/* This should be done by Eric 2004.12 yhlu add dual core support 2005.01 yhlu add support move apic before pci_domain in MB devicetree.cb 2005.02 yhlu add e0 memory hole support 2005.11 yhlu add put sb ht chain on bus 0 */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if CONFIG_LOGICAL_CPUS #include #endif #include "chip.h" #include "root_complex/chip.h" #include "northbridge.h" #include "amdk8.h" #include #include struct amdk8_sysconf_t sysconf; #define MAX_FX_DEVS 8 static device_t __f0_dev[MAX_FX_DEVS]; static device_t __f1_dev[MAX_FX_DEVS]; static unsigned fx_devs=0; static void get_fx_devs(void) { int i; for(i = 0; i < MAX_FX_DEVS; i++) { __f0_dev[i] = dev_find_slot(0, PCI_DEVFN(0x18 + i, 0)); __f1_dev[i] = dev_find_slot(0, PCI_DEVFN(0x18 + i, 1)); if (__f0_dev[i] != NULL && __f1_dev[i] != NULL) fx_devs = i+1; } if (__f1_dev[0] == NULL || __f0_dev[0] == NULL || fx_devs == 0) { die("Cannot find 0:0x18.[0|1]\n"); } } static u32 f1_read_config32(unsigned reg) { if (fx_devs == 0) get_fx_devs(); return pci_read_config32(__f1_dev[0], reg); } static void f1_write_config32(unsigned reg, u32 value) { int i; if (fx_devs == 0) get_fx_devs(); for(i = 0; i < fx_devs; i++) { device_t dev; dev = __f1_dev[i]; if (dev && dev->enabled) { pci_write_config32(dev, reg, value); } } } static u32 amdk8_nodeid(device_t dev) { return (dev->path.pci.devfn >> 3) - 0x18; } static u32 amdk8_scan_chain(device_t dev, u32 nodeid, struct bus *link, u32 link_num, u32 sblink, u32 max, u32 offset_unitid) { u32 link_type; int i; u32 busses, config_busses; u32 free_reg, config_reg; u32 ht_unitid_base[4]; // here assume only 4 HT device on chain u32 max_bus; u32 min_bus; u32 max_devfn; link->cap = 0x80 + (link_num *0x20); do { link_type = pci_read_config32(dev, link->cap + 0x18); } while(link_type & ConnectionPending); if (!(link_type & LinkConnected)) { return max; } do { link_type = pci_read_config32(dev, link->cap + 0x18); } while(!(link_type & InitComplete)); if (!(link_type & NonCoherent)) { return max; } /* See if there is an available configuration space mapping * register in function 1. */ free_reg = 0; for(config_reg = 0xe0; config_reg <= 0xec; config_reg += 4) { u32 config; config = f1_read_config32(config_reg); if (!free_reg && ((config & 3) == 0)) { free_reg = config_reg; continue; } if (((config & 3) == 3) && (((config >> 4) & 7) == nodeid) && (((config >> 8) & 3) == link_num)) { break; } } if (free_reg && (config_reg > 0xec)) { config_reg = free_reg; } /* If we can't find an available configuration space mapping * register skip this bus */ if (config_reg > 0xec) { return max; } /* Set up the primary, secondary and subordinate bus numbers. * We have no idea how many busses are behind this bridge yet, * so we set the subordinate bus number to 0xff for the moment. */ #if CONFIG_SB_HT_CHAIN_ON_BUS0 > 0 // first chain will on bus 0 if((nodeid == 0) && (sblink==link_num)) { // actually max is 0 here min_bus = max; } #if CONFIG_SB_HT_CHAIN_ON_BUS0 > 1 // second chain will be on 0x40, third 0x80, forth 0xc0 else { min_bus = ((max>>6) + 1) * 0x40; } max = min_bus; #else //other ... else { min_bus = ++max; } #endif #else min_bus = ++max; #endif max_bus = 0xff; link->secondary = min_bus; link->subordinate = max_bus; /* Read the existing primary/secondary/subordinate bus * number configuration. */ busses = pci_read_config32(dev, link->cap + 0x14); config_busses = f1_read_config32(config_reg); /* Configure the bus numbers for this bridge: the configuration * transactions will not be propagates by the bridge if it is * not correctly configured */ busses &= 0xff000000; busses |= (((unsigned int)(dev->bus->secondary) << 0) | ((unsigned int)(link->secondary) << 8) | ((unsigned int)(link->subordinate) << 16)); pci_write_config32(dev, link->cap + 0x14, busses); config_busses &= 0x000fc88; config_busses |= (3 << 0) | /* rw enable, no device compare */ (( nodeid & 7) << 4) | (( link_num & 3 ) << 8) | ((link->secondary) << 16) | ((link->subordinate) << 24); f1_write_config32(config_reg, config_busses); /* Now we can scan all of the subordinate busses i.e. the * chain on the hypertranport link */ for(i=0;i<4;i++) { ht_unitid_base[i] = 0x20; } if (min_bus == 0) max_devfn = (0x17<<3) | 7; else max_devfn = (0x1f<<3) | 7; max = hypertransport_scan_chain(link, 0, max_devfn, max, ht_unitid_base, offset_unitid); /* We know the number of busses behind this bridge. Set the * subordinate bus number to it's real value */ link->subordinate = max; busses = (busses & 0xff00ffff) | ((unsigned int) (link->subordinate) << 16); pci_write_config32(dev, link->cap + 0x14, busses); config_busses = (config_busses & 0x00ffffff) | (link->subordinate << 24); f1_write_config32(config_reg, config_busses); { // use config_reg and ht_unitid_base to update hcdn_reg int index; u32 temp = 0; index = (config_reg-0xe0) >> 2; for(i=0;i<4;i++) { temp |= (ht_unitid_base[i] & 0xff) << (i*8); } sysconf.hcdn_reg[index] = temp; } return max; } static unsigned amdk8_scan_chains(device_t dev, unsigned max) { unsigned nodeid; struct bus *link; unsigned sblink = 0; unsigned offset_unitid = 0; nodeid = amdk8_nodeid(dev); if(nodeid==0) { sblink = (pci_read_config32(dev, 0x64)>>8) & 3; #if CONFIG_SB_HT_CHAIN_ON_BUS0 > 0 #if ((CONFIG_HT_CHAIN_UNITID_BASE != 1) || (CONFIG_HT_CHAIN_END_UNITID_BASE != 0x20)) offset_unitid = 1; #endif for (link = dev->link_list; link; link = link->next) if (link->link_num == sblink) max = amdk8_scan_chain(dev, nodeid, link, sblink, sblink, max, offset_unitid ); // do sb ht chain at first, in case s2885 put sb chain (8131/8111) on link2, but put 8151 on link0 #endif } for (link = dev->link_list; link; link = link->next) { #if CONFIG_SB_HT_CHAIN_ON_BUS0 > 0 if( (nodeid == 0) && (sblink == link->link_num) ) continue; //already done #endif offset_unitid = 0; #if ((CONFIG_HT_CHAIN_UNITID_BASE != 1) || (CONFIG_HT_CHAIN_END_UNITID_BASE != 0x20)) #if CONFIG_SB_HT_CHAIN_UNITID_OFFSET_ONLY if((nodeid == 0) && (sblink == link->link_num)) #endif offset_unitid = 1; #endif max = amdk8_scan_chain(dev, nodeid, link, link->link_num, sblink, max, offset_unitid); } return max; } static int reg_useable(unsigned reg, device_t goal_dev, unsigned goal_nodeid, unsigned goal_link) { struct resource *res; unsigned nodeid, link = 0; int result; res = 0; for(nodeid = 0; !res && (nodeid < fx_devs); nodeid++) { device_t dev; dev = __f0_dev[nodeid]; if (!dev) continue; for(link = 0; !res && (link < 3); link++) { res = probe_resource(dev, IOINDEX(0x100 + reg, link)); } } result = 2; if (res) { result = 0; if ( (goal_link == (link - 1)) && (goal_nodeid == (nodeid - 1)) && (res->flags <= 1)) { result = 1; } } return result; } static unsigned amdk8_find_reg(device_t dev, unsigned nodeid, unsigned link, unsigned min, unsigned max) { unsigned resource; unsigned free_reg, reg; resource = 0; free_reg = 0; for(reg = min; reg <= max; reg += 0x8) { int result; result = reg_useable(reg, dev, nodeid, link); if (result == 1) { /* I have been allocated this one */ break; } else if (result > 1) { /* I have a free register pair */ free_reg = reg; } } if (reg > max) { reg = free_reg; } if (reg > 0) { resource = IOINDEX(0x100 + reg, link); } return resource; } static unsigned amdk8_find_iopair(device_t dev, unsigned nodeid, unsigned link) { return amdk8_find_reg(dev, nodeid, link, 0xc0, 0xd8); } static unsigned amdk8_find_mempair(device_t dev, unsigned nodeid, unsigned link) { return amdk8_find_reg(dev, nodeid, link, 0x80, 0xb8); } static void amdk8_link_read_bases(device_t dev, unsigned nodeid, unsigned link) { struct resource *resource; /* Initialize the io space constraints on the current bus */ resource = new_resource(dev, IOINDEX(0, link)); if (resource) { resource->base = 0; resource->size = 0; resource->align = log2(HT_IO_HOST_ALIGN); resource->gran = log2(HT_IO_HOST_ALIGN); resource->limit = 0xffffUL; resource->flags = IORESOURCE_IO | IORESOURCE_BRIDGE; } /* Initialize the prefetchable memory constraints on the current bus */ resource = new_resource(dev, IOINDEX(2, link)); if (resource) { resource->base = 0; resource->size = 0; resource->align = log2(HT_MEM_HOST_ALIGN); resource->gran = log2(HT_MEM_HOST_ALIGN); resource->limit = 0xffffffffffULL; resource->flags = IORESOURCE_MEM | IORESOURCE_PREFETCH; resource->flags |= IORESOURCE_BRIDGE; } /* Initialize the memory constraints on the current bus */ resource = new_resource(dev, IOINDEX(1, link)); if (resource) { resource->base = 0; resource->size = 0; resource->align = log2(HT_MEM_HOST_ALIGN); resource->gran = log2(HT_MEM_HOST_ALIGN); resource->limit = 0xffffffffULL; resource->flags = IORESOURCE_MEM | IORESOURCE_BRIDGE; } } static void amdk8_create_vga_resource(device_t dev, unsigned nodeid); static void amdk8_read_resources(device_t dev) { unsigned nodeid; struct bus *link; nodeid = amdk8_nodeid(dev); for(link = dev->link_list; link; link = link->next) { if (link->children) { amdk8_link_read_bases(dev, nodeid, link->link_num); } } amdk8_create_vga_resource(dev, nodeid); } static void amdk8_set_resource(device_t dev, struct resource *resource, unsigned nodeid) { struct bus *link; resource_t rbase, rend; unsigned reg, link_num; char buf[50]; /* Make certain the resource has actually been set */ if (!(resource->flags & IORESOURCE_ASSIGNED)) { printk(BIOS_ERR, "%s: can't set unassigned resource @%lx %lx\n", __func__, resource->index, resource->flags); return; } /* If I have already stored this resource don't worry about it */ if (resource->flags & IORESOURCE_STORED) { printk(BIOS_ERR, "%s: can't set stored resource @%lx %lx\n", __func__, resource->index, resource->flags); return; } /* Only handle PCI memory and IO resources */ if (!(resource->flags & (IORESOURCE_MEM | IORESOURCE_IO))) return; /* Ensure I am actually looking at a resource of function 1 */ if (resource->index < 0x100) { return; } if (resource->size == 0) return; /* Get the base address */ rbase = resource->base; /* Get the limit (rounded up) */ rend = resource_end(resource); /* Get the register and link */ reg = resource->index & 0xfc; link_num = IOINDEX_LINK(resource->index); for (link = dev->link_list; link; link = link->next) if (link->link_num == link_num) break; if (link == NULL) { printk(BIOS_ERR, "%s: can't find link %x for %lx\n", __func__, link_num, resource->index); return; } if (resource->flags & IORESOURCE_IO) { u32 base, limit; base = f1_read_config32(reg); limit = f1_read_config32(reg + 0x4); base &= 0xfe000fcc; base |= rbase & 0x01fff000; base |= 3; limit &= 0xfe000fc8; limit |= rend & 0x01fff000; limit |= (link_num & 3) << 4; limit |= (nodeid & 7); if (link->bridge_ctrl & PCI_BRIDGE_CTL_VGA) { printk(BIOS_SPEW, "%s, enabling legacy VGA IO forwarding for %s link 0x%x\n", __func__, dev_path(dev), link_num); base |= PCI_IO_BASE_VGA_EN; } if (link->bridge_ctrl & PCI_BRIDGE_CTL_NO_ISA) { base |= PCI_IO_BASE_NO_ISA; } f1_write_config32(reg + 0x4, limit); f1_write_config32(reg, base); } else if (resource->flags & IORESOURCE_MEM) { u32 base, limit; base = f1_read_config32(reg); limit = f1_read_config32(reg + 0x4); base &= 0x000000f0; base |= (rbase >> 8) & 0xffffff00; base |= 3; limit &= 0x00000048; limit |= (rend >> 8) & 0xffffff00; limit |= (link_num & 3) << 4; limit |= (nodeid & 7); f1_write_config32(reg + 0x4, limit); f1_write_config32(reg, base); } resource->flags |= IORESOURCE_STORED; sprintf(buf, " ", nodeid, link_num); report_resource_stored(dev, resource, buf); } static void amdk8_create_vga_resource(device_t dev, unsigned nodeid) { struct resource *resource; struct bus *link; /* find out which link the VGA card is connected, * we only deal with the 'first' vga card */ for (link = dev->link_list; link; link = link->next) { if (link->bridge_ctrl & PCI_BRIDGE_CTL_VGA) { #if CONFIG_MULTIPLE_VGA_ADAPTERS extern device_t vga_pri; // the primary vga device, defined in device.c printk(BIOS_DEBUG, "VGA: vga_pri bus num = %d link bus range [%d,%d]\n", vga_pri->bus->secondary, link->secondary,link->subordinate); /* We need to make sure the vga_pri is under the link */ if((vga_pri->bus->secondary >= link->secondary ) && (vga_pri->bus->secondary <= link->subordinate ) ) #endif break; } } /* no VGA card installed */ if (link == NULL) return; printk(BIOS_DEBUG, "VGA: %s (aka node %d) link %d has VGA device\n", dev_path(dev), nodeid, link->link_num); /* allocate a temp resource for the legacy VGA buffer */ resource = new_resource(dev, IOINDEX(4, link->link_num)); if(!resource){ printk(BIOS_DEBUG, "VGA: %s out of resources.\n", dev_path(dev)); return; } resource->base = 0xa0000; resource->size = 0x20000; resource->limit = 0xffffffff; resource->flags = IORESOURCE_FIXED | IORESOURCE_MEM | IORESOURCE_ASSIGNED; } static void amdk8_set_resources(device_t dev) { unsigned nodeid; struct bus *bus; struct resource *res; /* Find the nodeid */ nodeid = amdk8_nodeid(dev); /* Set each resource we have found */ for(res = dev->resource_list; res; res = res->next) { struct resource *old = NULL; unsigned index; if (res->size == 0) /* No need to allocate registers. */ continue; if (res->flags & IORESOURCE_IO) index = amdk8_find_iopair(dev, nodeid, IOINDEX_LINK(res->index)); else index = amdk8_find_mempair(dev, nodeid, IOINDEX_LINK(res->index)); old = probe_resource(dev, index); if (old) { res->index = old->index; old->index = 0; old->flags = 0; } else res->index = index; amdk8_set_resource(dev, res, nodeid); } compact_resources(dev); for(bus = dev->link_list; bus; bus = bus->next) { if (bus->children) { assign_resources(bus); } } } static void mcf0_control_init(struct device *dev) { #if 0 printk(BIOS_DEBUG, "NB: Function 0 Misc Control.. "); #endif #if 0 printk(BIOS_DEBUG, "done.\n"); #endif } static struct device_operations northbridge_operations = { .read_resources = amdk8_read_resources, .set_resources = amdk8_set_resources, .enable_resources = pci_dev_enable_resources, .init = mcf0_control_init, .scan_bus = amdk8_scan_chains, .enable = 0, .ops_pci = 0, }; static const struct pci_driver mcf0_driver __pci_driver = { .ops = &northbridge_operations, .vendor = PCI_VENDOR_ID_AMD, .device = 0x1100, }; struct chip_operations northbridge_amd_amdk8_ops = { CHIP_NAME("AMD K8 Northbridge") .enable_dev = 0, }; static void amdk8_domain_read_resources(device_t dev) { unsigned reg; /* Find the already assigned resource pairs */ get_fx_devs(); for(reg = 0x80; reg <= 0xd8; reg+= 0x08) { u32 base, limit; base = f1_read_config32(reg); limit = f1_read_config32(reg + 0x04); /* Is this register allocated? */ if ((base & 3) != 0) { unsigned nodeid, reg_link; device_t reg_dev; nodeid = limit & 7; reg_link = (limit >> 4) & 3; reg_dev = __f0_dev[nodeid]; if (reg_dev) { /* Reserve the resource */ struct resource *res; res = new_resource(reg_dev, IOINDEX(0x100 + reg, reg_link)); if (res) { res->base = base; res->limit = limit; res->flags = 1; } } } } pci_domain_read_resources(dev); #if CONFIG_PCI_64BIT_PREF_MEM /* Initialize the system wide prefetchable memory resources constraints */ resource = new_resource(dev, 2); resource->limit = 0xfcffffffffULL; resource->flags = IORESOURCE_MEM | IORESOURCE_PREFETCH; #endif } static void my_tolm_test(void *gp, struct device *dev, struct resource *new) { struct resource **best_p = gp; struct resource *best; best = *best_p; /* Skip VGA. */ if (!best || (best->base > new->base && new->base > 0xa0000)) { best = new; } *best_p = best; } static u32 my_find_pci_tolm(struct bus *bus) { struct resource *min; u32 tolm; min = 0; search_bus_resources(bus, IORESOURCE_MEM, IORESOURCE_MEM, my_tolm_test, &min); tolm = 0xffffffffUL; if (min && tolm > min->base) { tolm = min->base; } return tolm; } #if CONFIG_HW_MEM_HOLE_SIZEK != 0 struct hw_mem_hole_info { unsigned hole_startk; int node_id; }; static struct hw_mem_hole_info get_hw_mem_hole_info(void) { struct hw_mem_hole_info mem_hole; int i; mem_hole.hole_startk = CONFIG_HW_MEM_HOLE_SIZEK; mem_hole.node_id = -1; for (i = 0; i < fx_devs; i++) { u32 base; u32 hole; base = f1_read_config32(0x40 + (i << 3)); if ((base & ((1<<1)|(1<<0))) != ((1<<1)|(1<<0))) { continue; } hole = pci_read_config32(__f1_dev[i], 0xf0); if(hole & 1) { // we find the hole mem_hole.hole_startk = (hole & (0xff<<24)) >> 10; mem_hole.node_id = i; // record the node No with hole break; // only one hole } } //We need to double check if there is speical set on base reg and limit reg are not continous instead of hole, it will find out it's hole_startk if(mem_hole.node_id==-1) { u32 limitk_pri = 0; for(i=0; i<8; i++) { u32 base, limit; unsigned base_k, limit_k; base = f1_read_config32(0x40 + (i << 3)); if ((base & ((1<<1)|(1<<0))) != ((1<<1)|(1<<0))) { continue; } base_k = (base & 0xffff0000) >> 2; if(limitk_pri != base_k) { // we find the hole mem_hole.hole_startk = limitk_pri; mem_hole.node_id = i; break; //only one hole } limit = f1_read_config32(0x44 + (i << 3)); limit_k = ((limit + 0x00010000) & 0xffff0000) >> 2; limitk_pri = limit_k; } } return mem_hole; } static void disable_hoist_memory(unsigned long hole_startk, int node_id) { int i; device_t dev; u32 base, limit; u32 hoist; u32 hole_sizek; //1. find which node has hole //2. change limit in that node. //3. change base and limit in later node //4. clear that node f0 //if there is not mem hole enabled, we need to change it's base instead hole_sizek = (4*1024*1024) - hole_startk; for(i=7;i>node_id;i--) { base = f1_read_config32(0x40 + (i << 3)); if ((base & ((1<<1)|(1<<0))) != ((1<<1)|(1<<0))) { continue; } limit = f1_read_config32(0x44 + (i << 3)); f1_write_config32(0x44 + (i << 3),limit - (hole_sizek << 2)); f1_write_config32(0x40 + (i << 3),base - (hole_sizek << 2)); } limit = f1_read_config32(0x44 + (node_id << 3)); f1_write_config32(0x44 + (node_id << 3),limit - (hole_sizek << 2)); dev = __f1_dev[node_id]; if (dev == NULL) { printk(BIOS_ERR, "%s: node %x is NULL!\n", __func__, node_id); return; } hoist = pci_read_config32(dev, 0xf0); if(hoist & 1) { pci_write_config32(dev, 0xf0, 0); } else { base = pci_read_config32(dev, 0x40 + (node_id << 3)); f1_write_config32(0x40 + (node_id << 3),base - (hole_sizek << 2)); } } static u32 hoist_memory(unsigned long hole_startk, int node_id) { int i; u32 carry_over; device_t dev; u32 base, limit; u32 basek; u32 hoist; carry_over = (4*1024*1024) - hole_startk; for(i=7;i>node_id;i--) { base = f1_read_config32(0x40 + (i << 3)); if ((base & ((1<<1)|(1<<0))) != ((1<<1)|(1<<0))) { continue; } limit = f1_read_config32(0x44 + (i << 3)); f1_write_config32(0x44 + (i << 3),limit + (carry_over << 2)); f1_write_config32(0x40 + (i << 3),base + (carry_over << 2)); } limit = f1_read_config32(0x44 + (node_id << 3)); f1_write_config32(0x44 + (node_id << 3),limit + (carry_over << 2)); dev = __f1_dev[node_id]; base = pci_read_config32(dev, 0x40 + (node_id << 3)); basek = (base & 0xffff0000) >> 2; if(basek == hole_startk) { //don't need set memhole here, because hole off set will be 0, overflow //so need to change base reg instead, new basek will be 4*1024*1024 base &= 0x0000ffff; base |= (4*1024*1024)<<2; f1_write_config32(0x40 + (node_id<<3), base); } else if (dev) { hoist = /* hole start address */ ((hole_startk << 10) & 0xff000000) + /* hole address to memory controller address */ (((basek + carry_over) >> 6) & 0x0000ff00) + /* enable */ 1; pci_write_config32(dev, 0xf0, hoist); } return carry_over; } #endif #if CONFIG_WRITE_HIGH_TABLES #include #endif static void setup_uma_memory(void) { #if CONFIG_GFXUMA uint32_t topmem = (uint32_t) bsp_topmem(); #if !CONFIG_BOARD_ASROCK_939A785GMH && !CONFIG_BOARD_AMD_MAHOGANY switch (topmem) { case 0x10000000: /* 256M system memory */ uma_memory_size = 0x2000000; /* 32M recommended UMA */ break; case 0x18000000: /* 384M system memory */ uma_memory_size = 0x4000000; /* 64M recommended UMA */ break; case 0x20000000: /* 512M system memory */ uma_memory_size = 0x4000000; /* 64M recommended UMA */ break; default: /* 1GB and above system memory */ uma_memory_size = 0x8000000; /* 128M recommended UMA */ break; } #else /* refer to UMA Size Consideration in 780 BDG. */ switch (topmem) { case 0x10000000: /* 256M system memory */ uma_memory_size = 0x4000000; /* 64M recommended UMA */ break; case 0x20000000: /* 512M system memory */ uma_memory_size = 0x8000000; /* 128M recommended UMA */ break; default: /* 1GB and above system memory */ uma_memory_size = 0x10000000; /* 256M recommended UMA */ break; } #endif uma_memory_base = topmem - uma_memory_size; /* TOP_MEM1 */ printk(BIOS_INFO, "%s: uma size 0x%08llx, memory start 0x%08llx\n", __func__, uma_memory_size, uma_memory_base); #endif } static void amdk8_domain_set_resources(device_t dev) { #if CONFIG_PCI_64BIT_PREF_MEM struct resource *io, *mem1, *mem2; struct resource *res; #endif unsigned long mmio_basek; u32 pci_tolm; int i, idx; #if CONFIG_HW_MEM_HOLE_SIZEK != 0 struct hw_mem_hole_info mem_hole; u32 reset_memhole = 1; #endif setup_bsp_ramtop(); setup_uma_memory(); #if 0 /* Place the IO devices somewhere safe */ io = find_resource(dev, 0); io->base = DEVICE_IO_START; #endif #if CONFIG_PCI_64BIT_PREF_MEM /* Now reallocate the pci resources memory with the * highest addresses I can manage. */ mem1 = find_resource(dev, 1); mem2 = find_resource(dev, 2); #if 1 printk(BIOS_DEBUG, "base1: 0x%08Lx limit1: 0x%08Lx size: 0x%08Lx align: %d\n", mem1->base, mem1->limit, mem1->size, mem1->align); printk(BIOS_DEBUG, "base2: 0x%08Lx limit2: 0x%08Lx size: 0x%08Lx align: %d\n", mem2->base, mem2->limit, mem2->size, mem2->align); #endif /* See if both resources have roughly the same limits */ if (((mem1->limit <= 0xffffffff) && (mem2->limit <= 0xffffffff)) || ((mem1->limit > 0xffffffff) && (mem2->limit > 0xffffffff))) { /* If so place the one with the most stringent alignment first */ if (mem2->align > mem1->align) { struct resource *tmp; tmp = mem1; mem1 = mem2; mem2 = tmp; } /* Now place the memory as high up as it will go */ mem2->base = resource_max(mem2); mem1->limit = mem2->base - 1; mem1->base = resource_max(mem1); } else { /* Place the resources as high up as they will go */ mem2->base = resource_max(mem2); mem1->base = resource_max(mem1); } #if 1 printk(BIOS_DEBUG, "base1: 0x%08Lx limit1: 0x%08Lx size: 0x%08Lx align: %d\n", mem1->base, mem1->limit, mem1->size, mem1->align); printk(BIOS_DEBUG, "base2: 0x%08Lx limit2: 0x%08Lx size: 0x%08Lx align: %d\n", mem2->base, mem2->limit, mem2->size, mem2->align); #endif for(res = dev->resource_list; res; res = res->next) { res->flags |= IORESOURCE_ASSIGNED; res->flags |= IORESOURCE_STORED; report_resource_stored(dev, res, ""); } #endif pci_tolm = my_find_pci_tolm(dev->link_list); // FIXME handle interleaved nodes. If you fix this here, please fix // amdfam10, too. mmio_basek = pci_tolm >> 10; /* Round mmio_basek to something the processor can support */ mmio_basek &= ~((1 << 6) -1); // FIXME improve mtrr.c so we don't use up all of the mtrrs with a 64M // MMIO hole. If you fix this here, please fix amdfam10, too. /* Round the mmio hole to 64M */ mmio_basek &= ~((64*1024) - 1); #if CONFIG_HW_MEM_HOLE_SIZEK != 0 /* if the hw mem hole is already set in raminit stage, here we will compare mmio_basek and hole_basek * if mmio_basek is bigger that hole_basek and will use hole_basek as mmio_basek and we don't need to reset hole. * otherwise We reset the hole to the mmio_basek */ #if !CONFIG_K8_REV_F_SUPPORT if (!is_cpu_pre_e0()) { #endif mem_hole = get_hw_mem_hole_info(); if ((mem_hole.node_id != -1) && (mmio_basek > mem_hole.hole_startk)) { //We will use hole_basek as mmio_basek, and we don't need to reset hole anymore mmio_basek = mem_hole.hole_startk; reset_memhole = 0; } //mmio_basek = 3*1024*1024; // for debug to meet boundary if(reset_memhole) { if(mem_hole.node_id!=-1) { // We need to select CONFIG_HW_MEM_HOLE_SIZEK for raminit, it can not make hole_startk to some basek too....! // We need to reset our Mem Hole, because We want more big HOLE than we already set //Before that We need to disable mem hole at first, becase memhole could already be set on i+1 instead disable_hoist_memory(mem_hole.hole_startk, mem_hole.node_id); } #if CONFIG_HW_MEM_HOLE_SIZE_AUTO_INC //We need to double check if the mmio_basek is valid for hole setting, if it is equal to basek, we need to decrease it some u32 basek_pri; for (i = 0; i < fx_devs; i++) { u32 base; u32 basek; base = f1_read_config32(0x40 + (i << 3)); if ((base & ((1<<1)|(1<<0))) != ((1<<1)|(1<<0))) { continue; } basek = (base & 0xffff0000) >> 2; if(mmio_basek == basek) { mmio_basek -= (basek - basek_pri)>>1; // increase mem hole size to make sure it is on middle of pri node break; } basek_pri = basek; } #endif } #if !CONFIG_K8_REV_F_SUPPORT } // is_cpu_pre_e0 #endif #endif idx = 0x10; for(i = 0; i < fx_devs; i++) { u32 base, limit; u32 basek, limitk, sizek; base = f1_read_config32(0x40 + (i << 3)); limit = f1_read_config32(0x44 + (i << 3)); if ((base & ((1<<1)|(1<<0))) != ((1<<1)|(1<<0))) { continue; } basek = (base & 0xffff0000) >> 2; limitk = ((limit + 0x00010000) & 0xffff0000) >> 2; sizek = limitk - basek; /* see if we need a hole from 0xa0000 to 0xbffff */ if ((basek < ((8*64)+(8*16))) && (sizek > ((8*64)+(16*16)))) { ram_resource(dev, (idx | i), basek, ((8*64)+(8*16)) - basek); idx += 0x10; basek = (8*64)+(16*16); sizek = limitk - ((8*64)+(16*16)); } #if CONFIG_GFXUMA printk(BIOS_DEBUG, "node %d : uma_memory_base/1024=0x%08llx, mmio_basek=0x%08lx, basek=0x%08x, limitk=0x%08x\n", i, uma_memory_base >> 10, mmio_basek, basek, limitk); if ((uma_memory_base >> 10) < mmio_basek) printk(BIOS_ALERT, "node %d: UMA memory starts below mmio_basek\n", i); #else // printk(BIOS_DEBUG, "node %d : mmio_basek=%08x, basek=%08x, limitk=%08x\n", i, mmio_basek, basek, limitk); //yhlu #endif /* See if I need to split the region to accomodate pci memory space */ if ( (basek < 4*1024*1024 ) && (limitk > mmio_basek) ) { if (basek <= mmio_basek) { unsigned pre_sizek; pre_sizek = mmio_basek - basek; if(pre_sizek>0) { ram_resource(dev, (idx | i), basek, pre_sizek); idx += 0x10; sizek -= pre_sizek; #if CONFIG_WRITE_HIGH_TABLES if (high_tables_base==0) { /* Leave some space for ACPI, PIRQ and MP tables */ #if CONFIG_GFXUMA high_tables_base = uma_memory_base - HIGH_MEMORY_SIZE; #else high_tables_base = (mmio_basek * 1024) - HIGH_MEMORY_SIZE; #endif high_tables_size = HIGH_MEMORY_SIZE; printk(BIOS_DEBUG, " split: %dK table at =%08llx\n", HIGH_MEMORY_SIZE / 1024, high_tables_base); } #endif } #if CONFIG_HW_MEM_HOLE_SIZEK != 0 if(reset_memhole) #if !CONFIG_K8_REV_F_SUPPORT if(!is_cpu_pre_e0() ) #endif sizek += hoist_memory(mmio_basek,i); #endif basek = mmio_basek; } if ((basek + sizek) <= 4*1024*1024) { sizek = 0; } else { basek = 4*1024*1024; sizek -= (4*1024*1024 - mmio_basek); } } ram_resource(dev, (idx | i), basek, sizek); idx += 0x10; #if CONFIG_WRITE_HIGH_TABLES printk(BIOS_DEBUG, "%d: mmio_basek=%08lx, basek=%08x, limitk=%08x\n", i, mmio_basek, basek, limitk); if (high_tables_base==0) { /* Leave some space for ACPI, PIRQ and MP tables */ #if CONFIG_GFXUMA high_tables_base = uma_memory_base - HIGH_MEMORY_SIZE; #else high_tables_base = (limitk * 1024) - HIGH_MEMORY_SIZE; #endif high_tables_size = HIGH_MEMORY_SIZE; } #endif } #if CONFIG_GFXUMA uma_resource(dev, 7, uma_memory_base >> 10, uma_memory_size >> 10); #endif assign_resources(dev->link_list); } static u32 amdk8_domain_scan_bus(device_t dev, u32 max) { u32 reg; int i; /* Unmap all of the HT chains */ for(reg = 0xe0; reg <= 0xec; reg += 4) { f1_write_config32(reg, 0); } max = pci_scan_bus(dev->link_list, PCI_DEVFN(0x18, 0), 0xff, max); /* Tune the hypertransport transaction for best performance. * Including enabling relaxed ordering if it is safe. */ get_fx_devs(); for(i = 0; i < fx_devs; i++) { device_t f0_dev; f0_dev = __f0_dev[i]; if (f0_dev && f0_dev->enabled) { u32 httc; httc = pci_read_config32(f0_dev, HT_TRANSACTION_CONTROL); httc &= ~HTTC_RSP_PASS_PW; if (!dev->link_list->disable_relaxed_ordering) { httc |= HTTC_RSP_PASS_PW; } printk(BIOS_SPEW, "%s passpw: %s\n", dev_path(dev), (!dev->link_list->disable_relaxed_ordering)? "enabled":"disabled"); pci_write_config32(f0_dev, HT_TRANSACTION_CONTROL, httc); } } return max; } static struct device_operations pci_domain_ops = { .read_resources = amdk8_domain_read_resources, .set_resources = amdk8_domain_set_resources, .enable_resources = NULL, .init = NULL, .scan_bus = amdk8_domain_scan_bus, .ops_pci_bus = &pci_cf8_conf1, }; static void add_more_links(device_t dev, unsigned total_links) { struct bus *link, *last = NULL; int link_num; for (link = dev->link_list; link; link = link->next) last = link; if (last) { int links = total_links - last->link_num; link_num = last->link_num; if (links > 0) { link = malloc(links*sizeof(*link)); if (!link) die("Couldn't allocate more links!\n"); memset(link, 0, links*sizeof(*link)); last->next = link; } } else { link_num = -1; link = malloc(total_links*sizeof(*link)); memset(link, 0, total_links*sizeof(*link)); dev->link_list = link; } for (link_num = link_num + 1; link_num < total_links; link_num++) { link->link_num = link_num; link->dev = dev; link->next = link + 1; last = link; link = link->next; } last->next = NULL; } static u32 cpu_bus_scan(device_t dev, u32 max) { struct bus *cpu_bus; device_t dev_mc; int bsp_apicid; int i,j; unsigned nb_cfg_54; unsigned siblings; int e0_later_single_core; int disable_siblings; nb_cfg_54 = 0; sysconf.enabled_apic_ext_id = 0; sysconf.lift_bsp_apicid = 0; siblings = 0; /* Find the bootstrap processors apicid */ bsp_apicid = lapicid(); sysconf.apicid_offset = bsp_apicid; disable_siblings = !CONFIG_LOGICAL_CPUS; #if CONFIG_LOGICAL_CPUS get_option(&disable_siblings, "multi_core"); #endif // for pre_e0, nb_cfg_54 can not be set, (when you read it still is 0) // How can I get the nb_cfg_54 of every node's nb_cfg_54 in bsp??? // and differ d0 and e0 single core nb_cfg_54 = read_nb_cfg_54(); dev_mc = dev_find_slot(0, PCI_DEVFN(0x18, 0)); if (!dev_mc) { die("0:18.0 not found?"); } sysconf.nodes = ((pci_read_config32(dev_mc, 0x60)>>4) & 7) + 1; if (pci_read_config32(dev_mc, 0x68) & (HTTC_APIC_EXT_ID|HTTC_APIC_EXT_BRD_CST)) { sysconf.enabled_apic_ext_id = 1; if(bsp_apicid == 0) { /* bsp apic id is not changed */ sysconf.apicid_offset = CONFIG_APIC_ID_OFFSET; } else { sysconf.lift_bsp_apicid = 1; } } /* Find which cpus are present */ cpu_bus = dev->link_list; /* Always use the devicetree node with lapic_id 0 for BSP. */ remap_bsp_lapic(cpu_bus); for(i = 0; i < sysconf.nodes; i++) { device_t cpu_dev; /* Find the cpu's pci device */ cpu_dev = dev_find_slot(0, PCI_DEVFN(0x18 + i, 3)); if (!cpu_dev) { /* If I am probing things in a weird order * ensure all of the cpu's pci devices are found. */ int local_j; device_t dev_f0; for(local_j = 0; local_j <= 3; local_j++) { cpu_dev = pci_probe_dev(NULL, dev_mc->bus, PCI_DEVFN(0x18 + i, local_j)); } /* Ok, We need to set the links for that device. * otherwise the device under it will not be scanned */ dev_f0 = dev_find_slot(0, PCI_DEVFN(0x18+i,0)); if(dev_f0) { add_more_links(dev_f0, 3); } } e0_later_single_core = 0; int enable_node = cpu_dev && cpu_dev->enabled; if (enable_node) { j = pci_read_config32(cpu_dev, 0xe8); j = (j >> 12) & 3; // dev is func 3 printk(BIOS_DEBUG, " %s siblings=%d\n", dev_path(cpu_dev), j); if(nb_cfg_54) { // For e0 single core if nb_cfg_54 is set, apicid will be 0, 2, 4.... // ----> you can mixed single core e0 and dual core e0 at any sequence // That is the typical case if(j == 0 ){ #if !CONFIG_K8_REV_F_SUPPORT e0_later_single_core = is_e0_later_in_bsp(i); // single core #else e0_later_single_core = is_cpu_f0_in_bsp(i); // We can read cpuid(1) from Func3 #endif } else { e0_later_single_core = 0; } if(e0_later_single_core) { printk(BIOS_DEBUG, "\tFound Rev E or Rev F later single core\n"); j=1; } if(siblings > j ) { } else { siblings = j; } } else { siblings = j; } } u32 jj; if(e0_later_single_core || disable_siblings) { jj = 0; } else { jj = siblings; } for (j = 0; j <=jj; j++ ) { u32 apic_id = i * (nb_cfg_54?(siblings+1):1) + j * (nb_cfg_54?1:8); if(sysconf.enabled_apic_ext_id) { if (apic_id != 0 || sysconf.lift_bsp_apicid) { apic_id += sysconf.apicid_offset; } } device_t cpu = add_cpu_device(cpu_bus, apic_id, enable_node); if (cpu) amd_cpu_topology(cpu, i, j); } //j } return max; } static void cpu_bus_init(device_t dev) { #if CONFIG_WAIT_BEFORE_CPUS_INIT cpus_ready_for_init(); #endif initialize_cpus(dev->link_list); } static void cpu_bus_noop(device_t dev) { } static struct device_operations cpu_bus_ops = { .read_resources = cpu_bus_noop, .set_resources = cpu_bus_noop, .enable_resources = cpu_bus_noop, .init = cpu_bus_init, .scan_bus = cpu_bus_scan, }; static void root_complex_enable_dev(struct device *dev) { /* Set the operations if it is a special bus type */ if (dev->path.type == DEVICE_PATH_PCI_DOMAIN) { dev->ops = &pci_domain_ops; } else if (dev->path.type == DEVICE_PATH_APIC_CLUSTER) { dev->ops = &cpu_bus_ops; } } struct chip_operations northbridge_amd_amdk8_root_complex_ops = { CHIP_NAME("AMD K8 Root Complex") .enable_dev = root_complex_enable_dev, };