/* * This file is part of the coreboot project. * * Copyright (C) 2007 Advanced Micro Devices, Inc. * * 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; version 2 of the License. * * 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. */ /* * This file initializes the CPU cores for voltage and frequency settings * in the different power states. */ /* checklist (functions are in this file if no source file named) Fam10 Bios and Kernel Development Guide #31116, rev 3.48, April 22, 2010 2.4.2.6 Requirements for p-states 1.- F3x[84:80] According to table 100 : prep_fid_change 2.- COF/VID : 2.4.2.9.1 Steps 1,3-6 and warning for 2,7 if they apply fixPsNbVidBeforeWR(...) 2.4.2.9.1 Step 8 enable_fid_change We do this for all nodes, I don't understand BKDG 100% on whether this is or isn't meant by "on the local processor". Must be OK. 2.4.2.9.1 Steps 9-10 (repeat 1-7 and reset) romstage.c/init_cpus ? 2.4.2.9.1 Steps 11-12 init_fidvid_stage2 2.4.2.9.2 DualPlane PVI : Not supported, don't know how to detect, needs specific circuitry. 3.- 2.4.2.7 dualPlaneOnly(dev) 4.- 2.4.2.8 applyBoostFIDOffset(dev) 5.- enableNbPState1(dev) 6.- 2.4.1.7 a) UpdateSinglePlaneNbVid() b) setVSRamp(), called from prep_fid_change c) prep_fid_change d) improperly, for lack of voltage regulator details?, F3xA0[PsiVidEn] in defaults.h F3xA0[PsiVid] in init_cpus.c AMD_SetupPSIVID_d (before prep_fid_change) 7.- TODO (Core Performance Boost is only available in revision E cpus, and we don't seem to support those yet, at least they don't have any constant in amddefs.h ) 8.- FIXME ? Transition to min Pstate according to 2.4.2.15.3 is required by 2.4.2.6 after warm reset. But 2.4.2.15 states that it is not required if the warm reset is issued by coreboot to update NbFid. So it is required or not ? How can I tell who issued warm reset ? Coreboot transitions to P0 instead, which is not recommended, and does not follow 2.4.2.15.2 to do so. 9.- TODO Requires information on current delivery capability (depends on mainboard and maybe power supply ?). One might use a config option with the maximum number of Amperes that the board can deliver to CPU. 10.- [Multiprocessor] TODO 2.4.2.12 [Uniprocessor] FIXME ? We call setPStateMaxVal() in init_fidvid_stage2, but not sure this is what is meant by "Determine the valid set of P-states based on enabled P-states indicated in MSRC001_00[68:64][PstateEn]" in 2.4.2.6-10 11.- finalPstateChange() from init_fidvid_Stage2 (BKDG says just "may", anyway) 12.- generate ACPI for p-states. generated in powernow_acpi.c amd_generate_powernow() "must also be completed" a.- PllLockTime set in ruleset in defaults.h BKDG says set it "If MSRC001_00[68:64][CpuFid] is different between any two enabled P-states", but since it does not say "only if" I guess it is safe to do it always. b.- prep_fid_change(...) */ #if CONFIG_SET_FIDVID #include static inline void print_debug_fv(const char *str, u32 val) { #if CONFIG_SET_FIDVID_DEBUG printk(BIOS_DEBUG, "%s%x\n", str, val); #endif } static inline void print_debug_fv_8(const char *str, u8 val) { #if CONFIG_SET_FIDVID_DEBUG printk(BIOS_DEBUG, "%s%02x\n", str, val); #endif } static inline void print_debug_fv_64(const char *str, u32 val, u32 val2) { #if CONFIG_SET_FIDVID_DEBUG printk(BIOS_DEBUG, "%s%x%x\n", str, val, val2); #endif } struct fidvid_st { u32 common_fid; }; static void enable_fid_change(u8 fid) { u32 dword; u32 nodes; device_t dev; int i; nodes = get_nodes(); for (i = 0; i < nodes; i++) { dev = NODE_PCI(i, 3); dword = pci_read_config32(dev, 0xd4); dword &= ~0x1F; dword |= (u32) fid & 0x1F; dword |= 1 << 5; // enable pci_write_config32(dev, 0xd4, dword); printk(BIOS_DEBUG, "FID Change Node:%02x, F3xD4: %08x \n", i, dword); } } static void applyBoostFIDOffset( device_t dev ) { // BKDG 2.4.2.8 // revision E only, but E is apparently not supported yet, therefore untested if ((cpuid_edx(0x80000007) & CPB_MASK) && ((cpuid_ecx(0x80000008) & NC_MASK) ==5) ) { u32 core = get_node_core_id_x().coreid; u32 asymetricBoostThisCore = ((pci_read_config32(dev, 0x10C) >> (core*2))) & 3; msr_t msr = rdmsr(PS_REG_BASE); u32 cpuFid = msr.lo & PS_CPU_FID_MASK; cpuFid = cpuFid + asymetricBoostThisCore; msr.lo &= ~PS_CPU_FID_MASK; msr.lo |= cpuFid ; wrmsr(PS_REG_BASE , msr); } } static void enableNbPState1( device_t dev ) { u32 cpuRev = mctGetLogicalCPUID(0xFF); if (cpuRev & AMD_FAM10_C3) { u32 nbPState = (pci_read_config32(dev, 0x1F0) & NB_PSTATE_MASK); if ( nbPState){ u32 nbVid1 = (pci_read_config32(dev, 0x1F4) & NB_VID1_MASK) >> NB_VID1_SHIFT; u32 i; for (i = nbPState; i < NM_PS_REG; i++) { msr_t msr = rdmsr(PS_REG_BASE + i); if (msr.hi & PS_EN_MASK ) { msr.hi |= NB_DID_M_ON; msr.lo &= NB_VID_MASK_OFF; msr.lo |= ( nbVid1 << NB_VID_POS); wrmsr(PS_REG_BASE + i, msr); } } } } } static u8 setPStateMaxVal( device_t dev ) { u8 i,maxpstate=0; for (i = 0; i < NM_PS_REG; i++) { msr_t msr = rdmsr(PS_REG_BASE + i); if (msr.hi & PS_IDD_VALUE_MASK) { msr.hi |= PS_EN_MASK ; wrmsr(PS_REG_BASE + i, msr); } if (msr.hi & PS_EN_MASK) { maxpstate = i; } } //FIXME: CPTC2 and HTC_REG should get max per node, not per core ? u32 reg = pci_read_config32(dev, CPTC2); reg &= PS_MAX_VAL_MASK; reg |= (maxpstate << PS_MAX_VAL_POS); pci_write_config32(dev, CPTC2,reg); return maxpstate; } static void dualPlaneOnly( device_t dev ) { // BKDG 2.4.2.7 u32 cpuRev = mctGetLogicalCPUID(0xFF); if ((mctGetProcessorPackageType() == AMD_PKGTYPE_AM3_2r2) && (cpuRev & AMD_DR_Cx)) { // should be rev C or rev E but there's no constant for E if ( (pci_read_config32(dev, 0x1FC) & DUAL_PLANE_ONLY_MASK) && (pci_read_config32(dev, 0xA0) & PVI_MODE) ){ if (cpuid_edx(0x80000007) & CPB_MASK) { // revision E only, but E is apparently not supported yet, therefore untested msr_t minPstate = rdmsr(0xC0010065); wrmsr(0xC0010065, rdmsr(0xC0010068) ); wrmsr(0xC0010068,minPstate); } else { msr_t msr; msr.lo=0; msr.hi=0; wrmsr(0xC0010064, rdmsr(0xC0010068) ); wrmsr(0xC0010068, msr ); } //FIXME: CPTC2 and HTC_REG should get max per node, not per core ? u8 maxpstate = setPStateMaxVal(dev); u32 reg = pci_read_config32(dev, HTC_REG); reg &= HTC_PS_LMT_MASK; reg |= (maxpstate << PS_LIMIT_POS); pci_write_config32(dev, HTC_REG,reg); } } } static int vidTo100uV(u8 vid) {// returns voltage corresponding to vid in tenths of mV, i.e. hundreds of uV // BKDG #31116 rev 3.48 2.4.1.6 int voltage; if (vid >= 0x7c) { voltage = 0; } else { voltage = (15500 - (125*vid)); } return voltage; } static void setVSRamp(device_t dev) { /* BKDG r31116 2010-04-22 2.4.1.7 step b F3xD8[VSRampTime] * If this field accepts 8 values between 10 and 500 us why * does page 324 say "BIOS should set this field to 001b." * (20 us) ? * Shouldn't it depend on the voltage regulators, mainboard * or something ? */ u32 dword; dword = pci_read_config32(dev, 0xd8); dword &= VSRAMP_MASK; dword |= VSRAMP_VALUE; pci_write_config32(dev, 0xd8, dword); } static void recalculateVsSlamTimeSettingOnCorePre(device_t dev) { u8 pviModeFlag; u8 highVoltageVid, lowVoltageVid, bValue; u16 minimumSlamTime; u16 vSlamTimes[7] = { 1000, 2000, 3000, 4000, 6000, 10000, 20000 }; /* Reg settings scaled by 100 */ u32 dtemp; msr_t msr; /* This function calculates the VsSlamTime using the range of possible * voltages instead of a hardcoded 200us. * Note: his function is called only from prep_fid_change, * and that from init_cpus.c finalize_node_setup() * (after set AMD MSRs and init ht ) */ /* BKDG r31116 2010-04-22 2.4.1.7 step b F3xD8[VSSlamTime] */ /* Calculate Slam Time * Vslam = (mobileCPU?0.2:0.4)us/mV * (Vp0 - (lowest out of Vpmin or Valt)) mV * In our case, we will scale the values by 100 to avoid * decimals. */ /* Determine if this is a PVI or SVI system */ dtemp = pci_read_config32(dev, 0xA0); if (dtemp & PVI_MODE) pviModeFlag = 1; else pviModeFlag = 0; /* Get P0's voltage */ /* MSRC001_00[68:64] are not programmed yet when called from prep_fid_change, one might use F4x1[F0:E0] instead, but theoretically MSRC001_00[68:64] are equal to them after reset. */ msr = rdmsr(0xC0010064); highVoltageVid = (u8) ((msr.lo >> PS_CPU_VID_SHFT) & 0x7F); if (!(msr.hi & 0x80000000)) { printk(BIOS_ERR,"P-state info in MSRC001_0064 is invalid !!!\n"); highVoltageVid = (u8) ((pci_read_config32(dev, 0x1E0) >> PS_CPU_VID_SHFT) & 0x7F); } /* If SVI, we only care about CPU VID. * If PVI, determine the higher voltage b/t NB and CPU */ if (pviModeFlag) { bValue = (u8) ((msr.lo >> PS_NB_VID_SHFT) & 0x7F); if (highVoltageVid > bValue) highVoltageVid = bValue; } /* Get PSmax's index */ msr = rdmsr(0xC0010061); bValue = (u8) ((msr.lo >> PS_MAX_VAL_SHFT) & BIT_MASK_3); /* Get PSmax's VID */ msr = rdmsr(0xC0010064 + bValue); lowVoltageVid = (u8) ((msr.lo >> PS_CPU_VID_SHFT) & 0x7F); if (!(msr.hi & 0x80000000)) { printk(BIOS_ERR,"P-state info in MSR%8x is invalid !!!\n",0xC0010064 + bValue); lowVoltageVid = (u8) ((pci_read_config32(dev, 0x1E0+(bValue*4)) >> PS_CPU_VID_SHFT) & 0x7F); } /* If SVI, we only care about CPU VID. * If PVI, determine the higher voltage b/t NB and CPU * BKDG 2.4.1.7 (a) */ if (pviModeFlag) { bValue = (u8) ((msr.lo >> PS_NB_VID_SHFT) & 0x7F); if (lowVoltageVid > bValue) lowVoltageVid = bValue; } /* Get AltVID */ dtemp = pci_read_config32(dev, 0xDC); bValue = (u8) (dtemp & BIT_MASK_7); /* Use the VID with the lowest voltage (higher VID) */ if (lowVoltageVid < bValue) lowVoltageVid = bValue; u8 mobileFlag = get_platform_type() & AMD_PTYPE_MOB; minimumSlamTime = (mobileFlag?2:4) * (vidTo100uV(highVoltageVid) - vidTo100uV(lowVoltageVid)); /* * 0.01 us */ /* Now round up to nearest register setting. * Note that if we don't find a value, we * will fall through to a value of 7 */ for (bValue = 0; bValue < 7; bValue++) { if (minimumSlamTime <= vSlamTimes[bValue]) break; } /* Apply the value */ dtemp = pci_read_config32(dev, 0xD8); dtemp &= VSSLAM_MASK; dtemp |= bValue; pci_write_config32(dev, 0xd8, dtemp); } static u32 nb_clk_did(int node, u32 cpuRev,u8 procPkg) { u8 link0isGen3 = 0; u8 offset; if (AMD_CpuFindCapability(node, 0, &offset)) { link0isGen3 = (AMD_checkLinkType(node, 0, offset) & HTPHY_LINKTYPE_HT3 ); } /* FIXME: NB_CLKDID should be 101b for AMD_DA_C2 in package S1g3 in link Gen3 mode, but I don't know how to tell package S1g3 from S1g4 */ if ((cpuRev & AMD_DA_C2) && (procPkg & AMD_PKGTYPE_S1gX) && link0isGen3) { return 5 ; /* divide clk by 128*/ } else { return 4 ; /* divide clk by 16 */ } } static u32 power_up_down(int node, u8 procPkg) { u32 dword=0; /* from CPU rev guide #41322 rev 3.74 June 2010 Table 26 */ u8 singleLinkFlag = ((procPkg == AMD_PKGTYPE_AM3_2r2) || (procPkg == AMD_PKGTYPE_S1gX) || (procPkg == AMD_PKGTYPE_ASB2)); if (singleLinkFlag) { /* * PowerStepUp=01000b - 50nS * PowerStepDown=01000b - 50ns */ dword |= PW_STP_UP50 | PW_STP_DN50; } else { u32 dispRefModeEn = (pci_read_config32(NODE_PCI(node,0),0x68) >> 24) & 1; u32 isocEn = 0; int j; for(j=0 ; (j<4) && (!isocEn) ; j++ ) { u8 offset; if (AMD_CpuFindCapability(node, j, &offset)) { isocEn = (pci_read_config32(NODE_PCI(node,0),offset+4) >>12) & 1; } } if (dispRefModeEn || isocEn) { dword |= PW_STP_UP50 | PW_STP_DN50 ; } else { /* get number of cores for PowerStepUp & PowerStepDown in server 1 core - 400nS - 0000b 2 cores - 200nS - 0010b 3 cores - 133nS -> 100nS - 0011b 4 cores - 100nS - 0011b */ switch (get_core_num_in_bsp(node)) { case 0: dword |= PW_STP_UP400 | PW_STP_DN400; break; case 1: case 2: dword |= PW_STP_UP200 | PW_STP_DN200; break; case 3: dword |= PW_STP_UP100 | PW_STP_DN100; break; default: dword |= PW_STP_UP100 | PW_STP_DN100; break; } } } return dword; } static void config_clk_power_ctrl_reg0(int node, u32 cpuRev, u8 procPkg) { device_t dev = NODE_PCI(node, 3); /* Program fields in Clock Power/Control register0 (F3xD4) */ /* set F3xD4 Clock Power/Timing Control 0 Register * NbClkDidApplyAll=1b * NbClkDid=100b or 101b * PowerStepUp= "platform dependent" * PowerStepDown= "platform dependent" * LinkPllLink=01b * ClkRampHystCtl=HW default * ClkRampHystSel=1111b */ u32 dword= pci_read_config32(dev, 0xd4); dword &= CPTC0_MASK; dword |= NB_CLKDID_ALL | LNK_PLL_LOCK | CLK_RAMP_HYST_SEL_VAL; dword |= (nb_clk_did(node,cpuRev,procPkg) << NB_CLKDID_SHIFT); dword |= power_up_down(node, procPkg); pci_write_config32(dev, 0xd4, dword); } static void config_power_ctrl_misc_reg(device_t dev,u32 cpuRev, u8 procPkg) { /* check PVI/SVI */ u32 dword = pci_read_config32(dev, 0xA0); /* BKDG r31116 2010-04-22 2.4.1.7 step b F3xA0[VSSlamVidMod] */ /* PllLockTime and PsiVidEn set in ruleset in defaults.h */ if (dword & PVI_MODE) { /* PVI */ /* set slamVidMode to 0 for PVI */ dword &= VID_SLAM_OFF ; } else { /* SVI */ /* set slamVidMode to 1 for SVI */ dword |= VID_SLAM_ON; } /* set the rest of A0 since we're at it... */ if (cpuRev & (AMD_DA_Cx | AMD_RB_C3 )) { dword |= NB_PSTATE_FORCE_ON; } // else should we clear it ? if ((procPkg == AMD_PKGTYPE_G34) || (procPkg == AMD_PKGTYPE_C32) ) { dword |= BP_INS_TRI_EN_ON ; } /* TODO: look into C1E state and F3xA0[IdleExitEn]*/ #if CONFIG_SVI_HIGH_FREQ if (cpuRev & AMD_FAM10_C3) { dword |= SVI_HIGH_FREQ_ON; } #endif pci_write_config32(dev, 0xA0, dword); } static void config_nb_syn_ptr_adj(device_t dev, u32 cpuRev) { /* Note the following settings are additional from the ported * function setFidVidRegs() */ /* adjust FIFO between nb and core clocks to max allowed values (min latency) */ u32 nbPstate = pci_read_config32(dev,0x1f0) & NB_PSTATE_MASK; u8 nbSynPtrAdj; if ((cpuRev & (AMD_DR_Bx|AMD_DA_Cx) ) || ( (cpuRev & AMD_RB_C3) && (nbPstate!=0))) { nbSynPtrAdj = 5; } else { nbSynPtrAdj = 6; } u32 dword = pci_read_config32(dev, 0xDc); dword &= ~ NB_SYN_PTR_ADJ_MASK; dword |= nbSynPtrAdj << NB_SYN_PTR_ADJ_POS; /* NbsynPtrAdj set to 5 or 6 per BKDG (needs reset) */ pci_write_config32(dev, 0xdc, dword); } static void config_acpi_pwr_state_ctrl_regs(device_t dev, u32 cpuRev, u8 procPkg) { /* step 1, chapter 2.4.2.6 of AMD Fam 10 BKDG #31116 Rev 3.48 22.4.2010 */ u32 dword; u32 c1= 1; if (cpuRev & (AMD_DR_Bx)) { // will coreboot ever enable cache scrubbing ? // if it does, will it be enough to check the current state // or should we configure for what we'll set up later ? dword = pci_read_config32(dev, 0x58); u32 scrubbingCache = dword & ( (0x1F << 16) // DCacheScrub | (0x1F << 8) ); // L2Scrub if (scrubbingCache) { c1 = 0x80; } else { c1 = 0xA0; } } else { // rev C or later // same doubt as cache scrubbing: ok to check current state ? dword = pci_read_config32(dev, 0xDC); u32 cacheFlushOnHalt = dword & (7 << 16); if (!cacheFlushOnHalt) { c1 = 0x80; } } dword = (c1 << 24) | (0xE641E6); pci_write_config32(dev, 0x84, dword); /* FIXME: BKDG Table 100 says if the link is at a Gen1 frequency and the chipset does not support a 10us minimum LDTSTOP assertion time, then { If ASB2 && SVI then smaf001 = F6h else smaf001=87h. } else ... I hardly know what it means or how to check it from here, so I bluntly assume it is false and code here the else, which is easier */ u32 smaf001 = 0xE6; if (cpuRev & AMD_DR_Bx ) { smaf001 = 0xA6; } else { #if CONFIG_SVI_HIGH_FREQ if (cpuRev & (AMD_RB_C3 | AMD_DA_C3)) { smaf001 = 0xF6; } #endif } u32 fidvidChange = 0; if (((cpuRev & AMD_DA_Cx) && (procPkg & AMD_PKGTYPE_S1gX)) || (cpuRev & AMD_RB_C3) ) { fidvidChange=0x0B; } dword = (0xE6 << 24) | (fidvidChange << 16) | (smaf001 << 8) | 0x81; pci_write_config32(dev, 0x80, dword); } static void prep_fid_change(void) { u32 dword; u32 nodes; device_t dev; int i; /* This needs to be run before any Pstate changes are requested */ nodes = get_nodes(); for (i = 0; i < nodes; i++) { printk(BIOS_DEBUG, "Prep FID/VID Node:%02x \n", i); dev = NODE_PCI(i, 3); u32 cpuRev = mctGetLogicalCPUID(0xFF) ; u8 procPkg = mctGetProcessorPackageType(); setVSRamp(dev); /* BKDG r31116 2010-04-22 2.4.1.7 step b F3xD8[VSSlamTime] */ /* Figure out the value for VsSlamTime and program it */ recalculateVsSlamTimeSettingOnCorePre(dev); config_clk_power_ctrl_reg0(i,cpuRev,procPkg); config_power_ctrl_misc_reg(dev,cpuRev,procPkg); config_nb_syn_ptr_adj(dev,cpuRev); config_acpi_pwr_state_ctrl_regs(dev,cpuRev,procPkg); dword = pci_read_config32(dev, 0x80); printk(BIOS_DEBUG, " F3x80: %08x \n", dword); dword = pci_read_config32(dev, 0x84); printk(BIOS_DEBUG, " F3x84: %08x \n", dword); dword = pci_read_config32(dev, 0xD4); printk(BIOS_DEBUG, " F3xD4: %08x \n", dword); dword = pci_read_config32(dev, 0xD8); printk(BIOS_DEBUG, " F3xD8: %08x \n", dword); dword = pci_read_config32(dev, 0xDC); printk(BIOS_DEBUG, " F3xDC: %08x \n", dword); } } static void waitCurrentPstate(u32 target_pstate){ msr_t initial_msr = rdmsr(TSC_MSR); msr_t pstate_msr = rdmsr(CUR_PSTATE_MSR); msr_t tsc_msr; u8 timedout ; /* paranoia ? I fear when we run fixPsNbVidBeforeWR we can enter a * P1 that is a copy of P0, therefore has the same NB DID but the * TSC will count twice per tick, so we have to wait for twice the * count to achieve the desired timeout. But I'm likely to * misunderstand this... */ u32 corrected_timeout = ( (pstate_msr.lo==1) && (!(rdmsr(0xC0010065).lo & NB_DID_M_ON)) ) ? WAIT_PSTATE_TIMEOUT*2 : WAIT_PSTATE_TIMEOUT ; msr_t timeout; timeout.lo = initial_msr.lo + corrected_timeout ; timeout.hi = initial_msr.hi; if ( (((u32)0xffffffff) - initial_msr.lo) < corrected_timeout ) { timeout.hi++; } // assuming TSC ticks at 1.25 ns per tick (800 MHz) do { pstate_msr = rdmsr(CUR_PSTATE_MSR); tsc_msr = rdmsr(TSC_MSR); timedout = (tsc_msr.hi > timeout.hi) || ((tsc_msr.hi == timeout.hi) && (tsc_msr.lo > timeout.lo )); } while ( (pstate_msr.lo != target_pstate) && (! timedout) ) ; if (pstate_msr.lo != target_pstate) { msr_t limit_msr = rdmsr(0xc0010061); printk(BIOS_ERR, "*** Time out waiting for P-state %01x. Current P-state %01x P-state current limit MSRC001_0061=%02x\n", target_pstate, pstate_msr.lo, limit_msr.lo); do { // should we just go on instead ? pstate_msr = rdmsr(CUR_PSTATE_MSR); } while ( pstate_msr.lo != target_pstate ) ; } } static void set_pstate(u32 nonBoostedPState) { msr_t msr; // Transition P0 for calling core. msr = rdmsr(0xC0010062); msr.lo = nonBoostedPState; wrmsr(0xC0010062, msr); /* Wait for P0 to set. */ waitCurrentPstate(nonBoostedPState); } static void UpdateSinglePlaneNbVid(void) { u32 nbVid, cpuVid; u8 i; msr_t msr; /* copy higher voltage (lower VID) of NBVID & CPUVID to both */ for (i = 0; i < 5; i++) { msr = rdmsr(PS_REG_BASE + i); nbVid = (msr.lo & PS_CPU_VID_M_ON) >> PS_CPU_VID_SHFT; cpuVid = (msr.lo & PS_NB_VID_M_ON) >> PS_NB_VID_SHFT; if (nbVid != cpuVid) { if (nbVid > cpuVid) nbVid = cpuVid; msr.lo = msr.lo & PS_BOTH_VID_OFF; msr.lo = msr.lo | (u32) ((nbVid) << PS_NB_VID_SHFT); msr.lo = msr.lo | (u32) ((nbVid) << PS_CPU_VID_SHFT); wrmsr(PS_REG_BASE + i, msr); } } } static void fixPsNbVidBeforeWR(u32 newNbVid, u32 coreid, u32 dev, u8 pviMode) { msr_t msr; u8 startup_pstate; /* This function sets NbVid before the warm reset. * Get StartupPstate from MSRC001_0071. * Read Pstate register pointed by [StartupPstate]. * and copy its content to P0 and P1 registers. * Copy newNbVid to P0[NbVid]. * transition to P1 on all cores, * then transition to P0 on core 0. * Wait for MSRC001_0063[CurPstate] = 000b on core 0. * see BKDG rev 3.48 2.4.2.9.1 BIOS NB COF and VID Configuration * for SVI and Single-Plane PVI Systems */ msr = rdmsr(0xc0010071); startup_pstate = (msr.hi >> (32 - 32)) & 0x07; /* Copy startup pstate to P1 and P0 MSRs. Set the maxvid for * this node in P0. Then transition to P1 for corex and P0 * for core0. These setting will be cleared by the warm reset */ msr = rdmsr(0xC0010064 + startup_pstate); wrmsr(0xC0010065, msr); wrmsr(0xC0010064, msr); /* missing step 2 from BDKG , F3xDC[PstateMaxVal] = * max(1,F3xDC[PstateMaxVal] ) because it would take * synchronization between cores and we don't think * PstatMaxVal is going to be 0 on cold reset anyway ? */ if ( ! (pci_read_config32(dev, 0xDC) & (~ PS_MAX_VAL_MASK)) ) { printk(BIOS_ERR,"F3xDC[PstateMaxVal] is zero. Northbridge voltage setting will fail. fixPsNbVidBeforeWR in fidvid.c needs fixing. See AMD # 31116 rev 3.48 BKDG 2.4.2.9.1 \n"); }; msr.lo &= ~0xFE000000; // clear nbvid msr.lo |= (newNbVid << 25); wrmsr(0xC0010064, msr); if (pviMode) { /* single plane*/ UpdateSinglePlaneNbVid(); } // Transition to P1 for all APs and P0 for core0. set_pstate(1); if (coreid == 0) { set_pstate(0); } /* missing step 7 (restore PstateMax to 0 if needed) because * we skipped step 2 */ } static u32 needs_NB_COF_VID_update(void) { u8 nb_cof_vid_update; u8 nodes; u8 i; /* If any node has nb_cof_vid_update set all nodes need an update. */ nodes = get_nodes(); nb_cof_vid_update = 0; for (i = 0; i < nodes; i++) { u32 cpuRev = mctGetLogicalCPUID(i) ; u32 nbCofVidUpdateDefined = (cpuRev & (AMD_FAM10_LT_D)); if (nbCofVidUpdateDefined && (pci_read_config32(NODE_PCI(i, 3), 0x1FC) & NB_COF_VID_UPDATE_MASK)) { nb_cof_vid_update = 1; break; } } return nb_cof_vid_update; } static u32 init_fidvid_core(u32 nodeid, u32 coreid) { device_t dev; u32 vid_max; u32 fid_max = 0; u8 nb_cof_vid_update = needs_NB_COF_VID_update(); u8 pvimode; u32 reg1fc; /* Steps 1-6 of BIOS NB COF and VID Configuration * for SVI and Single-Plane PVI Systems. BKDG 2.4.2.9 #31116 rev 3.48 */ dev = NODE_PCI(nodeid, 3); pvimode = pci_read_config32(dev, PW_CTL_MISC) & PVI_MODE; reg1fc = pci_read_config32(dev, 0x1FC); if (nb_cof_vid_update) { vid_max = (reg1fc & SINGLE_PLANE_NB_VID_MASK ) >> SINGLE_PLANE_NB_VID_SHIFT ; fid_max = (reg1fc & SINGLE_PLANE_NB_FID_MASK ) >> SINGLE_PLANE_NB_FID_SHIFT ; if (!pvimode) { /* SVI, dual power plane */ vid_max = vid_max - ((reg1fc & DUAL_PLANE_NB_VID_OFF_MASK ) >> DUAL_PLANE_NB_VID_SHIFT ); fid_max = fid_max + ((reg1fc & DUAL_PLANE_NB_FID_OFF_MASK ) >> DUAL_PLANE_NB_FID_SHIFT ); } /* write newNbVid to P-state Reg's NbVid always if NbVidUpdatedAll=1 */ fixPsNbVidBeforeWR(vid_max, coreid,dev,pvimode); /* fid setup is handled by the BSP at the end. */ } else { /* ! nb_cof_vid_update */ /* Use max values */ if (pvimode) UpdateSinglePlaneNbVid(); } return ((nb_cof_vid_update << 16) | (fid_max << 8)); } static void init_fidvid_ap(u32 apicid, u32 nodeid, u32 coreid) { u32 send; printk(BIOS_DEBUG, "FIDVID on AP: %02x\n", apicid); send = init_fidvid_core(nodeid,coreid); send |= (apicid << 24); // ap apicid // Send signal to BSP about this AP max fid // This also indicates this AP is ready for warm reset (if required). lapic_write(LAPIC_MSG_REG, send | F10_APSTATE_RESET); } static u32 calc_common_fid(u32 fid_packed, u32 fid_packed_new) { u32 fidmax; u32 fidmax_new; fidmax = (fid_packed >> 8) & 0xFF; fidmax_new = (fid_packed_new >> 8) & 0xFF; if (fidmax > fidmax_new) { fidmax = fidmax_new; } fid_packed &= 0xFF << 16; fid_packed |= (fidmax << 8); fid_packed |= fid_packed_new & (0xFF << 16); // set nb_cof_vid_update return fid_packed; } static void init_fidvid_bsp_stage1(u32 ap_apicid, void *gp) { u32 readback = 0; u32 timeout = 1; struct fidvid_st *fvp = gp; int loop; print_debug_fv("Wait for AP stage 1: ap_apicid = ", ap_apicid); loop = 100000; while (--loop > 0) { if (lapic_remote_read(ap_apicid, LAPIC_MSG_REG, &readback) != 0) continue; if ((readback & 0x3f) == 1) { timeout = 0; break; /* target ap is in stage 1 */ } } if (timeout) { printk(BIOS_DEBUG, "%s: timed out reading from ap %02x\n", __func__, ap_apicid); return; } print_debug_fv("\treadback = ", readback); fvp->common_fid = calc_common_fid(fvp->common_fid, readback); print_debug_fv("\tcommon_fid(packed) = ", fvp->common_fid); } static void fixPsNbVidAfterWR(u32 newNbVid, u8 NbVidUpdatedAll,u8 pviMode) { msr_t msr; u8 i; u8 StartupPstate; /* BKDG 2.4.2.9.1 11-12 * This function copies newNbVid to NbVid bits in P-state * Registers[4:0] if its NbDid bit=0, and IddValue!=0 in case of * NbVidUpdatedAll =0 or copies newNbVid to NbVid bits in * P-state Registers[4:0] if its IddValue!=0 in case of * NbVidUpdatedAll=1. Then transition to StartPstate. */ /* write newNbVid to P-state Reg's NbVid if its NbDid=0 */ for (i = 0; i < 5; i++) { msr = rdmsr(0xC0010064 + i); /* NbDid (bit 22 of P-state Reg) == 0 or NbVidUpdatedAll = 1 */ if ( (msr.hi & PS_IDD_VALUE_MASK) && (msr.hi & PS_EN_MASK) &&(((msr.lo & PS_NB_DID_MASK) == 0) || NbVidUpdatedAll)) { msr.lo &= PS_NB_VID_M_OFF; msr.lo |= (newNbVid & 0x7F) << PS_NB_VID_SHFT; wrmsr(0xC0010064 + i, msr); } } /* Not documented. Would overwrite Nb_Vids just copied * should we just update cpu_vid or nothing at all ? */ if (pviMode) { //single plane UpdateSinglePlaneNbVid(); } /* For each core in the system, transition all cores to StartupPstate */ msr = rdmsr(0xC0010071); StartupPstate = msr.hi & 0x07; /* Set and wait for StartupPstate to set. */ set_pstate(StartupPstate); } static void finalPstateChange(void) { /* Enable P0 on all cores for best performance. * Linux can slow them down later if need be. * It is safe since they will be in C1 halt * most of the time anyway. */ set_pstate(0); } static void init_fidvid_stage2(u32 apicid, u32 nodeid) { msr_t msr; device_t dev; u32 reg1fc; u32 dtemp; u32 nbvid; u8 nb_cof_vid_update = needs_NB_COF_VID_update(); u8 NbVidUpdateAll; u8 pvimode; /* After warm reset finish the fid/vid setup for all cores. */ /* If any node has nb_cof_vid_update set all nodes need an update. */ dev = NODE_PCI(nodeid, 3); pvimode = (pci_read_config32(dev, 0xA0) >> 8) & 1; reg1fc = pci_read_config32(dev, 0x1FC); nbvid = (reg1fc >> 7) & 0x7F; NbVidUpdateAll = (reg1fc >> 1) & 1; if (nb_cof_vid_update) { if (!pvimode) { /* SVI */ nbvid = nbvid - ((reg1fc >> 17) & 0x1F); } /* write newNbVid to P-state Reg's NbVid if its NbDid=0 */ fixPsNbVidAfterWR(nbvid, NbVidUpdateAll,pvimode); } else { /* !nb_cof_vid_update */ if (pvimode) UpdateSinglePlaneNbVid(); } dtemp = pci_read_config32(dev, 0xA0); dtemp &= PLLLOCK_OFF; dtemp |= PLLLOCK_DFT_L; pci_write_config32(dev, 0xA0, dtemp); dualPlaneOnly(dev); applyBoostFIDOffset(dev); enableNbPState1(dev); finalPstateChange(); /* Set TSC to tick at the P0 ndfid rate */ msr = rdmsr(HWCR); msr.lo |= 1 << 24; wrmsr(HWCR, msr); } #if CONFIG_SET_FIDVID_STORE_AP_APICID_AT_FIRST struct ap_apicid_st { u32 num; // it could use 256 bytes for 64 node quad core system u8 apicid[NODE_NUMS * 4]; }; static void store_ap_apicid(unsigned ap_apicid, void *gp) { struct ap_apicid_st *p = gp; p->apicid[p->num++] = ap_apicid; } #endif static int init_fidvid_bsp(u32 bsp_apicid, u32 nodes) { #if CONFIG_SET_FIDVID_STORE_AP_APICID_AT_FIRST struct ap_apicid_st ap_apicidx; u32 i; #endif struct fidvid_st fv; printk(BIOS_DEBUG, "FIDVID on BSP, APIC_id: %02x\n", bsp_apicid); /* Steps 1-6 of BIOS NB COF and VID Configuration * for SVI and Single-Plane PVI Systems. */ fv.common_fid = init_fidvid_core(0,0); print_debug_fv("BSP fid = ", fv.common_fid); #if CONFIG_SET_FIDVID_STORE_AP_APICID_AT_FIRST && !CONFIG_SET_FIDVID_CORE0_ONLY /* For all APs (We know the APIC ID of all APs even when the APIC ID is lifted) remote read from AP LAPIC_MSG_REG about max fid. Then calculate the common max fid that can be used for all APs and BSP */ ap_apicidx.num = 0; for_each_ap(bsp_apicid, CONFIG_SET_FIDVID_CORE_RANGE, store_ap_apicid, &ap_apicidx); for (i = 0; i < ap_apicidx.num; i++) { init_fidvid_bsp_stage1(ap_apicidx.apicid[i], &fv); } #else for_each_ap(bsp_apicid, CONFIG_SET_FIDVID_CORE0_ONLY, init_fidvid_bsp_stage1, &fv); #endif print_debug_fv("common_fid = ", fv.common_fid); if (fv.common_fid & (1 << 16)) { /* check nb_cof_vid_update */ // Enable the common fid and other settings. enable_fid_change((fv.common_fid >> 8) & 0x1F); // nbfid change need warm reset, so reset at first return 1; } return 0; // No FID/VID changes. Don't reset } #endif