/* * Setup routines for AGP 3.5 compliant bridges. */ #include #include #include #include #include #include "agp.h" /* Generic AGP 3.5 enabling routines */ struct agp_3_5_dev { struct list_head list; u8 capndx; u32 maxbw; struct pci_dev *dev; }; static void agp_3_5_dev_list_insert(struct list_head *head, struct list_head *new) { struct agp_3_5_dev *cur, *n = list_entry(new, struct agp_3_5_dev, list); struct list_head *pos; list_for_each(pos, head) { cur = list_entry(pos, struct agp_3_5_dev, list); if (cur->maxbw > n->maxbw) break; } list_add_tail(new, pos); } static void agp_3_5_dev_list_sort(struct agp_3_5_dev *list, unsigned int ndevs) { struct agp_3_5_dev *cur; struct pci_dev *dev; struct list_head *pos, *tmp, *head = &list->list, *start = head->next; u32 nistat; INIT_LIST_HEAD(head); for (pos=start; pos!=head; ) { cur = list_entry(pos, struct agp_3_5_dev, list); dev = cur->dev; pci_read_config_dword(dev, cur->capndx+AGPNISTAT, &nistat); cur->maxbw = (nistat >> 16) & 0xff; tmp = pos; pos = pos->next; agp_3_5_dev_list_insert(head, tmp); } } /* * Initialize all isochronous transfer parameters for an AGP 3.0 * node (i.e. a host bridge in combination with the adapters * lying behind it...) */ static int agp_3_5_isochronous_node_enable(struct agp_bridge_data *bridge, struct agp_3_5_dev *dev_list, unsigned int ndevs) { /* * Convenience structure to make the calculations clearer * here. The field names come straight from the AGP 3.0 spec. */ struct isoch_data { u32 maxbw; u32 n; u32 y; u32 l; u32 rq; struct agp_3_5_dev *dev; }; struct pci_dev *td = bridge->dev, *dev; struct list_head *head = &dev_list->list, *pos; struct agp_3_5_dev *cur; struct isoch_data *master, target; unsigned int cdev = 0; u32 mnistat, tnistat, tstatus, mcmd; u16 tnicmd, mnicmd; u8 mcapndx; u32 tot_bw = 0, tot_n = 0, tot_rq = 0, y_max, rq_isoch, rq_async; u32 step, rem, rem_isoch, rem_async; int ret = 0; /* * We'll work with an array of isoch_data's (one for each * device in dev_list) throughout this function. */ if ((master = kmalloc(ndevs * sizeof(*master), GFP_KERNEL)) == NULL) { ret = -ENOMEM; goto get_out; } /* * Sort the device list by maxbw. We need to do this because the * spec suggests that the devices with the smallest requirements * have their resources allocated first, with all remaining resources * falling to the device with the largest requirement. * * We don't exactly do this, we divide target resources by ndevs * and split them amongst the AGP 3.0 devices. The remainder of such * division operations are dropped on the last device, sort of like * the spec mentions it should be done. * * We can't do this sort when we initially construct the dev_list * because we don't know until this function whether isochronous * transfers are enabled and consequently whether maxbw will mean * anything. */ agp_3_5_dev_list_sort(dev_list, ndevs); pci_read_config_dword(td, bridge->capndx+AGPNISTAT, &tnistat); pci_read_config_dword(td, bridge->capndx+AGPSTAT, &tstatus); /* Extract power-on defaults from the target */ target.maxbw = (tnistat >> 16) & 0xff; target.n = (tnistat >> 8) & 0xff; target.y = (tnistat >> 6) & 0x3; target.l = (tnistat >> 3) & 0x7; target.rq = (tstatus >> 24) & 0xff; y_max = target.y; /* * Extract power-on defaults for each device in dev_list. Along * the way, calculate the total isochronous bandwidth required * by these devices and the largest requested payload size. */ list_for_each(pos, head) { cur = list_entry(pos, struct agp_3_5_dev, list); dev = cur->dev; mcapndx = cur->capndx; pci_read_config_dword(dev, cur->capndx+AGPNISTAT, &mnistat); master[cdev].maxbw = (mnistat >> 16) & 0xff; master[cdev].n = (mnistat >> 8) & 0xff; master[cdev].y = (mnistat >> 6) & 0x3; master[cdev].dev = cur; tot_bw += master[cdev].maxbw; y_max = max(y_max, master[cdev].y); cdev++; } /* Check if this configuration has any chance of working */ if (tot_bw > target.maxbw) { dev_err(&td->dev, "isochronous bandwidth required " "by AGP 3.0 devices exceeds that which is supported by " "the AGP 3.0 bridge!\n"); ret = -ENODEV; goto free_and_exit; } target.y = y_max; /* * Write the calculated payload size into the target's NICMD * register. Doing this directly effects the ISOCH_N value * in the target's NISTAT register, so we need to do this now * to get an accurate value for ISOCH_N later. */ pci_read_config_word(td, bridge->capndx+AGPNICMD, &tnicmd); tnicmd &= ~(0x3 << 6); tnicmd |= target.y << 6; pci_write_config_word(td, bridge->capndx+AGPNICMD, tnicmd); /* Reread the target's ISOCH_N */ pci_read_config_dword(td, bridge->capndx+AGPNISTAT, &tnistat); target.n = (tnistat >> 8) & 0xff; /* Calculate the minimum ISOCH_N needed by each master */ for (cdev=0; cdev target.n) { dev_err(&td->dev, "number of isochronous " "transactions per period required by AGP 3.0 devices " "exceeds that which is supported by the AGP 3.0 " "bridge!\n"); ret = -ENODEV; goto free_and_exit; } /* Calculate left over ISOCH_N capability in the target. We'll give * this to the hungriest device (as per the spec) */ rem = target.n - tot_n; /* * Calculate the minimum isochronous RQ depth needed by each master. * Along the way, distribute the extra ISOCH_N capability calculated * above. */ for (cdev=0; cdev 64B, then ISOCH_Y * byte isochronous writes will be broken into 64B pieces. * This means we need to budget more RQ depth to account for * these kind of writes (each isochronous write is actually * many writes on the AGP bus). */ master[cdev].rq = master[cdev].n; if (master[cdev].y > 0x1) master[cdev].rq *= (1 << (master[cdev].y - 1)); tot_rq += master[cdev].rq; } master[ndevs-1].n += rem; /* Figure the number of isochronous and asynchronous RQ slots the * target is providing. */ rq_isoch = (target.y > 0x1) ? target.n * (1 << (target.y - 1)) : target.n; rq_async = target.rq - rq_isoch; /* Exit if the minimal RQ needs of the masters exceeds what the target * can provide. */ if (tot_rq > rq_isoch) { dev_err(&td->dev, "number of request queue slots " "required by the isochronous bandwidth requested by " "AGP 3.0 devices exceeds the number provided by the " "AGP 3.0 bridge!\n"); ret = -ENODEV; goto free_and_exit; } /* Calculate asynchronous RQ capability in the target (per master) as * well as the total number of leftover isochronous RQ slots. */ step = rq_async / ndevs; rem_async = step + (rq_async % ndevs); rem_isoch = rq_isoch - tot_rq; /* Distribute the extra RQ slots calculated above and write our * isochronous settings out to the actual devices. */ for (cdev=0; cdevdev; mcapndx = cur->capndx; master[cdev].rq += (cdev == ndevs - 1) ? (rem_async + rem_isoch) : step; pci_read_config_word(dev, cur->capndx+AGPNICMD, &mnicmd); pci_read_config_dword(dev, cur->capndx+AGPCMD, &mcmd); mnicmd &= ~(0xff << 8); mnicmd &= ~(0x3 << 6); mcmd &= ~(0xff << 24); mnicmd |= master[cdev].n << 8; mnicmd |= master[cdev].y << 6; mcmd |= master[cdev].rq << 24; pci_write_config_dword(dev, cur->capndx+AGPCMD, mcmd); pci_write_config_word(dev, cur->capndx+AGPNICMD, mnicmd); } free_and_exit: kfree(master); get_out: return ret; } /* * This function basically allocates request queue slots among the * AGP 3.0 systems in nonisochronous nodes. The algorithm is * pretty stupid, divide the total number of RQ slots provided by the * target by ndevs. Distribute this many slots to each AGP 3.0 device, * giving any left over slots to the last device in dev_list. */ static void agp_3_5_nonisochronous_node_enable(struct agp_bridge_data *bridge, struct agp_3_5_dev *dev_list, unsigned int ndevs) { struct agp_3_5_dev *cur; struct list_head *head = &dev_list->list, *pos; u32 tstatus, mcmd; u32 trq, mrq, rem; unsigned int cdev = 0; pci_read_config_dword(bridge->dev, bridge->capndx+AGPSTAT, &tstatus); trq = (tstatus >> 24) & 0xff; mrq = trq / ndevs; rem = mrq + (trq % ndevs); for (pos=head->next; cdevnext) { cur = list_entry(pos, struct agp_3_5_dev, list); pci_read_config_dword(cur->dev, cur->capndx+AGPCMD, &mcmd); mcmd &= ~(0xff << 24); mcmd |= ((cdev == ndevs - 1) ? rem : mrq) << 24; pci_write_config_dword(cur->dev, cur->capndx+AGPCMD, mcmd); } } /* * Fully configure and enable an AGP 3.0 host bridge and all the devices * lying behind it. */ int agp_3_5_enable(struct agp_bridge_data *bridge) { struct pci_dev *td = bridge->dev, *dev = NULL; u8 mcapndx; u32 isoch, arqsz; u32 tstatus, mstatus, ncapid; u32 mmajor; u16 mpstat; struct agp_3_5_dev *dev_list, *cur; struct list_head *head, *pos; unsigned int ndevs = 0; int ret = 0; /* Extract some power-on defaults from the target */ pci_read_config_dword(td, bridge->capndx+AGPSTAT, &tstatus); isoch = (tstatus >> 17) & 0x1; if (isoch == 0) /* isoch xfers not available, bail out. */ return -ENODEV; arqsz = (tstatus >> 13) & 0x7; /* * Allocate a head for our AGP 3.5 device list * (multiple AGP v3 devices are allowed behind a single bridge). */ if ((dev_list = kmalloc(sizeof(*dev_list), GFP_KERNEL)) == NULL) { ret = -ENOMEM; goto get_out; } head = &dev_list->list; INIT_LIST_HEAD(head); /* Find all AGP devices, and add them to dev_list. */ for_each_pci_dev(dev) { mcapndx = pci_find_capability(dev, PCI_CAP_ID_AGP); if (mcapndx == 0) continue; switch ((dev->class >>8) & 0xff00) { case 0x0600: /* Bridge */ /* Skip bridges. We should call this function for each one. */ continue; case 0x0001: /* Unclassified device */ /* Don't know what this is, but log it for investigation. */ if (mcapndx != 0) { dev_info(&td->dev, "wacky, found unclassified AGP device %s [%04x/%04x]\n", pci_name(dev), dev->vendor, dev->device); } continue; case 0x0300: /* Display controller */ case 0x0400: /* Multimedia controller */ if ((cur = kmalloc(sizeof(*cur), GFP_KERNEL)) == NULL) { ret = -ENOMEM; goto free_and_exit; } cur->dev = dev; pos = &cur->list; list_add(pos, head); ndevs++; continue; default: continue; } } /* * Take an initial pass through the devices lying behind our host * bridge. Make sure each one is actually an AGP 3.0 device, otherwise * exit with an error message. Along the way store the AGP 3.0 * cap_ptr for each device */ list_for_each(pos, head) { cur = list_entry(pos, struct agp_3_5_dev, list); dev = cur->dev; pci_read_config_word(dev, PCI_STATUS, &mpstat); if ((mpstat & PCI_STATUS_CAP_LIST) == 0) continue; pci_read_config_byte(dev, PCI_CAPABILITY_LIST, &mcapndx); if (mcapndx != 0) { do { pci_read_config_dword(dev, mcapndx, &ncapid); if ((ncapid & 0xff) != 2) mcapndx = (ncapid >> 8) & 0xff; } while (((ncapid & 0xff) != 2) && (mcapndx != 0)); } if (mcapndx == 0) { dev_err(&td->dev, "woah! Non-AGP device %s on " "secondary bus of AGP 3.5 bridge!\n", pci_name(dev)); ret = -ENODEV; goto free_and_exit; } mmajor = (ncapid >> AGP_MAJOR_VERSION_SHIFT) & 0xf; if (mmajor < 3) { dev_err(&td->dev, "woah! AGP 2.0 device %s on " "secondary bus of AGP 3.5 bridge operating " "with AGP 3.0 electricals!\n", pci_name(dev)); ret = -ENODEV; goto free_and_exit; } cur->capndx = mcapndx; pci_read_config_dword(dev, cur->capndx+AGPSTAT, &mstatus); if (((mstatus >> 3) & 0x1) == 0) { dev_err(&td->dev, "woah! AGP 3.x device %s not " "operating in AGP 3.x mode on secondary bus " "of AGP 3.5 bridge operating with AGP 3.0 " "electricals!\n", pci_name(dev)); ret = -ENODEV; goto free_and_exit; } } /* * Call functions to divide target resources amongst the AGP 3.0 * masters. This process is dramatically different depending on * whether isochronous transfers are supported. */ if (isoch) { ret = agp_3_5_isochronous_node_enable(bridge, dev_list, ndevs); if (ret) { dev_info(&td->dev, "something bad happened setting " "up isochronous xfers; falling back to " "non-isochronous xfer mode\n"); } else { goto free_and_exit; } } agp_3_5_nonisochronous_node_enable(bridge, dev_list, ndevs); free_and_exit: /* Be sure to free the dev_list */ for (pos=head->next; pos!=head; ) { cur = list_entry(pos, struct agp_3_5_dev, list); pos = pos->next; kfree(cur); } kfree(dev_list); get_out: return ret; }