/* * (c) 2003-2010 Advanced Micro Devices, Inc. * Your use of this code is subject to the terms and conditions of the * GNU general public license version 2. See "COPYING" or * http://www.gnu.org/licenses/gpl.html * * Support : mark.langsdorf@amd.com * * Based on the powernow-k7.c module written by Dave Jones. * (C) 2003 Dave Jones on behalf of SuSE Labs * (C) 2004 Dominik Brodowski * (C) 2004 Pavel Machek * Licensed under the terms of the GNU GPL License version 2. * Based upon datasheets & sample CPUs kindly provided by AMD. * * Valuable input gratefully received from Dave Jones, Pavel Machek, * Dominik Brodowski, Jacob Shin, and others. * Originally developed by Paul Devriendt. * Processor information obtained from Chapter 9 (Power and Thermal Management) * of the "BIOS and Kernel Developer's Guide for the AMD Athlon 64 and AMD * Opteron Processors" available for download from www.amd.com * * Tables for specific CPUs can be inferred from * http://www.amd.com/us-en/assets/content_type/white_papers_and_tech_docs/30430.pdf */ #include #include #include #include #include #include #include #include #include /* for current / set_cpus_allowed() */ #include #include #include #include #include #include #define PFX "powernow-k8: " #define VERSION "version 2.20.00" #include "powernow-k8.h" #include "mperf.h" /* serialize freq changes */ static DEFINE_MUTEX(fidvid_mutex); static DEFINE_PER_CPU(struct powernow_k8_data *, powernow_data); static int cpu_family = CPU_OPTERON; /* core performance boost */ static bool cpb_capable, cpb_enabled; static struct msr __percpu *msrs; static struct cpufreq_driver cpufreq_amd64_driver; #ifndef CONFIG_SMP static inline const struct cpumask *cpu_core_mask(int cpu) { return cpumask_of(0); } #endif /* Return a frequency in MHz, given an input fid */ static u32 find_freq_from_fid(u32 fid) { return 800 + (fid * 100); } /* Return a frequency in KHz, given an input fid */ static u32 find_khz_freq_from_fid(u32 fid) { return 1000 * find_freq_from_fid(fid); } static u32 find_khz_freq_from_pstate(struct cpufreq_frequency_table *data, u32 pstate) { return data[pstate].frequency; } /* Return the vco fid for an input fid * * Each "low" fid has corresponding "high" fid, and you can get to "low" fids * only from corresponding high fids. This returns "high" fid corresponding to * "low" one. */ static u32 convert_fid_to_vco_fid(u32 fid) { if (fid < HI_FID_TABLE_BOTTOM) return 8 + (2 * fid); else return fid; } /* * Return 1 if the pending bit is set. Unless we just instructed the processor * to transition to a new state, seeing this bit set is really bad news. */ static int pending_bit_stuck(void) { u32 lo, hi; if (cpu_family == CPU_HW_PSTATE) return 0; rdmsr(MSR_FIDVID_STATUS, lo, hi); return lo & MSR_S_LO_CHANGE_PENDING ? 1 : 0; } /* * Update the global current fid / vid values from the status msr. * Returns 1 on error. */ static int query_current_values_with_pending_wait(struct powernow_k8_data *data) { u32 lo, hi; u32 i = 0; if (cpu_family == CPU_HW_PSTATE) { rdmsr(MSR_PSTATE_STATUS, lo, hi); i = lo & HW_PSTATE_MASK; data->currpstate = i; /* * a workaround for family 11h erratum 311 might cause * an "out-of-range Pstate if the core is in Pstate-0 */ if ((boot_cpu_data.x86 == 0x11) && (i >= data->numps)) data->currpstate = HW_PSTATE_0; return 0; } do { if (i++ > 10000) { dprintk("detected change pending stuck\n"); return 1; } rdmsr(MSR_FIDVID_STATUS, lo, hi); } while (lo & MSR_S_LO_CHANGE_PENDING); data->currvid = hi & MSR_S_HI_CURRENT_VID; data->currfid = lo & MSR_S_LO_CURRENT_FID; return 0; } /* the isochronous relief time */ static void count_off_irt(struct powernow_k8_data *data) { udelay((1 << data->irt) * 10); return; } /* the voltage stabilization time */ static void count_off_vst(struct powernow_k8_data *data) { udelay(data->vstable * VST_UNITS_20US); return; } /* need to init the control msr to a safe value (for each cpu) */ static void fidvid_msr_init(void) { u32 lo, hi; u8 fid, vid; rdmsr(MSR_FIDVID_STATUS, lo, hi); vid = hi & MSR_S_HI_CURRENT_VID; fid = lo & MSR_S_LO_CURRENT_FID; lo = fid | (vid << MSR_C_LO_VID_SHIFT); hi = MSR_C_HI_STP_GNT_BENIGN; dprintk("cpu%d, init lo 0x%x, hi 0x%x\n", smp_processor_id(), lo, hi); wrmsr(MSR_FIDVID_CTL, lo, hi); } /* write the new fid value along with the other control fields to the msr */ static int write_new_fid(struct powernow_k8_data *data, u32 fid) { u32 lo; u32 savevid = data->currvid; u32 i = 0; if ((fid & INVALID_FID_MASK) || (data->currvid & INVALID_VID_MASK)) { printk(KERN_ERR PFX "internal error - overflow on fid write\n"); return 1; } lo = fid; lo |= (data->currvid << MSR_C_LO_VID_SHIFT); lo |= MSR_C_LO_INIT_FID_VID; dprintk("writing fid 0x%x, lo 0x%x, hi 0x%x\n", fid, lo, data->plllock * PLL_LOCK_CONVERSION); do { wrmsr(MSR_FIDVID_CTL, lo, data->plllock * PLL_LOCK_CONVERSION); if (i++ > 100) { printk(KERN_ERR PFX "Hardware error - pending bit very stuck - " "no further pstate changes possible\n"); return 1; } } while (query_current_values_with_pending_wait(data)); count_off_irt(data); if (savevid != data->currvid) { printk(KERN_ERR PFX "vid change on fid trans, old 0x%x, new 0x%x\n", savevid, data->currvid); return 1; } if (fid != data->currfid) { printk(KERN_ERR PFX "fid trans failed, fid 0x%x, curr 0x%x\n", fid, data->currfid); return 1; } return 0; } /* Write a new vid to the hardware */ static int write_new_vid(struct powernow_k8_data *data, u32 vid) { u32 lo; u32 savefid = data->currfid; int i = 0; if ((data->currfid & INVALID_FID_MASK) || (vid & INVALID_VID_MASK)) { printk(KERN_ERR PFX "internal error - overflow on vid write\n"); return 1; } lo = data->currfid; lo |= (vid << MSR_C_LO_VID_SHIFT); lo |= MSR_C_LO_INIT_FID_VID; dprintk("writing vid 0x%x, lo 0x%x, hi 0x%x\n", vid, lo, STOP_GRANT_5NS); do { wrmsr(MSR_FIDVID_CTL, lo, STOP_GRANT_5NS); if (i++ > 100) { printk(KERN_ERR PFX "internal error - pending bit " "very stuck - no further pstate " "changes possible\n"); return 1; } } while (query_current_values_with_pending_wait(data)); if (savefid != data->currfid) { printk(KERN_ERR PFX "fid changed on vid trans, old " "0x%x new 0x%x\n", savefid, data->currfid); return 1; } if (vid != data->currvid) { printk(KERN_ERR PFX "vid trans failed, vid 0x%x, " "curr 0x%x\n", vid, data->currvid); return 1; } return 0; } /* * Reduce the vid by the max of step or reqvid. * Decreasing vid codes represent increasing voltages: * vid of 0 is 1.550V, vid of 0x1e is 0.800V, vid of VID_OFF is off. */ static int decrease_vid_code_by_step(struct powernow_k8_data *data, u32 reqvid, u32 step) { if ((data->currvid - reqvid) > step) reqvid = data->currvid - step; if (write_new_vid(data, reqvid)) return 1; count_off_vst(data); return 0; } /* Change hardware pstate by single MSR write */ static int transition_pstate(struct powernow_k8_data *data, u32 pstate) { wrmsr(MSR_PSTATE_CTRL, pstate, 0); data->currpstate = pstate; return 0; } /* Change Opteron/Athlon64 fid and vid, by the 3 phases. */ static int transition_fid_vid(struct powernow_k8_data *data, u32 reqfid, u32 reqvid) { if (core_voltage_pre_transition(data, reqvid, reqfid)) return 1; if (core_frequency_transition(data, reqfid)) return 1; if (core_voltage_post_transition(data, reqvid)) return 1; if (query_current_values_with_pending_wait(data)) return 1; if ((reqfid != data->currfid) || (reqvid != data->currvid)) { printk(KERN_ERR PFX "failed (cpu%d): req 0x%x 0x%x, " "curr 0x%x 0x%x\n", smp_processor_id(), reqfid, reqvid, data->currfid, data->currvid); return 1; } dprintk("transitioned (cpu%d): new fid 0x%x, vid 0x%x\n", smp_processor_id(), data->currfid, data->currvid); return 0; } /* Phase 1 - core voltage transition ... setup voltage */ static int core_voltage_pre_transition(struct powernow_k8_data *data, u32 reqvid, u32 reqfid) { u32 rvosteps = data->rvo; u32 savefid = data->currfid; u32 maxvid, lo, rvomult = 1; dprintk("ph1 (cpu%d): start, currfid 0x%x, currvid 0x%x, " "reqvid 0x%x, rvo 0x%x\n", smp_processor_id(), data->currfid, data->currvid, reqvid, data->rvo); if ((savefid < LO_FID_TABLE_TOP) && (reqfid < LO_FID_TABLE_TOP)) rvomult = 2; rvosteps *= rvomult; rdmsr(MSR_FIDVID_STATUS, lo, maxvid); maxvid = 0x1f & (maxvid >> 16); dprintk("ph1 maxvid=0x%x\n", maxvid); if (reqvid < maxvid) /* lower numbers are higher voltages */ reqvid = maxvid; while (data->currvid > reqvid) { dprintk("ph1: curr 0x%x, req vid 0x%x\n", data->currvid, reqvid); if (decrease_vid_code_by_step(data, reqvid, data->vidmvs)) return 1; } while ((rvosteps > 0) && ((rvomult * data->rvo + data->currvid) > reqvid)) { if (data->currvid == maxvid) { rvosteps = 0; } else { dprintk("ph1: changing vid for rvo, req 0x%x\n", data->currvid - 1); if (decrease_vid_code_by_step(data, data->currvid-1, 1)) return 1; rvosteps--; } } if (query_current_values_with_pending_wait(data)) return 1; if (savefid != data->currfid) { printk(KERN_ERR PFX "ph1 err, currfid changed 0x%x\n", data->currfid); return 1; } dprintk("ph1 complete, currfid 0x%x, currvid 0x%x\n", data->currfid, data->currvid); return 0; } /* Phase 2 - core frequency transition */ static int core_frequency_transition(struct powernow_k8_data *data, u32 reqfid) { u32 vcoreqfid, vcocurrfid, vcofiddiff; u32 fid_interval, savevid = data->currvid; if (data->currfid == reqfid) { printk(KERN_ERR PFX "ph2 null fid transition 0x%x\n", data->currfid); return 0; } dprintk("ph2 (cpu%d): starting, currfid 0x%x, currvid 0x%x, " "reqfid 0x%x\n", smp_processor_id(), data->currfid, data->currvid, reqfid); vcoreqfid = convert_fid_to_vco_fid(reqfid); vcocurrfid = convert_fid_to_vco_fid(data->currfid); vcofiddiff = vcocurrfid > vcoreqfid ? vcocurrfid - vcoreqfid : vcoreqfid - vcocurrfid; if ((reqfid <= LO_FID_TABLE_TOP) && (data->currfid <= LO_FID_TABLE_TOP)) vcofiddiff = 0; while (vcofiddiff > 2) { (data->currfid & 1) ? (fid_interval = 1) : (fid_interval = 2); if (reqfid > data->currfid) { if (data->currfid > LO_FID_TABLE_TOP) { if (write_new_fid(data, data->currfid + fid_interval)) return 1; } else { if (write_new_fid (data, 2 + convert_fid_to_vco_fid(data->currfid))) return 1; } } else { if (write_new_fid(data, data->currfid - fid_interval)) return 1; } vcocurrfid = convert_fid_to_vco_fid(data->currfid); vcofiddiff = vcocurrfid > vcoreqfid ? vcocurrfid - vcoreqfid : vcoreqfid - vcocurrfid; } if (write_new_fid(data, reqfid)) return 1; if (query_current_values_with_pending_wait(data)) return 1; if (data->currfid != reqfid) { printk(KERN_ERR PFX "ph2: mismatch, failed fid transition, " "curr 0x%x, req 0x%x\n", data->currfid, reqfid); return 1; } if (savevid != data->currvid) { printk(KERN_ERR PFX "ph2: vid changed, save 0x%x, curr 0x%x\n", savevid, data->currvid); return 1; } dprintk("ph2 complete, currfid 0x%x, currvid 0x%x\n", data->currfid, data->currvid); return 0; } /* Phase 3 - core voltage transition flow ... jump to the final vid. */ static int core_voltage_post_transition(struct powernow_k8_data *data, u32 reqvid) { u32 savefid = data->currfid; u32 savereqvid = reqvid; dprintk("ph3 (cpu%d): starting, currfid 0x%x, currvid 0x%x\n", smp_processor_id(), data->currfid, data->currvid); if (reqvid != data->currvid) { if (write_new_vid(data, reqvid)) return 1; if (savefid != data->currfid) { printk(KERN_ERR PFX "ph3: bad fid change, save 0x%x, curr 0x%x\n", savefid, data->currfid); return 1; } if (data->currvid != reqvid) { printk(KERN_ERR PFX "ph3: failed vid transition\n, " "req 0x%x, curr 0x%x", reqvid, data->currvid); return 1; } } if (query_current_values_with_pending_wait(data)) return 1; if (savereqvid != data->currvid) { dprintk("ph3 failed, currvid 0x%x\n", data->currvid); return 1; } if (savefid != data->currfid) { dprintk("ph3 failed, currfid changed 0x%x\n", data->currfid); return 1; } dprintk("ph3 complete, currfid 0x%x, currvid 0x%x\n", data->currfid, data->currvid); return 0; } static void check_supported_cpu(void *_rc) { u32 eax, ebx, ecx, edx; int *rc = _rc; *rc = -ENODEV; if (__this_cpu_read(cpu_info.x86_vendor) != X86_VENDOR_AMD) return; eax = cpuid_eax(CPUID_PROCESSOR_SIGNATURE); if (((eax & CPUID_XFAM) != CPUID_XFAM_K8) && ((eax & CPUID_XFAM) < CPUID_XFAM_10H)) return; if ((eax & CPUID_XFAM) == CPUID_XFAM_K8) { if (((eax & CPUID_USE_XFAM_XMOD) != CPUID_USE_XFAM_XMOD) || ((eax & CPUID_XMOD) > CPUID_XMOD_REV_MASK)) { printk(KERN_INFO PFX "Processor cpuid %x not supported\n", eax); return; } eax = cpuid_eax(CPUID_GET_MAX_CAPABILITIES); if (eax < CPUID_FREQ_VOLT_CAPABILITIES) { printk(KERN_INFO PFX "No frequency change capabilities detected\n"); return; } cpuid(CPUID_FREQ_VOLT_CAPABILITIES, &eax, &ebx, &ecx, &edx); if ((edx & P_STATE_TRANSITION_CAPABLE) != P_STATE_TRANSITION_CAPABLE) { printk(KERN_INFO PFX "Power state transitions not supported\n"); return; } } else { /* must be a HW Pstate capable processor */ cpuid(CPUID_FREQ_VOLT_CAPABILITIES, &eax, &ebx, &ecx, &edx); if ((edx & USE_HW_PSTATE) == USE_HW_PSTATE) cpu_family = CPU_HW_PSTATE; else return; } *rc = 0; } static int check_pst_table(struct powernow_k8_data *data, struct pst_s *pst, u8 maxvid) { unsigned int j; u8 lastfid = 0xff; for (j = 0; j < data->numps; j++) { if (pst[j].vid > LEAST_VID) { printk(KERN_ERR FW_BUG PFX "vid %d invalid : 0x%x\n", j, pst[j].vid); return -EINVAL; } if (pst[j].vid < data->rvo) { /* vid + rvo >= 0 */ printk(KERN_ERR FW_BUG PFX "0 vid exceeded with pstate" " %d\n", j); return -ENODEV; } if (pst[j].vid < maxvid + data->rvo) { /* vid + rvo >= maxvid */ printk(KERN_ERR FW_BUG PFX "maxvid exceeded with pstate" " %d\n", j); return -ENODEV; } if (pst[j].fid > MAX_FID) { printk(KERN_ERR FW_BUG PFX "maxfid exceeded with pstate" " %d\n", j); return -ENODEV; } if (j && (pst[j].fid < HI_FID_TABLE_BOTTOM)) { /* Only first fid is allowed to be in "low" range */ printk(KERN_ERR FW_BUG PFX "two low fids - %d : " "0x%x\n", j, pst[j].fid); return -EINVAL; } if (pst[j].fid < lastfid) lastfid = pst[j].fid; } if (lastfid & 1) { printk(KERN_ERR FW_BUG PFX "lastfid invalid\n"); return -EINVAL; } if (lastfid > LO_FID_TABLE_TOP) printk(KERN_INFO FW_BUG PFX "first fid not from lo freq table\n"); return 0; } static void invalidate_entry(struct cpufreq_frequency_table *powernow_table, unsigned int entry) { powernow_table[entry].frequency = CPUFREQ_ENTRY_INVALID; } static void print_basics(struct powernow_k8_data *data) { int j; for (j = 0; j < data->numps; j++) { if (data->powernow_table[j].frequency != CPUFREQ_ENTRY_INVALID) { if (cpu_family == CPU_HW_PSTATE) { printk(KERN_INFO PFX " %d : pstate %d (%d MHz)\n", j, data->powernow_table[j].index, data->powernow_table[j].frequency/1000); } else { printk(KERN_INFO PFX "fid 0x%x (%d MHz), vid 0x%x\n", data->powernow_table[j].index & 0xff, data->powernow_table[j].frequency/1000, data->powernow_table[j].index >> 8); } } } if (data->batps) printk(KERN_INFO PFX "Only %d pstates on battery\n", data->batps); } static u32 freq_from_fid_did(u32 fid, u32 did) { u32 mhz = 0; if (boot_cpu_data.x86 == 0x10) mhz = (100 * (fid + 0x10)) >> did; else if (boot_cpu_data.x86 == 0x11) mhz = (100 * (fid + 8)) >> did; else BUG(); return mhz * 1000; } static int fill_powernow_table(struct powernow_k8_data *data, struct pst_s *pst, u8 maxvid) { struct cpufreq_frequency_table *powernow_table; unsigned int j; if (data->batps) { /* use ACPI support to get full speed on mains power */ printk(KERN_WARNING PFX "Only %d pstates usable (use ACPI driver for full " "range\n", data->batps); data->numps = data->batps; } for (j = 1; j < data->numps; j++) { if (pst[j-1].fid >= pst[j].fid) { printk(KERN_ERR PFX "PST out of sequence\n"); return -EINVAL; } } if (data->numps < 2) { printk(KERN_ERR PFX "no p states to transition\n"); return -ENODEV; } if (check_pst_table(data, pst, maxvid)) return -EINVAL; powernow_table = kmalloc((sizeof(struct cpufreq_frequency_table) * (data->numps + 1)), GFP_KERNEL); if (!powernow_table) { printk(KERN_ERR PFX "powernow_table memory alloc failure\n"); return -ENOMEM; } for (j = 0; j < data->numps; j++) { int freq; powernow_table[j].index = pst[j].fid; /* lower 8 bits */ powernow_table[j].index |= (pst[j].vid << 8); /* upper 8 bits */ freq = find_khz_freq_from_fid(pst[j].fid); powernow_table[j].frequency = freq; } powernow_table[data->numps].frequency = CPUFREQ_TABLE_END; powernow_table[data->numps].index = 0; if (query_current_values_with_pending_wait(data)) { kfree(powernow_table); return -EIO; } dprintk("cfid 0x%x, cvid 0x%x\n", data->currfid, data->currvid); data->powernow_table = powernow_table; if (cpumask_first(cpu_core_mask(data->cpu)) == data->cpu) print_basics(data); for (j = 0; j < data->numps; j++) if ((pst[j].fid == data->currfid) && (pst[j].vid == data->currvid)) return 0; dprintk("currfid/vid do not match PST, ignoring\n"); return 0; } /* Find and validate the PSB/PST table in BIOS. */ static int find_psb_table(struct powernow_k8_data *data) { struct psb_s *psb; unsigned int i; u32 mvs; u8 maxvid; u32 cpst = 0; u32 thiscpuid; for (i = 0xc0000; i < 0xffff0; i += 0x10) { /* Scan BIOS looking for the signature. */ /* It can not be at ffff0 - it is too big. */ psb = phys_to_virt(i); if (memcmp(psb, PSB_ID_STRING, PSB_ID_STRING_LEN) != 0) continue; dprintk("found PSB header at 0x%p\n", psb); dprintk("table vers: 0x%x\n", psb->tableversion); if (psb->tableversion != PSB_VERSION_1_4) { printk(KERN_ERR FW_BUG PFX "PSB table is not v1.4\n"); return -ENODEV; } dprintk("flags: 0x%x\n", psb->flags1); if (psb->flags1) { printk(KERN_ERR FW_BUG PFX "unknown flags\n"); return -ENODEV; } data->vstable = psb->vstable; dprintk("voltage stabilization time: %d(*20us)\n", data->vstable); dprintk("flags2: 0x%x\n", psb->flags2); data->rvo = psb->flags2 & 3; data->irt = ((psb->flags2) >> 2) & 3; mvs = ((psb->flags2) >> 4) & 3; data->vidmvs = 1 << mvs; data->batps = ((psb->flags2) >> 6) & 3; dprintk("ramp voltage offset: %d\n", data->rvo); dprintk("isochronous relief time: %d\n", data->irt); dprintk("maximum voltage step: %d - 0x%x\n", mvs, data->vidmvs); dprintk("numpst: 0x%x\n", psb->num_tables); cpst = psb->num_tables; if ((psb->cpuid == 0x00000fc0) || (psb->cpuid == 0x00000fe0)) { thiscpuid = cpuid_eax(CPUID_PROCESSOR_SIGNATURE); if ((thiscpuid == 0x00000fc0) || (thiscpuid == 0x00000fe0)) cpst = 1; } if (cpst != 1) { printk(KERN_ERR FW_BUG PFX "numpst must be 1\n"); return -ENODEV; } data->plllock = psb->plllocktime; dprintk("plllocktime: 0x%x (units 1us)\n", psb->plllocktime); dprintk("maxfid: 0x%x\n", psb->maxfid); dprintk("maxvid: 0x%x\n", psb->maxvid); maxvid = psb->maxvid; data->numps = psb->numps; dprintk("numpstates: 0x%x\n", data->numps); return fill_powernow_table(data, (struct pst_s *)(psb+1), maxvid); } /* * If you see this message, complain to BIOS manufacturer. If * he tells you "we do not support Linux" or some similar * nonsense, remember that Windows 2000 uses the same legacy * mechanism that the old Linux PSB driver uses. Tell them it * is broken with Windows 2000. * * The reference to the AMD documentation is chapter 9 in the * BIOS and Kernel Developer's Guide, which is available on * www.amd.com */ printk(KERN_ERR FW_BUG PFX "No PSB or ACPI _PSS objects\n"); printk(KERN_ERR PFX "Make sure that your BIOS is up to date" " and Cool'N'Quiet support is enabled in BIOS setup\n"); return -ENODEV; } static void powernow_k8_acpi_pst_values(struct powernow_k8_data *data, unsigned int index) { u64 control; if (!data->acpi_data.state_count || (cpu_family == CPU_HW_PSTATE)) return; control = data->acpi_data.states[index].control; data->irt = (control >> IRT_SHIFT) & IRT_MASK; data->rvo = (control >> RVO_SHIFT) & RVO_MASK; data->exttype = (control >> EXT_TYPE_SHIFT) & EXT_TYPE_MASK; data->plllock = (control >> PLL_L_SHIFT) & PLL_L_MASK; data->vidmvs = 1 << ((control >> MVS_SHIFT) & MVS_MASK); data->vstable = (control >> VST_SHIFT) & VST_MASK; } static int powernow_k8_cpu_init_acpi(struct powernow_k8_data *data) { struct cpufreq_frequency_table *powernow_table; int ret_val = -ENODEV; u64 control, status; if (acpi_processor_register_performance(&data->acpi_data, data->cpu)) { dprintk("register performance failed: bad ACPI data\n"); return -EIO; } /* verify the data contained in the ACPI structures */ if (data->acpi_data.state_count <= 1) { dprintk("No ACPI P-States\n"); goto err_out; } control = data->acpi_data.control_register.space_id; status = data->acpi_data.status_register.space_id; if ((control != ACPI_ADR_SPACE_FIXED_HARDWARE) || (status != ACPI_ADR_SPACE_FIXED_HARDWARE)) { dprintk("Invalid control/status registers (%x - %x)\n", control, status); goto err_out; } /* fill in data->powernow_table */ powernow_table = kmalloc((sizeof(struct cpufreq_frequency_table) * (data->acpi_data.state_count + 1)), GFP_KERNEL); if (!powernow_table) { dprintk("powernow_table memory alloc failure\n"); goto err_out; } /* fill in data */ data->numps = data->acpi_data.state_count; powernow_k8_acpi_pst_values(data, 0); if (cpu_family == CPU_HW_PSTATE) ret_val = fill_powernow_table_pstate(data, powernow_table); else ret_val = fill_powernow_table_fidvid(data, powernow_table); if (ret_val) goto err_out_mem; powernow_table[data->acpi_data.state_count].frequency = CPUFREQ_TABLE_END; powernow_table[data->acpi_data.state_count].index = 0; data->powernow_table = powernow_table; if (cpumask_first(cpu_core_mask(data->cpu)) == data->cpu) print_basics(data); /* notify BIOS that we exist */ acpi_processor_notify_smm(THIS_MODULE); if (!zalloc_cpumask_var(&data->acpi_data.shared_cpu_map, GFP_KERNEL)) { printk(KERN_ERR PFX "unable to alloc powernow_k8_data cpumask\n"); ret_val = -ENOMEM; goto err_out_mem; } return 0; err_out_mem: kfree(powernow_table); err_out: acpi_processor_unregister_performance(&data->acpi_data, data->cpu); /* data->acpi_data.state_count informs us at ->exit() * whether ACPI was used */ data->acpi_data.state_count = 0; return ret_val; } static int fill_powernow_table_pstate(struct powernow_k8_data *data, struct cpufreq_frequency_table *powernow_table) { int i; u32 hi = 0, lo = 0; rdmsr(MSR_PSTATE_CUR_LIMIT, lo, hi); data->max_hw_pstate = (lo & HW_PSTATE_MAX_MASK) >> HW_PSTATE_MAX_SHIFT; for (i = 0; i < data->acpi_data.state_count; i++) { u32 index; index = data->acpi_data.states[i].control & HW_PSTATE_MASK; if (index > data->max_hw_pstate) { printk(KERN_ERR PFX "invalid pstate %d - " "bad value %d.\n", i, index); printk(KERN_ERR PFX "Please report to BIOS " "manufacturer\n"); invalidate_entry(powernow_table, i); continue; } rdmsr(MSR_PSTATE_DEF_BASE + index, lo, hi); if (!(hi & HW_PSTATE_VALID_MASK)) { dprintk("invalid pstate %d, ignoring\n", index); invalidate_entry(powernow_table, i); continue; } powernow_table[i].index = index; /* Frequency may be rounded for these */ if ((boot_cpu_data.x86 == 0x10 && boot_cpu_data.x86_model < 10) || boot_cpu_data.x86 == 0x11) { powernow_table[i].frequency = freq_from_fid_did(lo & 0x3f, (lo >> 6) & 7); } else powernow_table[i].frequency = data->acpi_data.states[i].core_frequency * 1000; } return 0; } static int fill_powernow_table_fidvid(struct powernow_k8_data *data, struct cpufreq_frequency_table *powernow_table) { int i; for (i = 0; i < data->acpi_data.state_count; i++) { u32 fid; u32 vid; u32 freq, index; u64 status, control; if (data->exttype) { status = data->acpi_data.states[i].status; fid = status & EXT_FID_MASK; vid = (status >> VID_SHIFT) & EXT_VID_MASK; } else { control = data->acpi_data.states[i].control; fid = control & FID_MASK; vid = (control >> VID_SHIFT) & VID_MASK; } dprintk(" %d : fid 0x%x, vid 0x%x\n", i, fid, vid); index = fid | (vid<<8); powernow_table[i].index = index; freq = find_khz_freq_from_fid(fid); powernow_table[i].frequency = freq; /* verify frequency is OK */ if ((freq > (MAX_FREQ * 1000)) || (freq < (MIN_FREQ * 1000))) { dprintk("invalid freq %u kHz, ignoring\n", freq); invalidate_entry(powernow_table, i); continue; } /* verify voltage is OK - * BIOSs are using "off" to indicate invalid */ if (vid == VID_OFF) { dprintk("invalid vid %u, ignoring\n", vid); invalidate_entry(powernow_table, i); continue; } if (freq != (data->acpi_data.states[i].core_frequency * 1000)) { printk(KERN_INFO PFX "invalid freq entries " "%u kHz vs. %u kHz\n", freq, (unsigned int) (data->acpi_data.states[i].core_frequency * 1000)); invalidate_entry(powernow_table, i); continue; } } return 0; } static void powernow_k8_cpu_exit_acpi(struct powernow_k8_data *data) { if (data->acpi_data.state_count) acpi_processor_unregister_performance(&data->acpi_data, data->cpu); free_cpumask_var(data->acpi_data.shared_cpu_map); } static int get_transition_latency(struct powernow_k8_data *data) { int max_latency = 0; int i; for (i = 0; i < data->acpi_data.state_count; i++) { int cur_latency = data->acpi_data.states[i].transition_latency + data->acpi_data.states[i].bus_master_latency; if (cur_latency > max_latency) max_latency = cur_latency; } if (max_latency == 0) { /* * Fam 11h and later may return 0 as transition latency. This * is intended and means "very fast". While cpufreq core and * governors currently can handle that gracefully, better set it * to 1 to avoid problems in the future. */ if (boot_cpu_data.x86 < 0x11) printk(KERN_ERR FW_WARN PFX "Invalid zero transition " "latency\n"); max_latency = 1; } /* value in usecs, needs to be in nanoseconds */ return 1000 * max_latency; } /* Take a frequency, and issue the fid/vid transition command */ static int transition_frequency_fidvid(struct powernow_k8_data *data, unsigned int index) { u32 fid = 0; u32 vid = 0; int res, i; struct cpufreq_freqs freqs; dprintk("cpu %d transition to index %u\n", smp_processor_id(), index); /* fid/vid correctness check for k8 */ /* fid are the lower 8 bits of the index we stored into * the cpufreq frequency table in find_psb_table, vid * are the upper 8 bits. */ fid = data->powernow_table[index].index & 0xFF; vid = (data->powernow_table[index].index & 0xFF00) >> 8; dprintk("table matched fid 0x%x, giving vid 0x%x\n", fid, vid); if (query_current_values_with_pending_wait(data)) return 1; if ((data->currvid == vid) && (data->currfid == fid)) { dprintk("target matches current values (fid 0x%x, vid 0x%x)\n", fid, vid); return 0; } dprintk("cpu %d, changing to fid 0x%x, vid 0x%x\n", smp_processor_id(), fid, vid); freqs.old = find_khz_freq_from_fid(data->currfid); freqs.new = find_khz_freq_from_fid(fid); for_each_cpu(i, data->available_cores) { freqs.cpu = i; cpufreq_notify_transition(&freqs, CPUFREQ_PRECHANGE); } res = transition_fid_vid(data, fid, vid); freqs.new = find_khz_freq_from_fid(data->currfid); for_each_cpu(i, data->available_cores) { freqs.cpu = i; cpufreq_notify_transition(&freqs, CPUFREQ_POSTCHANGE); } return res; } /* Take a frequency, and issue the hardware pstate transition command */ static int transition_frequency_pstate(struct powernow_k8_data *data, unsigned int index) { u32 pstate = 0; int res, i; struct cpufreq_freqs freqs; dprintk("cpu %d transition to index %u\n", smp_processor_id(), index); /* get MSR index for hardware pstate transition */ pstate = index & HW_PSTATE_MASK; if (pstate > data->max_hw_pstate) return 0; freqs.old = find_khz_freq_from_pstate(data->powernow_table, data->currpstate); freqs.new = find_khz_freq_from_pstate(data->powernow_table, pstate); for_each_cpu(i, data->available_cores) { freqs.cpu = i; cpufreq_notify_transition(&freqs, CPUFREQ_PRECHANGE); } res = transition_pstate(data, pstate); freqs.new = find_khz_freq_from_pstate(data->powernow_table, pstate); for_each_cpu(i, data->available_cores) { freqs.cpu = i; cpufreq_notify_transition(&freqs, CPUFREQ_POSTCHANGE); } return res; } /* Driver entry point to switch to the target frequency */ static int powernowk8_target(struct cpufreq_policy *pol, unsigned targfreq, unsigned relation) { cpumask_var_t oldmask; struct powernow_k8_data *data = per_cpu(powernow_data, pol->cpu); u32 checkfid; u32 checkvid; unsigned int newstate; int ret = -EIO; if (!data) return -EINVAL; checkfid = data->currfid; checkvid = data->currvid; /* only run on specific CPU from here on. */ /* This is poor form: use a workqueue or smp_call_function_single */ if (!alloc_cpumask_var(&oldmask, GFP_KERNEL)) return -ENOMEM; cpumask_copy(oldmask, tsk_cpus_allowed(current)); set_cpus_allowed_ptr(current, cpumask_of(pol->cpu)); if (smp_processor_id() != pol->cpu) { printk(KERN_ERR PFX "limiting to cpu %u failed\n", pol->cpu); goto err_out; } if (pending_bit_stuck()) { printk(KERN_ERR PFX "failing targ, change pending bit set\n"); goto err_out; } dprintk("targ: cpu %d, %d kHz, min %d, max %d, relation %d\n", pol->cpu, targfreq, pol->min, pol->max, relation); if (query_current_values_with_pending_wait(data)) goto err_out; if (cpu_family != CPU_HW_PSTATE) { dprintk("targ: curr fid 0x%x, vid 0x%x\n", data->currfid, data->currvid); if ((checkvid != data->currvid) || (checkfid != data->currfid)) { printk(KERN_INFO PFX "error - out of sync, fix 0x%x 0x%x, " "vid 0x%x 0x%x\n", checkfid, data->currfid, checkvid, data->currvid); } } if (cpufreq_frequency_table_target(pol, data->powernow_table, targfreq, relation, &newstate)) goto err_out; mutex_lock(&fidvid_mutex); powernow_k8_acpi_pst_values(data, newstate); if (cpu_family == CPU_HW_PSTATE) ret = transition_frequency_pstate(data, newstate); else ret = transition_frequency_fidvid(data, newstate); if (ret) { printk(KERN_ERR PFX "transition frequency failed\n"); ret = 1; mutex_unlock(&fidvid_mutex); goto err_out; } mutex_unlock(&fidvid_mutex); if (cpu_family == CPU_HW_PSTATE) pol->cur = find_khz_freq_from_pstate(data->powernow_table, newstate); else pol->cur = find_khz_freq_from_fid(data->currfid); ret = 0; err_out: set_cpus_allowed_ptr(current, oldmask); free_cpumask_var(oldmask); return ret; } /* Driver entry point to verify the policy and range of frequencies */ static int powernowk8_verify(struct cpufreq_policy *pol) { struct powernow_k8_data *data = per_cpu(powernow_data, pol->cpu); if (!data) return -EINVAL; return cpufreq_frequency_table_verify(pol, data->powernow_table); } struct init_on_cpu { struct powernow_k8_data *data; int rc; }; static void __cpuinit powernowk8_cpu_init_on_cpu(void *_init_on_cpu) { struct init_on_cpu *init_on_cpu = _init_on_cpu; if (pending_bit_stuck()) { printk(KERN_ERR PFX "failing init, change pending bit set\n"); init_on_cpu->rc = -ENODEV; return; } if (query_current_values_with_pending_wait(init_on_cpu->data)) { init_on_cpu->rc = -ENODEV; return; } if (cpu_family == CPU_OPTERON) fidvid_msr_init(); init_on_cpu->rc = 0; } /* per CPU init entry point to the driver */ static int __cpuinit powernowk8_cpu_init(struct cpufreq_policy *pol) { static const char ACPI_PSS_BIOS_BUG_MSG[] = KERN_ERR FW_BUG PFX "No compatible ACPI _PSS objects found.\n" FW_BUG PFX "Try again with latest BIOS.\n"; struct powernow_k8_data *data; struct init_on_cpu init_on_cpu; int rc; struct cpuinfo_x86 *c = &cpu_data(pol->cpu); if (!cpu_online(pol->cpu)) return -ENODEV; smp_call_function_single(pol->cpu, check_supported_cpu, &rc, 1); if (rc) return -ENODEV; data = kzalloc(sizeof(struct powernow_k8_data), GFP_KERNEL); if (!data) { printk(KERN_ERR PFX "unable to alloc powernow_k8_data"); return -ENOMEM; } data->cpu = pol->cpu; data->currpstate = HW_PSTATE_INVALID; if (powernow_k8_cpu_init_acpi(data)) { /* * Use the PSB BIOS structure. This is only availabe on * an UP version, and is deprecated by AMD. */ if (num_online_cpus() != 1) { printk_once(ACPI_PSS_BIOS_BUG_MSG); goto err_out; } if (pol->cpu != 0) { printk(KERN_ERR FW_BUG PFX "No ACPI _PSS objects for " "CPU other than CPU0. Complain to your BIOS " "vendor.\n"); goto err_out; } rc = find_psb_table(data); if (rc) goto err_out; /* Take a crude guess here. * That guess was in microseconds, so multiply with 1000 */ pol->cpuinfo.transition_latency = ( ((data->rvo + 8) * data->vstable * VST_UNITS_20US) + ((1 << data->irt) * 30)) * 1000; } else /* ACPI _PSS objects available */ pol->cpuinfo.transition_latency = get_transition_latency(data); /* only run on specific CPU from here on */ init_on_cpu.data = data; smp_call_function_single(data->cpu, powernowk8_cpu_init_on_cpu, &init_on_cpu, 1); rc = init_on_cpu.rc; if (rc != 0) goto err_out_exit_acpi; if (cpu_family == CPU_HW_PSTATE) cpumask_copy(pol->cpus, cpumask_of(pol->cpu)); else cpumask_copy(pol->cpus, cpu_core_mask(pol->cpu)); data->available_cores = pol->cpus; if (cpu_family == CPU_HW_PSTATE) pol->cur = find_khz_freq_from_pstate(data->powernow_table, data->currpstate); else pol->cur = find_khz_freq_from_fid(data->currfid); dprintk("policy current frequency %d kHz\n", pol->cur); /* min/max the cpu is capable of */ if (cpufreq_frequency_table_cpuinfo(pol, data->powernow_table)) { printk(KERN_ERR FW_BUG PFX "invalid powernow_table\n"); powernow_k8_cpu_exit_acpi(data); kfree(data->powernow_table); kfree(data); return -EINVAL; } /* Check for APERF/MPERF support in hardware */ if (cpu_has(c, X86_FEATURE_APERFMPERF)) cpufreq_amd64_driver.getavg = cpufreq_get_measured_perf; cpufreq_frequency_table_get_attr(data->powernow_table, pol->cpu); if (cpu_family == CPU_HW_PSTATE) dprintk("cpu_init done, current pstate 0x%x\n", data->currpstate); else dprintk("cpu_init done, current fid 0x%x, vid 0x%x\n", data->currfid, data->currvid); per_cpu(powernow_data, pol->cpu) = data; return 0; err_out_exit_acpi: powernow_k8_cpu_exit_acpi(data); err_out: kfree(data); return -ENODEV; } static int __devexit powernowk8_cpu_exit(struct cpufreq_policy *pol) { struct powernow_k8_data *data = per_cpu(powernow_data, pol->cpu); if (!data) return -EINVAL; powernow_k8_cpu_exit_acpi(data); cpufreq_frequency_table_put_attr(pol->cpu); kfree(data->powernow_table); kfree(data); per_cpu(powernow_data, pol->cpu) = NULL; return 0; } static void query_values_on_cpu(void *_err) { int *err = _err; struct powernow_k8_data *data = __this_cpu_read(powernow_data); *err = query_current_values_with_pending_wait(data); } static unsigned int powernowk8_get(unsigned int cpu) { struct powernow_k8_data *data = per_cpu(powernow_data, cpu); unsigned int khz = 0; int err; if (!data) return 0; smp_call_function_single(cpu, query_values_on_cpu, &err, true); if (err) goto out; if (cpu_family == CPU_HW_PSTATE) khz = find_khz_freq_from_pstate(data->powernow_table, data->currpstate); else khz = find_khz_freq_from_fid(data->currfid); out: return khz; } static void _cpb_toggle_msrs(bool t) { int cpu; get_online_cpus(); rdmsr_on_cpus(cpu_online_mask, MSR_K7_HWCR, msrs); for_each_cpu(cpu, cpu_online_mask) { struct msr *reg = per_cpu_ptr(msrs, cpu); if (t) reg->l &= ~BIT(25); else reg->l |= BIT(25); } wrmsr_on_cpus(cpu_online_mask, MSR_K7_HWCR, msrs); put_online_cpus(); } /* * Switch on/off core performance boosting. * * 0=disable * 1=enable. */ static void cpb_toggle(bool t) { if (!cpb_capable) return; if (t && !cpb_enabled) { cpb_enabled = true; _cpb_toggle_msrs(t); printk(KERN_INFO PFX "Core Boosting enabled.\n"); } else if (!t && cpb_enabled) { cpb_enabled = false; _cpb_toggle_msrs(t); printk(KERN_INFO PFX "Core Boosting disabled.\n"); } } static ssize_t store_cpb(struct cpufreq_policy *policy, const char *buf, size_t count) { int ret = -EINVAL; unsigned long val = 0; ret = strict_strtoul(buf, 10, &val); if (!ret && (val == 0 || val == 1) && cpb_capable) cpb_toggle(val); else return -EINVAL; return count; } static ssize_t show_cpb(struct cpufreq_policy *policy, char *buf) { return sprintf(buf, "%u\n", cpb_enabled); } #define define_one_rw(_name) \ static struct freq_attr _name = \ __ATTR(_name, 0644, show_##_name, store_##_name) define_one_rw(cpb); static struct freq_attr *powernow_k8_attr[] = { &cpufreq_freq_attr_scaling_available_freqs, &cpb, NULL, }; static struct cpufreq_driver cpufreq_amd64_driver = { .verify = powernowk8_verify, .target = powernowk8_target, .bios_limit = acpi_processor_get_bios_limit, .init = powernowk8_cpu_init, .exit = __devexit_p(powernowk8_cpu_exit), .get = powernowk8_get, .name = "powernow-k8", .owner = THIS_MODULE, .attr = powernow_k8_attr, }; /* * Clear the boost-disable flag on the CPU_DOWN path so that this cpu * cannot block the remaining ones from boosting. On the CPU_UP path we * simply keep the boost-disable flag in sync with the current global * state. */ static int cpb_notify(struct notifier_block *nb, unsigned long action, void *hcpu) { unsigned cpu = (long)hcpu; u32 lo, hi; switch (action) { case CPU_UP_PREPARE: case CPU_UP_PREPARE_FROZEN: if (!cpb_enabled) { rdmsr_on_cpu(cpu, MSR_K7_HWCR, &lo, &hi); lo |= BIT(25); wrmsr_on_cpu(cpu, MSR_K7_HWCR, lo, hi); } break; case CPU_DOWN_PREPARE: case CPU_DOWN_PREPARE_FROZEN: rdmsr_on_cpu(cpu, MSR_K7_HWCR, &lo, &hi); lo &= ~BIT(25); wrmsr_on_cpu(cpu, MSR_K7_HWCR, lo, hi); break; default: break; } return NOTIFY_OK; } static struct notifier_block cpb_nb = { .notifier_call = cpb_notify, }; /* driver entry point for init */ static int __cpuinit powernowk8_init(void) { unsigned int i, supported_cpus = 0, cpu; int rv; for_each_online_cpu(i) { int rc; smp_call_function_single(i, check_supported_cpu, &rc, 1); if (rc == 0) supported_cpus++; } if (supported_cpus != num_online_cpus()) return -ENODEV; printk(KERN_INFO PFX "Found %d %s (%d cpu cores) (" VERSION ")\n", num_online_nodes(), boot_cpu_data.x86_model_id, supported_cpus); if (boot_cpu_has(X86_FEATURE_CPB)) { cpb_capable = true; msrs = msrs_alloc(); if (!msrs) { printk(KERN_ERR "%s: Error allocating msrs!\n", __func__); return -ENOMEM; } register_cpu_notifier(&cpb_nb); rdmsr_on_cpus(cpu_online_mask, MSR_K7_HWCR, msrs); for_each_cpu(cpu, cpu_online_mask) { struct msr *reg = per_cpu_ptr(msrs, cpu); cpb_enabled |= !(!!(reg->l & BIT(25))); } printk(KERN_INFO PFX "Core Performance Boosting: %s.\n", (cpb_enabled ? "on" : "off")); } rv = cpufreq_register_driver(&cpufreq_amd64_driver); if (rv < 0 && boot_cpu_has(X86_FEATURE_CPB)) { unregister_cpu_notifier(&cpb_nb); msrs_free(msrs); msrs = NULL; } return rv; } /* driver entry point for term */ static void __exit powernowk8_exit(void) { dprintk("exit\n"); if (boot_cpu_has(X86_FEATURE_CPB)) { msrs_free(msrs); msrs = NULL; unregister_cpu_notifier(&cpb_nb); } cpufreq_unregister_driver(&cpufreq_amd64_driver); } MODULE_AUTHOR("Paul Devriendt and " "Mark Langsdorf "); MODULE_DESCRIPTION("AMD Athlon 64 and Opteron processor frequency driver."); MODULE_LICENSE("GPL"); late_initcall(powernowk8_init); module_exit(powernowk8_exit);