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/*
* Copyright © <2010>, Intel Corporation.
*
* This program is licensed under the terms and conditions of the
* Eclipse Public License (EPL), version 1.0. The full text of the EPL is at
* http://www.opensource.org/licenses/eclipse-1.0.php.
*
*/
////////// AVC LDB filter vertical Mbaff UV ///////////////////////////////////////////////////////
//
// This filter code prepares the src data and control data for ILDB filtering on all vertical edges of UV.
//
// It sssumes the data for vertical de-blocking is already transposed.
//
// Chroma:
//
// +-------+-------+
// | | |
// | | |
// | | |
// +-------+-------+
// | | |
// | | |
// | | |
// +-------+-------+
//
// V0 V1
// Edge Edge
//
/////////////////////////////////////////////////////////////////////////////
#if defined(_DEBUG)
mov (1) EntrySignatureC:w 0xBBBC:w
#endif
//=============== Chroma deblocking ================
//---------- Deblock U external left edge ----------
and.z.f0.0 (1) null:w r[ECM_AddrReg, BitFlags]:ub FilterLeftMbEdgeFlag:w // Check for FilterLeftMbEdgeFlag
cmp.z.f0.1 (1) null:w VertEdgePattern:uw LEFT_FIELD_CUR_FRAME:w
// Get Luma maskA and maskB
shr (16) TempRow0(0)<1> r[ECM_AddrReg, wEdgeCntlMapA_ExtLeftVert0]<0;1,0>:uw RRampW(0)
shr (16) TempRow1(0)<1> r[ECM_AddrReg, wEdgeCntlMapB_ExtLeftVert0]<0;1,0>:uw RRampW(0)
(f0.0) jmpi BYPASS_V0_UV // Do not deblock Left ext edge
cmp.z.f0.0 (1) null:w VertEdgePattern:uw LEFT_FRAME_CUR_FIELD:w
(-f0.1) jmpi V0_U_NEXT1 // Jump if not LEFT_FIELD_CUR_FRAME
//----- For LEFT_FIELD_CUR_FRAME
// Extract UV MaskA and MaskB from every other 2 bits of Y masks
and.nz.f0.0 (8) null:w TempRow0(0)<4;2,1> 1:w
and.nz.f0.1 (8) null:w TempRow1(0)<4;2,1> 1:w
// For FieldModeLeftMbFlag=1 && FieldModeCurrentMbFlag=0
mov (4) Mbaff_ALPHA(0,0)<2> r[ECM_AddrReg, bAlphaLeft0_Cb]<0;1,0>:ub { NoDDClr }
mov (4) Mbaff_ALPHA(0,1)<2> r[ECM_AddrReg, bAlphaLeft1_Cb]<0;1,0>:ub { NoDDChk }
mov (4) Mbaff_BETA(0,0)<2> r[ECM_AddrReg, bBetaLeft0_Cb]<0;1,0>:ub { NoDDClr }
mov (4) Mbaff_BETA(0,1)<2> r[ECM_AddrReg, bBetaLeft1_Cb]<0;1,0>:ub { NoDDChk }
mov (4) Mbaff_TC0(0,0)<2> r[ECM_AddrReg, bTc0_v00_0_Cb]<4;4,1>:ub { NoDDClr }
mov (4) Mbaff_TC0(0,1)<2> r[ECM_AddrReg, bTc0_v00_1_Cb]<4;4,1>:ub { NoDDChk }
jmpi V0_U_NEXT3
V0_U_NEXT1:
(-f0.0) jmpi V0_U_NEXT2 // Jump if not LEFT_FRAME_CUR_FIELD
//----- For LEFT_FRAME_CUR_FIELD
// Extract UV MaskA and MaskB from every other bit of Y masks
and.nz.f0.0 (8) null:w TempRow0(0)<16;8,2> 1:w
and.nz.f0.1 (8) null:w TempRow1(0)<16;8,2> 1:w
// For FieldModeLeftMbFlag=0 && FieldModeCurrentMbFlag=1
mov (4) Mbaff_ALPHA(0,0)<1> r[ECM_AddrReg, bAlphaLeft0_Cb]<0;1,0>:ub { NoDDClr }
mov (4) Mbaff_ALPHA(0,4)<1> r[ECM_AddrReg, bAlphaLeft1_Cb]<0;1,0>:ub { NoDDChk }
mov (4) Mbaff_BETA(0,0)<1> r[ECM_AddrReg, bBetaLeft0_Cb]<0;1,0>:ub { NoDDClr }
mov (4) Mbaff_BETA(0,4)<1> r[ECM_AddrReg, bBetaLeft1_Cb]<0;1,0>:ub { NoDDChk }
mov (4) Mbaff_TC0(0,0)<1> r[ECM_AddrReg, bTc0_v00_0_Cb]<4;4,1>:ub { NoDDClr }
mov (4) Mbaff_TC0(0,4)<1> r[ECM_AddrReg, bTc0_v00_1_Cb]<4;4,1>:ub { NoDDChk }
jmpi V0_U_NEXT3
V0_U_NEXT2:
// Extract UV MaskA and MaskB from every other bit of Y masks
and.nz.f0.0 (8) null:w TempRow0(0)<16;8,2> 1:w
and.nz.f0.1 (8) null:w TempRow1(0)<16;8,2> 1:w
// Both are frames or fields
mov (8) Mbaff_ALPHA(0,0)<1> r[ECM_AddrReg, bAlphaLeft0_Cb]<0;1,0>:ub
mov (8) Mbaff_BETA(0,0)<1> r[ECM_AddrReg, bBetaLeft0_Cb]<0;1,0>:ub
mov (8) Mbaff_TC0(0,0)<1> r[ECM_AddrReg, bTc0_v00_0_Cb]<1;2,0>:ub
V0_U_NEXT3:
// p1 = Prev MB U row 0
// p0 = Prev MB U row 1
// q0 = Cur MB U row 0
// q1 = Cur MB U row 1
mov (1) P_AddrReg:w PREV_MB_U_BASE:w { NoDDClr }
mov (1) Q_AddrReg:w SRC_MB_U_BASE:w { NoDDChk }
// Store UV MaskA and MaskB
mov (2) MaskA<1>:uw f0.0<2;2,1>:uw
CALL(FILTER_UV_MBAFF, 1)
//-----------------------------------------------
//---------- Deblock V external left edge ----------
// No change to MaskA and MaskB
cmp.z.f0.0 (4) null:w VertEdgePattern:uw LEFT_FIELD_CUR_FRAME:w
cmp.z.f0.1 (4) null:w VertEdgePattern:uw LEFT_FRAME_CUR_FIELD:w
// both are frame or field
mov (8) Mbaff_ALPHA(0,0)<1> r[ECM_AddrReg, bAlphaLeft0_Cr]<0;1,0>:ub
mov (8) Mbaff_BETA(0,0)<1> r[ECM_AddrReg, bBetaLeft0_Cr]<0;1,0>:ub
mov (8) Mbaff_TC0(0,0)<1> r[ECM_AddrReg, bTc0_v00_0_Cr]<1;2,0>:ub
// p1 = Prev MB V row 0
// p0 = Prev MB V row 1
// q0 = Cur MB V row 0
// q1 = Cur MB V row 1
mov (1) P_AddrReg:w PREV_MB_V_BASE:w { NoDDClr }
mov (1) Q_AddrReg:w SRC_MB_V_BASE:w { NoDDChk }
// For FieldModeLeftMbFlag=1 && FieldModeCurrentMbFlag=0
(f0.0) mov (4) Mbaff_ALPHA(0,0)<2> r[ECM_AddrReg, bAlphaLeft0_Cr]<0;1,0>:ub { NoDDClr }
(f0.0) mov (4) Mbaff_ALPHA(0,1)<2> r[ECM_AddrReg, bAlphaLeft1_Cr]<0;1,0>:ub { NoDDChk }
(f0.0) mov (4) Mbaff_BETA(0,0)<2> r[ECM_AddrReg, bBetaLeft0_Cr]<0;1,0>:ub { NoDDClr }
(f0.0) mov (4) Mbaff_BETA(0,1)<2> r[ECM_AddrReg, bBetaLeft1_Cr]<0;1,0>:ub { NoDDChk }
(f0.0) mov (4) Mbaff_TC0(0,0)<2> r[ECM_AddrReg, bTc0_v00_0_Cr]<4;4,1>:ub { NoDDClr }
(f0.0) mov (4) Mbaff_TC0(0,1)<2> r[ECM_AddrReg, bTc0_v00_1_Cr]<4;4,1>:ub { NoDDChk }
// For FieldModeLeftMbFlag=0 && FieldModeCurrentMbFlag=1
(f0.1) mov (4) Mbaff_ALPHA(0,0)<1> r[ECM_AddrReg, bAlphaLeft0_Cr]<0;1,0>:ub { NoDDClr }
(f0.1) mov (4) Mbaff_ALPHA(0,4)<1> r[ECM_AddrReg, bAlphaLeft1_Cr]<0;1,0>:ub { NoDDChk }
(f0.1) mov (4) Mbaff_BETA(0,0)<1> r[ECM_AddrReg, bBetaLeft0_Cr]<0;1,0>:ub { NoDDClr }
(f0.1) mov (4) Mbaff_BETA(0,4)<1> r[ECM_AddrReg, bBetaLeft1_Cr]<0;1,0>:ub { NoDDChk }
(f0.1) mov (4) Mbaff_TC0(0,0)<1> r[ECM_AddrReg, bTc0_v00_0_Cr]<4;4,1>:ub { NoDDClr }
(f0.1) mov (4) Mbaff_TC0(0,4)<1> r[ECM_AddrReg, bTc0_v00_1_Cr]<4;4,1>:ub { NoDDChk }
// Set UV MaskA and MaskB
mov (2) f0.0<1>:uw MaskA<2;2,1>:uw
CALL(FILTER_UV_MBAFF, 1)
//-----------------------------------------------
BYPASS_V0_UV:
// Set EdgeCntlMap2 = 0, so it always uses bS < 4 algorithm.
// Same alpha and beta for all internal vert and horiz edges
//---------- Deblock U internal vert middle edge ----------
//***** Need to take every other bit to form U or V maskA
shr (16) TempRow0(0)<1> r[ECM_AddrReg, wEdgeCntlMap_IntMidVert]<0;1,0>:uw RRampW(0)
// p1 = Cur MB U row 2
// p0 = Cur MB U row 3
// q0 = Cur MB U row 4
// q1 = Cur MB U row 5
mov (1) P_AddrReg:w 4*UV_ROW_WIDTH+SRC_MB_U_BASE:w { NoDDClr } // Skip 2 U rows and 2 V rows
mov (1) Q_AddrReg:w 8*UV_ROW_WIDTH+SRC_MB_U_BASE:w { NoDDChk }
mov (8) Mbaff_ALPHA(0,0)<1> r[ECM_AddrReg, bAlphaInternal_Cb]<0;1,0>:ub
mov (8) Mbaff_BETA(0,0)<1> r[ECM_AddrReg, bBetaInternal_Cb]<0;1,0>:ub
mov (8) Mbaff_TC0(0,0)<1> r[ECM_AddrReg, bTc0_v02_Cb]<1;2,0>:ub
and.nz.f0.0 (8) null:w TempRow0(0)<16;8,2> 1:w
// Store MaskA and MaskB
mov (1) f0.1:uw 0:w
mov (1) MaskB:uw 0:w { NoDDClr }
mov (1) MaskA:uw f0.0:uw { NoDDChk }
CALL(FILTER_UV_MBAFF, 1)
//-----------------------------------------------
//---------- Deblock V internal vert middle edge ----------
// P1 = Cur MB V row 2
// P0 = Cur MB V row 3
// Q0 = Cur MB V row 4
// Q1 = Cur MB V row 5
mov (1) P_AddrReg:w 4*UV_ROW_WIDTH+SRC_MB_V_BASE:w { NoDDClr } // Skip 2 U rows and 2 V rows
mov (1) Q_AddrReg:w 8*UV_ROW_WIDTH+SRC_MB_V_BASE:w { NoDDChk }
// Put MaskA into f0.0
// Put MaskB into f0.1
mov (2) f0.0<1>:uw MaskA<2;2,1>:uw
mov (8) Mbaff_ALPHA(0,0)<1> r[ECM_AddrReg, bAlphaInternal_Cr]<0;1,0>:ub
mov (8) Mbaff_BETA(0,0)<1> r[ECM_AddrReg, bBetaInternal_Cr]<0;1,0>:ub
mov (8) Mbaff_TC0(0,0)<1> r[ECM_AddrReg, bTc0_v02_Cr]<1;2,0>:ub
CALL(FILTER_UV_MBAFF, 1)
//-----------------------------------------------
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