/* * (C) Copyright IBM Corporation 2006 * All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * on the rights to use, copy, modify, merge, publish, distribute, sub * license, and/or sell copies of the Software, and to permit persons to whom * the Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL * IBM AND/OR THEIR SUPPLIERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ /** * \file common_bridge.c * Support routines used to process PCI header information for bridges. * * \author Ian Romanick */ #include "config.h" #include #include #include #include #if defined(HAVE_STRING_H) # include #elif defined(HAVE_STRINGS_H) # include #endif #if defined(HAVE_INTTYPES_H) # include #elif defined(HAVE_STDINT_H) # include #endif #include "pciaccess.h" #include "pciaccess_private.h" static int read_bridge_info( struct pci_device_private * priv ) { uint8_t buf[0x40]; pciaddr_t bytes; int err; /* Make sure the device has been probed. If not, header_type won't be * set and the rest of this function will fail. */ err = pci_device_probe(& priv->base); if (err) { return err; } switch ( priv->header_type & 0x7f ) { case 0x00: break; case 0x01: { struct pci_bridge_info *info; info = malloc(sizeof(*info)); if (info != NULL) { pci_device_cfg_read( (struct pci_device *) priv, buf + 0x18, 0x18, 0x40 - 0x18, & bytes ); info->primary_bus = buf[0x18]; info->secondary_bus = buf[0x19]; info->subordinate_bus = buf[0x1a]; info->secondary_latency_timer = buf[0x1b]; info->io_type = buf[0x1c] & 0x0f; info->io_base = (((uint32_t) (buf[0x1c] & 0x0f0)) << 8) + (((uint32_t) buf[0x30]) << 16) + (((uint32_t) buf[0x31]) << 24); info->io_limit = 0x00000fff + (((uint32_t) (buf[0x1d] & 0x0f0)) << 8) + (((uint32_t) buf[0x32]) << 16) + (((uint32_t) buf[0x33]) << 24); info->mem_type = buf[0x20] & 0x0f; info->mem_base = (((uint32_t) (buf[0x20] & 0x0f0)) << 16) + (((uint32_t) buf[0x21]) << 24); info->mem_limit = 0x0000ffff + (((uint32_t) (buf[0x22] & 0x0f0)) << 16) + (((uint32_t) buf[0x23]) << 24); info->prefetch_mem_type = buf[0x24] & 0x0f; info->prefetch_mem_base = (((uint64_t) (buf[0x24] & 0x0f0)) << 16) + (((uint64_t) buf[0x25]) << 24) + (((uint64_t) buf[0x28]) << 32) + (((uint64_t) buf[0x29]) << 40) + (((uint64_t) buf[0x2a]) << 48) + (((uint64_t) buf[0x2b]) << 56); info->prefetch_mem_limit = 0x0000ffff + (((uint64_t) (buf[0x26] & 0x0f0)) << 16) + (((uint64_t) buf[0x27]) << 24) + (((uint64_t) buf[0x2c]) << 32) + (((uint64_t) buf[0x2d]) << 40) + (((uint64_t) buf[0x2e]) << 48) + (((uint64_t) buf[0x2f]) << 56); info->bridge_control = ((uint16_t) buf[0x3e]) + (((uint16_t) buf[0x3f]) << 8); info->secondary_status = ((uint16_t) buf[0x1e]) + (((uint16_t) buf[0x1f]) << 8); } priv->bridge.pci = info; break; } case 0x02: { struct pci_pcmcia_bridge_info *info; info = malloc(sizeof(*info)); if (info != NULL) { pci_device_cfg_read( (struct pci_device *) priv, buf + 0x16, 0x16, 0x40 - 0x16, & bytes ); info->primary_bus = buf[0x18]; info->card_bus = buf[0x19]; info->subordinate_bus = buf[0x1a]; info->cardbus_latency_timer = buf[0x1b]; info->mem[0].base = (((uint32_t) buf[0x1c])) + (((uint32_t) buf[0x1d]) << 8) + (((uint32_t) buf[0x1e]) << 16) + (((uint32_t) buf[0x1f]) << 24); info->mem[0].limit = (((uint32_t) buf[0x20])) + (((uint32_t) buf[0x21]) << 8) + (((uint32_t) buf[0x22]) << 16) + (((uint32_t) buf[0x23]) << 24); info->mem[1].base = (((uint32_t) buf[0x24])) + (((uint32_t) buf[0x25]) << 8) + (((uint32_t) buf[0x26]) << 16) + (((uint32_t) buf[0x27]) << 24); info->mem[1].limit = (((uint32_t) buf[0x28])) + (((uint32_t) buf[0x29]) << 8) + (((uint32_t) buf[0x2a]) << 16) + (((uint32_t) buf[0x2b]) << 24); info->io[0].base = (((uint32_t) buf[0x2c])) + (((uint32_t) buf[0x2d]) << 8) + (((uint32_t) buf[0x2e]) << 16) + (((uint32_t) buf[0x2f]) << 24); info->io[0].limit = (((uint32_t) buf[0x30])) + (((uint32_t) buf[0x31]) << 8) + (((uint32_t) buf[0x32]) << 16) + (((uint32_t) buf[0x33]) << 24); info->io[1].base = (((uint32_t) buf[0x34])) + (((uint32_t) buf[0x35]) << 8) + (((uint32_t) buf[0x36]) << 16) + (((uint32_t) buf[0x37]) << 24); info->io[1].limit = (((uint32_t) buf[0x38])) + (((uint32_t) buf[0x39]) << 8) + (((uint32_t) buf[0x3a]) << 16) + (((uint32_t) buf[0x3b]) << 24); info->secondary_status = ((uint16_t) buf[0x16]) + (((uint16_t) buf[0x17]) << 8); info->bridge_control = ((uint16_t) buf[0x3e]) + (((uint16_t) buf[0x3f]) << 8); } priv->bridge.pcmcia = info; break; } } return 0; } /** * Get the PCI bridge information for a device * * \returns * If \c dev is a PCI-to-PCI bridge, a pointer to a \c pci_bridge_info * structure. Otherwise, \c NULL is returned. */ const struct pci_bridge_info * pci_device_get_bridge_info( struct pci_device * dev ) { struct pci_device_private * priv = (struct pci_device_private *) dev; if (priv->bridge.pci == NULL) { read_bridge_info(priv); } return (priv->header_type == 1) ? priv->bridge.pci : NULL; } /** * Get the PCMCIA bridge information for a device * * \returns * If \c dev is a PCI-to-PCMCIA bridge, a pointer to a * \c pci_pcmcia_bridge_info structure. Otherwise, \c NULL is returned. */ const struct pci_pcmcia_bridge_info * pci_device_get_pcmcia_bridge_info( struct pci_device * dev ) { struct pci_device_private * priv = (struct pci_device_private *) dev; if (priv->bridge.pcmcia == NULL) { read_bridge_info(priv); } return (priv->header_type == 2) ? priv->bridge.pcmcia : NULL; } /** * Determine the primary, secondary, and subordinate buses for a bridge * * Determines the IDs of the primary, secondary, and subordinate buses for * a specified bridge. Not all bridges directly store this information * (e.g., PCI-to-ISA bridges). For those bridges, no error is returned, but * -1 is stored in the bus IDs that don't make sense. * * For example, for a PCI-to-ISA bridge, \c primary_bus will be set to the ID * of the bus containing the device and both \c secondary_bus and * \c subordinate_bus will be set to -1. * * \return * On success, zero is returned. If \c dev is not a bridge, \c ENODEV is * returned. * * \bug * Host bridges are handled the same way as PCI-to-ISA bridges. This is * almost certainly not correct. */ int pci_device_get_bridge_buses(struct pci_device * dev, int *primary_bus, int *secondary_bus, int *subordinate_bus) { struct pci_device_private * priv = (struct pci_device_private *) dev; /* If the device isn't a bridge, return an error. */ if (((dev->device_class >> 16) & 0x0ff) != 0x06) { return ENODEV; } if (!priv->bridge.pci) { return ENODEV; } switch ((dev->device_class >> 8) & 0x0ff) { case 0x00: /* What to do for host bridges? I'm pretty sure this isn't right. */ *primary_bus = dev->bus; *secondary_bus = -1; *subordinate_bus = -1; break; case 0x01: case 0x02: case 0x03: *primary_bus = dev->bus; *secondary_bus = -1; *subordinate_bus = -1; break; case 0x04: if (priv->bridge.pci == NULL) read_bridge_info(priv); if (priv->header_type == 0x01) { *primary_bus = priv->bridge.pci->primary_bus; *secondary_bus = priv->bridge.pci->secondary_bus; *subordinate_bus = priv->bridge.pci->subordinate_bus; } else { *primary_bus = dev->bus; *secondary_bus = -1; *subordinate_bus = -1; } break; case 0x07: if (priv->bridge.pcmcia == NULL) read_bridge_info(priv); if (priv->header_type == 0x02) { *primary_bus = priv->bridge.pcmcia->primary_bus; *secondary_bus = priv->bridge.pcmcia->card_bus; *subordinate_bus = priv->bridge.pcmcia->subordinate_bus; } else { *primary_bus = dev->bus; *secondary_bus = -1; *subordinate_bus = -1; } break; } return 0; } #define PCI_CLASS_BRIDGE 0x06 #define PCI_SUBCLASS_BRIDGE_PCI 0x04 struct pci_device * pci_device_get_parent_bridge(struct pci_device *dev) { struct pci_id_match bridge_match = { PCI_MATCH_ANY, PCI_MATCH_ANY, PCI_MATCH_ANY, PCI_MATCH_ANY, (PCI_CLASS_BRIDGE << 16) | (PCI_SUBCLASS_BRIDGE_PCI << 8), 0 }; struct pci_device *bridge; struct pci_device_iterator *iter; if (dev == NULL) return NULL; iter = pci_id_match_iterator_create(& bridge_match); if (iter == NULL) return NULL; while ((bridge = pci_device_next(iter)) != NULL) { if (bridge->domain == dev->domain) { const struct pci_bridge_info *info = pci_device_get_bridge_info(bridge); if (info != NULL) { if (info->secondary_bus == dev->bus) { break; } } } } pci_iterator_destroy(iter); return bridge; }