Oskar Enoksson (enok@lysator.liu.se) just uploaded a new patch set to gerrit, which you can find at http://review.coreboot.org/239
-gerrit
commit 00bff5758e8104153ff9668fe739026ab977ab9a Author: Oskar Enoksson enok@lysator.liu.se Date: Thu Oct 6 18:43:43 2011 +0200
Fixes several issues with amd k8 SSDT P-state generation
For multi-socket CPU the current implementation emitted Processor objects for cores in the first CPU only. This commit fixes the bug. One caveat though: the unlikely case of mixed CPU models is still not handled correctly.
Second issue fixed: One loop was wrong in case a processor in the table declares no P-states at all. The rewritten loop is safe. Some possibly dangerous array lengths were also fixed.
Third issue: on MP-boards the recommended ramp-voltage (RVO) is 0mV according to the BKDG. The current implementation always set it to 25mV. This commit selects 0 or 25mV depending on CONFIG_MAX_PHYSICAL_CPUS.
Signed-off-by: Oskar Enoksson enok@lysator.liu.se Change-Id: I61f6e2210b84ccba33a36c5efc866447b7134417 --- src/cpu/amd/model_fxx/powernow_acpi.c | 81 +++++++++++++++++++++++++-------- 1 files changed, 61 insertions(+), 20 deletions(-)
diff --git a/src/cpu/amd/model_fxx/powernow_acpi.c b/src/cpu/amd/model_fxx/powernow_acpi.c index bbcf013..c49322f 100644 --- a/src/cpu/amd/model_fxx/powernow_acpi.c +++ b/src/cpu/amd/model_fxx/powernow_acpi.c @@ -586,15 +586,17 @@ static int pstates_algorithm(u32 pcontrol_blk, u8 plen, u8 onlyBSP) u8 cmp_cap; struct cpuentry *data = NULL; uint32_t control; - int i = 0, index, len = 0, Pstate_num = 0; + int i = 0, index = 0, len = 0, Pstate_num = 0, dev = 0; msr_t msr; - u8 Pstate_fid[10]; - u16 Pstate_feq[10]; - u8 Pstate_vid[10]; - u32 Pstate_power[10]; + u8 Pstate_fid[MAXP+1]; + u16 Pstate_feq[MAXP+1]; + u8 Pstate_vid[MAXP+1]; + u32 Pstate_power[MAXP+1]; u8 Max_fid, Start_fid, Start_vid, Max_vid; struct cpuid_result cpuid1 = cpuid(0x80000001);
+ // Because I don't know how to read msr registers from + // other CPU's I assume they all have the same SYSCONF values msr = rdmsr(0xc0010042); Max_fid = (msr.lo & 0x3F0000) >> 16; Max_vid = (msr.hi & 0x3F0000) >> 16; @@ -619,25 +621,57 @@ static int pstates_algorithm(u32 pcontrol_blk, u8 plen, u8 onlyBSP) printk(BIOS_WARNING, "Unknown CPU, please update the powernow_acpi.c\n"); return 0; } + /* See if the CPUID(0x80000007) returned EDX[2:1]==11b */ + cpuid1 = cpuid(0x80000007); + if((cpuid1.edx & 0x6)!=0x6) { + printk(BIOS_INFO, "Processor not capable of performing P-state transitions\n"); + return 0; + } + +#if CONFIG_MAX_PHYSICAL_CPUS==1 + // IRT 80us RVO = 50mV PLL_LOCK_TIME 2us, MVS 25mv, VST 100us + control = (3 << 30) | (2 << 28) | (2 << 20) | (0 << 18) | (5 << 11); +#else + // MP-systems should default to RVO=0mV (no ramp voltage) + // IRT 80us RVO = 0mV PLL_LOCK_TIME 2us, MVS 25mv, VST 100us + control = (3 << 30) | (0 << 28) | (2 << 20) | (0 << 18) | (5 << 11); +#endif + // RVO (Ramp Voltage Offset) + // 00 0mV (default for MP-systems) + // 01 25mV + // 10 50mV (default) + // 11 75mV + // IRT (Isochronous Release Time) + // 00 10uS + // 01 20uS + // 10 40uS + // 11 80uS (default) + // MVS (Maximum Voltage Step) + // 00 25mV (default) + // 01 50mV (reserved) + // 10 100mV (reserved) + // 11 200mV (reserved) + // VST (Voltage Stabilization Time) + // time = value*20uS (default value: 5 => 100uS) + // PLL_LOCK_TIME + // time is value*1uS (often seen value: 2uS) + //
- /* IRT 80us, PLL_LOCK_TIME 2us, MVS 25mv, VST 100us */ - control = (3 << 30) | (2 << 20) | (0 << 18) | (5 << 11) | (1 << 29); len = 0; - Pstate_num = 0;
- Pstate_fid[Pstate_num] = Max_fid; - Pstate_feq[Pstate_num] = fid_to_freq(Max_fid); - Pstate_vid[Pstate_num] = Max_vid; - Pstate_power[Pstate_num] = data->pwr * 100; - Pstate_num++; + Pstate_fid[0] = Max_fid; + Pstate_feq[0] = fid_to_freq(Max_fid); + Pstate_vid[0] = Max_vid; + Pstate_power[0] = data->pwr * 100;
- do { + for(Pstate_num = 1; + (Pstate_num <= MAXP) && (data->pstates[Pstate_num - 1].freqMhz != 0); + Pstate_num++) { Pstate_fid[Pstate_num] = freq_to_fid(data->pstates[Pstate_num - 1].freqMhz) & 0x3f; Pstate_feq[Pstate_num] = data->pstates[Pstate_num - 1].freqMhz; Pstate_vid[Pstate_num] = vid_to_reg(data->pstates[Pstate_num - 1].voltage); Pstate_power[Pstate_num] = data->pstates[Pstate_num - 1].tdp * 100; - Pstate_num++; - } while ((Pstate_num < MAXP) && (data->pstates[Pstate_num - 1].freqMhz != 0)); + }
for (i=0;i<Pstate_num;i++) printk(BIOS_DEBUG, "P#%d freq %d [MHz] voltage %d [mV] TDP %d [mW]\n", i, @@ -645,11 +679,18 @@ static int pstates_algorithm(u32 pcontrol_blk, u8 plen, u8 onlyBSP) vid_from_reg(Pstate_vid[i]), Pstate_power[i]);
- for (index = 0; index < (cmp_cap + 1); index++) { - len += write_pstates_for_core(Pstate_num, Pstate_feq, Pstate_vid, - Pstate_fid, Pstate_power, index, - pcontrol_blk, plen, onlyBSP, control); + for (dev = 0x18; dev < 0x1c; dev++) { + if(dev_find_slot(0, PCI_DEVFN(dev, 0))==NULL) + continue; + + for (i = 0; i < (cmp_cap + 1); i++) { + len += write_pstates_for_core(Pstate_num, Pstate_feq, Pstate_vid, + Pstate_fid, Pstate_power, index+i, + pcontrol_blk, plen, onlyBSP, control); + } + index += i; } + printk(BIOS_DEBUG,"%d Processor objects emitted to SSDT\n",index);
return len; }