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/********************************************************************************** Theia, Ray Cast Programable graphic Processing Unit. Copyright (C) 2010 Diego Valverde (diego.valverde.g@gmail.com) This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. ***********************************************************************************/ /********************************************************************************** Description: This is the top level block for THEIA. THEIA core has 5 main logical blocks called Units. This module implements the interconections between the Units. Units: > EXE: Mananges execution logic for the SHADERS. > GEO: Manages geometry data structures. > IO: Input/Output (Wishbone). > MEM: Internal memory, separate for Instructions and data. > CONTROL: Main control Finite state machine. Internal Buses: THEIA has separate instruction and data buses. THEIA avoids using tri-state buses by having separate input/output for each bus. There are 2 separate data buses since the Data memory has a Dual read channel. Please see the MEM unit chapter in the documentation for more details. External Buses: External buses are managed by the IO Unit. External buses follow the wishbone protocol. Please see the IO unit chapter in the documentation for more details. **********************************************************************************/ `timescale 1ns / 1ps `include "aDefinitions.v" `ifdef VERILATOR `include "Unit_Control.v" `include "Unit_MEM.v" `include "Unit_EXE.v" `include "Unit_IO.v" `endif module THEIACORE ( input wire CLK_I, //Input clock input wire RST_I, //Input reset //Theia Interfaces input wire MST_I, //Master signal, THEIA enters configuration mode //when this gets asserted (see documentation) //Wish Bone Interface input wire [`WB_WIDTH-1:0] DAT_I, //Input data bus (Wishbone) output wire [`WB_WIDTH-1:0] DAT_O, //Output data bus (Wishbone) input wire ACK_I, //Input ack output wire ACK_O, //Output ack output wire [`WB_WIDTH-1:0] ADR_O, //Output address input wire [`WB_WIDTH-1:0] ADR_I, //Input address output wire WE_O, //Output write enable input wire WE_I, //Input write enable output wire STB_O, //Strobe signal, see wishbone documentation input wire STB_I, //Strobe signal, see wishbone documentation output wire CYC_O, //Bus cycle signal, see wishbone documentation input wire CYC_I, //Bus cycle signal, see wishbone documentation output wire [1:0] TGC_O, //Bus cycle tag, see THEAI documentation input wire [1:0] TGA_I, //Input address tag, see THEAI documentation output wire [1:0] TGA_O, //Output address tag, see THEAI documentation input wire [1:0] TGC_I, //Bus cycle tag, see THEAI documentation input wire GNT_I, //Bus arbiter 'Granted' signal, see THEAI documentation input wire RENDREN_I, output wire HDL_O, //Data Latched input wire HDLACK_I, //Data Latched ACK input wire STDONE_I, //Scene traverse complete input wire HDA_I, output wire RCOMMIT_O, output wire [`WB_WIDTH-1:0] OMEM_DAT_O, output wire [`WB_WIDTH-1:0] OMEM_ADR_O, output wire OMEM_WE_O, input wire TMEM_ACK_I, input wire [`WB_WIDTH-1:0] TMEM_DAT_I , output wire [`WB_WIDTH-1:0] TMEM_ADR_O , output wire TMEM_WE_O, output wire TMEM_STB_O, output wire TMEM_CYC_O, input wire TMEM_GNT_I, `ifdef DEBUG input wire[`MAX_CORES-1:0] iDebug_CoreID, `endif //Control Register input wire [15:0] CREG_I, output wire DONE_O ); //When we flip the SMEM, this means we are ready to receive more data //Alias this signals wire Clock,Reset; assign Clock = CLK_I; assign Reset = RST_I; wire wIO_Busy; wire [`DATA_ROW_WIDTH-1:0] wEXE_2__MEM_WriteData; wire [`DATA_ROW_WIDTH-1:0] wUCODE_RAMBus; wire [`DATA_ADDRESS_WIDTH-1:0] wEXE_2__MEM_wDataWriteAddress; wire w2IO__AddrIsImm; wire [`DATA_ADDRESS_WIDTH-1:0] wUCODE_RAMAddress; wire [`DATA_ADDRESS_WIDTH-1:0] w2IO__Adr_O_Pointer; wire [`DATA_ADDRESS_WIDTH-1:0] wGEO2_IO__Adr_O_Pointer; wire wEXE_2__DataWriteEnable; wire wUCODE_RAMWriteEnable; //wire [2:0] RamBusOwner; //Unit intercoanection wires wire wCU2__MicrocodeExecutionDone; wire [`ROM_ADDRESS_WIDTH-1:0] InitialCodeAddress; wire [`ROM_ADDRESS_WIDTH-1:0] wInstructionPointer1,wInstructionPointer2; wire [`INSTRUCTION_WIDTH-1:0] wEncodedInstruction1,wEncodedInstruction2,wIO2_MEM__ExternalInstruction; wire wCU2__ExecuteMicroCode; wire [`ROM_ADDRESS_WIDTH-1:0] wIO2_MEM__InstructionWriteAddr; wire [95:0] wMEM_2__EXE_DataRead0, wMEM_2__EXE_DataRead1,wMEM_2__IO_DataRead0, wMEM_2__IO_DataRead1; wire [`DATA_ADDRESS_WIDTH-1:0] wEXE_2__MEM_DataReadAddress0,wEXE_2__MEM_DataReadAddress1; wire [`DATA_ADDRESS_WIDTH-1:0] wUCODE_RAMReadAddress0,wUCODE_RAMReadAddress1; wire [`WIDTH-1:0] w2IO__AddressOffset; wire [`DATA_ADDRESS_WIDTH-1:0] w2IO__DataWriteAddress; wire w2IO__Store; wire w2IO__EnableWBMaster; wire [`DATA_ADDRESS_WIDTH-1:0] wIO2_MEM__DataWriteAddress; wire [`DATA_ADDRESS_WIDTH-1:0] wIO_2_MEM__DataReadAddress0; wire [`DATA_ROW_WIDTH-1:0] wIO2_MEM__Bus; wire [`WIDTH-1:0] wIO2_MEM__Data; wire [`WIDTH-1:0] wIO2_WBM__Address; wire wIO2_MEM__DataWriteEnable; wire wIO2__Done; wire wCU2_GEO__GeometryFetchEnable; wire wIFU2__MicroCodeReturnValue; wire wCU2_BCU__ACK; wire wGEO2_CU__RequestAABBIU; wire wGEO2_CU__RequestBIU; wire wGEO2_CU__RequestTCC; wire wGEO2_CU__GeometryUnitDone; wire wGEO2_CU__Sync; wire wEXE2__uCodeDone; wire wEXE2_IFU__EXEBusy; wire [`DATA_ADDRESS_WIDTH-1:0] wEXE2_IDU_DataFordward_LastDestination; wire wALU2_EXE__BranchTaken; wire wALU2_IFU_BranchNotTaken; wire w2IO__SetAddress; wire wIDU2_IFU__IDUBusy; //Control Registe wires wire[15:0] wCR2_ControlRegister; wire wCR2_TextureMappingEnabled; wire wGEO2_CU__TFFDone; wire wCU2_GEO__TriggerTFF; wire wIO2_MEM_InstructionWriteEnable; wire wCU2_IO__WritePixel; wire wGEO2_IO__AddrIsImm; wire[31:0] wGEO2_IO__AddressOffset; wire wGEO2_IO__EnableWBMaster; wire wGEO2_IO__SetAddress; wire[`WIDTH-1:0] wGEO2__CurrentPitch,wCU2_GEO_Pitch; wire wCU2_GEO__SetPitch,wCU2_GEO__IncPicth; wire [`DATA_ROW_WIDTH-1:0] wEXE_2__IO_WriteAddress; wire [`DATA_ROW_WIDTH-1:0] wEXE_2__IO_WriteData; wire wEXE_2__IO_OMEMWriteEnable; wire [`DATA_ROW_WIDTH-1:0] wEXE_2__IO_TMEMAddress; wire [`DATA_ROW_WIDTH-1:0] wIO_2_EXE__TMEMData; wire wIO_2_EXE__DataAvailable; wire wEXE_2_IO__DataRequest; wire wCU2_FlipMem; wire wCU2_FlipMemEnabled; wire w2MEM_FlipMemory; wire wGEO2__RequestingTextures; wire w2IO_WriteBack_Set; wire[`DATA_ADDRESS_WIDTH-1:0] wIO_2_MEM__DataReadAddress1; `ifdef DEBUG wire [`ROM_ADDRESS_WIDTH-1:0] wDEBUG_IDU2_EXE_InstructionPointer; `endif //-------------------------------------------------------- assign HDL_O = wCU2_FlipMem; assign wCR2_TextureMappingEnabled = wCR2_ControlRegister[ `CR_EN_TEXTURE ]; //-------------------------------------------------------- //Control Unit Instance ControlUnit CU ( .Clock(Clock), .Reset(Reset), .oFlipMemEnabled( wCU2_FlipMemEnabled ), .oFlipMem( wCU2_FlipMem ), .iControlRegister( wCR2_ControlRegister ), //.oRamBusOwner( RamBusOwner ), .oGFUEnable( wCU2_GEO__GeometryFetchEnable ), .iTriggerAABBIURequest( wGEO2_CU__RequestAABBIU ), .iTriggerBIURequest( wGEO2_CU__RequestBIU ), .iTriggertTCCRequest( wGEO2_CU__RequestTCC ), .oUCodeEnable( wCU2__ExecuteMicroCode ), .oCodeInstructioPointer( InitialCodeAddress ), .iUCodeDone( wCU2__MicrocodeExecutionDone ), .iIODone( wIO2__Done ), .oIOWritePixel( wCU2_IO__WritePixel ), .iUCodeReturnValue( wIFU2__MicroCodeReturnValue ), .iGEOSync( wGEO2_CU__Sync ), .iTFFDone( wGEO2_CU__TFFDone ), .oTriggerTFF( wCU2_GEO__TriggerTFF ), .MST_I( MST_I ), .oSetCurrentPitch( wCU2_GEO__SetPitch ), .iGFUDone( wGEO2_CU__GeometryUnitDone ), .iRenderEnable( RENDREN_I ), .iSceneTraverseComplete( STDONE_I ), .oResultCommited( RCOMMIT_O ), .iHostDataAvailable( HDA_I ), .iHostAckDataRead( HDLACK_I ), `ifdef DEBUG .iDebug_CoreID( iDebug_CoreID ), `endif .oDone( DONE_O ) ); //-------------------------------------------------------- //assign w2MEM_FlipMemory = (wCU2__ExecuteMicroCode | wCU2_FlipMem ) & wCU2_FlipMemEnabled; assign w2MEM_FlipMemory = wCU2_FlipMem & wCU2_FlipMemEnabled; MemoryUnit MEM ( .Clock(Clock), .Reset(Reset), .iFlipMemory( w2MEM_FlipMemory ), //Data Bus to/from EXE .iDataReadAddress1_EXE( wEXE_2__MEM_DataReadAddress0 ), .iDataReadAddress2_EXE( wEXE_2__MEM_DataReadAddress1 ), .oData1_EXE( wMEM_2__EXE_DataRead0 ), .oData2_EXE( wMEM_2__EXE_DataRead1 ), .iDataWriteEnable_EXE( wEXE_2__DataWriteEnable ), .iDataWriteAddress_EXE( wEXE_2__MEM_wDataWriteAddress ), .iData_EXE( wEXE_2__MEM_WriteData ), //Data Bus to/from IO .iDataReadAddress1_IO( wIO_2_MEM__DataReadAddress0 ), .iDataReadAddress2_IO( wIO_2_MEM__DataReadAddress1 ), .oData1_IO( wMEM_2__IO_DataRead0 ), .oData2_IO( wMEM_2__IO_DataRead1 ), .iDataWriteEnable_IO( wIO2_MEM__DataWriteEnable ), .iDataWriteAddress_IO( wIO2_MEM__DataWriteAddress ), .iData_IO( wIO2_MEM__Bus ), `ifdef DEBUG .iDebug_CoreID( iDebug_CoreID ), `endif //Instruction Bus .iInstructionReadAddress1( wInstructionPointer1 ), .iInstructionReadAddress2( wInstructionPointer2 ), .oInstruction1( wEncodedInstruction1 ), .oInstruction2( wEncodedInstruction2 ), .iInstructionWriteEnable( wIO2_MEM_InstructionWriteEnable ), .iInstructionWriteAddress( wIO2_MEM__InstructionWriteAddr ), .iInstruction( wIO2_MEM__ExternalInstruction ), .iControlRegister( CREG_I ), .oControlRegister( wCR2_ControlRegister ) ); ////-------------------------------------------------------- ExecutionUnit EXE ( .Clock( Clock), .Reset( Reset ), .iInitialCodeAddress( InitialCodeAddress ), .iInstruction1( wEncodedInstruction1 ), .iInstruction2( wEncodedInstruction2 ), .oInstructionPointer1( wInstructionPointer1 ), .oInstructionPointer2( wInstructionPointer2 ), .iDataRead0( wMEM_2__EXE_DataRead0 ), .iDataRead1( wMEM_2__EXE_DataRead1 ), .iTrigger( wCU2__ExecuteMicroCode ), .oDataReadAddress0( wEXE_2__MEM_DataReadAddress0 ), .oDataReadAddress1( wEXE_2__MEM_DataReadAddress1 ), .oDataWriteEnable( wEXE_2__DataWriteEnable ), .oDataWriteAddress( wEXE_2__MEM_wDataWriteAddress ), .oDataBus( wEXE_2__MEM_WriteData ), .oReturnCode( wIFU2__MicroCodeReturnValue ), /**************/ .oOMEMWriteAddress( wEXE_2__IO_WriteAddress ), .oOMEMWriteData( wEXE_2__IO_WriteData ), .oOMEMWriteEnable( wEXE_2__IO_OMEMWriteEnable ), .oTMEMReadAddress( wEXE_2__IO_TMEMAddress ), .iTMEMReadData( wIO_2_EXE__TMEMData ), .iTMEMDataAvailable( wIO_2_EXE__DataAvailable ), .oTMEMDataRequest( wEXE_2_IO__DataRequest ), /**************/ `ifdef DEBUG .iDebug_CoreID( iDebug_CoreID ), `endif .oDone( wCU2__MicrocodeExecutionDone ) ); ////-------------------------------------------------------- assign TGA_O = (wGEO2__RequestingTextures) ? 2'b1: 2'b0; //--------------------------------------------------------------------------------------------------- //assign wEXE_2__MEM_DataReadAddress1 = (wCU2_IO__WritePixel == 0) ? wUCODE_RAMReadAddress1 : wIO_2_MEM__DataReadAddress1; assign w2IO__EnableWBMaster = (wCU2_IO__WritePixel == 0 ) ? wGEO2_IO__EnableWBMaster : wCU2_IO__WritePixel; assign w2IO__AddrIsImm = 0;//(wCU2_IO__WritePixel == 0 ) ? wGEO2_IO__AddrIsImm : 1'b0; assign w2IO__AddressOffset = 0;//(wCU2_IO__WritePixel == 0 ) ? wGEO2_IO__AddressOffset : 32'b0; assign w2IO__Adr_O_Pointer = (wCU2_IO__WritePixel == 0 ) ? wGEO2_IO__Adr_O_Pointer : `OREG_ADDR_O; //assign w2IO__Adr_O_Pointer = (wCU2_IO__WritePixel == 0 ) ? wGEO2_IO__Adr_O_Pointer : `CREG_PIXEL_2D_INITIAL_POSITION; wire w2IO_MasterCycleType; assign w2IO_MasterCycleType = (wCU2_IO__WritePixel) ? `WB_SIMPLE_WRITE_CYCLE : `WB_SIMPLE_READ_CYCLE; assign w2IO__SetAddress = (wCU2_IO__WritePixel == 0 )? wGEO2_IO__SetAddress : wCU2_GEO__SetPitch; IO_Unit IO ( .Clock( Clock ), .Reset( Reset ), .iEnable( 1'b0 ),// w2IO__EnableWBMaster ), .iBusCyc_Type( w2IO_MasterCycleType ), .iStore( 1'b1),//w2IO__Store ), .iAdr_DataWriteBack( w2IO__DataWriteAddress ), .iAdr_O_Set( w2IO__SetAddress ), .iAdr_O_Imm( w2IO__AddressOffset ), .iAdr_O_Type( w2IO__AddrIsImm ), .iAdr_O_Pointer( w2IO__Adr_O_Pointer ), .iReadDataBus( wMEM_2__IO_DataRead0 ), .iReadDataBus2( wMEM_2__IO_DataRead1 ), .iDat_O_Pointer( `OREG_PIXEL_COLOR ), .oDataReadAddress( wIO_2_MEM__DataReadAddress0 ), .oDataReadAddress2( wIO_2_MEM__DataReadAddress1 ), .oDataWriteAddress( wIO2_MEM__DataWriteAddress ), .oDataBus( wIO2_MEM__Bus ), .oInstructionBus( wIO2_MEM__ExternalInstruction ), .oDataWriteEnable( wIO2_MEM__DataWriteEnable ), .oData( wIO2_MEM__Data ), .oInstructionWriteEnable( wIO2_MEM_InstructionWriteEnable ), .oInstructionWriteAddress( wIO2_MEM__InstructionWriteAddr ), .iWriteBack_Set( w2IO_WriteBack_Set ), .oBusy( wIO_Busy ), .oDone( wIO2__Done ), /**********/ .iOMEM_WriteAddress( wEXE_2__IO_WriteAddress ), .iOMEM_WriteData( wEXE_2__IO_WriteData ), .iOMEM_WriteEnable( wEXE_2__IO_OMEMWriteEnable ), .OMEM_DAT_O( OMEM_DAT_O ), .OMEM_ADR_O( OMEM_ADR_O ), .OMEM_WE_O( OMEM_WE_O ), .oTMEMReadData( wIO_2_EXE__TMEMData ), .iTMEMDataRequest( wEXE_2_IO__DataRequest ), .iTMEMReadAddress( wEXE_2__IO_TMEMAddress ), .oTMEMDataAvailable( wIO_2_EXE__DataAvailable ), .TMEM_ACK_I( TMEM_ACK_I ), .TMEM_DAT_I( TMEM_DAT_I ), .TMEM_ADR_O( TMEM_ADR_O ), .TMEM_WE_O( TMEM_WE_O ), .TMEM_STB_O( TMEM_STB_O ), .TMEM_CYC_O( TMEM_CYC_O ), .TMEM_GNT_I( TMEM_GNT_I ), /**********/ .MST_I( MST_I ), //Wish Bone Interface .DAT_I( DAT_I ), .DAT_O( DAT_O ), .ACK_I( ACK_I & GNT_I ), .ACK_O( ACK_O ), .ADR_O( ADR_O ), .ADR_I( ADR_I ), .WE_O( WE_O ), .WE_I( WE_I ), .STB_O( STB_O ), .STB_I( STB_I ), .CYC_O( CYC_O ), .TGA_I( TGA_I ), .CYC_I( CYC_I ), .GNT_I( GNT_I ), .TGC_O( TGC_O ) ); //--------------------------------------------------------------------------------------------------- endmodule
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