/* $NoKeywords:$ */ /** * @file * * PCIe late post initialization. * * * * @xrefitem bom "File Content Label" "Release Content" * @e project: AGESA * @e sub-project: GNB * @e \$Revision: 63425 $ @e \$Date: 2011-12-22 11:24:10 -0600 (Thu, 22 Dec 2011) $ * */ /* ***************************************************************************** * * Copyright (c) 2008 - 2012, Advanced Micro Devices, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Advanced Micro Devices, Inc. nor the names of * its contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL ADVANCED MICRO DEVICES, INC. BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * *************************************************************************** * */ /*---------------------------------------------------------------------------------------- * M O D U L E S U S E D *---------------------------------------------------------------------------------------- */ #include "AGESA.h" #include "Ids.h" #include "amdlib.h" #include "Gnb.h" #include "GnbGfx.h" #include "GnbTable.h" #include "GnbPcieConfig.h" #include "GnbCommonLib.h" #include "GnbGfxInitLibV1.h" #include "GnbGfxConfig.h" #include "GnbGfxFamServices.h" #include "GfxLibTN.h" #include "GnbRegistersTN.h" #include "GnbInitTN.h" #include "GnbRegisterAccTN.h" #include "GnbHandleLib.h" #include "GnbTimerLib.h" #include "cpuFamilyTranslation.h" #include "OptionGnb.h" #include "Filecode.h" #define FILECODE PROC_GNB_MODULES_GNBINITTN_GFXENVINITTN_FILECODE /*---------------------------------------------------------------------------------------- * D E F I N I T I O N S A N D M A C R O S *---------------------------------------------------------------------------------------- */ extern GNB_TABLE ROMDATA GfxEnvInitTableTN[]; extern GNB_BUILD_OPTIONS GnbBuildOptions; /*---------------------------------------------------------------------------------------- * T Y P E D E F S A N D S T R U C T U R E S *---------------------------------------------------------------------------------------- */ /*---------------------------------------------------------------------------------------- * P R O T O T Y P E S O F L O C A L F U N C T I O N S *---------------------------------------------------------------------------------------- */ AGESA_STATUS GfxEnvInterfaceTN ( IN AMD_CONFIG_PARAMS *StdHeader ); /*----------------------------------------------------------------------------------------*/ /** * Shut Down Disabled SIMDs * * @param[in] Property GNB property * @param[in] Gfx Pointer to global GFX configuration * @retval AGESA_STATUS */ STATIC AGESA_STATUS GfxShutDownDisabledSimdsTN ( IN UINT32 Property, IN GFX_PLATFORM_CONFIG *Gfx ) { ex1006_STRUCT ex1006 ; ex1009_STRUCT ex1009; D0F0xBC_xE03002F8_STRUCT D0F0xBC_xE03002F8; D0F0xBC_xE03002FC_STRUCT D0F0xBC_xE03002FC; D0F0xBC_xE0300054_STRUCT GfxChainPgfsmConfig; UINT8 n; UINT32 Mask; CPU_LOGICAL_ID LogicalId; GNB_HANDLE *GnbHandle; IDS_HDT_CONSOLE (GNB_TRACE, "GfxShutDownDisabledSimdsTN Enter\n"); GnbHandle = GnbGetHandle (GnbLibGetHeader (Gfx)); ASSERT (GnbHandle != NULL); GetLogicalIdOfSocket (GnbGetSocketId (GnbHandle), &LogicalId, GnbLibGetHeader (Gfx)); GfxChainPgfsmConfig.Value = 0; GfxChainPgfsmConfig.Field.PowerDown = 1; GfxChainPgfsmConfig.Field.P2Select = 1; GfxChainPgfsmConfig.Field.FsmAddr = 0xFF; //Step 1: Read fuse to see which SIMD(s) have been disabled GnbRegisterReadTN (TYPE_D0F0xBC , 0xe000101c , &ex1006.Value, 0, GnbLibGetHeader (Gfx)); //Step 2: Check which SIMD has been disabled for (n = 0; n < 6; n++) { if (((Property & TABLE_PROPERTY_IGFX_DISABLED) != 0) || ((ex1006.Field.ex1006_0 >> n) & 0x1)) { IDS_HDT_CONSOLE (GNB_TRACE, "Disable SIMD %d\n", n); //Step 3: Make sure PGFSM has been programmed in GFX Power Island. //Step 4: Make sure SCLK frequency is below 400Mhz //Step 5: Enable PGFSM clock GnbRegisterReadTN (TYPE_D0F0xBC , 0xe0300328 , &ex1009.Value, 0, GnbLibGetHeader (Gfx)); ex1009.Value |= (0x1 << (0 + n)); GnbRegisterWriteTN (TYPE_D0F0xBC , 0xe0300328 , &ex1009.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); //Step 6 GnbRegisterWriteTN (TYPE_D0F0xBC, (D0F0xBC_xE0300054_ADDRESS + (n * 0x1C)), &GfxChainPgfsmConfig.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); //Step 7 Mask = (UINT32) (0x1F << (n * 5)); do { GnbRegisterReadTN (D0F0xBC_xE03002F8_TYPE, D0F0xBC_xE03002F8_ADDRESS, &D0F0xBC_xE03002F8.Value, 0, GnbLibGetHeader (Gfx)); } while ((D0F0xBC_xE03002F8.Value & Mask )!= 0); //Step 8: Restore previous SCLK divider if ((LogicalId.Revision & 0x0000000000000100ull ) != 0x0000000000000100ull ) { do { GnbRegisterReadTN (D0F0xBC_xE03002FC_TYPE, D0F0xBC_xE03002FC_ADDRESS, &D0F0xBC_xE03002FC.Value, 0, GnbLibGetHeader (Gfx)); } while ((D0F0xBC_xE03002FC.Value & Mask )!= Mask); } else { } //Step 10: Turn off PGFSM clock GnbRegisterReadTN (TYPE_D0F0xBC , 0xe0300328 , &ex1009.Value, 0, GnbLibGetHeader (Gfx)); ex1009.Value &= (~ (UINT64) (0x1 << (0 + n))); GnbRegisterWriteTN (TYPE_D0F0xBC , 0xe0300328 , &ex1009.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); } } IDS_HDT_CONSOLE (GNB_TRACE, "GfxShutDownDisabledSimdsTN Exit\n"); return AGESA_SUCCESS; } /*----------------------------------------------------------------------------------------*/ /** * Shut Down Disabled SIMDs * * * @param[in] Gfx Pointer to global GFX configuration * @retval AGESA_STATUS */ STATIC AGESA_STATUS GfxShutDownDisabledRbsTN ( IN GFX_PLATFORM_CONFIG *Gfx ) { ex1006_STRUCT ex1006 ; D0F0xBC_xE0003024_STRUCT D0F0xBC_xE0003024; D0F0xBC_xE03000FC_STRUCT D0F0xBC_xE03000FC; D0F0xBC_xE0300100_STRUCT D0F0xBC_xE0300100; ex1009_STRUCT ex1009 ; D0F0xBC_xE03002F4_STRUCT D0F0xBC_xE03002F4; D0F0xBC_xE03002E4_STRUCT D0F0xBC_xE03002E4; UINT8 i; UINT8 RbNumber; UINT32 Mask1; UINT32 Mask2; D0F0xBC_xE03000FC.Value = 0; D0F0xBC_xE03000FC.Field.WriteOp = 1; IDS_HDT_CONSOLE (GNB_TRACE, "GfxShutDownDisabledRbsTN Enter\n"); //Step 1: Read fuse to see which SIMD(s) have been disabled GnbRegisterReadTN (TYPE_D0F0xBC , 0xe000101c , &ex1006.Value, 0, GnbLibGetHeader (Gfx)); //Step 2: Power down disabled RB if (ex1006.Field.ex1006_1 == 0x1) { RbNumber = 0; Mask1 = 0x3FFFA; Mask2 = 0x5; } else if (ex1006.Field.ex1006_1 == 0x2) { RbNumber = 1; Mask1 = 0x3FFF5; Mask2 = 0xA; } else { return AGESA_SUCCESS; } //Step 3: Enable PGFSM commands during reset GnbRegisterReadTN (D0F0xBC_xE0003024_TYPE, D0F0xBC_xE0003024_ADDRESS, &D0F0xBC_xE0003024.Value, 0, GnbLibGetHeader (Gfx)); D0F0xBC_xE0003024.Value |= 0x1; GnbRegisterWriteTN (D0F0xBC_xE0003024_TYPE, D0F0xBC_xE0003024_ADDRESS, &D0F0xBC_xE0003024.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); //Step 4: Make sure PGFSM has been programmed before sending power down command. //CB0 = 0, DB0 = 2, CB1 = 1, DB1 = 3 for (i = RbNumber; i < 4; i += 2) { D0F0xBC_xE0300100.Value = (5 << 16 ) | (4 << 8 ) | (10 << 0 ); //reg0 GnbRegisterWriteTN (D0F0xBC_xE0300100_TYPE, D0F0xBC_xE0300100_ADDRESS, &D0F0xBC_xE0300100.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); D0F0xBC_xE03000FC.Field.FsmAddr = i; D0F0xBC_xE03000FC.Field.RegAddr = 2 ; GnbRegisterWriteTN (D0F0xBC_xE03000FC_TYPE, D0F0xBC_xE03000FC_ADDRESS, &D0F0xBC_xE03000FC.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); GnbLibStallS3Save (1, GnbLibGetHeader (Gfx)); D0F0xBC_xE0300100.Value = (50 << 0 ) | (50 << 12 ); //reg1 GnbRegisterWriteTN (D0F0xBC_xE0300100_TYPE, D0F0xBC_xE0300100_ADDRESS, &D0F0xBC_xE0300100.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); D0F0xBC_xE03000FC.Field.RegAddr = 3 ; GnbRegisterWriteTN (D0F0xBC_xE03000FC_TYPE, D0F0xBC_xE03000FC_ADDRESS, &D0F0xBC_xE03000FC.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); GnbLibStallS3Save (1, GnbLibGetHeader (Gfx)); D0F0xBC_xE0300100.Value = 0; //control GnbRegisterWriteTN (D0F0xBC_xE0300100_TYPE, D0F0xBC_xE0300100_ADDRESS, &D0F0xBC_xE0300100.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); D0F0xBC_xE03000FC.Field.RegAddr = 1 ; GnbRegisterWriteTN (D0F0xBC_xE03000FC_TYPE, D0F0xBC_xE03000FC_ADDRESS, &D0F0xBC_xE03000FC.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); GnbLibStallS3Save (1, GnbLibGetHeader (Gfx)); } //Step 5: Make sure SCLK frequency is below 400Mhz //Step 6: Enable PGFSM clock GnbRegisterReadTN (TYPE_D0F0xBC , 0xe0300328 , &ex1009.Value, 0, GnbLibGetHeader (Gfx)); ex1009.Field.ex1009_1 = 1; GnbRegisterWriteTN (TYPE_D0F0xBC , 0xe0300328 , &ex1009.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); //Step 7 D0F0xBC_xE03000FC.Value = 0; D0F0xBC_xE03000FC.Field.PowerDown = 1; D0F0xBC_xE03000FC.Field.P1Select = 1; D0F0xBC_xE03000FC.Field.P2Select = 1; D0F0xBC_xE03000FC.Field.FsmAddr = RbNumber; GnbRegisterWriteTN (D0F0xBC_xE03000FC_TYPE, D0F0xBC_xE03000FC_ADDRESS, &D0F0xBC_xE03000FC.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); GnbLibStallS3Save (1, GnbLibGetHeader (Gfx)); //Step 8 D0F0xBC_xE03000FC.Field.FsmAddr = RbNumber + 1; GnbRegisterWriteTN (D0F0xBC_xE03000FC_TYPE, D0F0xBC_xE03000FC_ADDRESS, &D0F0xBC_xE03000FC.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); GnbLibStallS3Save (1, GnbLibGetHeader (Gfx)); //Step 9: Wait for isolation to be asserted for RB0/RB1 do { GnbRegisterReadTN (D0F0xBC_xE03002F4_TYPE, D0F0xBC_xE03002F4_ADDRESS, &D0F0xBC_xE03002F4.Value, 0, GnbLibGetHeader (Gfx)); } while ((D0F0xBC_xE03002F4.Value & Mask1 )!= 0); //Step 10: Restore previous SCLK divider //Step 11: Wait for PSO daughter to be asserted for RB0/RB1 do { GnbRegisterReadTN (D0F0xBC_xE03002E4_TYPE, D0F0xBC_xE03002E4_ADDRESS, &D0F0xBC_xE03002E4.Value, 0, GnbLibGetHeader (Gfx)); } while ((D0F0xBC_xE03002E4.Value & Mask2 )!= Mask2); //Step 12: Set PGFSM power up override bits so SMU will not power up disabled RB D0F0xBC_xE0300100.Value = 0x3 << 11; D0F0xBC_xE03000FC.Value = 0; D0F0xBC_xE03000FC.Field.RegAddr = 1 ; GnbRegisterWriteTN (D0F0xBC_xE0300100_TYPE, D0F0xBC_xE0300100_ADDRESS, &D0F0xBC_xE0300100.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); D0F0xBC_xE03000FC.Field.FsmAddr = RbNumber; GnbRegisterWriteTN (D0F0xBC_xE03000FC_TYPE, D0F0xBC_xE03000FC_ADDRESS, &D0F0xBC_xE03000FC.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); GnbLibStallS3Save (1, GnbLibGetHeader (Gfx)); D0F0xBC_xE03000FC.Field.FsmAddr = RbNumber + 1; GnbRegisterWriteTN (D0F0xBC_xE03000FC_TYPE, D0F0xBC_xE03000FC_ADDRESS, &D0F0xBC_xE03000FC.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); GnbLibStallS3Save (1, GnbLibGetHeader (Gfx)); //Step 13: Turn off PGFSM clock GnbRegisterReadTN (TYPE_D0F0xBC , 0xe0300328 , &ex1009.Value, 0, GnbLibGetHeader (Gfx)); ex1009.Field.ex1009_1 = 1; GnbRegisterWriteTN (TYPE_D0F0xBC , 0xe0300328 , &ex1009.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); //Step 14: Disable PGFSM commands during reset GnbRegisterReadTN (D0F0xBC_xE0003024_TYPE, D0F0xBC_xE0003024_ADDRESS, &D0F0xBC_xE0003024.Value, 0, GnbLibGetHeader (Gfx)); D0F0xBC_xE0003024.Value &= 0xFFFFFFFE; GnbRegisterWriteTN (D0F0xBC_xE0003024_TYPE, D0F0xBC_xE0003024_ADDRESS, &D0F0xBC_xE0003024.Value, GNB_REG_ACC_FLAG_S3SAVE, GnbLibGetHeader (Gfx)); IDS_HDT_CONSOLE (GNB_TRACE, "GfxShutDownDisabledRbsTN Exit\n"); return AGESA_SUCCESS; } /*----------------------------------------------------------------------------------------*/ /** * Initialize GFX straps. * * * @param[in] Gfx Pointer to global GFX configuration * @retval AGESA_STATUS */ STATIC AGESA_STATUS GfxEnvInitTN ( IN GFX_PLATFORM_CONFIG *Gfx ) { D0F0x64_x1C_STRUCT D0F0x64_x1C; D0F0x64_x1D_STRUCT D0F0x64_x1D; IDS_HDT_CONSOLE (GNB_TRACE, "GfxEnvInitTN Enter\n"); GnbLibPciIndirectRead ( GNB_SBDFO | D0F0x60_ADDRESS, D0F0x64_x1C_ADDRESS | IOC_WRITE_ENABLE, AccessWidth32, &D0F0x64_x1C.Value, GnbLibGetHeader (Gfx) ); GnbLibPciIndirectRead ( GNB_SBDFO | D0F0x60_ADDRESS, D0F0x64_x1D_ADDRESS | IOC_WRITE_ENABLE, AccessWidth32, &D0F0x64_x1D.Value, GnbLibGetHeader (Gfx) ); D0F0x64_x1C.Field.AudioNonlegacyDeviceTypeEn = 0x0; D0F0x64_x1C.Field.F0NonlegacyDeviceTypeEn = 0x0; D0F0x64_x1D.Field.IntGfxAsPcieEn = 0x1; D0F0x64_x1C.Field.RcieEn = 0x1; D0F0x64_x1D.Field.VgaEn = 0x1; D0F0x64_x1C.Field.AudioEn = Gfx->GnbHdAudio; D0F0x64_x1C.Field.F0En = 0x1; D0F0x64_x1C.Field.RegApSize = 0x1; if (Gfx->UmaInfo.UmaSize > 128 * 0x100000) { D0F0x64_x1C.Field.MemApSize = 0x1; } else if (Gfx->UmaInfo.UmaSize > 64 * 0x100000) { D0F0x64_x1C.Field.MemApSize = 0x0; } else if (Gfx->UmaInfo.UmaSize > 32 * 0x100000) { D0F0x64_x1C.Field.MemApSize = 0x2; } else { D0F0x64_x1C.Field.MemApSize = 0x3; } GnbLibPciIndirectWrite ( GNB_SBDFO | D0F0x60_ADDRESS, D0F0x64_x1D_ADDRESS | IOC_WRITE_ENABLE, AccessS3SaveWidth32, &D0F0x64_x1D.Value, GnbLibGetHeader (Gfx) ); GnbLibPciIndirectWrite ( GNB_SBDFO | D0F0x60_ADDRESS, D0F0x64_x1C_ADDRESS | IOC_WRITE_ENABLE, AccessS3SaveWidth32, &D0F0x64_x1C.Value, GnbLibGetHeader (Gfx) ); D0F0x64_x1C.Field.WriteDis = 0x1; GnbLibPciIndirectWrite ( GNB_SBDFO | D0F0x60_ADDRESS, D0F0x64_x1C_ADDRESS | IOC_WRITE_ENABLE, AccessS3SaveWidth32, &D0F0x64_x1C.Value, GnbLibGetHeader (Gfx) ); IDS_HDT_CONSOLE (GNB_TRACE, "GfxEnvInitTN Exit\n"); return AGESA_SUCCESS; } /*----------------------------------------------------------------------------------------*/ /** * Init GFX at Env Post. * * * * @param[in] StdHeader Standard configuration header * @retval AGESA_STATUS */ AGESA_STATUS GfxEnvInterfaceTN ( IN AMD_CONFIG_PARAMS *StdHeader ) { AGESA_STATUS Status; AGESA_STATUS AgesaStatus; GFX_PLATFORM_CONFIG *Gfx; GNB_HANDLE *GnbHandle; UINT32 Property; BOOLEAN ShutDownDisabledSimd; BOOLEAN ShutDownDisabledRb; UINT8 SclkDid; IDS_HDT_CONSOLE (GNB_TRACE, "GfxEnvInterfaceTN Enter\n"); AgesaStatus = AGESA_SUCCESS; Property = TABLE_PROPERTY_DEAFULT; ShutDownDisabledSimd = GnbBuildOptions.CfgUnusedSimdPowerGatingEnable; ShutDownDisabledRb = GnbBuildOptions.CfgUnusedRbPowerGatingEnable; Status = GfxLocateConfigData (StdHeader, &Gfx); AGESA_STATUS_UPDATE (Status, AgesaStatus); if (Status == AGESA_SUCCESS) { if (Gfx->UmaInfo.UmaMode != UMA_NONE) { Status = GfxEnvInitTN (Gfx); AGESA_STATUS_UPDATE (Status, AgesaStatus); ASSERT (Status == AGESA_SUCCESS); } else { GfxFmDisableController (StdHeader); Property |= TABLE_PROPERTY_IGFX_DISABLED; } } else { GfxFmDisableController (StdHeader); Property |= TABLE_PROPERTY_IGFX_DISABLED; } // // Set sclk to 100Mhz // SclkDid = GfxRequestSclkTNS3Save ( GfxLibCalculateDidTN (98 * 100, StdHeader), StdHeader ); GnbHandle = GnbGetHandle (StdHeader); ASSERT (GnbHandle != NULL); Status = GnbProcessTable ( GnbHandle, GfxEnvInitTableTN, Property, GNB_TABLE_FLAGS_FORCE_S3_SAVE, StdHeader ); AGESA_STATUS_UPDATE (Status, AgesaStatus); if (ShutDownDisabledSimd == TRUE) { GfxShutDownDisabledSimdsTN (Property, Gfx); } if ((Property & TABLE_PROPERTY_IGFX_DISABLED) != 0) { if (ShutDownDisabledRb == TRUE) { GfxShutDownDisabledRbsTN (Gfx); } } // // Restore Sclk // GfxRequestSclkTNS3Save ( SclkDid, StdHeader ); IDS_HDT_CONSOLE (GNB_TRACE, "GfxEnvInterfaceTN Exit [0x%x]\n", AgesaStatus); return Status; }