#define ASSEMBLY 1 #include #include #include "arch/romcc_io.h" #include "pc80/serial.c" #include "arch/i386/lib/console.c" #include "ram/ramtest.c" #include "northbridge/amd/amdk8/early_ht.c" #include "southbridge/amd/amd8111/amd8111_early_smbus.c" #include "northbridge/amd/amdk8/raminit.h" #warning "FIXME move these delay functions somewhere more appropriate" #warning "FIXME use the apic timer instead it needs no calibration on an Opteron it runs at 200Mhz" static void print_clock_multiplier(void) { msr_t msr; print_debug("clock multipler: 0x"); msr = rdmsr(0xc0010042); print_debug_hex32(msr.lo & 0x3f); print_debug(" = 0x"); print_debug_hex32(((msr.lo & 0x3f) + 8) * 100); print_debug("Mhz\r\n"); } static unsigned usecs_to_ticks(unsigned usecs) { #warning "FIXME make usecs_to_ticks work properly" #if 1 return usecs *2000; #else /* This can only be done if cpuid says fid changing is supported * I need to look up the base frequency another way for other * cpus. Is it worth dedicating a global register to this? * Are the PET timers useable for this purpose? */ msr_t msr; msr = rdmsr(0xc0010042); return ((msr.lo & 0x3f) + 8) * 100 *usecs; #endif } static void init_apic_timer(void) { volatile uint32_t *apic_reg = (volatile uint32_t *)0xfee00000; uint32_t start, end; /* Set the apic timer to no interrupts and periodic mode */ apic_reg[0x320 >> 2] = (1 << 17)|(1<< 16)|(0 << 12)|(0 << 0); /* Set the divider to 1, no divider */ apic_reg[0x3e0 >> 2] = (1 << 3) | 3; /* Set the initial counter to 0xffffffff */ apic_reg[0x380 >> 2] = 0xffffffff; } static void udelay(unsigned usecs) { #if 1 uint32_t start, ticks; tsc_t tsc; /* Calculate the number of ticks to run for */ ticks = usecs_to_ticks(usecs); /* Find the current time */ tsc = rdtsc(); start = tsc.lo; do { tsc = rdtsc(); } while((tsc.lo - start) < ticks); #else volatile uint32_t *apic_reg = (volatile uint32_t *)0xfee00000; uint32_t start, value, ticks; /* Calculate the number of ticks to run for */ ticks = usecs * 200; start = apic_reg[0x390 >> 2]; do { value = apic_reg[0x390 >> 2]; } while((start - value) < ticks); #endif } static void mdelay(unsigned msecs) { int i; for(i = 0; i < msecs; i++) { udelay(1000); } } static void delay(unsigned secs) { int i; for(i = 0; i < secs; i++) { mdelay(1000); } } static void memreset_setup(const struct mem_controller *ctrl) { /* Set the memreset low */ outb((0 << 7)|(0 << 6)|(0<<5)|(0<<4)|(1<<2)|(0<<0), SMBUS_IO_BASE + 0xc0 + 28); /* Ensure the BIOS has control of the memory lines */ outb((0 << 7)|(0 << 6)|(0<<5)|(0<<4)|(1<<2)|(0<<0), SMBUS_IO_BASE + 0xc0 + 29); print_debug("memreset lo\r\n"); } static void memreset(const struct mem_controller *ctrl) { udelay(800); /* Set memreset_high */ outb((0<<7)|(0<<6)|(0<<5)|(0<<4)|(1<<2)|(1<<0), SMBUS_IO_BASE + 0xc0 + 28); print_debug("memreset hi\r\n"); udelay(50); } #include "northbridge/amd/amdk8/raminit.c" #include "northbridge/amd/amdk8/coherent_ht.c" #include "sdram/generic_sdram.c" #define NODE_ID 0x60 #define HT_INIT_CONTROL 0x6c #define HTIC_ColdR_Detect (1<<4) #define HTIC_BIOSR_Detect (1<<5) #define HTIC_INIT_Detect (1<<6) static int boot_cpu(void) { volatile unsigned long *local_apic; unsigned long apic_id; int bsp; msr_t msr; msr = rdmsr(0x1b); bsp = !!(msr.lo & (1 << 8)); if (bsp) { print_debug("Bootstrap cpu\r\n"); } return bsp; } static int cpu_init_detected(void) { unsigned long dcl; int cpu_init; unsigned long htic; htic = pci_read_config32(PCI_DEV(0, 0x18, 0), HT_INIT_CONTROL); #if 0 print_debug("htic: "); print_debug_hex32(htic); print_debug("\r\n"); if (!(htic & HTIC_ColdR_Detect)) { print_debug("Cold Reset.\r\n"); } if ((htic & HTIC_ColdR_Detect) && !(htic & HTIC_BIOSR_Detect)) { print_debug("BIOS generated Reset.\r\n"); } if (htic & HTIC_INIT_Detect) { print_debug("Init event.\r\n"); } #endif cpu_init = (htic & HTIC_INIT_Detect); if (cpu_init) { print_debug("CPU INIT Detected.\r\n"); } return cpu_init; } static void print_debug_pci_dev(unsigned dev) { print_debug("PCI: "); print_debug_hex8((dev >> 16) & 0xff); print_debug_char(':'); print_debug_hex8((dev >> 11) & 0x1f); print_debug_char('.'); print_debug_hex8((dev >> 8) & 7); } static void print_pci_devices(void) { device_t dev; for(dev = PCI_DEV(0, 0, 0); dev <= PCI_DEV(0, 0x1f, 0x7); dev += PCI_DEV(0,0,1)) { uint32_t id; id = pci_read_config32(dev, PCI_VENDOR_ID); if (((id & 0xffff) == 0x0000) || ((id & 0xffff) == 0xffff) || (((id >> 16) & 0xffff) == 0xffff) || (((id >> 16) & 0xffff) == 0x0000)) { continue; } print_debug_pci_dev(dev); print_debug("\r\n"); } } static void dump_pci_device(unsigned dev) { int i; print_debug_pci_dev(dev); print_debug("\r\n"); for(i = 0; i <= 255; i++) { unsigned char val; if ((i & 0x0f) == 0) { print_debug_hex8(i); print_debug_char(':'); } val = pci_read_config8(dev, i); print_debug_char(' '); print_debug_hex8(val); if ((i & 0x0f) == 0x0f) { print_debug("\r\n"); } } } static void dump_pci_devices(void) { device_t dev; for(dev = PCI_DEV(0, 0, 0); dev <= PCI_DEV(0, 0x1f, 0x7); dev += PCI_DEV(0,0,1)) { uint32_t id; id = pci_read_config32(dev, PCI_VENDOR_ID); if (((id & 0xffff) == 0x0000) || ((id & 0xffff) == 0xffff) || (((id >> 16) & 0xffff) == 0xffff) || (((id >> 16) & 0xffff) == 0x0000)) { continue; } dump_pci_device(dev); } } static void dump_spd_registers(const struct mem_controller *ctrl) { int i; print_debug("\r\n"); for(i = 0; i < 4; i++) { unsigned device; device = ctrl->channel0[i]; if (device) { int j; print_debug("dimm: "); print_debug_hex8(i); print_debug(".0: "); print_debug_hex8(device); for(j = 0; j < 256; j++) { int status; unsigned char byte; if ((j & 0xf) == 0) { print_debug("\r\n"); print_debug_hex8(j); print_debug(": "); } status = smbus_read_byte(device, j); if (status < 0) { print_debug("bad device\r\n"); break; } byte = status & 0xff; print_debug_hex8(byte); print_debug_char(' '); } print_debug("\r\n"); } device = ctrl->channel1[i]; if (device) { int j; print_debug("dimm: "); print_debug_hex8(i); print_debug(".1: "); print_debug_hex8(device); for(j = 0; j < 256; j++) { int status; unsigned char byte; if ((j & 0xf) == 0) { print_debug("\r\n"); print_debug_hex8(j); print_debug(": "); } status = smbus_read_byte(device, j); if (status < 0) { print_debug("bad device\r\n"); break; } byte = status & 0xff; print_debug_hex8(byte); print_debug_char(' '); } print_debug("\r\n"); } } } static void pnp_write_config(unsigned char port, unsigned char value, unsigned char reg) { outb(reg, port); outb(value, port +1); } static unsigned char pnp_read_config(unsigned char port, unsigned char reg) { outb(reg, port); return inb(port +1); } static void pnp_set_logical_device(unsigned char port, int device) { pnp_write_config(port, device, 0x07); } static void pnp_set_enable(unsigned char port, int enable) { pnp_write_config(port, enable?0x1:0x0, 0x30); } static int pnp_read_enable(unsigned char port) { return !!pnp_read_config(port, 0x30); } static void pnp_set_iobase0(unsigned char port, unsigned iobase) { pnp_write_config(port, (iobase >> 8) & 0xff, 0x60); pnp_write_config(port, iobase & 0xff, 0x61); } static void pnp_set_iobase1(unsigned char port, unsigned iobase) { pnp_write_config(port, (iobase >> 8) & 0xff, 0x62); pnp_write_config(port, iobase & 0xff, 0x63); } static void pnp_set_irq0(unsigned char port, unsigned irq) { pnp_write_config(port, irq, 0x70); } static void pnp_set_irq1(unsigned char port, unsigned irq) { pnp_write_config(port, irq, 0x72); } static void pnp_set_drq(unsigned char port, unsigned drq) { pnp_write_config(port, drq & 0xff, 0x74); } #define PC87360_FDC 0x00 #define PC87360_PP 0x01 #define PC87360_SP2 0x02 #define PC87360_SP1 0x03 #define PC87360_SWC 0x04 #define PC87360_KBCM 0x05 #define PC87360_KBCK 0x06 #define PC87360_GPIO 0x07 #define PC87360_ACB 0x08 #define PC87360_FSCM 0x09 #define PC87360_WDT 0x0A static void pc87360_enable_serial(void) { pnp_set_logical_device(SIO_BASE, PC87360_SP1); pnp_set_enable(SIO_BASE, 1); pnp_set_iobase0(SIO_BASE, 0x3f8); } static void main(void) { /* * GPIO28 of 8111 will control H0_MEMRESET_L * GPIO29 of 8111 will control H1_MEMRESET_L */ static const struct mem_controller cpu0 = { .f0 = PCI_DEV(0, 0x18, 0), .f1 = PCI_DEV(0, 0x18, 1), .f2 = PCI_DEV(0, 0x18, 2), .f3 = PCI_DEV(0, 0x18, 3), .channel0 = { (0xa<<3)|0, (0xa<<3)|2, 0, 0 }, .channel1 = { (0xa<<3)|1, (0xa<<3)|3, 0, 0 }, }; static const struct mem_controller cpu1 = { .f0 = PCI_DEV(0, 0x19, 0), .f1 = PCI_DEV(0, 0x19, 1), .f2 = PCI_DEV(0, 0x19, 2), .f3 = PCI_DEV(0, 0x19, 3), .channel0 = { (0xa<<3)|4, (0xa<<3)|6, 0, 0 }, .channel1 = { (0xa<<3)|5, (0xa<<3)|7, 0, 0 }, }; pc87360_enable_serial(); uart_init(); console_init(); if (boot_cpu() && !cpu_init_detected()) { #if 1 init_apic_timer(); #endif setup_default_resource_map(); setup_coherent_ht_domain(); enumerate_ht_chain(); print_pci_devices(); enable_smbus(); dump_spd_registers(&cpu0); sdram_initialize(&cpu0); #if 0 dump_pci_devices(); #endif #if 0 dump_pci_device(PCI_DEV(0, 0x18, 2)); #endif /* Check all of memory */ msr_t msr; msr = rdmsr(TOP_MEM); print_debug("TOP_MEM: "); print_debug_hex32(msr.hi); print_debug_hex32(msr.lo); print_debug("\r\n"); #if 0 ram_check(0x00000000, msr.lo); #else /* Check 16MB of memory */ ram_check(0x00000000, 0x1600000); #endif #if 0 print_debug("sleeping 15s\r\n"); delay(15); print_debug("sleeping 15s done\r\n"); #endif } }