tc_frac.v
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/**************************************************************************
* *
* Copyright (C) 1994, Silicon Graphics, Inc. *
* *
* These coded instructions, statements, and computer programs contain *
* unpublished proprietary information of Silicon Graphics, Inc., and *
* are protected by Federal copyright law. They may not be disclosed *
* to third parties or copied or duplicated in any form, in whole or *
* in part, without the prior written consent of Silicon Graphics, Inc. *
* *
*************************************************************************/
// $Id: tc_frac.v,v 1.1 2002/03/28 00:26:13 berndt Exp $
////////////////////////////////////////////////////////////////////////
//
// Project Reality
//
// module: tc_frac
// description: Texture coordinate fraction module.
// Determine tile coordinate fractions for RG and
// BA Tmem halves.
//
// designer: Tony DeLaurier
// date: 7/5/94
//
////////////////////////////////////////////////////////////////////////
module tc_frac (gclk, s_frac, t_frac, copy_1d, yuv_tex, a_byte, tlut_en,
s_frac_ba_out, t_frac_ba_out, s_frac_rg_out, t_frac_rg_out,
swap_ba_1d, swap_rg_1d);
input gclk; // RDP gated clock
input [4:0] s_frac; // s fraction
input [4:0] t_frac; // t fraction
input copy_1d; // copy delayed 1 cycle
input yuv_tex; // tile texel type is yuv
input a_byte; // byte bit of texel address A
input tlut_en; // enable texture lookup table
output [7:0] s_frac_ba_out; // s interp fraction to filter (BA)
wire [7:0] s_frac_ba_out; // s interp fraction to filter (BA)
output [7:0] t_frac_ba_out; // t interp fraction to filter (BA)
wire [7:0] t_frac_ba_out; // t interp fraction to filter (BA)
output [7:0] s_frac_rg_out; // s interp fraction to filter (RG)
wire [7:0] s_frac_rg_out; // s interp fraction to filter (RG)
output [7:0] t_frac_rg_out; // t interp fraction to filter (RG)
wire [7:0] t_frac_rg_out; // t interp fraction to filter (RG)
output swap_ba_1d; // swap texels (BA) delayed 1 cycle
reg swap_ba_1d; // swap texels (BA) delayed 1 cycle
output swap_rg_1d; // swap texels (RG) delayed 1 cycle
reg swap_rg_1d; // swap texels (RG) delayed 1 cycle
reg copy_2d; // copy delayed 2 cycles
reg swap_ba; // swap texels (BA)
reg swap_rg; // swap texels (RG)
reg [4:0] t_frac_tc; // 2's comp of t_frac
reg [4:0] s_frac_mod; // modified s fraction
reg [7:3] s_frac_ba; // s interp fraction to filter (BA)
reg [7:3] s_frac_ba_1d; // s_frac_ba delayed 1
reg [7:3] s_frac_ba_2d; // s_frac_ba delayed 2
reg [7:3] s_frac_ba_3d; // s_frac_ba delayed 3
reg [7:3] s_frac_ba_dly; // s_frac_ba delayed 1 or 3
reg [7:3] t_frac_ba; // t interp fraction to filter (BA)
reg [7:3] t_frac_ba_1d; // t_frac_ba delayed 1
reg [7:3] t_frac_ba_2d; // t_frac_ba delayed 2
reg [7:3] t_frac_ba_3d; // t_frac_ba delayed 3
reg [7:3] t_frac_ba_dly; // t_frac_ba delayed 1 or 3
reg [7:3] s_frac_rg; // s interp fraction to filter (RG)
reg [7:3] s_frac_rg_1d; // s_frac_rg delayed 1
reg [7:3] s_frac_rg_2d; // s_frac_rg delayed 2
reg [7:3] s_frac_rg_3d; // s_frac_rg delayed 3
reg [7:3] s_frac_rg_dly; // s_frac_rg delayed 1 or 3
reg [7:3] t_frac_rg; // t interp fraction to filter (RG)
reg [7:3] t_frac_rg_1d; // t_frac_rg delayed 1
reg [7:3] t_frac_rg_2d; // t_frac_rg delayed 2
reg [7:3] t_frac_rg_3d; // t_frac_rg delayed 3
reg [7:3] t_frac_rg_dly; // t_frac_rg delayed 1 or 3
reg tlut_en_1d; // tlut_en delayed 1
reg tlut_en_2d; // tlut_en delayed 2
wire [6:0] one = 6'h20; // 1.0
always @(posedge gclk)
begin
// delay tlut_en by 2 cycles
tlut_en_1d <= tlut_en;
tlut_en_2d <= tlut_en_1d;
// delay copy_1d by 1 cycle
copy_2d <= copy_1d;
// determine whether in upper or lower half of texel interval (BA)
swap_ba = ((s_frac[4:0] + t_frac[4:0]) >= one) && !copy_2d;
// determine s_frac_ba
s_frac_ba[7:3] <= swap_ba ? -s_frac[4:0] : s_frac[4:0];
s_frac_ba_1d <= s_frac_ba;
s_frac_ba_2d <= s_frac_ba_1d;
s_frac_ba_3d <= s_frac_ba_2d;
s_frac_ba_dly <= tlut_en_2d ? s_frac_ba_3d : s_frac_ba_1d;
// determine 2's comp of t_frac
t_frac_tc[4:0] = -t_frac[4:0];
// determine t_frac_ba
t_frac_ba[7:3] <= swap_ba ? t_frac_tc[4:0] : t_frac[4:0];
t_frac_ba_1d <= t_frac_ba;
t_frac_ba_2d <= t_frac_ba_1d;
t_frac_ba_3d <= t_frac_ba_2d;
t_frac_ba_dly <= tlut_en_2d ? t_frac_ba_3d : t_frac_ba_1d;
// determine s_frac_mod
s_frac_mod[4:0] = yuv_tex ? {a_byte, s_frac[4:1]} : s_frac[4:0];
// determine swap_rg
swap_rg = ((s_frac_mod[4:0] + t_frac[4:0]) >= one) && !copy_2d;
// determine s_frac_rg
s_frac_rg[7:3] <= swap_rg ? -s_frac_mod[4:0] : s_frac_mod[4:0];
s_frac_rg_1d <= s_frac_rg;
s_frac_rg_2d <= s_frac_rg_1d;
s_frac_rg_3d <= s_frac_rg_2d;
s_frac_rg_dly <= tlut_en_2d ? s_frac_rg_3d : s_frac_rg_1d;
// determine t_frac_rg
t_frac_rg[7:3] <= swap_rg ? t_frac_tc[4:0] : t_frac[4:0];
t_frac_rg_1d <= t_frac_rg;
t_frac_rg_2d <= t_frac_rg_1d;
t_frac_rg_3d <= t_frac_rg_2d;
t_frac_rg_dly <= tlut_en_2d ? t_frac_rg_3d : t_frac_rg_1d;
// delay swap flags and output
swap_ba_1d <= swap_ba;
swap_rg_1d <= swap_rg;
end // always
assign s_frac_ba_out = {s_frac_ba_dly, 3'b0};
assign t_frac_ba_out = {t_frac_ba_dly, 3'b0};
assign s_frac_rg_out = {s_frac_rg_dly, 3'b0};
assign t_frac_rg_out = {t_frac_rg_dly, 3'b0};
endmodule // tc_frac