From fe849b2ff7afe7437baa1798ecf74d80a4f09388 Mon Sep 17 00:00:00 2001 From: Rudolf Marek Date: Thu, 19 Feb 2009 08:39:16 +0000 Subject: This patch is for AMD boards which can do the P state generation. This just removes the ugly binary DSDT patching and all other related stuff. Stick to infrastructure in previous patch. Signed-off-by: Rudolf Marek Acked-by: Carl-Daniel Hailfinger git-svn-id: svn://svn.coreboot.org/coreboot/trunk@3955 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1 --- src/mainboard/amd/dbm690t/acpi_tables.c | 477 +------------------------------- 1 file changed, 4 insertions(+), 473 deletions(-) (limited to 'src/mainboard/amd/dbm690t/acpi_tables.c') diff --git a/src/mainboard/amd/dbm690t/acpi_tables.c b/src/mainboard/amd/dbm690t/acpi_tables.c index 57d8214e66..f3092fdb82 100644 --- a/src/mainboard/amd/dbm690t/acpi_tables.c +++ b/src/mainboard/amd/dbm690t/acpi_tables.c @@ -27,6 +27,9 @@ #include #include <../../../northbridge/amd/amdk8/amdk8_acpi.h> #include +#include + +extern u16 pm_base; #define DUMP_ACPI_TABLES 0 @@ -120,476 +123,9 @@ void update_ssdtx(void *ssdtx, int i) } -/* -* Details about this algorithm , refert to BDKG 10.5.1 -* Two parts are included, the another is the DSDT reconstruction process -*/ -u32 pstates_algorithm(acpi_header_t * dsdt) -{ - u8 processor_brand[49]; - u32 *v; - struct cpuid_result cpuid1; - - struct power_limit_encoding { - u8 socket_type; - u8 cmp_cap; - u8 pwr_lmt; - u32 power_limit; - }; - u8 Max_fid, Max_vid, Start_fid, Start_vid, Min_fid, Min_vid; - u16 Max_feq; - u8 Pstate_fid[10]; - u16 Pstate_feq[10]; - u8 Pstate_vid[10]; - u32 Pstate_power[10]; - u32 Pstate_volt[10]; - u8 PstateStep, PstateStep_coef; - u8 IntPstateSup; - u8 Pstate_num; - u16 Cur_feq; - u8 Cur_fid; - u8 cmp_cap, pwr_lmt; - u32 power_limit = 0; - u8 index; - u32 i, j; - u32 processor_length, scope_length; - msr_t msr; - u8 *dsdt_pointer; - u8 *pointer1; - u8 *pointer2; - u8 byte_index; - u32 old_dsdt_length, new_dsdt_length; - u32 corefeq, power, transitionlatency, busmasterlatency, control, - status; - u32 new_package_length; - u8 sum, checksum; - u32 fid_multiplier; - static struct power_limit_encoding TDP[20] = { - {0x11, 0x0, 0x8, 62}, - {0x11, 0x1, 0x8, 89}, - {0x11, 0x1, 0xa, 103}, - {0x11, 0x1, 0xc, 125}, - {0x11, 0x0, 0x2, 15}, - {0x11, 0x0, 0x4, 35}, - {0x11, 0x1, 0x2, 35}, - {0x11, 0x0, 0x5, 45}, - {0x11, 0x1, 0x7, 76}, - {0x11, 0x1, 0x6, 65}, - {0x11, 0x1, 0x8, 89}, - {0x11, 0x0, 0x1, 8}, - {0x11, 0x1, 0x1, 22}, - {0x12, 0x0, 0x6, 25}, - {0x12, 0x0, 0x1, 8}, - {0x12, 0x0, 0x2, 9}, - {0x12, 0x0, 0x4, 15}, - {0x12, 0x0, 0xc, 35}, - {0x12, 0x1, 0xc, 35}, - {0x12, 0x1, 0x4, 20} - }; - - /* Get the Processor Brand String using cpuid(0x8000000x) command x=2,3,4 */ - cpuid1 = cpuid(0x80000002); - v = (u32 *) processor_brand; - v[0] = cpuid1.eax; - v[1] = cpuid1.ebx; - v[2] = cpuid1.ecx; - v[3] = cpuid1.edx; - cpuid1 = cpuid(0x80000003); - v[4] = cpuid1.eax; - v[5] = cpuid1.ebx; - v[6] = cpuid1.ecx; - v[7] = cpuid1.edx; - cpuid1 = cpuid(0x80000004); - v[8] = cpuid1.eax; - v[9] = cpuid1.ebx; - v[10] = cpuid1.ecx; - v[11] = cpuid1.edx; - processor_brand[48] = 0; - printk_info("processor_brand=%s\n", processor_brand); - - /* - * Based on the CPU socket type,cmp_cap and pwr_lmt , get the power limit. - * socket_type : 0x10 SocketF; 0x11 AM2/ASB1 ; 0x12 S1G1 - * cmp_cap : 0x0 SingleCore ; 0x1 DualCore - */ - printk_info("Pstates Algorithm ...\n"); - cmp_cap = - (pci_read_config16(dev_find_slot(0, PCI_DEVFN(0x18, 3)), 0xE8) & - 0x3000) >> 12; - cpuid1 = cpuid(0x80000001); - pwr_lmt = ((cpuid1.ebx & 0x1C0) >> 5) | ((cpuid1.ebx & 0x4000) >> 14); - for (index = 0; index <= sizeof(TDP) / sizeof(TDP[0]); index++) - if (TDP[index].socket_type == CPU_SOCKET_TYPE && - TDP[index].cmp_cap == cmp_cap && - TDP[index].pwr_lmt == pwr_lmt) { - power_limit = TDP[index].power_limit; - } - - /* See if the CPUID(0x80000007) returned EDX[2:1]==11b */ - cpuid1 = cpuid(0x80000007); - if ((cpuid1.edx & 0x6) != 0x6) { - printk_info("No valid set of P-states\n"); - return 0; - } - - msr = rdmsr(0xc0010042); - Max_fid = (msr.lo & 0x3F0000) >> 16; - Start_fid = (msr.lo & 0x3F00) >> 8; - Max_vid = (msr.hi & 0x3F0000) >> 16; - Start_vid = (msr.hi & 0x3F00) >> 8; - PstateStep = (msr.hi & 0x1000000) >> 24; - IntPstateSup = (msr.hi & 0x20000000) >> 29; - - /* - * The P1...P[Min+1] VID need PstateStep to calculate - * P[N] = P[N-1]VID + 2^PstateStep - * PstateStep_coef = 2^PstateStep - */ - if (PstateStep == 0) - PstateStep_coef = 1; - else - PstateStep_coef = 2; - - if (IntPstateSup == 0) { - printk_info("No intermediate P-states are supported\n"); - return 0; - } - - /* Get the multipier of the fid frequency */ - /* - * Fid multiplier is always 100 revF and revG. - */ - fid_multiplier = 100; - - /* - * Formula1: CPUFreq = FID * fid_multiplier + 800 - * Formula2: CPUVolt = 1550 - VID * 25 (mv) - * Formula3: Power = (PwrLmt * P[N]Frequency*(P[N]Voltage^2))/(P[0]Frequency * P[0]Voltage^2)) - */ - - /* Construct P0(P[Max]) state */ - Pstate_num = 0; - Max_feq = Max_fid * fid_multiplier + 800; - if (Max_fid == 0x2A && Max_vid != 0x0) { - Min_fid = 0x2; - Pstate_fid[0] = Start_fid + 0xA; /* Start Frequency + 1GHz */ - Pstate_feq[0] = Pstate_fid[0] * fid_multiplier + 800; - Min_vid = Start_vid; - Pstate_vid[0] = Max_vid + 0x2; /* Maximum Voltage - 50mV */ - Pstate_volt[0] = 1550 - Pstate_vid[0] * 25; - Pstate_power[0] = power_limit * 1000; /* mw */ - Pstate_num++; - } else { - Min_fid = Start_fid; - Pstate_fid[0] = Max_fid; - Pstate_feq[0] = Max_feq; - Min_vid = Start_vid; - Pstate_vid[0] = Max_vid + 0x2; - Pstate_volt[0] = 1550 - Pstate_vid[0] * 25; - Pstate_power[0] = power_limit * 1000; /* mw */ - Pstate_num++; - } - - Cur_feq = Max_feq; - Cur_fid = Max_fid; - /* Construct P1 state */ - if (((Max_fid & 0x1) != 0) && ((Max_fid - 0x1) >= (Min_fid + 0x8))) { /* odd value */ - Pstate_fid[1] = Max_fid - 0x1; - Pstate_feq[1] = Pstate_fid[1] * fid_multiplier + 800; - Cur_fid = Pstate_fid[1]; - Cur_feq = Pstate_feq[1]; - if (((Pstate_vid[0] & 0x1) != 0) && ((Pstate_vid[0] - 0x1) < Min_vid)) { /* odd value */ - Pstate_vid[1] = Pstate_vid[0] + 0x1; - Pstate_volt[1] = 1550 - Pstate_vid[1] * 25; - Pstate_power[1] = - (unsigned long long)Pstate_power[0] * - Pstate_feq[1] * Pstate_volt[1] * Pstate_volt[1] / - (Pstate_feq[0] * Pstate_volt[0] * Pstate_volt[0]); - } - if (((Pstate_vid[0] & 0x1) == 0) && ((Pstate_vid[0] - 0x1) < Min_vid)) { /* even value */ - Pstate_vid[1] = Pstate_vid[0] + PstateStep_coef; - Pstate_volt[1] = 1550 - Pstate_vid[1] * 25; - Pstate_power[1] = - (unsigned long long)Pstate_power[0] * - Pstate_feq[1] * Pstate_volt[1] * Pstate_volt[1] / - (Pstate_feq[0] * Pstate_volt[0] * Pstate_volt[0]); - } - Pstate_num++; - } - - if (((Max_fid & 0x1) == 0) && ((Max_fid - 0x2) >= (Min_fid + 0x8))) { /* even value */ - Pstate_fid[1] = Max_fid - 0x2; - Pstate_feq[1] = Pstate_fid[1] * fid_multiplier + 800; - Cur_fid = Pstate_fid[1]; - Cur_feq = Pstate_feq[1]; - if (((Pstate_vid[0] & 0x1) != 0) && ((Pstate_vid[0] - 0x1) < Min_vid)) { /* odd value */ - Pstate_vid[1] = Pstate_vid[0] + 0x1; - Pstate_volt[1] = 1550 - Pstate_vid[1] * 25; - Pstate_power[1] = - (unsigned long long)Pstate_power[0] * - Pstate_feq[1] * Pstate_volt[1] * Pstate_volt[1] / - (Pstate_feq[0] * Pstate_volt[0] * Pstate_volt[0]); - } - if (((Pstate_vid[0] & 0x1) == 0) && ((Pstate_vid[0] - 0x1) < Min_vid)) { /* even value */ - Pstate_vid[1] = Pstate_vid[0] + PstateStep_coef; - Pstate_volt[1] = 1550 - Pstate_vid[1] * 25; - Pstate_power[1] = - (unsigned long long)Pstate_power[0] * - Pstate_feq[1] * Pstate_volt[1] * Pstate_volt[1] / - (Pstate_feq[0] * Pstate_volt[0] * Pstate_volt[0]); - } - - Pstate_num++; - } - - /* Construct P2...P[Min-1] state */ - Cur_fid = Cur_fid - 0x2; - Cur_feq = Cur_fid * fid_multiplier + 800; - while (Cur_feq >= ((Min_fid * fid_multiplier) + 800) * 2) { - Pstate_fid[Pstate_num] = Cur_fid; - Pstate_feq[Pstate_num] = - Pstate_fid[Pstate_num] * fid_multiplier + 800; - Cur_fid = Cur_fid - 0x2; - Cur_feq = Cur_fid * fid_multiplier + 800; - if (Pstate_vid[Pstate_num - 1] >= Min_vid) { - Pstate_vid[Pstate_num] = Pstate_vid[Pstate_num - 1]; - Pstate_volt[Pstate_num] = Pstate_volt[Pstate_num - 1]; - Pstate_power[Pstate_num] = Pstate_power[Pstate_num - 1]; - } else { - Pstate_vid[Pstate_num] = - Pstate_vid[Pstate_num - 1] + PstateStep_coef; - Pstate_volt[Pstate_num] = - 1550 - Pstate_vid[Pstate_num] * 25; - Pstate_power[Pstate_num] = - (unsigned long long)Pstate_power[0] * - Pstate_feq[Pstate_num] * Pstate_volt[Pstate_num] * - Pstate_volt[Pstate_num] / (Pstate_feq[0] * - Pstate_volt[0] * - Pstate_volt[0]); - } - Pstate_num++; - } - - /* Constuct P[Min] State */ - if (Max_fid == 0x2A && Max_vid != 0x0) { - Pstate_fid[Pstate_num] = 0x2; - Pstate_feq[Pstate_num] = - Pstate_fid[Pstate_num] * fid_multiplier + 800; - Pstate_vid[Pstate_num] = Min_vid; - Pstate_volt[Pstate_num] = 1550 - Pstate_vid[Pstate_num] * 25; - Pstate_power[Pstate_num] = - (unsigned long long)Pstate_power[0] * - Pstate_feq[Pstate_num] * Pstate_volt[Pstate_num] * - Pstate_volt[Pstate_num] / (Pstate_feq[0] * Pstate_volt[0] * - Pstate_volt[0]); - Pstate_num++; - } else { - Pstate_fid[Pstate_num] = Start_fid; - Pstate_feq[Pstate_num] = - Pstate_fid[Pstate_num] * fid_multiplier + 800; - Pstate_vid[Pstate_num] = Min_vid; - Pstate_volt[Pstate_num] = 1550 - Pstate_vid[Pstate_num] * 25; - Pstate_power[Pstate_num] = - (unsigned long long)Pstate_power[0] * - Pstate_feq[Pstate_num] * Pstate_volt[Pstate_num] * - Pstate_volt[Pstate_num] / (Pstate_feq[0] * Pstate_volt[0] * - Pstate_volt[0]); - Pstate_num++; - } - - /* Print Pstate freq,vid,volt,power */ - - for (index = 0; index < Pstate_num; index++) { - printk_info("Pstate_freq[%d] = %dMHz\t", index, - Pstate_feq[index]); - printk_info("Pstate_vid[%d] = %d\t", index, Pstate_vid[index]); - printk_info("Pstate_volt[%d] = %dmv\t", index, - Pstate_volt[index]); - printk_info("Pstate_power[%d] = %dmw\n", index, - Pstate_power[index]); - } - - /* - * Modify the DSDT Table to put the actural _PSS package - * corefeq-->Pstate_feq[index] - * power-->Pstate_power[index] - * transitionlatency-->0x64 - * busmasterlatency-->0x7, - * control--> 0xE8202800| Pstate_vid[index]<<6 | Pstate_fid[index] - * status --> Pstate_vid[index]<<6 | Pstate_fid[index] - * Get the _PSS control method Sig. - */ - - dsdt_pointer = (u8 *) dsdt; - old_dsdt_length = dsdt->length; - new_dsdt_length = old_dsdt_length; - printk_info("DSDT reconstruction...\n"); - for (i = 0x20; i < new_dsdt_length; i++) - if ((*(dsdt_pointer + i) == '_') - && (*(dsdt_pointer + i + 1) == 'P') - && (*(dsdt_pointer + i + 2) == 'S') - && (*(dsdt_pointer + i + 3) == 'S')) { - - if ((*(dsdt_pointer + i + 4) != - 0x12) | (*(dsdt_pointer + i + 5) != - 0x4B) | (*(dsdt_pointer + i + 6) != - 0x10)) { - printk_info - ("Error:No _PSS package leader byte!\n"); - } else { - new_package_length = - 0x10B - Defpkglength * (Maxpstate - - Pstate_num); - /* two Pstates length will larger than 63, so we need not worry about the length */ - if (new_package_length > 63) { - *(dsdt_pointer + i + 5) = - 0x40 | (new_package_length & 0xf); - *(dsdt_pointer + i + 6) = - (new_package_length & 0xff0) >> 4; - } - *(dsdt_pointer + i + 7) = Pstate_num; - } - - if ((*(dsdt_pointer + i + 8) != - 0x12) | (*(dsdt_pointer + i + 9) != - 0x20) | (*(dsdt_pointer + i + 10) != 0x6)) - printk_info - ("Error:No package leader for the first Pstate!\n"); - for (index = 0; index < Pstate_num; index++) { - corefeq = Pstate_feq[index]; - power = Pstate_power[index]; - transitionlatency = 0x64; - busmasterlatency = 0x7; - control = - (0x3 << 30) | /* IRT */ - (0x2 << 28) | /* RVO */ - (0x1 << 27) | /* ExtType */ - (0x2 << 20) | /* PLL_LOCK_TIME */ - (0x0 << 18) | /* MVS */ - (0x5 << 11) | /* VST */ - (Pstate_vid[index] << 6) | - Pstate_fid[index]; - status = - (Pstate_vid[index] << 6) | - Pstate_fid[index]; - for (byte_index = 0; byte_index < 4; - byte_index++) { - *(dsdt_pointer + i + 0xC + - Defpkglength * index + byte_index) = - corefeq >> (8 * byte_index); - *(dsdt_pointer + i + 0xC + - Defpkglength * index + 0x5 + - byte_index) = - power >> (8 * byte_index); - *(dsdt_pointer + i + 0xC + - Defpkglength * index + 0x5 * 2 + - byte_index) = - transitionlatency >> (8 * byte_index); - *(dsdt_pointer + i + 0xC + - Defpkglength * index + 0x5 * 3 + - byte_index) = - busmasterlatency >> (8 * byte_index); - *(dsdt_pointer + i + 0xC + - Defpkglength * index + 0x5 * 4 + - byte_index) = - control >> (8 * byte_index); - *(dsdt_pointer + i + 0xC + - Defpkglength * index + 0x5 * 5 + - byte_index) = - status >> (8 * byte_index); - } - } - pointer1 = - dsdt_pointer + i + 8 + Pstate_num * Defpkglength; - pointer2 = - dsdt_pointer + i + 8 + Maxpstate * Defpkglength; - while (pointer2 < dsdt_pointer + new_dsdt_length) { - *pointer1 = *pointer2; - pointer1++; - pointer2++; - } - /* Recalcute the DSDT length */ - new_dsdt_length = - new_dsdt_length - Defpkglength * (Maxpstate - - Pstate_num); - - /* Search the first processor(CPUx) item and recalculate the processor length */ - for (j = 0; (dsdt_pointer + i - j) > dsdt_pointer; j++) { - if ((*(dsdt_pointer + i - j) == 'C') - && (*(dsdt_pointer + i - j + 1) == 'P') - && (*(dsdt_pointer + i - j + 2) == 'U')) { - processor_length = - ((*(dsdt_pointer + i - j - 1) << 4) - | (*(dsdt_pointer + i - j - 2) & - 0xf)); - processor_length = - processor_length - - Defpkglength * (Maxpstate - - Pstate_num); - *(dsdt_pointer + i - j - 2) = - (processor_length & 0xf) | 0x40; - *(dsdt_pointer + i - j - 1) = - (processor_length & 0xff0) >> 4; - break; - } - } - - /* Search the first scope(_PR_) item and recalculate the scope length */ - for (j = 0; (dsdt_pointer + i - j) > dsdt_pointer; j++) { - if ((*(dsdt_pointer + i - j) == '_') - && (*(dsdt_pointer + i - j + 1) == 'P') - && (*(dsdt_pointer + i - j + 2) == 'R') - && (*(dsdt_pointer + i - j + 3) == '_')) { - scope_length = - ((*(dsdt_pointer + i - j - 1) << 4) - | (*(dsdt_pointer + i - j - 2) & - 0xf)); - scope_length = - scope_length - - Defpkglength * (Maxpstate - - Pstate_num); - *(dsdt_pointer + i - j - 2) = - (scope_length & 0xf) | 0x40; - *(dsdt_pointer + i - j - 1) = - (scope_length & 0xff0) >> 4; - break; - } - } - - } - - /* Recalculate the DSDT length and fill back to the table */ - *(dsdt_pointer + 0x4) = new_dsdt_length; - *(dsdt_pointer + 0x5) = new_dsdt_length >> 8; - - /* - * Recalculate the DSDT checksum and fill back to the table - * We must make sure the sum of the whole table is 0 - */ - sum = 0; - for (i = 0; i < new_dsdt_length; i++) - if (i != 9) - sum = sum + *(dsdt_pointer + i); - checksum = 0x100 - sum; - *(dsdt_pointer + 0x9) = checksum; - - /*Check the DSDT Table */ - /* - * printk_info("The new DSDT table length is %x\n", new_dsdt_length); - * printk_info("Details is as below:\n"); - * for(i=0; i< new_dsdt_length; i++){ - * printk_info("%x\t",(unsigned char)*(dsdt_pointer+i)); - * if( ((i+1)&0x7) == 0x0) - * printk_info("**0x%x**\n",i-7); - *} - */ - - return 1; - -} - unsigned long acpi_fill_ssdt_generator(unsigned long current, char *oem_table_id) { k8acpi_write_vars(); + amd_model_fxx_generate_powernow(pm_base + 8, 6, 1); return (unsigned long) (acpigen_get_current()); } @@ -717,11 +253,6 @@ unsigned long write_acpi_tables(unsigned long start) dsdt = (acpi_header_t *) current; memcpy((void *)dsdt, (void *)AmlCode, ((acpi_header_t *) AmlCode)->length); - if (!pstates_algorithm(dsdt)) - printk_debug("pstates_algorithm error!\n"); - else - printk_debug("pstates_algorithm success.\n"); - current += dsdt->length; printk_debug("ACPI: * DSDT @ %08x Length %x\n", dsdt, dsdt->length); /* FADT */ -- cgit v1.2.3