/* * This file is part of the coreboot project. * * Copyright (C) 2007-2008 coresystems GmbH * * 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., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include #include #include #include #include "raminit.h" #include "i945.h" #include "lib/memset.c" #define DEBUG_RAM_SETUP /* Debugging macros. */ #if defined(DEBUG_RAM_SETUP) #define PRINTK_DEBUG(x...) printk_debug(x) #else #define PRINTK_DEBUG(x...) #endif #define RAM_INITIALIZATION_COMPLETE (1 << 19) #define RAM_COMMAND_SELF_REFRESH (0x0 << 16) #define RAM_COMMAND_NOP (0x1 << 16) #define RAM_COMMAND_PRECHARGE (0x2 << 16) #define RAM_COMMAND_MRS (0x3 << 16) #define RAM_COMMAND_EMRS (0x4 << 16) #define RAM_COMMAND_CBR (0x6 << 16) #define RAM_COMMAND_NORMAL (0x7 << 16) #define RAM_EMRS_1 (0x0 << 21) #define RAM_EMRS_2 (0x1 << 21) #define RAM_EMRS_3 (0x2 << 21) static void do_ram_command(u32 command) { u32 reg32; reg32 = MCHBAR32(DCC); reg32 &= ~( (3<<21) | (1<<20) | (1<<19) | (7 << 16) ); reg32 |= command; /* Also set Init Complete */ if (command == RAM_COMMAND_NORMAL) reg32 |= RAM_INITIALIZATION_COMPLETE; PRINTK_DEBUG(" Sending RAM command 0x%08x", reg32); MCHBAR32(DCC) = reg32; /* This is the actual magic */ PRINTK_DEBUG("...done\r\n"); } static void ram_read32(u32 offset) { PRINTK_DEBUG(" ram read: %08x\r\n", offset); read32(offset); } #ifdef DEBUG_RAM_SETUP static void sdram_dump_mchbar_registers(void) { int i; printk_debug("Dumping MCHBAR Registers\r\n"); for (i=0; i<0xfff; i+=4) { if (MCHBAR32(i) == 0) continue; printk_debug("0x%04x: 0x%08x\r\n", i, MCHBAR32(i)); } } #endif static int sdram_capabilities_max_supported_memory_frequency(void) { u32 reg32; reg32 = pci_read_config32(PCI_DEV(0, 0x00, 0), 0xe4); reg32 &= (7 << 0); switch (reg32) { case 4: return 400; case 3: return 533; case 2: return 667; } /* Newer revisions of this chipset rather support faster memory clocks, * so if it's a reserved value, return the fastest memory clock that we * know of and can handle */ return 667; } /** * @brief determine whether chipset is capable of dual channel interleaved mode * * @return 1 if interleaving is supported, 0 otherwise */ static int sdram_capabilities_interleave(void) { u32 reg32; reg32 = pci_read_config8(PCI_DEV(0, 0x00,0), 0xe4); reg32 >>= 25; reg32 &= 1; return (!reg32); } /** * @brief determine whether chipset is capable of two memory channels * * @return 1 if dual channel operation is supported, 0 otherwise */ static int sdram_capabilities_dual_channel(void) { u32 reg32; reg32 = pci_read_config8(PCI_DEV(0, 0x00,0), 0xe4); reg32 >>= 24; reg32 &= 1; return (!reg32); } static int sdram_capabilities_enhanced_addressing_xor(void) { u8 reg8; reg8 = pci_read_config8(PCI_DEV(0, 0x00, 0), 0xe5); /* CAPID0 + 5 */ reg8 &= (1 << 7); return (!reg8); } static int sdram_capabilities_two_dimms_per_channel(void) { u8 reg8; reg8 = pci_read_config8(PCI_DEV(0, 0x00, 0), 0xe8); /* CAPID0 + 8 */ reg8 &= (1 << 0); return (reg8 != 0); } static int sdram_capabilities_MEM4G_disable(void) { u8 reg8; reg8 = pci_read_config8(PCI_DEV(0, 0x00, 0), 0xe5); reg8 &= (1 << 0); return (reg8 != 0); } static void sdram_detect_errors(void) { u8 reg8; reg8 = pci_read_config8(PCI_DEV(0, 0x1f, 0), 0xa2); if (reg8 & ((1<<7)|(1<<2))) { if (reg8 & (1<<2)) { printk_debug("SLP S4# Assertion Width Violation.\r\n"); pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, reg8); } if (reg8 & (1<<7)) { printk_debug("DRAM initialization was interrupted.\r\n"); reg8 &= ~(1<<7); pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, reg8); } /* Set SLP_S3# Assertion Stretch Enable */ reg8 = pci_read_config8(PCI_DEV(0, 0x1f, 0), 0xa4); /* GEN_PMCON_3 */ reg8 |= (1 << 3); pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa4, reg8); printk_debug("Reset required.\r\n"); outb(0x00, 0xcf9); outb(0x0e, 0xcf9); for (;;) ; /* Wait for reset! */ } /* Set DRAM initialization bit in ICH7 */ reg8 = pci_read_config8(PCI_DEV(0, 0x1f, 0), 0xa2); reg8 |= (1<<7); pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, reg8); } /** * @brief Get generic DIMM parameters. * @param sysinfo Central memory controller information structure * * This function gathers several pieces of information for each system DIMM: * o DIMM width (x8 / x16) * o DIMM sides (single sided / dual sided) * * Also, some non-supported scenarios are detected. */ static void sdram_get_dram_configuration(struct sys_info *sysinfo) { u32 dimm_mask = 0; int i; /** * i945 supports two DIMMs, in two configurations: * * - single channel with two dimms * - dual channel with one dimm per channel * * In practice dual channel mainboards have their spd at 0x50, 0x52 * whereas single channel configurations have their spd at 0x50/x51 * * The capability register knows a lot about the channel configuration * but for now we stick with the information we gather from the SPD * ROMs */ if (sdram_capabilities_dual_channel()) { sysinfo->dual_channel = 1; printk_debug("This mainboard supports Dual Channel Operation.\n"); } else { sysinfo->dual_channel = 0; printk_debug("This mainboard supports only Single Channel Operation.\n"); } /** * Since we only support two DIMMs in total, there is a limited number * of combinations. This function returns the type of DIMMs. * return value: * [0:7] lower DIMM population * [8-15] higher DIMM population * [16] dual channel? * * There are 5 different possible populations for a DIMM socket: * 1. x16 double sided (X16DS) * 2. x8 double sided (X8DS) * 3. x16 single sided (X16SS) * 4. x8 double stacked (X8DDS) * 5. not populated (NC) * * For the return value we start counting at zero. * */ for (i=0; i<(2 * DIMM_SOCKETS); i++) { u8 reg8, device = DIMM_SPD_BASE + i; /* Initialize the socket information with a sane value */ sysinfo->dimm[i] = SYSINFO_DIMM_NOT_POPULATED; if (!sdram_capabilities_dual_channel() && (i >> 1)) continue; if (!sdram_capabilities_two_dimms_per_channel() && (i& 1)) continue; printk_debug("DDR II Channel %d Socket %d: ", (i >> 1), (i & 1)); if (spd_read_byte(device, SPD_MEMORY_TYPE) != SPD_MEMORY_TYPE_SDRAM_DDR2) { printk_debug("N/A\n"); continue; } reg8 = spd_read_byte(device, SPD_DIMM_CONFIG_TYPE); if (reg8 == ERROR_SCHEME_ECC) die("Error: ECC memory not supported by this chipset\r\n"); reg8 = spd_read_byte(device, SPD_MODULE_ATTRIBUTES); if (reg8 & MODULE_BUFFERED) die("Error: Buffered memory not supported by this chipset\r\n"); if (reg8 & MODULE_REGISTERED) die("Error: Registered memory not supported by this chipset\r\n"); switch (spd_read_byte(device, SPD_PRIMARY_SDRAM_WIDTH)) { case 0x08: switch (spd_read_byte(device, SPD_NUM_DIMM_BANKS) & 0x0f) { case 1: printk_debug("x8DDS\r\n"); sysinfo->dimm[i] = SYSINFO_DIMM_X8DDS; break; case 0: printk_debug("x8DS\r\n"); sysinfo->dimm[i] = SYSINFO_DIMM_X8DS; break; default: printk_debug ("Unsupported.\r\n"); } break; case 0x10: switch (spd_read_byte(device, SPD_NUM_DIMM_BANKS) & 0x0f) { case 1: printk_debug("x16DS\r\n"); sysinfo->dimm[i] = SYSINFO_DIMM_X16DS; break; case 0: printk_debug("x16SS\r\n"); sysinfo->dimm[i] = SYSINFO_DIMM_X16SS; break; default: printk_debug ("Unsupported.\r\n"); } break; default: die("Unsupported DDR-II memory width.\r\n"); } dimm_mask |= (1 << i); } if (!dimm_mask) { die("No memory installed.\r\n"); } /* The chipset might be able to do this. What the heck, legacy bios * just beeps when a single DIMM is in the Channel 1 socket. So let's * not bother until someone needs this enough to cope with it. */ if (!(dimm_mask & ((1 << DIMM_SOCKETS) - 1))) { printk_err("Channel 0 has no memory populated. This setup is not usable. Please move the DIMM.\r\n"); } } /** * @brief determine if any DIMMs are stacked * * @param sysinfo central sysinfo data structure. */ static void sdram_verify_package_type(struct sys_info * sysinfo) { int i; /* Assume no stacked DIMMs are available until we find one */ sysinfo->package = 0; for (i=0; i<2*DIMM_SOCKETS; i++) { if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; /* Is the current DIMM a stacked DIMM? */ if (spd_read_byte(DIMM_SPD_BASE + i, SPD_NUM_DIMM_BANKS) & (1 << 4)) sysinfo->package = 1; } } static u8 sdram_possible_cas_latencies(struct sys_info * sysinfo) { int i; u8 cas_mask; /* Setup CAS mask with all supported CAS Latencies */ cas_mask = SPD_CAS_LATENCY_DDR2_3 | SPD_CAS_LATENCY_DDR2_4 | SPD_CAS_LATENCY_DDR2_5; for (i=0; i<2*DIMM_SOCKETS; i++) { if (sysinfo->dimm[i] != SYSINFO_DIMM_NOT_POPULATED) cas_mask &= spd_read_byte(DIMM_SPD_BASE + i, SPD_ACCEPTABLE_CAS_LATENCIES); } if(!cas_mask) { die("No DDR-II modules with accepted CAS latencies found.\n"); } return cas_mask; } static void sdram_detect_cas_latency_and_ram_speed(struct sys_info * sysinfo, u8 cas_mask) { int i, j, idx; int lowest_common_cas = 0; int max_ram_speed; const u8 ddr2_speeds_table[] = { 0x50, 0x60, /* DDR2 400: tCLK = 5.0ns tAC = 0.6ns */ 0x3d, 0x50, /* DDR2 533: tCLK = 3.75ns tAC = 0.5ns */ 0x30, 0x45, /* DDR2 667: tCLK = 3.0ns tAC = 0.45ns */ }; const u8 spd_lookup_table[] = { SPD_MIN_CYCLE_TIME_AT_CAS_MAX, SPD_ACCESS_TIME_FROM_CLOCK, SPD_SDRAM_CYCLE_TIME_2ND, SPD_ACCESS_TIME_FROM_CLOCK_2ND, SPD_SDRAM_CYCLE_TIME_3RD, SPD_ACCESS_TIME_FROM_CLOCK_3RD }; switch (sdram_capabilities_max_supported_memory_frequency()) { case 400: max_ram_speed = 0; break; case 533: max_ram_speed = 1; break; case 667: max_ram_speed = 2; break; } sysinfo->memory_frequency = 0; sysinfo->cas = 0; if (cas_mask & SPD_CAS_LATENCY_DDR2_3) { lowest_common_cas = 3; } else if (cas_mask & SPD_CAS_LATENCY_DDR2_4) { lowest_common_cas = 4; } else if (cas_mask & SPD_CAS_LATENCY_DDR2_5) { lowest_common_cas = 5; } PRINTK_DEBUG("lowest common cas = %d\n", lowest_common_cas); for (j = max_ram_speed; j>=0; j--) { int freq_cas_mask = cas_mask; PRINTK_DEBUG("Probing Speed %d\n", j); for (i=0; i<2*DIMM_SOCKETS; i++) { int current_cas_mask; PRINTK_DEBUG(" DIMM: %d\n", i); if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) { continue; } current_cas_mask = spd_read_byte(DIMM_SPD_BASE + i, SPD_ACCEPTABLE_CAS_LATENCIES); while (current_cas_mask) { int highest_supported_cas = 0, current_cas = 0; PRINTK_DEBUG(" Current CAS mask: %04x; ", current_cas_mask); if (current_cas_mask & SPD_CAS_LATENCY_DDR2_5) { highest_supported_cas = 5; } else if (current_cas_mask & SPD_CAS_LATENCY_DDR2_4) { highest_supported_cas = 4; } else if (current_cas_mask & SPD_CAS_LATENCY_DDR2_3) { highest_supported_cas = 3; } if (current_cas_mask & SPD_CAS_LATENCY_DDR2_3) { current_cas = 3; } else if (current_cas_mask & SPD_CAS_LATENCY_DDR2_4) { current_cas = 4; } else if (current_cas_mask & SPD_CAS_LATENCY_DDR2_5) { current_cas = 5; } idx = highest_supported_cas - current_cas; PRINTK_DEBUG("idx=%d, ", idx); PRINTK_DEBUG("tCLK=%x, ", spd_read_byte(DIMM_SPD_BASE + i, spd_lookup_table[2*idx])); PRINTK_DEBUG("tAC=%x", spd_read_byte(DIMM_SPD_BASE + i, spd_lookup_table[(2*idx)+1])); if (spd_read_byte(DIMM_SPD_BASE + i, spd_lookup_table[2*idx]) <= ddr2_speeds_table[2*j] && spd_read_byte(DIMM_SPD_BASE + i, spd_lookup_table[(2*idx)+1]) <= ddr2_speeds_table[(2*j)+1]) { PRINTK_DEBUG(": OK\n"); break; } PRINTK_DEBUG(": Not fast enough!\n"); current_cas_mask &= ~(1 << (current_cas)); } freq_cas_mask &= current_cas_mask; if (!current_cas_mask) { PRINTK_DEBUG(" No valid CAS for this speed on DIMM %d\n", i); break; } } PRINTK_DEBUG(" freq_cas_mask for speed %d: %04x\n", j, freq_cas_mask); if (freq_cas_mask) { switch (j) { case 0: sysinfo->memory_frequency = 400; break; case 1: sysinfo->memory_frequency = 533; break; case 2: sysinfo->memory_frequency = 667; break; } if (freq_cas_mask & SPD_CAS_LATENCY_DDR2_3) { sysinfo->cas = 3; } else if (freq_cas_mask & SPD_CAS_LATENCY_DDR2_4) { sysinfo->cas = 4; } else if (freq_cas_mask & SPD_CAS_LATENCY_DDR2_5) { sysinfo->cas = 5; } break; } } if (sysinfo->memory_frequency && sysinfo->cas) { printk_debug("Memory will be driven at %dMHz with CAS=%d clocks\n", sysinfo->memory_frequency, sysinfo->cas); } else { die("Could not find common memory frequency and CAS\n"); } } static void sdram_detect_smallest_tRAS(struct sys_info * sysinfo) { int i; int tRAS_time; int tRAS_cycles; int freq_multiplier = 0; switch (sysinfo->memory_frequency) { case 400: freq_multiplier = 0x14; break; /* 5ns */ case 533: freq_multiplier = 0x0f; break; /* 3.75ns */ case 667: freq_multiplier = 0x0c; break; /* 3ns */ } tRAS_cycles = 4; /* 4 clocks minimum */ tRAS_time = tRAS_cycles * freq_multiplier; for (i=0; i<2*DIMM_SOCKETS; i++) { u8 reg8; if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; reg8 = spd_read_byte(DIMM_SPD_BASE + i, SPD_MIN_ACTIVE_TO_PRECHARGE_DELAY); if (!reg8) { die("Invalid tRAS value.\n"); } while ((tRAS_time >> 2) < reg8) { tRAS_time += freq_multiplier; tRAS_cycles++; } } if(tRAS_cycles > 0x18) { die("DDR-II Module does not support this frequency (tRAS error)\n"); } printk_debug("tRAS = %d cycles\n", tRAS_cycles); sysinfo->tras = tRAS_cycles; } static void sdram_detect_smallest_tRP(struct sys_info * sysinfo) { int i; int tRP_time; int tRP_cycles; int freq_multiplier = 0; switch (sysinfo->memory_frequency) { case 400: freq_multiplier = 0x14; break; /* 5ns */ case 533: freq_multiplier = 0x0f; break; /* 3.75ns */ case 667: freq_multiplier = 0x0c; break; /* 3ns */ } tRP_cycles = 2; /* 2 clocks minimum */ tRP_time = tRP_cycles * freq_multiplier; for (i=0; i<2*DIMM_SOCKETS; i++) { u8 reg8; if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; reg8 = spd_read_byte(DIMM_SPD_BASE + i, SPD_MIN_ROW_PRECHARGE_TIME); if (!reg8) { die("Invalid tRP value.\n"); } while (tRP_time < reg8) { tRP_time += freq_multiplier; tRP_cycles++; } } if(tRP_cycles > 6) { die("DDR-II Module does not support this frequency (tRP error)\n"); } printk_debug("tRP = %d cycles\n", tRP_cycles); sysinfo->trp = tRP_cycles; } static void sdram_detect_smallest_tRCD(struct sys_info * sysinfo) { int i; int tRCD_time; int tRCD_cycles; int freq_multiplier = 0; switch (sysinfo->memory_frequency) { case 400: freq_multiplier = 0x14; break; /* 5ns */ case 533: freq_multiplier = 0x0f; break; /* 3.75ns */ case 667: freq_multiplier = 0x0c; break; /* 3ns */ } tRCD_cycles = 2; tRCD_time = tRCD_cycles * freq_multiplier; for (i=0; i<2*DIMM_SOCKETS; i++) { u8 reg8; if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; reg8 = spd_read_byte(DIMM_SPD_BASE + i, SPD_MIN_RAS_TO_CAS_DELAY); if (!reg8) { die("Invalid tRCD value.\n"); } while (tRCD_time < reg8) { tRCD_time += freq_multiplier; tRCD_cycles++; } } if(tRCD_cycles > 6) { die("DDR-II Module does not support this frequency (tRCD error)\n"); } printk_debug("tRCD = %d cycles\n", tRCD_cycles); sysinfo->trcd = tRCD_cycles; } static void sdram_detect_smallest_tWR(struct sys_info * sysinfo) { int i; int tWR_time; int tWR_cycles; int freq_multiplier = 0; switch (sysinfo->memory_frequency) { case 400: freq_multiplier = 0x14; break; /* 5ns */ case 533: freq_multiplier = 0x0f; break; /* 3.75ns */ case 667: freq_multiplier = 0x0c; break; /* 3ns */ } tWR_cycles = 2; /* 2 clocks minimum */ tWR_time = tWR_cycles * freq_multiplier; for (i=0; i<2*DIMM_SOCKETS; i++) { u8 reg8; if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; reg8 = spd_read_byte(DIMM_SPD_BASE + i, SPD_WRITE_RECOVERY_TIME); if (!reg8) { die("Invalid tWR value.\n"); } while (tWR_time < reg8) { tWR_time += freq_multiplier; tWR_cycles++; } } if(tWR_cycles > 5) { die("DDR-II Module does not support this frequency (tWR error)\n"); } printk_debug("tWR = %d cycles\n", tWR_cycles); sysinfo->twr = tWR_cycles; } static void sdram_detect_smallest_tRFC(struct sys_info * sysinfo) { int i, index = 0; const u8 tRFC_cycles[] = { /* 75 105 127.5 */ 15, 21, 26, /* DDR2-400 */ 20, 28, 34, /* DDR2-533 */ 25, 35, 43 /* DDR2-667 */ }; for (i=0; i<2*DIMM_SOCKETS; i++) { u8 reg8; if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; reg8 = sysinfo->banksize[i*2]; switch (reg8) { case 0x04: reg8 = 0; break; case 0x08: reg8 = 1; break; case 0x10: reg8 = 2; break; case 0x20: reg8 = 3; break; } if (sysinfo->dimm[i] == SYSINFO_DIMM_X16DS || sysinfo->dimm[i] == SYSINFO_DIMM_X16SS) reg8++; if (reg8 > 3) { /* Can this happen? Go back to 127.5ns just to be sure * we don't run out of the array. This may be wrong */ printk_debug("DIMM %d is 1Gb x16.. Please report.\n", i); reg8 = 3; } if (reg8 > index) index = reg8; } index--; switch (sysinfo->memory_frequency) { case 667: index += 3; case 533: index += 3; case 400: break; } sysinfo->trfc = tRFC_cycles[index]; printk_debug("tRFC = %d cycles\n", tRFC_cycles[index]); } static void sdram_detect_smallest_refresh(struct sys_info * sysinfo) { int i; sysinfo->refresh = 0; for (i=0; i<2*DIMM_SOCKETS; i++) { int refresh; if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; refresh = spd_read_byte(DIMM_SPD_BASE + i, SPD_REFRESH) & ~(1 << 7); /* 15.6us */ if (!refresh) continue; /* Refresh is slower than 15.6us, use 15.6us */ if (refresh > 2) continue; if (refresh == 2) { sysinfo->refresh = 1; break; } die("DDR-II module has unsupported refresh value\n"); } printk_debug("Refresh: %s\n", sysinfo->refresh?"7.8us":"15.6us"); } static void sdram_verify_burst_length(struct sys_info * sysinfo) { int i; for (i=0; i<2*DIMM_SOCKETS; i++) { if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; if (!(spd_read_byte(DIMM_SPD_BASE + i, SPD_SUPPORTED_BURST_LENGTHS) & SPD_BURST_LENGTH_8)) die("Only DDR-II RAM with burst length 8 is supported by this chipset.\n"); } } static void sdram_program_dram_width(struct sys_info * sysinfo) { u16 c0dramw=0, c1dramw=0; int idx; if (sysinfo->dual_channel) idx = 2; else idx = 1; switch (sysinfo->dimm[0]) { case 0: c0dramw = 0x0000; break; /* x16DS */ case 1: c0dramw = 0x0001; break; /* x8DS */ case 2: c0dramw = 0x0000; break; /* x16SS */ case 3: c0dramw = 0x0005; break; /* x8DDS */ case 4: c0dramw = 0x0000; break; /* NC */ } switch (sysinfo->dimm[idx]) { case 0: c1dramw = 0x0000; break; /* x16DS */ case 1: c1dramw = 0x0010; break; /* x8DS */ case 2: c1dramw = 0x0000; break; /* x16SS */ case 3: c1dramw = 0x0050; break; /* x8DDS */ case 4: c1dramw = 0x0000; break; /* NC */ } if ( !sdram_capabilities_dual_channel() ) { /* Single Channel */ c0dramw |= c1dramw; c1dramw = 0; } MCHBAR16(C0DRAMW) = c0dramw; MCHBAR16(C1DRAMW) = c1dramw; } static void sdram_write_slew_rates(u32 offset, const u32 *slew_rate_table) { int i; for (i=0; i<16; i++) MCHBAR32(offset+(i*4)) = slew_rate_table[i]; } static void sdram_rcomp_buffer_strength_and_slew(struct sys_info *sysinfo) { static const u32 dq2030[] = { 0x08070706, 0x0a090908, 0x0d0c0b0a, 0x12100f0e, 0x1a181614, 0x22201e1c, 0x2a282624, 0x3934302d, 0x0a090908, 0x0c0b0b0a, 0x0e0d0d0c, 0x1211100f, 0x19171513, 0x211f1d1b, 0x2d292623, 0x3f393531 }; static const u32 dq2330[] = { 0x08070706, 0x0a090908, 0x0d0c0b0a, 0x12100f0e, 0x1a181614, 0x22201e1c, 0x2a282624, 0x3934302d, 0x0a090908, 0x0c0b0b0a, 0x0e0d0d0c, 0x1211100f, 0x19171513, 0x211f1d1b, 0x2d292623, 0x3f393531 }; static const u32 cmd2710[] = { 0x07060605, 0x0f0d0b09, 0x19171411, 0x1f1f1d1b, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f, 0x1110100f, 0x0f0d0b09, 0x19171411, 0x1f1f1d1b, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f }; static const u32 cmd3210[] = { 0x0f0d0b0a, 0x17151311, 0x1f1d1b19, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f, 0x18171615, 0x1f1f1c1a, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f, 0x1f1f1f1f }; static const u32 clk2030[] = { 0x0e0d0d0c, 0x100f0f0e, 0x100f0e0d, 0x15131211, 0x1d1b1917, 0x2523211f, 0x2a282927, 0x32302e2c, 0x17161514, 0x1b1a1918, 0x1f1e1d1c, 0x23222120, 0x27262524, 0x2d2b2928, 0x3533312f, 0x3d3b3937 }; static const u32 ctl3215[] = { 0x01010000, 0x03020101, 0x07060504, 0x0b0a0908, 0x100f0e0d, 0x14131211, 0x18171615, 0x1c1b1a19, 0x05040403, 0x07060605, 0x0a090807, 0x0f0d0c0b, 0x14131211, 0x18171615, 0x1c1b1a19, 0x201f1e1d }; static const u32 ctl3220[] = { 0x05040403, 0x07060505, 0x0e0c0a08, 0x1a171411, 0x2825221f, 0x35322f2b, 0x3e3e3b38, 0x3e3e3e3e, 0x09080807, 0x0b0a0a09, 0x0f0d0c0b, 0x1b171311, 0x2825221f, 0x35322f2b, 0x3e3e3b38, 0x3e3e3e3e }; static const u32 nc[] = { 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000 }; static const u32 const * const dual_channel_slew_group_lookup[] = { dq2030, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2030, cmd3210, dq2030, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2030, cmd3210, dq2030, cmd3210, nc, ctl3215, nc, clk2030, dq2030, cmd3210, dq2030, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2030, cmd2710, dq2030, cmd3210, nc, ctl3215, nc, clk2030, nc, nc, dq2030, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2030, cmd3210, dq2030, cmd3210, ctl3215, nc, clk2030, nc, dq2030, cmd3210, dq2030, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2030, cmd3210, dq2030, cmd3210, ctl3215, nc, clk2030, nc, dq2030, cmd2710, dq2030, cmd3210, ctl3215, nc, clk2030, nc, nc, nc, dq2030, cmd3210, nc, ctl3215, nc, clk2030, dq2030, cmd3210, dq2030, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2030, cmd3210, dq2030, cmd3210, nc, ctl3215, nc, clk2030, dq2030, cmd3210, dq2030, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2030, cmd2710, dq2030, cmd3210, nc, ctl3215, nc, clk2030, nc, nc, dq2030, cmd2710, ctl3215, ctl3215, clk2030, clk2030, dq2030, cmd3210, dq2030, cmd2710, ctl3215, nc, clk2030, nc, dq2030, cmd3210, dq2030, cmd2710, ctl3215, ctl3215, clk2030, clk2030, dq2030, cmd3210, dq2030, cmd2710, ctl3215, nc, clk2030, nc, dq2030, cmd2710, dq2030, cmd2710, ctl3215, nc, clk2030, nc, nc, nc, nc, nc, nc, ctl3215, nc, clk2030, dq2030, cmd3210, nc, nc, ctl3215, nc, clk2030, nc, dq2030, cmd3210, nc, nc, nc, ctl3215, nc, clk2030, dq2030, cmd3210, nc, nc, ctl3215, nc, clk2030, clk2030, dq2030, cmd2710 }; static const u32 const * const single_channel_slew_group_lookup[] = { dq2330, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2330, cmd3210, dq2330, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2330, cmd3210, dq2330, cmd3210, nc, ctl3215, nc, clk2030, dq2330, cmd3210, dq2330, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2330, cmd3210, dq2330, cmd3210, nc, ctl3215, nc, clk2030, nc, nc, dq2330, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2330, cmd3210, dq2330, cmd3210, ctl3215, nc, clk2030, nc, dq2330, cmd3210, dq2330, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2330, cmd3210, dq2330, cmd3210, ctl3215, nc, clk2030, nc, dq2330, cmd3210, dq2330, cmd3210, ctl3215, nc, clk2030, nc, nc, nc, dq2330, cmd3210, nc, ctl3215, nc, clk2030, dq2330, cmd3210, dq2330, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2330, cmd3210, dq2330, cmd3210, nc, ctl3215, nc, clk2030, dq2330, cmd3210, dq2330, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2330, cmd3210, dq2330, cmd3210, nc, ctl3215, nc, clk2030, nc, nc, dq2330, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2330, cmd3210, dq2330, cmd3210, ctl3215, nc, clk2030, nc, dq2330, cmd3210, dq2330, cmd3210, ctl3215, ctl3215, clk2030, clk2030, dq2330, cmd3210, dq2330, cmd3210, ctl3215, nc, clk2030, nc, dq2330, cmd3210, dq2330, cmd3210, ctl3215, nc, clk2030, nc, nc, nc, dq2330, nc, nc, ctl3215, nc, clk2030, dq2030, cmd3210, dq2330, nc, ctl3215, nc, clk2030, nc, dq2030, cmd3210, dq2330, nc, nc, ctl3215, nc, clk2030, dq2030, cmd3210, dq2330, nc, ctl3215, nc, clk2030, clk2030, dq2030, cmd3210 }; /* Strength multiplier tables */ static const u8 dual_channel_strength_multiplier[] = { 0x44, 0x11, 0x11, 0x11, 0x44, 0x44, 0x44, 0x11, 0x44, 0x11, 0x11, 0x11, 0x44, 0x44, 0x44, 0x11, 0x44, 0x11, 0x00, 0x11, 0x00, 0x44, 0x44, 0x11, 0x44, 0x11, 0x11, 0x11, 0x44, 0x44, 0x44, 0x22, 0x44, 0x11, 0x00, 0x11, 0x00, 0x44, 0x00, 0x00, 0x44, 0x11, 0x11, 0x11, 0x44, 0x44, 0x44, 0x11, 0x44, 0x11, 0x11, 0x00, 0x44, 0x00, 0x44, 0x11, 0x44, 0x11, 0x11, 0x11, 0x44, 0x44, 0x44, 0x11, 0x44, 0x11, 0x11, 0x00, 0x44, 0x00, 0x44, 0x22, 0x44, 0x11, 0x11, 0x00, 0x44, 0x00, 0x00, 0x00, 0x44, 0x11, 0x00, 0x11, 0x00, 0x44, 0x44, 0x11, 0x44, 0x11, 0x11, 0x11, 0x44, 0x44, 0x44, 0x11, 0x44, 0x11, 0x00, 0x11, 0x00, 0x44, 0x44, 0x11, 0x44, 0x11, 0x11, 0x11, 0x44, 0x44, 0x44, 0x22, 0x44, 0x11, 0x00, 0x11, 0x00, 0x44, 0x00, 0x00, 0x44, 0x22, 0x11, 0x11, 0x44, 0x44, 0x44, 0x11, 0x44, 0x22, 0x11, 0x00, 0x44, 0x00, 0x44, 0x11, 0x44, 0x22, 0x11, 0x11, 0x44, 0x44, 0x44, 0x11, 0x44, 0x22, 0x11, 0x00, 0x44, 0x00, 0x44, 0x22, 0x44, 0x22, 0x11, 0x00, 0x44, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x11, 0x00, 0x44, 0x44, 0x11, 0x00, 0x00, 0x11, 0x00, 0x44, 0x00, 0x44, 0x11, 0x00, 0x00, 0x00, 0x11, 0x00, 0x44, 0x44, 0x11, 0x00, 0x00, 0x11, 0x00, 0x44, 0x44, 0x44, 0x22 }; static const u8 single_channel_strength_multiplier[] = { 0x33, 0x11, 0x11, 0x11, 0x44, 0x44, 0x33, 0x11, 0x33, 0x11, 0x11, 0x11, 0x44, 0x44, 0x33, 0x11, 0x33, 0x11, 0x00, 0x11, 0x00, 0x44, 0x33, 0x11, 0x33, 0x11, 0x11, 0x11, 0x44, 0x44, 0x33, 0x11, 0x33, 0x11, 0x00, 0x11, 0x00, 0x44, 0x00, 0x00, 0x33, 0x11, 0x11, 0x11, 0x44, 0x44, 0x33, 0x11, 0x33, 0x11, 0x11, 0x00, 0x44, 0x00, 0x33, 0x11, 0x33, 0x11, 0x11, 0x11, 0x44, 0x44, 0x33, 0x11, 0x33, 0x11, 0x11, 0x00, 0x44, 0x00, 0x33, 0x11, 0x33, 0x11, 0x11, 0x00, 0x44, 0x00, 0x00, 0x00, 0x33, 0x11, 0x00, 0x11, 0x00, 0x44, 0x33, 0x11, 0x33, 0x11, 0x11, 0x11, 0x44, 0x44, 0x33, 0x11, 0x33, 0x11, 0x00, 0x11, 0x00, 0x44, 0x33, 0x11, 0x33, 0x11, 0x11, 0x11, 0x44, 0x44, 0x33, 0x11, 0x33, 0x11, 0x00, 0x11, 0x00, 0x44, 0x00, 0x00, 0x33, 0x11, 0x11, 0x11, 0x44, 0x44, 0x33, 0x11, 0x33, 0x11, 0x11, 0x00, 0x44, 0x00, 0x33, 0x11, 0x33, 0x11, 0x11, 0x11, 0x44, 0x44, 0x33, 0x11, 0x33, 0x11, 0x11, 0x00, 0x44, 0x00, 0x33, 0x11, 0x33, 0x11, 0x11, 0x00, 0x44, 0x00, 0x00, 0x00, 0x33, 0x00, 0x00, 0x11, 0x00, 0x44, 0x33, 0x11, 0x33, 0x00, 0x11, 0x00, 0x44, 0x00, 0x33, 0x11, 0x33, 0x00, 0x00, 0x11, 0x00, 0x44, 0x33, 0x11, 0x33, 0x00, 0x11, 0x00, 0x44, 0x44, 0x33, 0x11 }; const u8 * strength_multiplier; const u32* const * slew_group_lookup; int idx; /* Set Strength Multipliers */ /* Dual Channel needs different tables. */ if (sdram_capabilities_dual_channel()) { printk_debug("Programming Dual Channel RCOMP\r\n"); strength_multiplier = dual_channel_strength_multiplier; slew_group_lookup = dual_channel_slew_group_lookup; idx = 5 * sysinfo->dimm[0] + sysinfo->dimm[2]; } else { printk_debug("Programming Single Channel RCOMP\r\n"); strength_multiplier = single_channel_strength_multiplier; slew_group_lookup = single_channel_slew_group_lookup; idx = 5 * sysinfo->dimm[0] + sysinfo->dimm[1]; } printk_debug("Table Index: %d\r\n", idx); MCHBAR8(G1SC) = strength_multiplier[idx * 8 + 0]; MCHBAR8(G2SC) = strength_multiplier[idx * 8 + 1]; MCHBAR8(G3SC) = strength_multiplier[idx * 8 + 2]; MCHBAR8(G4SC) = strength_multiplier[idx * 8 + 3]; MCHBAR8(G5SC) = strength_multiplier[idx * 8 + 4]; MCHBAR8(G6SC) = strength_multiplier[idx * 8 + 5]; MCHBAR8(G7SC) = strength_multiplier[idx * 8 + 6]; MCHBAR8(G8SC) = strength_multiplier[idx * 8 + 7]; /* Channel 0 */ sdram_write_slew_rates(G1SRPUT, slew_group_lookup[idx * 8 + 0]); sdram_write_slew_rates(G2SRPUT, slew_group_lookup[idx * 8 + 1]); if ((slew_group_lookup[idx * 8 + 2] != nc) && (sysinfo->package == SYSINFO_PACKAGE_STACKED)) { sdram_write_slew_rates(G3SRPUT, ctl3220); } else { sdram_write_slew_rates(G3SRPUT, slew_group_lookup[idx * 8 + 2]); } sdram_write_slew_rates(G4SRPUT, slew_group_lookup[idx * 8 + 3]); sdram_write_slew_rates(G5SRPUT, slew_group_lookup[idx * 8 + 4]); sdram_write_slew_rates(G6SRPUT, slew_group_lookup[idx * 8 + 5]); /* Channel 1 */ if (sysinfo->dual_channel) { sdram_write_slew_rates(G7SRPUT, slew_group_lookup[idx * 8 + 6]); sdram_write_slew_rates(G8SRPUT, slew_group_lookup[idx * 8 + 7]); } else { sdram_write_slew_rates(G7SRPUT, nc); sdram_write_slew_rates(G8SRPUT, nc); } } static void sdram_enable_rcomp(void) { u32 reg32; udelay(300); reg32 = MCHBAR32(GBRCOMPCTL); reg32 &= ~(1 << 23); MCHBAR32(GBRCOMPCTL) = reg32; } static void sdram_program_dll_timings(struct sys_info *sysinfo) { u32 chan0dll = 0, chan1dll = 0; int i; printk_debug ("Programming DLL Timings... \r\n"); MCHBAR16(DQSMT) &= ~( (3 << 12) | (1 << 10) | ( 0xf << 0) ); MCHBAR16(DQSMT) |= (1 << 13) | (0xc << 0); /* We drive both channels with the same speed */ switch (sysinfo->memory_frequency) { case 400: chan0dll = 0x26262626; chan1dll=0x26262626; break; /* 400MHz */ case 533: chan0dll = 0x22222222; chan1dll=0x22222222; break; /* 533MHz */ case 667: chan0dll = 0x11111111; chan1dll=0x11111111; break; /* 667MHz */ } for (i=0; i < 4; i++) { MCHBAR32(C0R0B00DQST + (i * 0x10) + 0) = chan0dll; MCHBAR32(C0R0B00DQST + (i * 0x10) + 4) = chan0dll; MCHBAR32(C1R0B00DQST + (i * 0x10) + 0) = chan1dll; MCHBAR32(C1R0B00DQST + (i * 0x10) + 4) = chan1dll; } } static void sdram_force_rcomp(void) { u32 reg32; u8 reg8; reg32 = MCHBAR32(ODTC); reg32 |= (1 << 28); MCHBAR32(ODTC) = reg32; reg32 = MCHBAR32(SMSRCTL); reg32 |= (1 << 0); MCHBAR32(SMSRCTL) = reg32; reg32 = MCHBAR32(GBRCOMPCTL); reg32 |= (1 << 8); MCHBAR32(GBRCOMPCTL) = reg32; reg8 = i945_silicon_revision(); if ((reg8 == 0 && (MCHBAR32(DCC) & (3 << 0)) == 0) || (reg8 == 1)) { reg32 = MCHBAR32(GBRCOMPCTL); reg32 |= (3 << 5); MCHBAR32(GBRCOMPCTL) = reg32; } } static void sdram_initialize_system_memory_io(struct sys_info *sysinfo) { u8 reg8; u32 reg32; printk_debug ("Initializing System Memory IO... \r\n"); reg8 = MCHBAR8(C0HCTC); reg8 &= ~0x1f; reg8 |= ( 1 << 0); MCHBAR8(C0HCTC) = reg8; reg8 = MCHBAR8(C1HCTC); reg8 &= ~0x1f; reg8 |= ( 1 << 0); MCHBAR8(C1HCTC) = reg8; MCHBAR16(WDLLBYPMODE) &= ~( (1 << 9) | (1 << 6) | (1 << 4) | (1 << 3) | (1 << 1) ); MCHBAR16(WDLLBYPMODE) |= (1 << 8) | (1 << 7) | (1 << 5) | (1 << 2) | (1 << 0); MCHBAR8(C0WDLLCMC) = 0; MCHBAR8(C1WDLLCMC) = 0; sdram_program_dram_width(sysinfo); sdram_rcomp_buffer_strength_and_slew(sysinfo); reg32 = MCHBAR32(GBRCOMPCTL); reg32 &= ~( (1 << 29) | (1 << 26) | (3 << 21) | (3 << 2) ); reg32 |= (3 << 27) | (3 << 0); MCHBAR32(GBRCOMPCTL) = reg32; MCHBAR32(GBRCOMPCTL) |= (1 << 10); sdram_program_dll_timings(sysinfo); sdram_force_rcomp(); } static void sdram_enable_system_memory_io(struct sys_info *sysinfo) { u32 reg32; printk_debug ("Enabling System Memory IO... \r\n"); reg32 = MCHBAR32(RCVENMT); reg32 &= ~(0x3f << 6); MCHBAR32(RCVENMT) = reg32; reg32 |= (1 << 11) | (1 << 9); MCHBAR32(RCVENMT) = reg32; reg32 = MCHBAR32(DRTST); reg32 |= (1 << 3) | (1 << 2); MCHBAR32(DRTST) = reg32; reg32 = MCHBAR32(DRTST); reg32 |= (1 << 6) | (1 << 4); MCHBAR32(DRTST) = reg32; asm volatile ("nop; nop;"); reg32 = MCHBAR32(DRTST); /* Is channel 0 populated? */ if (sysinfo->dimm[0] != SYSINFO_DIMM_NOT_POPULATED || sysinfo->dimm[1] != SYSINFO_DIMM_NOT_POPULATED) reg32 |= (1 << 7) | (1 << 5); else reg32 |= (1 << 31); /* Is channel 1 populated? */ if (sysinfo->dimm[2] != SYSINFO_DIMM_NOT_POPULATED || sysinfo->dimm[3] != SYSINFO_DIMM_NOT_POPULATED) reg32 |= (1 << 9) | (1 << 8); else reg32 |= (1 << 30); MCHBAR32(DRTST) = reg32; if (sysinfo->dimm[0] != SYSINFO_DIMM_NOT_POPULATED || sysinfo->dimm[1] != SYSINFO_DIMM_NOT_POPULATED) { reg32 = MCHBAR32(C0DRC1); reg32 |= (1 << 8); MCHBAR32(C0DRC1) = reg32; } if (sysinfo->dimm[2] != SYSINFO_DIMM_NOT_POPULATED || sysinfo->dimm[3] != SYSINFO_DIMM_NOT_POPULATED) { reg32 = MCHBAR32(C1DRC1); reg32 |= (1 << 8); MCHBAR32(C1DRC1) = reg32; } } struct dimm_size { unsigned long side1; unsigned long side2; }; static struct dimm_size sdram_get_dimm_size(u16 device) { /* Calculate the log base 2 size of a DIMM in bits */ struct dimm_size sz; int value, low, rows, columns; sz.side1 = 0; sz.side2 = 0; rows = spd_read_byte(device, SPD_NUM_ROWS); /* rows */ if (rows < 0) goto hw_err; if ((rows & 0xf) == 0) goto val_err; sz.side1 += rows & 0xf; columns = spd_read_byte(device, SPD_NUM_COLUMNS); /* columns */ if (columns < 0) goto hw_err; if ((columns & 0xf) == 0) goto val_err; sz.side1 += columns & 0xf; value = spd_read_byte(device, SPD_NUM_BANKS_PER_SDRAM); /* banks */ if (value < 0) goto hw_err; if ((value & 0xff) == 0) goto val_err; sz.side1 += log2(value & 0xff); /* Get the module data width and convert it to a power of two */ value = spd_read_byte(device, SPD_MODULE_DATA_WIDTH_MSB); /* (high byte) */ if (value < 0) goto hw_err; value &= 0xff; value <<= 8; low = spd_read_byte(device, SPD_MODULE_DATA_WIDTH_LSB); /* (low byte) */ if (low < 0) goto hw_err; value = value | (low & 0xff); if ((value != 72) && (value != 64)) goto val_err; sz.side1 += log2(value); /* side 2 */ value = spd_read_byte(device, SPD_NUM_DIMM_BANKS); /* number of physical banks */ if (value < 0) goto hw_err; value &= 7; value++; if (value == 1) goto out; if (value != 2) goto val_err; /* Start with the symmetrical case */ sz.side2 = sz.side1; if ((rows & 0xf0) == 0) goto out; /* If symmetrical we are done */ /* Don't die here, I have not come across any of these to test what * actually happens. */ printk_err("Assymetric DIMMs are not supported by this chipset\n"); sz.side2 -= (rows & 0x0f); /* Subtract out rows on side 1 */ sz.side2 += ((rows >> 4) & 0x0f); /* Add in rows on side 2 */ sz.side2 -= (columns & 0x0f); /* Subtract out columns on side 1 */ sz.side2 += ((columns >> 4) & 0x0f); /* Add in columns on side 2 */ goto out; val_err: die("Bad SPD value\r\n"); hw_err: /* If a hardware error occurs the spd rom probably does not exist. * In this case report that there is no memory */ sz.side1 = 0; sz.side2 = 0; out: return sz; } static void sdram_detect_dimm_size(struct sys_info * sysinfo) { int i; for(i = 0; i < 2 * DIMM_SOCKETS; i++) { struct dimm_size sz; sysinfo->banksize[i * 2] = 0; sysinfo->banksize[(i * 2) + 1] = 0; if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; sz = sdram_get_dimm_size(DIMM_SPD_BASE + i); sysinfo->banks[i] = spd_read_byte(DIMM_SPD_BASE + i, SPD_NUM_BANKS_PER_SDRAM); /* banks */ if (sz.side1 < 30) die("DDR-II rank size smaller than 128MB is not supported.\n"); sysinfo->banksize[i * 2] = sz.side1 - 30; printk_debug("DIMM %d side 0 = %d MB\n", i, (1 << sysinfo->banksize[i * 2]) * 128 ); if (!sz.side2) continue; /* If there is a second side, it has to have at least 128M, too */ if (sz.side2 < 30) die("DDR-II rank size smaller than 128MB is not supported.\n"); sysinfo->banksize[(i * 2) + 1] = sz.side2 - 30; printk_debug("DIMM %d side 1 = %d MB\n", i, (1 << sysinfo->banksize[(i * 2) + 1]) * 128); } } static int sdram_program_row_boundaries(struct sys_info *sysinfo) { int i; int cum0, cum1, tolud; printk_debug ("Setting RAM size... \r\n"); cum0 = 0; for(i = 0; i < 2 * DIMM_SOCKETS; i++) { cum0 += (sysinfo->banksize[i] << 3); MCHBAR8(C0DRB0+i) = cum0; } /* Assume we continue in Channel 1 where we stopped in Channel 0 */ cum1 = cum0; /* Exception: Interleaved starts from the beginning */ if (sysinfo->interleaved) cum1 = 0; /* Exception: Channel 1 is not populated. C1DRB stays zero */ if (sysinfo->dimm[2] == SYSINFO_DIMM_NOT_POPULATED && sysinfo->dimm[3] == SYSINFO_DIMM_NOT_POPULATED) cum1 = 0; for(i = 0; i < 2 * DIMM_SOCKETS; i++) { cum1 += (sysinfo->banksize[i + 4] << 3); MCHBAR8(C1DRB0+i) = cum1; } /* Set TOLUD Top Of Low Usable DRAM */ if (sysinfo->interleaved) tolud = (cum0 + cum1) << 1; else tolud = (cum1 ? cum1 : cum0) << 1; pci_write_config16(PCI_DEV(0,0,0), TOLUD, tolud); printk_debug("C0DRB = 0x%08x\r\n", MCHBAR32(C0DRB0)); printk_debug("C1DRB = 0x%08x\r\n", MCHBAR32(C1DRB0)); printk_debug("TOLUD = 0x%04x\r\n", tolud); pci_write_config16(PCI_DEV(0,0,0), TOM, tolud>>3); return 0; } static int sdram_set_row_attributes(struct sys_info *sysinfo) { int i, value; u16 dra0=0, dra1=0, dra = 0; printk_debug ("Setting row attributes... \r\n"); for(i=0; i < 2 * DIMM_SOCKETS; i++) { u16 device; u8 columnsrows; if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) { continue; } device = DIMM_SPD_BASE + i; columnsrows = 0; value = spd_read_byte(device, SPD_NUM_ROWS); /* rows */ columnsrows = (value & 0x0f); value = spd_read_byte(device, SPD_NUM_COLUMNS); /* columns */ columnsrows |= (value & 0xf) << 4; switch (columnsrows) { case 0x9d: dra = 2; break; case 0xad: dra = 3; break; case 0xbd: dra = 4; break; case 0xae: dra = 3; break; case 0xbe: dra = 4; break; default: die("Unsupported Rows/Columns. (DRA)"); } /* Double Sided DIMMs? */ if (sysinfo->banksize[(2 * i) + 1] != 0) { dra = (dra << 4) | dra; } if (i < DIMM_SOCKETS) dra0 |= (dra << (i*8)); else dra1 |= (dra << ((i - DIMM_SOCKETS)*8)); } MCHBAR16(C0DRA0) = dra0; MCHBAR16(C1DRA0) = dra1; printk_debug("C0DRA = 0x%04x\r\n", dra0); printk_debug("C1DRA = 0x%04x\r\n", dra1); return 0; } static void sdram_set_bank_architecture(struct sys_info *sysinfo) { u32 off32; int i; MCHBAR16(C1BNKARC) &= 0xff00; MCHBAR16(C0BNKARC) &= 0xff00; off32 = C0BNKARC; for (i=0; i < 2 * DIMM_SOCKETS; i++) { /* Switch to second channel */ if (i == DIMM_SOCKETS) off32 = C1BNKARC; if (sysinfo->dimm[i] == SYSINFO_DIMM_NOT_POPULATED) continue; if (sysinfo->banks[i] != 8) continue; printk_spew("DIMM%d has 8 banks.\n"); if (i & 1) MCHBAR16(off32) |= 0x50; else MCHBAR16(off32) |= 0x05; } } #define REFRESH_7_8US 1 #define REFRESH_15_6US 0 static void sdram_program_refresh_rate(struct sys_info *sysinfo) { u32 reg32; if (sysinfo->refresh == REFRESH_7_8US) { reg32 = (2 << 8); /* Refresh enabled at 7.8us */ } else { reg32 = (1 << 8); /* Refresh enabled at 15.6us */ } MCHBAR32(C0DRC0) &= ~(7 << 8); MCHBAR32(C0DRC0) |= reg32; MCHBAR32(C1DRC0) &= ~(7 << 8); MCHBAR32(C1DRC0) |= reg32; } static void sdram_program_cke_tristate(struct sys_info *sysinfo) { u32 reg32; int i; reg32 = MCHBAR32(C0DRC1); for (i=0; i < 4; i++) { if (sysinfo->banksize[i] == 0) { reg32 |= (1 << (16 + i)); } } reg32 |= (1 << 12); reg32 |= (1 << 11); MCHBAR32(C0DRC1) = reg32; /* Do we have to do this if we're in Single Channel Mode? */ reg32 = MCHBAR32(C1DRC1); for (i=4; i < 8; i++) { if (sysinfo->banksize[i] == 0) { reg32 |= (1 << (12 + i)); } } reg32 |= (1 << 12); reg32 |= (1 << 11); MCHBAR32(C1DRC1) = reg32; } static void sdram_program_odt_tristate(struct sys_info *sysinfo) { u32 reg32; int i; reg32 = MCHBAR32(C0DRC2); for (i=0; i < 4; i++) { if (sysinfo->banksize[i] == 0) { reg32 |= (1 << (24 + i)); } } MCHBAR32(C0DRC2) = reg32; reg32 = MCHBAR32(C1DRC2); for (i=4; i < 8; i++) { if (sysinfo->banksize[i] == 0) { reg32 |= (1 << (20 + i)); } } MCHBAR32(C1DRC2) = reg32; } static void sdram_set_timing_and_control(struct sys_info *sysinfo) { u32 reg32, off32; u32 tWTR; u32 temp_drt; int i, page_size; static const u8 const drt0_table[] = { /* CL 3, 4, 5 */ 3, 4, 5, /* FSB533/400, DDR533/400 */ 4, 5, 6, /* FSB667, DDR533/400 */ 4, 5, 6, /* FSB667, DDR667 */ }; static const u8 const cas_table[] = { 2, 1, 0, 3 }; reg32 = MCHBAR32(C0DRC0); reg32 |= (1 << 2); /* Burst Length 8 */ reg32 &= ~( (1 << 13) | (1 << 12) ); MCHBAR32(C0DRC0) = reg32; reg32 = MCHBAR32(C1DRC0); reg32 |= (1 << 2); /* Burst Length 8 */ reg32 &= ~( (1 << 13) | (1 << 12) ); MCHBAR32(C1DRC0) = reg32; if (!sysinfo->dual_channel && sysinfo->dimm[1] != SYSINFO_DIMM_NOT_POPULATED) { reg32 = MCHBAR32(C0DRC0); reg32 |= (1 << 15); MCHBAR32(C0DRC0) = reg32; } sdram_program_refresh_rate(sysinfo); sdram_program_cke_tristate(sysinfo); sdram_program_odt_tristate(sysinfo); /* Calculate DRT0 */ temp_drt = 0; /* B2B Write Precharge (same bank) = CL-1 + BL/2 + tWR */ reg32 = (sysinfo->cas - 1) + (BURSTLENGTH / 2) + sysinfo->twr; temp_drt |= (reg32 << 28); /* Write Auto Precharge (same bank) = CL-1 + BL/2 + tWR + tRP */ reg32 += sysinfo->trp; temp_drt |= (reg32 << 4); if (sysinfo->memory_frequency == 667) { tWTR = 3; /* 667MHz */ } else { tWTR = 2; /* 400 and 533 */ } /* B2B Write to Read Command Spacing */ reg32 = (sysinfo->cas - 1) + (BURSTLENGTH / 2) + tWTR; temp_drt |= (reg32 << 24); temp_drt |= ( (1 << 22) | (3 << 20) | (1 << 18) | (0 << 16) ); /* Program Write Auto Precharge to Activate */ off32 = 0; if (sysinfo->fsb_frequency == 667) { /* 667MHz FSB */ off32 += 3; } if (sysinfo->memory_frequency == 667) { off32 += 3; } off32 += sysinfo->cas - 3; reg32 = drt0_table[off32]; temp_drt |= (reg32 << 11); /* Read Auto Precharge to Activate */ temp_drt |= (8 << 0); MCHBAR32(C0DRT0) = temp_drt; MCHBAR32(C1DRT0) = temp_drt; /* Calculate DRT1 */ temp_drt = MCHBAR32(C0DRT1) & 0x00020088; /* DRAM RASB Precharge */ temp_drt |= (sysinfo->trp - 2) << 0; /* DRAM RASB to CASB Delay */ temp_drt |= (sysinfo->trcd - 2) << 4; /* CASB Latency */ temp_drt |= (cas_table[sysinfo->cas - 3]) << 8; /* Refresh Cycle Time */ temp_drt |= (sysinfo->trfc) << 10; /* Pre-All to Activate Delay */ temp_drt |= (0 << 16); /* Precharge to Precharge Delay stays at 1 clock */ temp_drt |= (0 << 18); /* Activate to Precharge Delay */ temp_drt |= (sysinfo->tras << 19); /* Read to Precharge (tRTP) */ if (sysinfo->memory_frequency == 667) { temp_drt |= (1 << 28); } else { temp_drt |= (0 << 28); } /* Determine page size */ reg32 = 0; page_size = 1; /* Default: 1k pagesize */ for (i=0; i< 2*DIMM_SOCKETS; i++) { if (sysinfo->dimm[i] == SYSINFO_DIMM_X16DS || sysinfo->dimm[i] == SYSINFO_DIMM_X16SS) page_size = 2; /* 2k pagesize */ } if (sysinfo->memory_frequency == 533 && page_size == 2) { reg32 = 1; } if (sysinfo->memory_frequency == 667) { reg32 = page_size; } temp_drt |= (reg32 << 30); MCHBAR32(C0DRT1) = temp_drt; MCHBAR32(C1DRT1) = temp_drt; /* Program DRT2 */ reg32 = MCHBAR32(C0DRT2); reg32 &= ~(1 << 8); MCHBAR32(C0DRT2) = reg32; reg32 = MCHBAR32(C1DRT2); reg32 &= ~(1 << 8); MCHBAR32(C1DRT2) = reg32; /* Calculate DRT3 */ temp_drt = MCHBAR32(C0DRT3) & ~0x07ffffff; /* Get old tRFC value */ reg32 = MCHBAR32(C0DRT1) >> 10; reg32 &= 0x3f; /* 788nS - tRFC */ switch (sysinfo->memory_frequency) { case 400: /* 5nS */ reg32 = ((78800 / 500) - reg32) & 0x1ff; reg32 |= (0x8c << 16) | (0x0c << 10); /* 1 us */ break; case 533: /* 3.75nS */ reg32 = ((78800 / 375) - reg32) & 0x1ff; reg32 |= (0xba << 16) | (0x10 << 10); /* 1 us */ break; case 667: /* 3nS */ reg32 = ((78800 / 300) - reg32) & 0x1ff; reg32 |= (0xe9 << 16) | (0x14 << 10); /* 1 us */ break; } temp_drt |= reg32; MCHBAR32(C0DRT3) = temp_drt; MCHBAR32(C1DRT3) = temp_drt; } static void sdram_set_channel_mode(struct sys_info *sysinfo) { u32 reg32; printk_debug("Setting mode of operation for memory channels..."); if (sdram_capabilities_interleave() && ( ( sysinfo->banksize[0] + sysinfo->banksize[1] + sysinfo->banksize[2] + sysinfo->banksize[3] ) == ( sysinfo->banksize[4] + sysinfo->banksize[5] + sysinfo->banksize[6] + sysinfo->banksize[7] ) ) ) { /* Both channels equipped with DIMMs of the same size */ sysinfo->interleaved = 1; } else { sysinfo->interleaved = 0; } reg32 = MCHBAR32(DCC); reg32 &= ~(7 << 0); if(sysinfo->interleaved) { /* Dual Channel Interleaved */ printk_debug("Dual Channel Interleaved.\n"); reg32 |= (1 << 1); } else if (sysinfo->dimm[0] == SYSINFO_DIMM_NOT_POPULATED && sysinfo->dimm[1] == SYSINFO_DIMM_NOT_POPULATED) { /* Channel 1 only */ printk_debug("Single Channel 1 only.\n"); reg32 |= (1 << 2); } else if (sdram_capabilities_dual_channel() && sysinfo->dimm[2] != SYSINFO_DIMM_NOT_POPULATED) { /* Dual Channel Assymetric */ printk_debug("Dual Channel Assymetric.\n"); reg32 |= (1 << 0); } else { /* All bits 0 means Single Channel 0 operation */ printk_debug("Single Channel 0 only.\n"); } reg32 |= (1 << 10); MCHBAR32(DCC) = reg32; PRINTK_DEBUG("DCC=0x%08x\r\n", MCHBAR32(DCC)); } static void sdram_program_pll_settings(void) { volatile u16 reg16; volatile u32 reg32; const u8 HPLLGPLLPowerDown[] = { 0x90, /* 400MHz */ 0x95, /* 533MHz */ 0x00, /* --- */ 0x8d, /* 667MHz */ }; MCHBAR32(PLLMON) = 0x80800000; reg32 = MCHBAR32(CLKCFG); reg32 &= (7 << 0); reg16 = MCHBAR16(CPCTL); reg16 &= 0xff00; reg16 |= HPLLGPLLPowerDown[reg32]; MCHBAR16(CPCTL) = reg16; reg16 &= ~(1 << 11); MCHBAR16(CPCTL) = reg16; reg16 = MCHBAR16(CPCTL); } static void sdram_program_graphics_frequency(struct sys_info *sysinfo) { u8 reg8; u16 reg16; u8 freq, second_vco; #define CRCLK_166MHz 0x00 #define CRCLK_200MHz 0x01 #define CRCLK_250MHz 0x03 #define CRCLK_400MHz 0x05 #define CDCLK_200MHz 0x00 #define CDCLK_320MHz 0x40 printk_debug ("Setting Graphics Frequency... \r\n"); reg16 = pci_read_config16(PCI_DEV(0,2,0), GCFC); reg16 |= (1<<11) | (1<<9); pci_write_config16(PCI_DEV(0,2,0), GCFC, reg16); /* Program CPCTL according to FSB speed */ reg16 = MCHBAR16(CPCTL); reg16 &= 0xff00; switch (MCHBAR32(CLKCFG) & 0x7) { case 0: sysinfo->fsb_frequency = 400; break; /* FSB400 */ case 1: sysinfo->fsb_frequency = 533; break; /* FSB533 */ case 3: sysinfo->fsb_frequency = 667; break; /* FSB667 */ default: die("Unsupported FSB speed"); } switch (sysinfo->fsb_frequency) { case 533: reg16 |= 0x95; break; /* FSB533 */ case 667: reg16 |= 0x8d; break; /* FSB667 */ } MCHBAR16(CPCTL) = reg16; /* Get graphics frequency capabilities */ reg8 = (pci_read_config8(PCI_DEV(0, 0x00,0), 0xe5) & 0x0e) >> 1; freq = CRCLK_250MHz; switch (reg8) { case 0: if (MCHBAR32(DFT_STRAP1) & (1 << 20)) freq = CRCLK_250MHz; else freq = CRCLK_400MHz; break; case 2: freq = CRCLK_250MHz; break; case 3: freq = CRCLK_200MHz; break; case 4: freq = CRCLK_166MHz; break; } if (freq != CRCLK_400MHz) { reg8 = (pci_read_config8(PCI_DEV(0, 0x00,0), 0xe7) & 0x70) >> 4; if (reg8==2) freq = CRCLK_166MHz; } if (i945_silicon_revision() == 0) { sysinfo->mvco4x = 1; } else { sysinfo->mvco4x = 0; } second_vco = 0; if (MCHBAR32(DFT_STRAP1) & (1 << 20)) { second_vco = 1; } else if ((i945_silicon_revision() > 0) && (freq == CRCLK_250MHz)) { u16 mem = sysinfo->memory_frequency; u16 fsb = sysinfo->fsb_frequency; if ( (fsb == 667 && mem == 533) || (fsb == 533 && mem == 533) || (fsb == 533 && mem == 400)) { second_vco = 1; } if (fsb == 667 && mem == 533) sysinfo->mvco4x = 1; } if (second_vco) { printk_debug("Programming second TCO\r\n"); sysinfo->clkcfg_bit7=1; } else { sysinfo->clkcfg_bit7=0; } reg16 = pci_read_config16(PCI_DEV(0,2,0), GCFC); reg16 &= ~( (7 << 0) | (1 << 13) ); reg16 |= freq; pci_write_config16(PCI_DEV(0,2,0), GCFC, reg16); reg16 = pci_read_config16(PCI_DEV(0,2,0), GCFC); reg16 &= ~( (1<<7) | (7<<4) ); if (MCHBAR32(DFT_STRAP1) & (1 << 20)) { reg16 |= CDCLK_200MHz; } else { reg16 |= CDCLK_320MHz; } pci_write_config16(PCI_DEV(0,2,0), GCFC, reg16); reg16 = pci_read_config16(PCI_DEV(0,2,0), GCFC); reg16 &= ~( (1<<10) | (1<<8) ); pci_write_config16(PCI_DEV(0,2,0), GCFC, reg16); reg16 |= (1<<10) | (1<<8); pci_write_config16(PCI_DEV(0,2,0), GCFC, reg16); reg16 &= 0xf0ff; pci_write_config16(PCI_DEV(0,2,0), GCFC, reg16); } static void sdram_program_memory_frequency(struct sys_info *sysinfo) { u32 clkcfg; u8 reg8; printk_debug ("Setting Memory Frequency... "); clkcfg = MCHBAR32(CLKCFG); printk_debug("CLKCFG=0x%08x, ", clkcfg); clkcfg &= ~( (1 << 12) | (1 << 7) | ( 7 << 4) ); if (sysinfo->mvco4x) { printk_debug("MVCO 4x, "); clkcfg &= ~(1 << 12); } if (sysinfo->clkcfg_bit7) { printk_debug("second VCO, "); clkcfg |= (1 << 7); } switch (sysinfo->memory_frequency) { case 400: clkcfg |= (2 << 4); break; case 533: clkcfg |= (3 << 4); break; case 667: clkcfg |= (4 << 4); break; default: die("Target Memory Frequency Error"); } if (MCHBAR32(CLKCFG) == clkcfg) { printk_debug ("ok (unchanged)\r\n"); return; } MCHBAR32(CLKCFG) = clkcfg; /* Make sure the following code is in the * cache before we execute it. */ goto cache_code; vco_update: reg8 = pci_read_config8(PCI_DEV(0,0x1f,0), 0xa2); reg8 &= ~(1 << 7); pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, reg8); clkcfg &= ~(1 << 10); MCHBAR32(CLKCFG) = clkcfg; clkcfg |= (1 << 10); MCHBAR32(CLKCFG) = clkcfg; __asm__ __volatile__ ( " movl $0x100, %%ecx\n" "delay_update:\n" " nop\n" " nop\n" " nop\n" " nop\n" " loop delay_update\n" : /* No outputs */ : /* No inputs */ : "%ecx" ); clkcfg &= ~(1 << 10); MCHBAR32(CLKCFG) = clkcfg; goto out; cache_code: goto vco_update; out: printk_debug("CLKCFG=0x%08x, ", MCHBAR32(CLKCFG)); printk_debug ("ok\r\n"); } static void sdram_program_clock_crossing(void) { u32 reg32; int idx = 0; /** * The first two lines of each of these tables are for FSB533, * the following three lines are for FSB667. We ignore FSB400. * Thus we add the indices according to our clocks from CLKCFG. */ static const u32 data_clock_crossing[] = { 0x08040120, 0x00000000, /* DDR400 FSB533 */ 0x00100401, 0x00000000, /* DDR533 FSB533 */ 0x04020120, 0x00000010, /* DDR400 FSB667 */ 0x10040280, 0x00000040, /* DDR533 FSB667 */ 0x00100401, 0x00000000 /* DDR667 FSB667 */ }; static const u32 command_clock_crossing[] = { 0x00060108, 0x00000000, /* DDR400 FSB533 */ 0x04020108, 0x00000000, /* DDR533 FSB533 */ 0x00040318, 0x00000000, /* DDR400 FSB667 */ 0x04020118, 0x00000000, /* DDR533 FSB667 */ 0x02010804, 0x00000000 /* DDR667 FSB667 */ }; printk_debug("Programming Clock Crossing..."); reg32 = MCHBAR32(CLKCFG); printk_debug("MEM="); switch ((reg32 >> 4) & 7) { case 2: printk_debug("400"); idx += 0; break; case 3: printk_debug("533"); idx += 2; break; case 4: printk_debug("667"); idx += 4; break; default: printk_debug("RSVD\r\n"); return; } printk_debug(" FSB="); switch (reg32 & 7) { case 0: printk_debug("400\r\n"); return; case 1: printk_debug("533"); idx += 0; break; case 3: printk_debug("667"); idx += 4; break; default: printk_debug("RSVD\r\n"); return; } MCHBAR32(C0DCCFT + 0) = data_clock_crossing[idx]; MCHBAR32(C0DCCFT + 4) = data_clock_crossing[idx + 1]; MCHBAR32(C1DCCFT + 0) = data_clock_crossing[idx]; MCHBAR32(C1DCCFT + 4) = data_clock_crossing[idx + 1]; MCHBAR32(CCCFT + 0) = command_clock_crossing[idx]; MCHBAR32(CCCFT + 4) = command_clock_crossing[idx + 1]; printk_debug("... ok\r\n"); } static void sdram_disable_fast_dispatch(void) { u32 reg32; reg32 = MCHBAR32(FSBPMC3); reg32 |= (1 << 1); MCHBAR32(FSBPMC3) = reg32; reg32 = MCHBAR32(SBTEST); reg32 |= (3 << 1); MCHBAR32(SBTEST) = reg32; } static void sdram_pre_jedec_initialization(void) { u32 reg32; reg32 = MCHBAR32(WCC); reg32 &= 0x113ff3ff; reg32 |= (4 << 29) | (3 << 25) | (1 << 10); MCHBAR32(WCC) = reg32; MCHBAR32(SMVREFC) |= (1 << 6); MCHBAR32(MMARB0) &= ~(3 << 17); MCHBAR32(MMARB0) |= (1 << 21) | (1 << 16); MCHBAR32(MMARB1) &= ~(7 << 8); MCHBAR32(MMARB1) |= (3 << 8); MCHBAR32(C0AIT) = 0x000006c4; MCHBAR32(C0AIT+4) = 0x871a066d; MCHBAR32(C1AIT) = 0x000006c4; MCHBAR32(C1AIT+4) = 0x871a066d; } #define EA_DUALCHANNEL_XOR_BANK_RANK_MODE (0xd4 << 24) #define EA_DUALCHANNEL_XOR_BANK_MODE (0xf4 << 24) #define EA_DUALCHANNEL_BANK_RANK_MODE (0xc2 << 24) #define EA_DUALCHANNEL_BANK_MODE (0xe2 << 24) #define EA_SINGLECHANNEL_XOR_BANK_RANK_MODE (0x91 << 24) #define EA_SINGLECHANNEL_XOR_BANK_MODE (0xb1 << 24) #define EA_SINGLECHANNEL_BANK_RANK_MODE (0x80 << 24) #define EA_SINGLECHANNEL_BANK_MODE (0xa0 << 24) static void sdram_enhanced_addressing_mode(struct sys_info *sysinfo) { u32 chan0 = 0, chan1 = 0; int chan0_dualsided, chan1_dualsided, chan0_populated, chan1_populated; chan0_populated = (sysinfo->dimm[0] != SYSINFO_DIMM_NOT_POPULATED || sysinfo->dimm[1] != SYSINFO_DIMM_NOT_POPULATED); chan1_populated = (sysinfo->dimm[0] != SYSINFO_DIMM_NOT_POPULATED || sysinfo->dimm[1] != SYSINFO_DIMM_NOT_POPULATED); chan0_dualsided = (sysinfo->banksize[1] || sysinfo->banksize[3]); chan1_dualsided = (sysinfo->banksize[5] || sysinfo->banksize[7]); if (sdram_capabilities_enhanced_addressing_xor()) { if (!sysinfo->interleaved) { /* Single Channel & Dual Channel Assymetric */ if (chan0_populated) { if (chan0_dualsided) { chan0 = EA_SINGLECHANNEL_XOR_BANK_RANK_MODE; } else { chan0 = EA_SINGLECHANNEL_XOR_BANK_MODE; } } if (chan1_populated) { if (chan1_dualsided) { chan1 = EA_SINGLECHANNEL_XOR_BANK_RANK_MODE; } else { chan1 = EA_SINGLECHANNEL_XOR_BANK_MODE; } } } else { /* Interleaved has always both channels populated */ if (chan0_dualsided) { chan0 = EA_DUALCHANNEL_XOR_BANK_RANK_MODE; } else { chan0 = EA_DUALCHANNEL_XOR_BANK_MODE; } if (chan1_dualsided) { chan1 = EA_DUALCHANNEL_XOR_BANK_RANK_MODE; } else { chan1 = EA_DUALCHANNEL_XOR_BANK_MODE; } } } else { if (!sysinfo->interleaved) { /* Single Channel & Dual Channel Assymetric */ if (chan0_populated) { if (chan0_dualsided) { chan0 = EA_SINGLECHANNEL_BANK_RANK_MODE; } else { chan0 = EA_SINGLECHANNEL_BANK_MODE; } } if (chan1_populated) { if (chan1_dualsided) { chan1 = EA_SINGLECHANNEL_BANK_RANK_MODE; } else { chan1 = EA_SINGLECHANNEL_BANK_MODE; } } } else { /* Interleaved has always both channels populated */ if (chan0_dualsided) { chan0 = EA_DUALCHANNEL_BANK_RANK_MODE; } else { chan0 = EA_DUALCHANNEL_BANK_MODE; } if (chan1_dualsided) { chan1 = EA_DUALCHANNEL_BANK_RANK_MODE; } else { chan1 = EA_DUALCHANNEL_BANK_MODE; } } } MCHBAR32(C0DRC1) &= 0x00ffffff; MCHBAR32(C0DRC1) |= chan0; MCHBAR32(C1DRC1) &= 0x00ffffff; MCHBAR32(C1DRC1) |= chan1; } static void sdram_post_jedec_initialization(struct sys_info *sysinfo) { u32 reg32; /* Enable Channel XORing for Dual Channel Interleave */ if (sysinfo->interleaved) { reg32 = MCHBAR32(DCC); #if CHANNEL_XOR_RANDOMIZATION reg32 &= ~(1 << 10); #endif reg32 &= ~(1 << 9); MCHBAR32(DCC) = reg32; } /* DRAM mode optimizations */ sdram_enhanced_addressing_mode(sysinfo); reg32 = MCHBAR32(FSBPMC3); reg32 &= ~(1 << 1); MCHBAR32(FSBPMC3) = reg32; reg32 = MCHBAR32(SBTEST); reg32 &= ~(1 << 2); MCHBAR32(SBTEST) = reg32; reg32 = MCHBAR32(SBOCC); reg32 &= 0xffbdb6ff; reg32 |= (0xbdb6 << 8) | (1 << 0); MCHBAR32(SBOCC) = reg32; } static void sdram_power_management(struct sys_info *sysinfo) { u8 reg8; u16 reg16; u32 reg32; int integrated_graphics = 1; int i; reg32 = MCHBAR32(C0DRT2); reg32 &= 0xffffff00; /* Idle timer = 8 clocks, CKE idle timer = 16 clocks */ reg32 |= (1 << 5) | (1 << 4); MCHBAR32(C0DRT2) = reg32; reg32 = MCHBAR32(C1DRT2); reg32 &= 0xffffff00; /* Idle timer = 8 clocks, CKE idle timer = 16 clocks */ reg32 |= (1 << 5) | (1 << 4); MCHBAR32(C1DRT2) = reg32; reg32 = MCHBAR32(C0DRC1); reg32 |= (1 << 12) | (1 << 11); MCHBAR32(C0DRC1) = reg32; reg32 = MCHBAR32(C1DRC1); reg32 |= (1 << 12) | (1 << 11); MCHBAR32(C1DRC1) = reg32; if (i945_silicon_revision()>1) { MCHBAR16(UPMC1) = 0x1010; } else { /* Rev 0 and 1 */ MCHBAR16(UPMC1) = 0x0010; } reg16 = MCHBAR16(UPMC2); reg16 &= 0xfc00; reg16 |= 0x0100; MCHBAR16(UPMC2) = reg16; MCHBAR32(UPMC3) = 0x000f06ff; for (i=0; i<5; i++) { MCHBAR32(UPMC3) &= ~(1 << 16); MCHBAR32(UPMC3) |= (1 << 16); } MCHBAR32(GIPMC1) = 0x8000000c; reg16 = MCHBAR16(CPCTL); reg16 &= ~(7 << 11); if (i945_silicon_revision()>2) { reg16 |= (6 << 11); } else { reg16 |= (4 << 11); } MCHBAR16(CPCTL) = reg16; if ((MCHBAR32(ECO) & (1 << 16)) != 0) { switch (sysinfo->fsb_frequency) { case 667: MCHBAR32(HGIPMC2) = 0x0d590d59; break; case 533: MCHBAR32(HGIPMC2) = 0x155b155b; break; } } else { switch (sysinfo->fsb_frequency) { case 667: MCHBAR32(HGIPMC2) = 0x09c409c4; break; case 533: MCHBAR32(HGIPMC2) = 0x0fa00fa0; break; } } MCHBAR32(FSBPMC1) = 0x8000000c; reg32 = MCHBAR32(C2C3TT); reg32 &= 0xffff0000; switch (sysinfo->fsb_frequency) { case 667: reg32 |= 0x0600; break; case 533: reg32 |= 0x0480; break; } MCHBAR32(C2C3TT) = reg32; reg32 = MCHBAR32(C3C4TT); reg32 &= 0xffff0000; switch (sysinfo->fsb_frequency) { case 667: reg32 |= 0x0b80; break; case 533: reg32 |= 0x0980; break; } MCHBAR32(C3C4TT) = reg32; if (i945_silicon_revision() == 0) { MCHBAR32(ECO) &= ~(1 << 16); } else { MCHBAR32(ECO) |= (1 << 16); } #if 0 if (i945_silicon_revision() == 0) { MCHBAR32(FSBPMC3) &= ~(1 << 29); } else { MCHBAR32(FSBPMC3) |= (1 << 29); } #endif MCHBAR32(FSBPMC3) &= ~(1 << 29); MCHBAR32(FSBPMC3) |= (1 << 21); MCHBAR32(FSBPMC3) &= ~(1 << 19); MCHBAR32(FSBPMC3) &= ~(1 << 13); reg32 = MCHBAR32(FSBPMC4); reg32 &= ~(3 << 24); reg32 |= ( 2 << 24); MCHBAR32(FSBPMC4) = reg32; MCHBAR32(FSBPMC4) |= (1 << 21); MCHBAR32(FSBPMC4) |= (1 << 5); if (i945_silicon_revision() < 2) { /* stepping 0 and 1 */ MCHBAR32(FSBPMC4) &= ~(1 << 4); } else { MCHBAR32(FSBPMC4) &= ~(1 << 4); } reg8 = pci_read_config8(PCI_DEV(0,0x0,0), 0xfc); reg8 |= (1 << 4); pci_write_config8(PCI_DEV(0, 0x0, 0), 0xfc, reg8); reg8 = pci_read_config8(PCI_DEV(0,0x2,0), 0xc1); reg8 |= (1 << 2); pci_write_config8(PCI_DEV(0, 0x2, 0), 0xc1, reg8); if (integrated_graphics) { MCHBAR16(MIPMC4) = 0x0468; MCHBAR16(MIPMC5) = 0x046c; MCHBAR16(MIPMC6) = 0x046c; } else { MCHBAR16(MIPMC4) = 0x6468; MCHBAR16(MIPMC5) = 0x646c; MCHBAR16(MIPMC6) = 0x646c; } reg32 = MCHBAR32(PMCFG); reg32 &= ~(3 << 17); reg32 |= (2 << 17); reg32 |= (1 << 4); MCHBAR32(PMCFG) = reg32; reg32 = MCHBAR32(0xc30); reg32 &= 0xffffff00; reg32 |= 0x01; MCHBAR32(0xc30) = reg32; MCHBAR32(0xb18) &= ~(1 << 21); } static void sdram_thermal_management(void) { /* The Thermal Sensors for DIMMs at 0x50, 0x52 are at I2C addr * 0x30/0x32. */ /* Explicitly set to 0 */ MCHBAR8(TCO1) = 0x00; MCHBAR8(TCO0) = 0x00; } #include "rcven.c" static void sdram_program_receive_enable(struct sys_info *sysinfo) { MCHBAR32(REPC) |= (1 << 0); receive_enable_adjust(sysinfo); MCHBAR32(C0DRC1) |= (1 << 6); MCHBAR32(C1DRC1) |= (1 << 6); MCHBAR32(C0DRC1) &= ~(1 << 6); MCHBAR32(C1DRC1) &= ~(1 << 6); MCHBAR32(MIPMC3) |= (0x0f << 0); } /** * @brief Enable On-Die Termination for DDR2. * */ static void sdram_on_die_termination(struct sys_info *sysinfo) { static const u32 odt[] = { 0x00024911, 0xe0010000, 0x00049211, 0xe0020000, 0x0006db11, 0xe0030000, }; u32 reg32; int cas; reg32 = MCHBAR32(ODTC); reg32 &= ~(3 << 16); reg32 |= (1 << 14) | (1 << 6) | (2 << 16); MCHBAR32(ODTC) = reg32; if ( !(sysinfo->dimm[0] != SYSINFO_DIMM_NOT_POPULATED && sysinfo->dimm[1] != SYSINFO_DIMM_NOT_POPULATED) ) { printk_debug("one dimm per channel config.. \n"); reg32 = MCHBAR32(C0ODT); reg32 &= ~(7 << 28); MCHBAR32(C0ODT) = reg32; reg32 = MCHBAR32(C1ODT); reg32 &= ~(7 << 28); MCHBAR32(C1ODT) = reg32; } cas = sysinfo->cas; reg32 = MCHBAR32(C0ODT) & 0xfff00000; reg32 |= odt[(cas-3) * 2]; MCHBAR32(C0ODT) = reg32; reg32 = MCHBAR32(C1ODT) & 0xfff00000; reg32 |= odt[(cas-3) * 2]; MCHBAR32(C1ODT) = reg32; reg32 = MCHBAR32(C0ODT + 4) & 0x1fc8ffff; reg32 |= odt[((cas-3) * 2) + 1]; MCHBAR32(C0ODT + 4) = reg32; reg32 = MCHBAR32(C1ODT + 4) & 0x1fc8ffff; reg32 |= odt[((cas-3) * 2) + 1]; MCHBAR32(C1ODT + 4) = reg32; } /** * @brief Enable clocks to populated sockets */ static void sdram_enable_memory_clocks(struct sys_info *sysinfo) { u8 clocks[2] = { 0, 0 }; if (sysinfo->dimm[0] != SYSINFO_DIMM_NOT_POPULATED) clocks[0] |= (1 << 0) | (1 << 1); if (sysinfo->dimm[1] != SYSINFO_DIMM_NOT_POPULATED) clocks[0] |= (1 << 2) | (1 << 3); if (sysinfo->dimm[2] != SYSINFO_DIMM_NOT_POPULATED) clocks[1] |= (1 << 0) | (1 << 1); if (sysinfo->dimm[3] != SYSINFO_DIMM_NOT_POPULATED) clocks[1] |= (1 << 2) | (1 << 3); #ifdef OVERRIDE_CLOCK_DISABLE clocks[0] = 0xf; clocks[1] = 0xf; #endif MCHBAR8(C0DCLKDIS) = clocks[0]; MCHBAR8(C1DCLKDIS) = clocks[1]; } #define RTT_ODT_75_OHM (1 << 5) #define RTT_ODT_150_OHM (1 << 9) #define EMRS_OCD_DEFAULT ( (1 << 12) | (1 << 11) | (1 << 10) ) #define MRS_CAS_3 (3 << 7) #define MRS_CAS_4 (4 << 7) #define MRS_CAS_5 (5 << 7) #define MRS_TWR_3 (2 << 12) #define MRS_TWR_4 (3 << 12) #define MRS_TWR_5 (4 << 12) #define MRS_BT (1 << 6) #define MRS_BL4 (2 << 3) #define MRS_BL8 (3 << 3) static void sdram_jedec_enable(struct sys_info *sysinfo) { int i, nonzero; u32 bankaddr = 0, tmpaddr, mrsaddr = 0; for (i = 0, nonzero = -1; i < 8; i++) { if (sysinfo->banksize[i] == 0) { continue; } printk_debug("jedec enable sequence: bank %d\n", i); switch (i) { case 0: /* Start at address 0 */ bankaddr = 0; break; case 4: if (sysinfo->interleaved) { bankaddr = 0x40; break; } default: if (nonzero != -1) { printk_debug("bankaddr from bank size of rank %d\n", nonzero); bankaddr += (1 << sysinfo->banksize[nonzero]) << (sysinfo->interleaved?28:27); break; } /* No populated bank hit before. Start at address 0 */ bankaddr = 0; } /* We have a bank with a non-zero size.. Remember it * for the next offset we have to calculate */ nonzero = i; /* Get CAS latency set up */ switch (sysinfo->cas) { case 5: mrsaddr = MRS_CAS_5; break; case 4: mrsaddr = MRS_CAS_4; break; case 3: mrsaddr = MRS_CAS_3; break; default: die("Jedec Error (CAS).\n"); } /* Get tWR set */ switch (sysinfo->twr) { case 5: mrsaddr |= MRS_TWR_5; break; case 4: mrsaddr |= MRS_TWR_4; break; case 3: mrsaddr |= MRS_TWR_3; break; default: die("Jedec Error (tWR).\n"); } /* Interleaved */ if (sysinfo->interleaved) { mrsaddr |= MRS_BT; mrsaddr = mrsaddr << 1; } /* Only burst length 8 supported */ mrsaddr |= MRS_BL8; /* Apply NOP */ PRINTK_DEBUG("Apply NOP\r\n"); do_ram_command(RAM_COMMAND_NOP); ram_read32(bankaddr); /* Precharge all banks */ PRINTK_DEBUG("All Banks Precharge\r\n"); do_ram_command(RAM_COMMAND_PRECHARGE); ram_read32(bankaddr); /* Extended Mode Register Set (2) */ PRINTK_DEBUG("Extended Mode Register Set(2)\r\n"); do_ram_command(RAM_COMMAND_EMRS | RAM_EMRS_2); ram_read32(bankaddr); /* Extended Mode Register Set (3) */ PRINTK_DEBUG("Extended Mode Register Set(3)\r\n"); do_ram_command(RAM_COMMAND_EMRS | RAM_EMRS_3); ram_read32(bankaddr); /* Extended Mode Register Set */ PRINTK_DEBUG("Extended Mode Register Set\r\n"); do_ram_command(RAM_COMMAND_EMRS | RAM_EMRS_1); tmpaddr = bankaddr; if (!sdram_capabilities_dual_channel()) { tmpaddr |= RTT_ODT_75_OHM; } else if (sysinfo->interleaved) { tmpaddr |= (RTT_ODT_150_OHM << 1); } else { tmpaddr |= RTT_ODT_150_OHM; } ram_read32(tmpaddr); /* Mode Register Set: Reset DLLs */ PRINTK_DEBUG("MRS: Reset DLLs\r\n"); do_ram_command(RAM_COMMAND_MRS); tmpaddr = bankaddr; tmpaddr |= mrsaddr; /* Set DLL reset bit */ if (sysinfo->interleaved) tmpaddr |= (1 << 12); else tmpaddr |= (1 << 11); ram_read32(tmpaddr); /* Precharge all banks */ PRINTK_DEBUG("All Banks Precharge\r\n"); do_ram_command(RAM_COMMAND_PRECHARGE); ram_read32(bankaddr); /* CAS before RAS Refresh */ PRINTK_DEBUG("CAS before RAS\r\n"); do_ram_command(RAM_COMMAND_CBR); /* CBR wants two READs */ ram_read32(bankaddr); ram_read32(bankaddr); /* Mode Register Set: Enable DLLs */ PRINTK_DEBUG("MRS: Enable DLLs\r\n"); do_ram_command(RAM_COMMAND_MRS); tmpaddr = bankaddr; tmpaddr |= mrsaddr; ram_read32(tmpaddr); /* Extended Mode Register Set */ PRINTK_DEBUG("Extended Mode Register Set: ODT/OCD\r\n"); do_ram_command(RAM_COMMAND_EMRS | RAM_EMRS_1); tmpaddr = bankaddr; if (!sdram_capabilities_dual_channel()) { tmpaddr |= RTT_ODT_75_OHM | EMRS_OCD_DEFAULT; } else if (sysinfo->interleaved) { tmpaddr |= ((RTT_ODT_150_OHM | EMRS_OCD_DEFAULT) << 1); } else { tmpaddr |= RTT_ODT_150_OHM | EMRS_OCD_DEFAULT; } ram_read32(tmpaddr); /* Extended Mode Register Set */ PRINTK_DEBUG("Extended Mode Register Set: OCD Exit\r\n"); do_ram_command(RAM_COMMAND_EMRS | RAM_EMRS_1); tmpaddr = bankaddr; if (!sdram_capabilities_dual_channel()) { tmpaddr |= RTT_ODT_75_OHM; } else if (sysinfo->interleaved) { tmpaddr |= (RTT_ODT_150_OHM << 1); } else { tmpaddr |= RTT_ODT_150_OHM; } ram_read32(tmpaddr); } } static void sdram_init_complete(void) { PRINTK_DEBUG("Normal Operation\r\n"); do_ram_command(RAM_COMMAND_NORMAL); } static void sdram_setup_processor_side(void) { if (i945_silicon_revision() == 0) MCHBAR32(FSBPMC3) |= (1 << 2); MCHBAR8(0xb00) |= 1; if (i945_silicon_revision() == 0) MCHBAR32(SLPCTL) |= (1 << 8); } #define BOOT_MODE_RESUME 1 #define BOOT_MODE_NORMAL 0 /** * @param boot_mode: 0 = normal, 1 = resume */ void sdram_initialize(int boot_mode) { struct sys_info sysinfo; u8 reg8, cas_mask; sdram_detect_errors(); printk_debug ("Setting up RAM controller.\r\n"); memset(&sysinfo, 0, sizeof(sysinfo)); /* Look at the type of DIMMs and verify all DIMMs are x8 or x16 width */ sdram_get_dram_configuration(&sysinfo); /* Check whether we have stacked DIMMs */ sdram_verify_package_type(&sysinfo); /* Determine common CAS */ cas_mask = sdram_possible_cas_latencies(&sysinfo); /* Choose Common Frequency */ sdram_detect_cas_latency_and_ram_speed(&sysinfo, cas_mask); /* Determine smallest common tRAS */ sdram_detect_smallest_tRAS(&sysinfo); /* Determine tRP */ sdram_detect_smallest_tRP(&sysinfo); /* Determine tRCD */ sdram_detect_smallest_tRCD(&sysinfo); /* Determine smallest refresh period */ sdram_detect_smallest_refresh(&sysinfo); /* Verify all DIMMs support burst length 8 */ sdram_verify_burst_length(&sysinfo); /* determine tWR */ sdram_detect_smallest_tWR(&sysinfo); /* Determine DIMM size parameters (rows, columns banks) */ sdram_detect_dimm_size(&sysinfo); /* determine tRFC */ sdram_detect_smallest_tRFC(&sysinfo); /* Program PLL settings */ sdram_program_pll_settings(); /* Program Graphics Frequency */ sdram_program_graphics_frequency(&sysinfo); /* Program System Memory Frequency */ sdram_program_memory_frequency(&sysinfo); /* Determine Mode of Operation (Interleaved etc) */ sdram_set_channel_mode(&sysinfo); /* Program Clock Crossing values */ sdram_program_clock_crossing(); /* Disable fast dispatch */ sdram_disable_fast_dispatch(); /* Enable WIODLL Power Down in ACPI states */ MCHBAR32(C0DMC) |= (1 << 24); MCHBAR32(C1DMC) |= (1 << 24); /* Program DRAM Row Boundary/Attribute Registers */ if (boot_mode != BOOT_MODE_RESUME) { /* program row size DRB and set TOLUD */ sdram_program_row_boundaries(&sysinfo); /* program page size DRA */ sdram_set_row_attributes(&sysinfo); } /* Program CxBNKARC */ sdram_set_bank_architecture(&sysinfo); /* Program DRAM Timing and Control registers based on SPD */ sdram_set_timing_and_control(&sysinfo); /* On-Die Termination Adjustment */ sdram_on_die_termination(&sysinfo); /* Pre Jedec Initialization */ sdram_pre_jedec_initialization(); /* Perform System Memory IO Initialization */ sdram_initialize_system_memory_io(&sysinfo); /* Perform System Memory IO Buffer Enable */ sdram_enable_system_memory_io(&sysinfo); /* Enable System Memory Clocks */ sdram_enable_memory_clocks(&sysinfo); if (boot_mode != BOOT_MODE_RESUME) { /* Jedec Initialization sequence */ sdram_jedec_enable(&sysinfo); } /* Program Power Management Registers */ sdram_power_management(&sysinfo); /* Post Jedec Init */ sdram_post_jedec_initialization(&sysinfo); /* Program DRAM Throttling */ sdram_thermal_management(); /* Normal Operations */ sdram_init_complete(); /* Program Receive Enable Timings */ sdram_program_receive_enable(&sysinfo); /* Enable Periodic RCOMP */ sdram_enable_rcomp(); /* Tell ICH7 that we're done */ reg8 = pci_read_config8(PCI_DEV(0,0x1f,0), 0xa2); reg8 &= ~(1 << 7); pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, reg8); printk_debug("RAM initialization finished.\r\n"); sdram_setup_processor_side(); }