#include #include #include #include #include #include #include #include /* Initialize the specified "mc" struct with initial values. */ void mptable_init(struct mp_config_table *mc, u32 lapic_addr) { int i; memset(mc, 0, sizeof(*mc)); memcpy(mc->mpc_signature, MPC_SIGNATURE, 4); mc->mpc_length = sizeof(*mc); /* Initially just the header size. */ mc->mpc_spec = 0x04; /* MultiProcessor specification 1.4 */ mc->mpc_checksum = 0; /* Not yet computed. */ mc->mpc_oemptr = 0; mc->mpc_oemsize = 0; mc->mpc_entry_count = 0; /* No entries yet... */ mc->mpc_lapic = lapic_addr; mc->mpe_length = 0; mc->mpe_checksum = 0; mc->reserved = 0; strncpy(mc->mpc_oem, CONFIG_MAINBOARD_VENDOR, 8); strncpy(mc->mpc_productid, CONFIG_MAINBOARD_PART_NUMBER, 12); /* * The oem/productid fields are exactly 8/12 bytes long. If the resp. * entry is shorter, the remaining bytes are filled with spaces. */ for (i = MIN(strlen(CONFIG_MAINBOARD_VENDOR), 8); i < 8; i++) mc->mpc_oem[i] = ' '; for (i = MIN(strlen(CONFIG_MAINBOARD_PART_NUMBER), 12); i < 12; i++) mc->mpc_productid[i] = ' '; } static unsigned char smp_compute_checksum(void *v, int len) { unsigned char *bytes; unsigned char checksum; int i; bytes = v; checksum = 0; for(i = 0; i < len; i++) { checksum -= bytes[i]; } return checksum; } static void *smp_write_floating_table_physaddr(unsigned long addr, unsigned long mpf_physptr, unsigned int virtualwire) { struct intel_mp_floating *mf; void *v; v = (void *)addr; mf = v; mf->mpf_signature[0] = '_'; mf->mpf_signature[1] = 'M'; mf->mpf_signature[2] = 'P'; mf->mpf_signature[3] = '_'; mf->mpf_physptr = mpf_physptr; mf->mpf_length = 1; mf->mpf_specification = 4; mf->mpf_checksum = 0; mf->mpf_feature1 = 0; mf->mpf_feature2 = virtualwire?MP_FEATURE_VIRTUALWIRE:0; mf->mpf_feature3 = 0; mf->mpf_feature4 = 0; mf->mpf_feature5 = 0; mf->mpf_checksum = smp_compute_checksum(mf, mf->mpf_length*16); return v; } void *smp_write_floating_table(unsigned long addr, unsigned int virtualwire) { /* 16 byte align the table address */ addr = (addr + 0xf) & (~0xf); return smp_write_floating_table_physaddr(addr, addr + SMP_FLOATING_TABLE_LEN, virtualwire); } void *smp_next_mpc_entry(struct mp_config_table *mc) { void *v; v = (void *)(((char *)mc) + mc->mpc_length); return v; } static void smp_add_mpc_entry(struct mp_config_table *mc, unsigned length) { mc->mpc_length += length; mc->mpc_entry_count++; } void *smp_next_mpe_entry(struct mp_config_table *mc) { void *v; v = (void *)(((char *)mc) + mc->mpc_length + mc->mpe_length); return v; } static void smp_add_mpe_entry(struct mp_config_table *mc, mpe_t mpe) { mc->mpe_length += mpe->mpe_length; } void smp_write_processor(struct mp_config_table *mc, unsigned char apicid, unsigned char apicver, unsigned char cpuflag, unsigned int cpufeature, unsigned int featureflag) { struct mpc_config_processor *mpc; mpc = smp_next_mpc_entry(mc); memset(mpc, '\0', sizeof(*mpc)); mpc->mpc_type = MP_PROCESSOR; mpc->mpc_apicid = apicid; mpc->mpc_apicver = apicver; mpc->mpc_cpuflag = cpuflag; mpc->mpc_cpufeature = cpufeature; mpc->mpc_featureflag = featureflag; smp_add_mpc_entry(mc, sizeof(*mpc)); } /* If we assume a symmetric processor configuration we can * get all of the information we need to write the processor * entry from the bootstrap processor. * Plus I don't think linux really even cares. * Having the proper apicid's in the table so the non-bootstrap * processors can be woken up should be enough. */ void smp_write_processors(struct mp_config_table *mc) { int boot_apic_id; int order_id; unsigned apic_version; unsigned cpu_features; unsigned cpu_feature_flags; struct cpuid_result result; device_t cpu; boot_apic_id = lapicid(); apic_version = lapic_read(LAPIC_LVR) & 0xff; result = cpuid(1); cpu_features = result.eax; cpu_feature_flags = result.edx; /* order the output of the cpus to fix a bug in kernel 2.6.11 */ for(order_id = 0;order_id <256; order_id++) { for(cpu = all_devices; cpu; cpu = cpu->next) { unsigned long cpu_flag; if ((cpu->path.type != DEVICE_PATH_APIC) || (cpu->bus->dev->path.type != DEVICE_PATH_APIC_CLUSTER)) { continue; } if (!cpu->enabled) { continue; } cpu_flag = MPC_CPU_ENABLED; if (boot_apic_id == cpu->path.apic.apic_id) { cpu_flag = MPC_CPU_ENABLED | MPC_CPU_BOOTPROCESSOR; } if(cpu->path.apic.apic_id == order_id) { smp_write_processor(mc, cpu->path.apic.apic_id, apic_version, cpu_flag, cpu_features, cpu_feature_flags ); break; } } } } static void smp_write_bus(struct mp_config_table *mc, unsigned char id, const char *bustype) { struct mpc_config_bus *mpc; mpc = smp_next_mpc_entry(mc); memset(mpc, '\0', sizeof(*mpc)); mpc->mpc_type = MP_BUS; mpc->mpc_busid = id; memcpy(mpc->mpc_bustype, bustype, sizeof(mpc->mpc_bustype)); smp_add_mpc_entry(mc, sizeof(*mpc)); } void smp_write_ioapic(struct mp_config_table *mc, unsigned char id, unsigned char ver, unsigned long apicaddr) { struct mpc_config_ioapic *mpc; mpc = smp_next_mpc_entry(mc); memset(mpc, '\0', sizeof(*mpc)); mpc->mpc_type = MP_IOAPIC; mpc->mpc_apicid = id; mpc->mpc_apicver = ver; mpc->mpc_flags = MPC_APIC_USABLE; mpc->mpc_apicaddr = apicaddr; smp_add_mpc_entry(mc, sizeof(*mpc)); } void smp_write_intsrc(struct mp_config_table *mc, unsigned char irqtype, unsigned short irqflag, unsigned char srcbus, unsigned char srcbusirq, unsigned char dstapic, unsigned char dstirq) { struct mpc_config_intsrc *mpc; mpc = smp_next_mpc_entry(mc); memset(mpc, '\0', sizeof(*mpc)); mpc->mpc_type = MP_INTSRC; mpc->mpc_irqtype = irqtype; mpc->mpc_irqflag = irqflag; mpc->mpc_srcbus = srcbus; mpc->mpc_srcbusirq = srcbusirq; mpc->mpc_dstapic = dstapic; mpc->mpc_dstirq = dstirq; smp_add_mpc_entry(mc, sizeof(*mpc)); #ifdef DEBUG_MPTABLE printk(BIOS_DEBUG, "add intsrc srcbus 0x%x srcbusirq 0x%x, dstapic 0x%x, dstirq 0x%x\n", srcbus, srcbusirq, dstapic, dstirq); hexdump(__func__, mpc, sizeof(*mpc)); #endif } void smp_write_intsrc_pci_bridge(struct mp_config_table *mc, unsigned char irqtype, unsigned short irqflag, struct device *dev, unsigned char dstapic, unsigned char *dstirq) { struct device *child; int i; int srcbus; int slot; struct bus *link; unsigned char dstirq_x[4]; for (link = dev->link_list; link; link = link->next) { child = link->children; srcbus = link->secondary; while (child) { if (child->path.type != DEVICE_PATH_PCI) goto next; slot = (child->path.pci.devfn >> 3); /* round pins */ for (i = 0; i < 4; i++) dstirq_x[i] = dstirq[(i + slot) % 4]; if ((child->class >> 16) != PCI_BASE_CLASS_BRIDGE) { /* pci device */ printk(BIOS_DEBUG, "route irq: %s\n", dev_path(child)); for (i = 0; i < 4; i++) smp_write_intsrc(mc, irqtype, irqflag, srcbus, (slot<<2)|i, dstapic, dstirq_x[i]); goto next; } switch (child->class>>8) { case PCI_CLASS_BRIDGE_PCI: case PCI_CLASS_BRIDGE_PCMCIA: case PCI_CLASS_BRIDGE_CARDBUS: printk(BIOS_DEBUG, "route irq bridge: %s\n", dev_path(child)); smp_write_intsrc_pci_bridge(mc, irqtype, irqflag, child, dstapic, dstirq_x); } next: child = child->sibling; } } } void smp_write_lintsrc(struct mp_config_table *mc, unsigned char irqtype, unsigned short irqflag, unsigned char srcbusid, unsigned char srcbusirq, unsigned char destapic, unsigned char destapiclint) { struct mpc_config_lintsrc *mpc; mpc = smp_next_mpc_entry(mc); memset(mpc, '\0', sizeof(*mpc)); mpc->mpc_type = MP_LINTSRC; mpc->mpc_irqtype = irqtype; mpc->mpc_irqflag = irqflag; mpc->mpc_srcbusid = srcbusid; mpc->mpc_srcbusirq = srcbusirq; mpc->mpc_destapic = destapic; mpc->mpc_destapiclint = destapiclint; smp_add_mpc_entry(mc, sizeof(*mpc)); } void smp_write_address_space(struct mp_config_table *mc, unsigned char busid, unsigned char address_type, unsigned int address_base_low, unsigned int address_base_high, unsigned int address_length_low, unsigned int address_length_high) { struct mp_exten_system_address_space *mpe; mpe = smp_next_mpe_entry(mc); memset(mpe, '\0', sizeof(*mpe)); mpe->mpe_type = MPE_SYSTEM_ADDRESS_SPACE; mpe->mpe_length = sizeof(*mpe); mpe->mpe_busid = busid; mpe->mpe_address_type = address_type; mpe->mpe_address_base_low = address_base_low; mpe->mpe_address_base_high = address_base_high; mpe->mpe_address_length_low = address_length_low; mpe->mpe_address_length_high = address_length_high; smp_add_mpe_entry(mc, (mpe_t)mpe); } void smp_write_bus_hierarchy(struct mp_config_table *mc, unsigned char busid, unsigned char bus_info, unsigned char parent_busid) { struct mp_exten_bus_hierarchy *mpe; mpe = smp_next_mpe_entry(mc); memset(mpe, '\0', sizeof(*mpe)); mpe->mpe_type = MPE_BUS_HIERARCHY; mpe->mpe_length = sizeof(*mpe); mpe->mpe_busid = busid; mpe->mpe_bus_info = bus_info; mpe->mpe_parent_busid = parent_busid; smp_add_mpe_entry(mc, (mpe_t)mpe); } void smp_write_compatibility_address_space(struct mp_config_table *mc, unsigned char busid, unsigned char address_modifier, unsigned int range_list) { struct mp_exten_compatibility_address_space *mpe; mpe = smp_next_mpe_entry(mc); memset(mpe, '\0', sizeof(*mpe)); mpe->mpe_type = MPE_COMPATIBILITY_ADDRESS_SPACE; mpe->mpe_length = sizeof(*mpe); mpe->mpe_busid = busid; mpe->mpe_address_modifier = address_modifier; mpe->mpe_range_list = range_list; smp_add_mpe_entry(mc, (mpe_t)mpe); } void mptable_lintsrc(struct mp_config_table *mc, unsigned long bus_isa) { smp_write_lintsrc(mc, mp_ExtINT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x0, MP_APIC_ALL, 0x0); smp_write_lintsrc(mc, mp_NMI, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x0, MP_APIC_ALL, 0x1); } void mptable_add_isa_interrupts(struct mp_config_table *mc, unsigned long bus_isa, unsigned long apicid, int external_int2) { /*I/O Ints: Type Trigger Polarity Bus ID IRQ APIC ID PIN# */ smp_write_intsrc(mc, external_int2?mp_INT:mp_ExtINT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x0, apicid, 0x0); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x1, apicid, 0x1); smp_write_intsrc(mc, external_int2?mp_ExtINT:mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x0, apicid, 0x2); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x3, apicid, 0x3); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x4, apicid, 0x4); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x6, apicid, 0x6); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x7, apicid, 0x7); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x8, apicid, 0x8); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0x9, apicid, 0x9); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0xa, apicid, 0xa); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0xb, apicid, 0xb); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0xc, apicid, 0xc); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0xd, apicid, 0xd); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0xe, apicid, 0xe); smp_write_intsrc(mc, mp_INT, MP_IRQ_TRIGGER_EDGE|MP_IRQ_POLARITY_HIGH, bus_isa, 0xf, apicid, 0xf); } void mptable_write_buses(struct mp_config_table *mc, int *max_pci_bus, int *isa_bus) { int dummy, i, highest; char buses[256]; struct device *dev; if (!max_pci_bus) max_pci_bus = &dummy; if (!isa_bus) isa_bus = &dummy; *max_pci_bus = 0; highest = 0; memset(buses, 0, sizeof(buses)); for (dev = all_devices; dev; dev = dev->next) { struct bus *bus; for (bus = dev->link_list; bus; bus = bus->next) { if (bus->secondary > 255) { printk(BIOS_ERR, "A bus claims to have a bus ID > 255?!? Aborting"); return; } buses[bus->secondary] = 1; if (highest < bus->secondary) highest = bus->secondary; } } for (i=0; i <= highest; i++) { if (buses[i]) { smp_write_bus(mc, i, "PCI "); *max_pci_bus = i; } } *isa_bus = *max_pci_bus + 1; smp_write_bus(mc, *isa_bus, "ISA "); } void *mptable_finalize(struct mp_config_table *mc) { mc->mpe_checksum = smp_compute_checksum(smp_next_mpc_entry(mc), mc->mpe_length); mc->mpc_checksum = smp_compute_checksum(mc, mc->mpc_length); printk(BIOS_DEBUG, "Wrote the mp table end at: %p - %p\n", mc, smp_next_mpe_entry(mc)); return smp_next_mpe_entry(mc); }