124,9 @@ module ram18p_var_w_var_r
ram18p_32w_lt32r #( ram18p_32w_lt32r #(
.REGISTERS (REGISTERS), .REGISTERS (REGISTERS),
.LOG2WIDTH_RD (LOG2WIDTH_RD) .LOG2WIDTH_RD (LOG2WIDTH_RD)
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[(>8):0] .raddr (raddr), // input[(>8):0]
...@@ -134,6 +143,9 @@ module ram18p_var_w_var_r ...@@ -134,6 +143,9 @@ module ram18p_var_w_var_r
ram18p_lt32w_32r #( ram18p_lt32w_32r #(
.REGISTERS (REGISTERS), .REGISTERS (REGISTERS),
.LOG2WIDTH_WR (LOG2WIDTH_WR) .LOG2WIDTH_WR (LOG2WIDTH_WR)
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[8:0] .raddr (raddr), // input[8:0]
...@@ -151,6 +163,9 @@ module ram18p_var_w_var_r ...@@ -151,6 +163,9 @@ module ram18p_var_w_var_r
.REGISTERS (REGISTERS), .REGISTERS (REGISTERS),
.LOG2WIDTH_WR (LOG2WIDTH_WR), .LOG2WIDTH_WR (LOG2WIDTH_WR),
.LOG2WIDTH_RD (LOG2WIDTH_RD) .LOG2WIDTH_RD (LOG2WIDTH_RD)
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[(>8):0] .raddr (raddr), // input[(>8):0]
...@@ -185,6 +200,9 @@ module ram18p_32w_32r ...@@ -185,6 +200,9 @@ module ram18p_32w_32r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [35:0] data_in // data out input [35:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
localparam PWIDTH_WR=72; localparam PWIDTH_WR=72;
localparam PWIDTH_RD=72; localparam PWIDTH_RD=72;
...@@ -205,6 +223,9 @@ module ram18p_32w_32r ...@@ -205,6 +223,9 @@ module ram18p_32w_32r
.SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY" .SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY"
.INIT_FILE ("NONE"), // "NONE" or filename with initialization data .INIT_FILE ("NONE"), // "NONE" or filename with initialization data
.SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES" .SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES"
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
...@@ -256,6 +277,9 @@ module ram18p_lt32w_lt32r ...@@ -256,6 +277,9 @@ module ram18p_lt32w_lt32r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR); localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR);
localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD); localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD);
localparam WIDTH_WR = 1 << LOG2WIDTH_WR; localparam WIDTH_WR = 1 << LOG2WIDTH_WR;
...@@ -289,7 +313,9 @@ module ram18p_lt32w_lt32r ...@@ -289,7 +313,9 @@ module ram18p_lt32w_lt32r
.SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY" .SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY"
.INIT_FILE ("NONE"), // "NONE" or filename with initialization data .INIT_FILE ("NONE"), // "NONE" or filename with initialization data
.SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES" .SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES"
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
...@@ -339,6 +365,10 @@ module ram18p_lt32w_32r ...@@ -339,6 +365,10 @@ module ram18p_lt32w_32r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR); localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR);
localparam PWIDTH_RD = 36; localparam PWIDTH_RD = 36;
localparam WIDTH_WR = 1 << LOG2WIDTH_WR; localparam WIDTH_WR = 1 << LOG2WIDTH_WR;
...@@ -367,6 +397,9 @@ module ram18p_lt32w_32r ...@@ -367,6 +397,9 @@ module ram18p_lt32w_32r
.SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY" .SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY"
.INIT_FILE ("NONE"), // "NONE" or filename with initialization data .INIT_FILE ("NONE"), // "NONE" or filename with initialization data
.SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES" .SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES"
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
...@@ -417,6 +450,9 @@ module ram18p_32w_lt32r ...@@ -417,6 +450,9 @@ module ram18p_32w_lt32r
input [ 3:0] web, // write byte enable input [ 3:0] web, // write byte enable
input [35:0] data_in // data out input [35:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram18_declare_init.vh"
`endif
localparam PWIDTH_WR = 72; localparam PWIDTH_WR = 72;
localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD); localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD);
localparam WIDTH_RD = 1 << LOG2WIDTH_RD; localparam WIDTH_RD = 1 << LOG2WIDTH_RD;
...@@ -441,6 +477,9 @@ module ram18p_32w_lt32r ...@@ -441,6 +477,9 @@ module ram18p_32w_lt32r
.SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY" .SIM_COLLISION_CHECK ("ALL"), // Valid: "ALL", "GENERATE_X_ONLY", "NONE", and "WARNING_ONLY"
.INIT_FILE ("NONE"), // "NONE" or filename with initialization data .INIT_FILE ("NONE"), // "NONE" or filename with initialization data
.SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES" .SIM_DEVICE ("7SERIES") // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES"
`ifdef PRELOAD_BRAMS
`include "includes/ram18_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
......
...@@ -92,6 +92,10 @@ module ramp_var_w_var_r ...@@ -92,6 +92,10 @@ module ramp_var_w_var_r
input [ 7:0] web, // write byte enable input [ 7:0] web, // write byte enable
input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram36_declare_init.vh"
`endif
generate generate
if (DUMMY) if (DUMMY)
ramp_dummy #( ramp_dummy #(
...@@ -102,6 +106,9 @@ module ramp_var_w_var_r ...@@ -102,6 +106,9 @@ module ramp_var_w_var_r
else if ((LOG2WIDTH_WR == 6) && (LOG2WIDTH_RD == 6)) else if ((LOG2WIDTH_WR == 6) && (LOG2WIDTH_RD == 6))
ramp_64w_64r #( ramp_64w_64r #(
.REGISTERS (REGISTERS) .REGISTERS (REGISTERS)
`ifdef PRELOAD_BRAMS
`include "includes/ram36_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[8:0] .raddr (raddr), // input[8:0]
...@@ -118,6 +125,9 @@ module ramp_var_w_var_r ...@@ -118,6 +125,9 @@ module ramp_var_w_var_r
ramp_64w_lt64r #( ramp_64w_lt64r #(
.REGISTERS (REGISTERS), .REGISTERS (REGISTERS),
.LOG2WIDTH_RD (LOG2WIDTH_RD) .LOG2WIDTH_RD (LOG2WIDTH_RD)
`ifdef PRELOAD_BRAMS
`include "includes/ram36_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[(>8):0] .raddr (raddr), // input[(>8):0]
...@@ -134,6 +144,9 @@ module ramp_var_w_var_r ...@@ -134,6 +144,9 @@ module ramp_var_w_var_r
ramp_lt64w_64r #( ramp_lt64w_64r #(
.REGISTERS (REGISTERS), .REGISTERS (REGISTERS),
.LOG2WIDTH_WR (LOG2WIDTH_WR) .LOG2WIDTH_WR (LOG2WIDTH_WR)
`ifdef PRELOAD_BRAMS
`include "includes/ram36_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[8:0] .raddr (raddr), // input[8:0]
...@@ -151,6 +164,9 @@ module ramp_var_w_var_r ...@@ -151,6 +164,9 @@ module ramp_var_w_var_r
.REGISTERS (REGISTERS), .REGISTERS (REGISTERS),
.LOG2WIDTH_WR (LOG2WIDTH_WR), .LOG2WIDTH_WR (LOG2WIDTH_WR),
.LOG2WIDTH_RD (LOG2WIDTH_RD) .LOG2WIDTH_RD (LOG2WIDTH_RD)
`ifdef PRELOAD_BRAMS
`include "includes/ram36_pass_init.vh"
`endif
) ram_i ( ) ram_i (
.rclk (rclk), // input .rclk (rclk), // input
.raddr (raddr), // input[(>8):0] .raddr (raddr), // input[(>8):0]
...@@ -184,6 +200,10 @@ module ramp_64w_64r ...@@ -184,6 +200,10 @@ module ramp_64w_64r
input [ 7:0] web, // write byte enable input [ 7:0] web, // write byte enable
input [71:0] data_in // data out input [71:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram36_declare_init.vh"
`endif
localparam PWIDTH_WR=72; localparam PWIDTH_WR=72;
localparam PWIDTH_RD=72; localparam PWIDTH_RD=72;
...@@ -208,6 +228,9 @@ module ramp_64w_64r ...@@ -208,6 +228,9 @@ module ramp_64w_64r
.SIM_DEVICE ("7SERIES"), // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES" .SIM_DEVICE ("7SERIES"), // Simulation device family - "VIRTEX6", "VIRTEX5" and "7_SERIES" // "7SERIES"
.EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry)
.EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry)
`ifdef PRELOAD_BRAMS
`include "includes/ram36_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
...@@ -272,6 +295,10 @@ module ramp_lt64w_lt64r ...@@ -272,6 +295,10 @@ module ramp_lt64w_lt64r
input [ 7:0] web, // write byte enable input [ 7:0] web, // write byte enable
input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram36_declare_init.vh"
`endif
localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR); localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR);
localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD); localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD);
localparam WIDTH_WR = 1 << LOG2WIDTH_WR; localparam WIDTH_WR = 1 << LOG2WIDTH_WR;
...@@ -324,6 +351,9 @@ module ramp_lt64w_lt64r ...@@ -324,6 +351,9 @@ module ramp_lt64w_lt64r
parameter IS_RSTREGARSTREG_INVERTED = 1'b0; parameter IS_RSTREGARSTREG_INVERTED = 1'b0;
parameter IS_RSTREGB_INVERTED = 1'b0; parameter IS_RSTREGB_INVERTED = 1'b0;
*/ */
`ifdef PRELOAD_BRAMS
`include "includes/ram36_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
...@@ -387,6 +417,9 @@ module ramp_lt64w_64r ...@@ -387,6 +417,9 @@ module ramp_lt64w_64r
input [ 7:0] web, // write byte enable input [ 7:0] web, // write byte enable
input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out input [(9 << (LOG2WIDTH_WR-3))-1:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram36_declare_init.vh"
`endif
localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR); localparam PWIDTH_WR = (LOG2WIDTH_WR > 2)? (9 << (LOG2WIDTH_WR - 3)): (1 << LOG2WIDTH_WR);
localparam PWIDTH_RD = 72; localparam PWIDTH_RD = 72;
localparam WIDTH_WR = 1 << LOG2WIDTH_WR; localparam WIDTH_WR = 1 << LOG2WIDTH_WR;
...@@ -420,6 +453,9 @@ module ramp_lt64w_64r ...@@ -420,6 +453,9 @@ module ramp_lt64w_64r
.EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry)
.EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry)
`ifdef PRELOAD_BRAMS
`include "includes/ram36_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
...@@ -482,6 +518,9 @@ module ramp_64w_lt64r ...@@ -482,6 +518,9 @@ module ramp_64w_lt64r
input [ 7:0] web, // write byte enable input [ 7:0] web, // write byte enable
input [71:0] data_in // data out input [71:0] data_in // data out
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram36_declare_init.vh"
`endif
localparam PWIDTH_WR = 72; localparam PWIDTH_WR = 72;
localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD); localparam PWIDTH_RD = (LOG2WIDTH_RD > 2)? (9 << (LOG2WIDTH_RD - 3)): (1 << LOG2WIDTH_RD);
localparam WIDTH_RD = 1 << LOG2WIDTH_RD; localparam WIDTH_RD = 1 << LOG2WIDTH_RD;
...@@ -511,6 +550,10 @@ module ramp_64w_lt64r ...@@ -511,6 +550,10 @@ module ramp_64w_lt64r
.EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry)
.EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry)
`ifdef PRELOAD_BRAMS
`include "includes/ram36_pass_init.vh"
`endif
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
......
...@@ -102,7 +102,9 @@ module ramt_var_w_var_r ...@@ -102,7 +102,9 @@ module ramt_var_w_var_r
output [(1 << LOG2WIDTH_B)-1:0] data_out_b,// data out port B output [(1 << LOG2WIDTH_B)-1:0] data_out_b,// data out port B
input [(1 << LOG2WIDTH_B)-1:0] data_in_b // data in port B input [(1 << LOG2WIDTH_B)-1:0] data_in_b // data in port B
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram36_declare_init.vh"
`endif
localparam PWIDTH_A = (LOG2WIDTH_A > 2)? (9 << (LOG2WIDTH_A - 3)): (1 << LOG2WIDTH_A); localparam PWIDTH_A = (LOG2WIDTH_A > 2)? (9 << (LOG2WIDTH_A - 3)): (1 << LOG2WIDTH_A);
localparam PWIDTH_B = (LOG2WIDTH_B > 2)? (9 << (LOG2WIDTH_B - 3)): (1 << LOG2WIDTH_B); localparam PWIDTH_B = (LOG2WIDTH_B > 2)? (9 << (LOG2WIDTH_B - 3)): (1 << LOG2WIDTH_B);
localparam WIDTH_A = 1 << LOG2WIDTH_A; localparam WIDTH_A = 1 << LOG2WIDTH_A;
...@@ -143,20 +145,9 @@ module ramt_var_w_var_r ...@@ -143,20 +145,9 @@ module ramt_var_w_var_r
.EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry)
.EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry)
// .INIT_A(36'h0), // Output latches initialization data `ifdef PRELOAD_BRAMS
// .INIT_B(36'h0), // Output latches initialization data `include "includes/ram36_pass_init.vh"
// .SRVAL_A(36'h0), // Output latches initialization data (copied at when RSTRAM/RSTREG activated) `endif
// .SRVAL_B(36'h0) // Output latches initialization data (copied at when RSTRAM/RSTREG activated)
/*
parameter IS_CLKARDCLK_INVERTED = 1'b0;
parameter IS_CLKBWRCLK_INVERTED = 1'b0;
parameter IS_ENARDEN_INVERTED = 1'b0;
parameter IS_ENBWREN_INVERTED = 1'b0;
parameter IS_RSTRAMARSTRAM_INVERTED = 1'b0;
parameter IS_RSTRAMB_INVERTED = 1'b0;
parameter IS_RSTREGARSTREG_INVERTED = 1'b0;
parameter IS_RSTREGB_INVERTED = 1'b0;
*/
) RAMB36E1_i ) RAMB36E1_i
( (
......
...@@ -102,7 +102,9 @@ module ramtp_var_w_var_r ...@@ -102,7 +102,9 @@ module ramtp_var_w_var_r
output [(9 << (LOG2WIDTH_B-3))-1:0] data_out_b,// data out port B output [(9 << (LOG2WIDTH_B-3))-1:0] data_out_b,// data out port B
input [(9 << (LOG2WIDTH_B-3))-1:0] data_in_b // data in port B input [(9 << (LOG2WIDTH_B-3))-1:0] data_in_b // data in port B
); );
`ifdef PRELOAD_BRAMS
`include "includes/ram36_declare_init.vh"
`endif
localparam PWIDTH_A = (LOG2WIDTH_A > 2)? (9 << (LOG2WIDTH_A - 3)): (1 << LOG2WIDTH_A); localparam PWIDTH_A = (LOG2WIDTH_A > 2)? (9 << (LOG2WIDTH_A - 3)): (1 << LOG2WIDTH_A);
localparam PWIDTH_B = (LOG2WIDTH_B > 2)? (9 << (LOG2WIDTH_B - 3)): (1 << LOG2WIDTH_B); localparam PWIDTH_B = (LOG2WIDTH_B > 2)? (9 << (LOG2WIDTH_B - 3)): (1 << LOG2WIDTH_B);
localparam WIDTH_A = 1 << LOG2WIDTH_A; localparam WIDTH_A = 1 << LOG2WIDTH_A;
...@@ -151,21 +153,9 @@ module ramtp_var_w_var_r ...@@ -151,21 +153,9 @@ module ramtp_var_w_var_r
.EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_READ ("FALSE"), // Valid:"FALSE","TRUE" (ECC decoder circuitry)
.EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry) .EN_ECC_WRITE ("FALSE") // Valid:"FALSE","TRUE" (ECC decoder circuitry)
// .INIT_A(36'h0), // Output latches initialization data `ifdef PRELOAD_BRAMS
// .INIT_B(36'h0), // Output latches initialization data `include "includes/ram36_pass_init.vh"
// .SRVAL_A(36'h0), // Output latches initialization data (copied at when RSTRAM/RSTREG activated) `endif
// .SRVAL_B(36'h0) // Output latches initialization data (copied at when RSTRAM/RSTREG activated)
/*
parameter IS_CLKARDCLK_INVERTED = 1'b0;
parameter IS_CLKBWRCLK_INVERTED = 1'b0;
parameter IS_ENARDEN_INVERTED = 1'b0;
parameter IS_ENBWREN_INVERTED = 1'b0;
parameter IS_RSTRAMARSTRAM_INVERTED = 1'b0;
parameter IS_RSTRAMB_INVERTED = 1'b0;
parameter IS_RSTREGARSTREG_INVERTED = 1'b0;
parameter IS_RSTREGB_INVERTED = 1'b0;
*/
) RAMB36E1_i ) RAMB36E1_i
( (
// Port A (Read port in SDP mode): // Port A (Read port in SDP mode):
......
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