/* ohci.c - OHCI Support. */ /* * GRUB -- GRand Unified Bootloader * Copyright (C) 2008 Free Software Foundation, Inc. * * GRUB is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * GRUB is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GRUB. If not, see . */ #include #include #include #include #include #include #include #include #include #include #include struct grub_ohci_hcca { /* Pointers to Interrupt Endpoint Descriptors. Not used by GRUB. */ grub_uint32_t inttable[32]; /* Current frame number. */ grub_uint16_t framenumber; grub_uint16_t pad; /* List of completed TDs. */ grub_uint32_t donehead; grub_uint8_t reserved[116]; } __attribute__((packed)); /* OHCI General Transfer Descriptor */ struct grub_ohci_td { /* Information used to construct the TOKEN packet. */ grub_uint32_t token; grub_uint32_t buffer; /* LittleEndian physical address */ grub_uint32_t next_td; /* LittleEndian physical address */ grub_uint32_t buffer_end; /* LittleEndian physical address */ /* next values are not for OHCI HW */ grub_uint32_t prev_td_phys; /* we need it to find previous TD * physical address in CPU endian */ grub_uint32_t link_td; /* pointer to next free/chained TD * pointer as uint32 */ grub_uint32_t tr_index; /* index of TD in transfer */ grub_uint8_t pad[4]; /* padding to 32 bytes */ } __attribute__((packed)); /* OHCI Endpoint Descriptor. */ struct grub_ohci_ed { grub_uint32_t target; grub_uint32_t td_tail; grub_uint32_t td_head; grub_uint32_t next_ed; } __attribute__((packed)); typedef volatile struct grub_ohci_td *grub_ohci_td_t; typedef volatile struct grub_ohci_ed *grub_ohci_ed_t; /* Experimental change of ED/TD allocation */ /* Little bit similar as in UHCI */ /* Implementation assumes: * 32-bits architecture - XXX: fix for 64-bits * memory allocated by grub_memalign_dma32 must be continuous * in virtual and also in physical memory */ struct grub_ohci { volatile grub_uint32_t *iobase; volatile struct grub_ohci_hcca *hcca; grub_uint32_t hcca_addr; struct grub_pci_dma_chunk *hcca_chunk; grub_ohci_ed_t ed_ctrl; /* EDs for CONTROL */ grub_uint32_t ed_ctrl_addr; struct grub_pci_dma_chunk *ed_ctrl_chunk; grub_ohci_ed_t ed_bulk; /* EDs for BULK */ grub_uint32_t ed_bulk_addr; struct grub_pci_dma_chunk *ed_bulk_chunk; grub_ohci_td_t td; /* TDs */ grub_uint32_t td_addr; struct grub_pci_dma_chunk *td_chunk; struct grub_ohci *next; grub_ohci_td_t td_free; /* Pointer to first free TD */ int bad_OHCI; }; static struct grub_ohci *ohci; typedef enum { GRUB_OHCI_REG_REVISION = 0x00, GRUB_OHCI_REG_CONTROL, GRUB_OHCI_REG_CMDSTATUS, GRUB_OHCI_REG_INTSTATUS, GRUB_OHCI_REG_INTENA, GRUB_OHCI_REG_INTDIS, GRUB_OHCI_REG_HCCA, GRUB_OHCI_REG_PERIODIC, GRUB_OHCI_REG_CONTROLHEAD, GRUB_OHCI_REG_CONTROLCURR, GRUB_OHCI_REG_BULKHEAD, GRUB_OHCI_REG_BULKCURR, GRUB_OHCI_REG_DONEHEAD, GRUB_OHCI_REG_FRAME_INTERVAL, GRUB_OHCI_REG_PERIODIC_START = 16, GRUB_OHCI_REG_RHUBA = 18, GRUB_OHCI_REG_RHUBPORT = 21, GRUB_OHCI_REG_LEGACY_CONTROL = 0x100, GRUB_OHCI_REG_LEGACY_INPUT = 0x104, GRUB_OHCI_REG_LEGACY_OUTPUT = 0x108, GRUB_OHCI_REG_LEGACY_STATUS = 0x10c } grub_ohci_reg_t; #define GRUB_OHCI_RHUB_PORT_POWER_MASK 0x300 #define GRUB_OHCI_RHUB_PORT_ALL_POWERED 0x200 #define GRUB_OHCI_REG_FRAME_INTERVAL_FSMPS_MASK 0x8fff0000 #define GRUB_OHCI_REG_FRAME_INTERVAL_FSMPS_SHIFT 16 #define GRUB_OHCI_REG_FRAME_INTERVAL_FI_SHIFT 0 /* XXX: Is this choice of timings sane? */ #define GRUB_OHCI_FSMPS 0x2778 #define GRUB_OHCI_PERIODIC_START 0x257f #define GRUB_OHCI_FRAME_INTERVAL 0x2edf #define GRUB_OHCI_SET_PORT_ENABLE (1 << 1) #define GRUB_OHCI_CLEAR_PORT_ENABLE (1 << 0) #define GRUB_OHCI_SET_PORT_RESET (1 << 4) #define GRUB_OHCI_SET_PORT_RESET_STATUS_CHANGE (1 << 20) #define GRUB_OHCI_REG_CONTROL_BULK_ENABLE (1 << 5) #define GRUB_OHCI_REG_CONTROL_CONTROL_ENABLE (1 << 4) #define GRUB_OHCI_RESET_CONNECT_CHANGE (1 << 16) #define GRUB_OHCI_CTRL_EDS 16 #define GRUB_OHCI_BULK_EDS 16 #define GRUB_OHCI_TDS 256 #define GRUB_OHCI_ED_ADDR_MASK 0x7ff #define GRUB_OHCI_ED_PHYS2VIRT(o, bulk, x) ( !(x) ? NULL : ( \ (bulk) ? \ (grub_ohci_ed_t)((x) - (o)->ed_bulk_addr + (grub_uint32_t)(o)->ed_bulk) \ : \ (grub_ohci_ed_t)((x) - (o)->ed_ctrl_addr + (grub_uint32_t)(o)->ed_ctrl) ) ) #define GRUB_OHCI_ED_VIRT2PHYS(o, bulk, x) ( !(x) ? 0 : ( \ (bulk) ? \ ((grub_uint32_t)(x) - (grub_uint32_t)(o)->ed_bulk + (o)->ed_bulk_addr) \ : \ ((grub_uint32_t)(x) - (grub_uint32_t)(o)->ed_ctrl + (o)->ed_ctrl_addr) ) ) #define GRUB_OHCI_TD_PHYS2VIRT(o, x) ( !(x) ? NULL : \ (grub_ohci_td_t)((x) - (o)->td_addr + (grub_uint32_t)(o)->td) ) #define GRUB_OHCI_TD_VIRT2PHYS(o, x) ( !(x) ? 0 : \ ((grub_uint32_t)(x) - (grub_uint32_t)(o)->td + (o)->td_addr) ) static grub_uint32_t grub_ohci_readreg32 (struct grub_ohci *o, grub_ohci_reg_t reg) { return grub_le_to_cpu32 (*(o->iobase + reg)); } static void grub_ohci_writereg32 (struct grub_ohci *o, grub_ohci_reg_t reg, grub_uint32_t val) { *(o->iobase + reg) = grub_cpu_to_le32 (val); } /* Iterate over all PCI devices. Determine if a device is an OHCI controller. If this is the case, initialize it. */ static int NESTED_FUNC_ATTR grub_ohci_pci_iter (grub_pci_device_t dev, grub_pci_id_t pciid) { grub_uint32_t interf; grub_uint32_t base; grub_pci_address_t addr; struct grub_ohci *o; grub_uint32_t revision; int cs5536; int j; /* Determine IO base address. */ grub_dprintf ("ohci", "pciid = %x\n", pciid); if (pciid == GRUB_CS5536_PCIID) { grub_uint64_t basereg; cs5536 = 1; basereg = grub_cs5536_read_msr (dev, GRUB_CS5536_MSR_USB_OHCI_BASE); if (!(basereg & GRUB_CS5536_MSR_USB_BASE_MEMORY_ENABLE)) { /* Shouldn't happen. */ grub_dprintf ("ohci", "No OHCI address is assigned\n"); return 0; } base = (basereg & GRUB_CS5536_MSR_USB_BASE_ADDR_MASK); basereg |= GRUB_CS5536_MSR_USB_BASE_BUS_MASTER; basereg &= ~GRUB_CS5536_MSR_USB_BASE_PME_ENABLED; basereg &= ~GRUB_CS5536_MSR_USB_BASE_PME_STATUS; grub_cs5536_write_msr (dev, GRUB_CS5536_MSR_USB_OHCI_BASE, basereg); } else { grub_uint32_t class_code; grub_uint32_t class; grub_uint32_t subclass; addr = grub_pci_make_address (dev, GRUB_PCI_REG_CLASS); class_code = grub_pci_read (addr) >> 8; interf = class_code & 0xFF; subclass = (class_code >> 8) & 0xFF; class = class_code >> 16; /* If this is not an OHCI controller, just return. */ if (class != 0x0c || subclass != 0x03 || interf != 0x10) return 0; addr = grub_pci_make_address (dev, GRUB_PCI_REG_ADDRESS_REG0); base = grub_pci_read (addr); #if 0 /* Stop if there is no IO space base address defined. */ if (! (base & 1)) return 0; #endif grub_dprintf ("ohci", "class=0x%02x 0x%02x interface 0x%02x\n", class, subclass, interf); } /* Allocate memory for the controller and register it. */ o = grub_malloc (sizeof (*o)); if (! o) return 1; grub_memset ((void*)o, 0, sizeof (*o)); o->iobase = grub_pci_device_map_range (dev, base, 0x800); grub_dprintf ("ohci", "base=%p\n", o->iobase); /* Reserve memory for the HCCA. */ o->hcca_chunk = grub_memalign_dma32 (256, 256); if (! o->hcca_chunk) goto fail; o->hcca = grub_dma_get_virt (o->hcca_chunk); o->hcca_addr = grub_dma_get_phys (o->hcca_chunk); grub_memset ((void*)o->hcca, 0, sizeof(*o->hcca)); grub_dprintf ("ohci", "hcca: chunk=%p, virt=%p, phys=0x%02x\n", o->hcca_chunk, o->hcca, o->hcca_addr); /* Reserve memory for ctrl EDs. */ o->ed_ctrl_chunk = grub_memalign_dma32 (16, sizeof(struct grub_ohci_ed)*GRUB_OHCI_CTRL_EDS); if (! o->ed_ctrl_chunk) goto fail; o->ed_ctrl = grub_dma_get_virt (o->ed_ctrl_chunk); o->ed_ctrl_addr = grub_dma_get_phys (o->ed_ctrl_chunk); /* Preset EDs */ grub_memset ((void*)o->ed_ctrl, 0, sizeof(struct grub_ohci_ed) * GRUB_OHCI_CTRL_EDS); for (j=0; j < GRUB_OHCI_CTRL_EDS; j++) o->ed_ctrl[j].target = grub_cpu_to_le32 (1 << 14); /* skip */ grub_dprintf ("ohci", "EDs-C: chunk=%p, virt=%p, phys=0x%02x\n", o->ed_ctrl_chunk, o->ed_ctrl, o->ed_ctrl_addr); /* Reserve memory for bulk EDs. */ o->ed_bulk_chunk = grub_memalign_dma32 (16, sizeof(struct grub_ohci_ed)*GRUB_OHCI_BULK_EDS); if (! o->ed_bulk_chunk) goto fail; o->ed_bulk = grub_dma_get_virt (o->ed_bulk_chunk); o->ed_bulk_addr = grub_dma_get_phys (o->ed_bulk_chunk); /* Preset EDs */ grub_memset ((void*)o->ed_bulk, 0, sizeof(struct grub_ohci_ed) * GRUB_OHCI_BULK_EDS); for (j=0; j < GRUB_OHCI_BULK_EDS; j++) o->ed_bulk[j].target = grub_cpu_to_le32 (1 << 14); /* skip */ grub_dprintf ("ohci", "EDs-B: chunk=%p, virt=%p, phys=0x%02x\n", o->ed_bulk_chunk, o->ed_bulk, o->ed_bulk_addr); /* Reserve memory for TDs. */ o->td_chunk = grub_memalign_dma32 (32, sizeof(struct grub_ohci_td)*GRUB_OHCI_TDS); /* Why is it aligned on 32 boundary if spec. says 16 ? * We have structure 32 bytes long and we don't want cross * 4K boundary inside structure. */ if (! o->td_chunk) goto fail; o->td_free = o->td = grub_dma_get_virt (o->td_chunk); o->td_addr = grub_dma_get_phys (o->td_chunk); /* Preset free TDs chain in TDs */ grub_memset ((void*)o->td, 0, sizeof(struct grub_ohci_td) * GRUB_OHCI_TDS); for (j=0; j < (GRUB_OHCI_TDS-1); j++) o->td[j].link_td = (grub_uint32_t)&o->td[j+1]; grub_dprintf ("ohci", "TDs: chunk=%p, virt=%p, phys=0x%02x\n", o->td_chunk, o->td, o->td_addr); /* Check if the OHCI revision is actually 1.0 as supported. */ revision = grub_ohci_readreg32 (o, GRUB_OHCI_REG_REVISION); grub_dprintf ("ohci", "OHCI revision=0x%02x\n", revision & 0xFF); if ((revision & 0xFF) != 0x10) goto fail; { grub_uint32_t control; /* Check SMM/BIOS ownership of OHCI (SMM = USB Legacy Support driver for BIOS) */ control = grub_ohci_readreg32 (o, GRUB_OHCI_REG_CONTROL); if ((control & 0x100) != 0) { unsigned i; grub_dprintf("ohci", "OHCI is owned by SMM\n"); /* Do change of ownership */ /* Ownership change request */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CMDSTATUS, (1<<3)); /* XXX: Magic. */ /* Waiting for SMM deactivation */ for (i=0; i < 10; i++) { if ((grub_ohci_readreg32 (o, GRUB_OHCI_REG_CONTROL) & 0x100) == 0) { grub_dprintf("ohci", "Ownership changed normally.\n"); break; } grub_millisleep (100); } if (i >= 10) { grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROL, grub_ohci_readreg32 (o, GRUB_OHCI_REG_CONTROL) & ~0x100); grub_dprintf("ohci", "Ownership changing timeout, change forced !\n"); } } else if (((control & 0x100) == 0) && ((control & 0xc0) != 0)) /* Not owned by SMM nor reset */ { grub_dprintf("ohci", "OHCI is owned by BIOS\n"); /* Do change of ownership - not implemented yet... */ /* In fact we probably need to do nothing ...? */ } else { grub_dprintf("ohci", "OHCI is not owned by SMM nor BIOS\n"); /* We can setup OHCI. */ } } /* Suspend the OHCI by issuing a reset. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CMDSTATUS, 1); /* XXX: Magic. */ grub_millisleep (1); grub_dprintf ("ohci", "OHCI reset\n"); grub_ohci_writereg32 (o, GRUB_OHCI_REG_FRAME_INTERVAL, (GRUB_OHCI_FSMPS << GRUB_OHCI_REG_FRAME_INTERVAL_FSMPS_SHIFT) | (GRUB_OHCI_FRAME_INTERVAL << GRUB_OHCI_REG_FRAME_INTERVAL_FI_SHIFT)); grub_ohci_writereg32 (o, GRUB_OHCI_REG_PERIODIC_START, GRUB_OHCI_PERIODIC_START); /* Setup the HCCA. */ o->hcca->donehead = 0; grub_ohci_writereg32 (o, GRUB_OHCI_REG_HCCA, o->hcca_addr); grub_dprintf ("ohci", "OHCI HCCA\n"); /* Misc. pre-sets. */ o->hcca->donehead = 0; grub_ohci_writereg32 (o, GRUB_OHCI_REG_INTSTATUS, 0x7f); /* Clears everything */ /* We don't want modify CONTROL/BULK HEAD registers. * So we assign to HEAD registers zero ED from related array * and we will not use this ED, it will be always skipped. * It should not produce notable performance penalty (I hope). */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROLHEAD, o->ed_ctrl_addr); grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROLCURR, 0); grub_ohci_writereg32 (o, GRUB_OHCI_REG_BULKHEAD, o->ed_bulk_addr); grub_ohci_writereg32 (o, GRUB_OHCI_REG_BULKCURR, 0); /* Check OHCI Legacy Support */ if ((revision & 0x100) != 0) { grub_dprintf ("ohci", "Legacy Support registers detected\n"); grub_dprintf ("ohci", "Current state of legacy control reg.: 0x%04x\n", grub_ohci_readreg32 (o, GRUB_OHCI_REG_LEGACY_CONTROL)); grub_ohci_writereg32 (o, GRUB_OHCI_REG_LEGACY_CONTROL, (grub_ohci_readreg32 (o, GRUB_OHCI_REG_LEGACY_CONTROL)) & ~1); grub_dprintf ("ohci", "OHCI Legacy Support disabled.\n"); } /* Enable the OHCI + enable CONTROL and BULK LIST. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROL, (2 << 6) | GRUB_OHCI_REG_CONTROL_CONTROL_ENABLE | GRUB_OHCI_REG_CONTROL_BULK_ENABLE ); grub_dprintf ("ohci", "OHCI enable: 0x%02x\n", (grub_ohci_readreg32 (o, GRUB_OHCI_REG_CONTROL) >> 6) & 3); /* Power on all ports */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_RHUBA, (grub_ohci_readreg32 (o, GRUB_OHCI_REG_RHUBA) & ~GRUB_OHCI_RHUB_PORT_POWER_MASK) | GRUB_OHCI_RHUB_PORT_ALL_POWERED); /* Now we have hot-plugging, we need to wait for stable power only */ grub_millisleep (100); /* Link to ohci now that initialisation is successful. */ o->next = ohci; ohci = o; return 0; fail: if (o) grub_dma_free (o->td_chunk); grub_dma_free (o->ed_bulk_chunk); grub_dma_free (o->ed_ctrl_chunk); grub_dma_free (o->hcca_chunk); grub_free (o); return 1; } static void grub_ohci_inithw (void) { grub_pci_iterate (grub_ohci_pci_iter); } static int grub_ohci_iterate (int (*hook) (grub_usb_controller_t dev)) { struct grub_ohci *o; struct grub_usb_controller dev; for (o = ohci; o; o = o->next) { dev.data = o; if (hook (&dev)) return 1; } return 0; } static grub_ohci_ed_t grub_ohci_find_ed (struct grub_ohci *o, int bulk, grub_uint32_t target) { grub_ohci_ed_t ed, ed_next; grub_uint32_t target_addr = target & GRUB_OHCI_ED_ADDR_MASK; int count; int i; /* Use proper values and structures. */ if (bulk) { count = GRUB_OHCI_BULK_EDS; ed = o->ed_bulk; ed_next = GRUB_OHCI_ED_PHYS2VIRT(o, bulk, grub_le_to_cpu32 (ed->next_ed) ); } else { count = GRUB_OHCI_CTRL_EDS; ed = o->ed_ctrl; ed_next = GRUB_OHCI_ED_PHYS2VIRT(o, bulk, grub_le_to_cpu32 (ed->next_ed) ); } /* First try to find existing ED with proper target address */ for (i = 0; ; ) { if (i && /* We ignore zero ED */ ((ed->target & GRUB_OHCI_ED_ADDR_MASK) == target_addr)) return ed; /* Found proper existing ED */ i++; if (ed_next && (i < count)) { ed = ed_next; ed_next = GRUB_OHCI_ED_PHYS2VIRT(o, bulk, grub_le_to_cpu32 (ed->next_ed) ); continue; } break; } /* ED with target_addr does not exist, we have to add it */ /* Have we any free ED in array ? */ if (i >= count) /* No. */ return NULL; /* Currently we simply take next ED in array, no allocation * function is used. It should be no problem until hot-plugging * will be implemented, i.e. until we will need to de-allocate EDs * of unplugged devices. */ /* We can link new ED to previous ED safely as the new ED should * still have set skip bit. */ ed->next_ed = grub_cpu_to_le32 ( GRUB_OHCI_ED_VIRT2PHYS (o, bulk, &ed[1])); return &ed[1]; } static grub_ohci_td_t grub_ohci_alloc_td (struct grub_ohci *o) { grub_ohci_td_t ret; /* Check if there is a Transfer Descriptor available. */ if (! o->td_free) return NULL; ret = o->td_free; /* Take current free TD */ o->td_free = (grub_ohci_td_t)ret->link_td; /* Advance to next free TD in chain */ ret->link_td = 0; /* Reset link_td in allocated TD */ return ret; } static void grub_ohci_free_td (struct grub_ohci *o, grub_ohci_td_t td) { grub_memset ( (void*)td, 0, sizeof(struct grub_ohci_td) ); td->link_td = (grub_uint32_t) o->td_free; /* Cahin new free TD & rest */ o->td_free = td; /* Change address of first free TD */ } static void grub_ohci_free_tds (struct grub_ohci *o, grub_ohci_td_t td) { if (!td) return; /* Unchain first TD from previous TD if it is chained */ if (td->prev_td_phys) { grub_ohci_td_t td_prev_virt = GRUB_OHCI_TD_PHYS2VIRT(o, td->prev_td_phys); if (td == (grub_ohci_td_t) td_prev_virt->link_td) td_prev_virt->link_td = 0; } /* Free all TDs from td (chained by link_td) */ while (td) { grub_ohci_td_t tdprev; /* Unlink the queue. */ tdprev = td; td = (grub_ohci_td_t) td->link_td; /* Free the TD. */ grub_ohci_free_td (o, tdprev); } } static void grub_ohci_transaction (grub_ohci_td_t td, grub_transfer_type_t type, unsigned int toggle, grub_size_t size, grub_uint32_t data) { grub_uint32_t token; grub_uint32_t buffer; grub_uint32_t buffer_end; grub_dprintf ("ohci", "OHCI transaction td=%p type=%d, toggle=%d, size=%d\n", td, type, toggle, size); switch (type) { case GRUB_USB_TRANSFER_TYPE_SETUP: token = 0 << 19; break; case GRUB_USB_TRANSFER_TYPE_IN: token = 2 << 19; break; case GRUB_USB_TRANSFER_TYPE_OUT: token = 1 << 19; break; default: token = 0; break; } /* Set the token (Always generate interrupt - bits 21-23 = 0). */ token |= toggle << 24; token |= 1 << 25; /* Set "Not accessed" error code */ token |= 15 << 28; buffer = data; buffer_end = buffer + size - 1; /* Set correct buffer values in TD if zero transfer occurs */ if (size) { buffer = (grub_uint32_t) data; buffer_end = buffer + size - 1; td->buffer = grub_cpu_to_le32 (buffer); td->buffer_end = grub_cpu_to_le32 (buffer_end); } else { td->buffer = 0; td->buffer_end = 0; } /* Set the rest of TD */ td->token = grub_cpu_to_le32 (token); td->next_td = 0; } static grub_usb_err_t grub_ohci_transfer (grub_usb_controller_t dev, grub_usb_transfer_t transfer) { struct grub_ohci *o = (struct grub_ohci *) dev->data; grub_ohci_ed_t ed_virt; int bulk = 0; grub_ohci_td_t td_head_virt; grub_ohci_td_t td_current_virt; grub_ohci_td_t td_next_virt; grub_ohci_td_t tderr_virt = NULL; grub_uint32_t target; grub_uint32_t td_head_phys; grub_uint32_t td_tail_phys; grub_uint32_t td_last_phys; grub_uint32_t tderr_phys = 0; grub_uint32_t status; grub_uint32_t control; grub_uint8_t errcode = 0; grub_usb_err_t err = GRUB_USB_ERR_NONE; int i; grub_uint64_t maxtime; grub_uint64_t bad_OHCI_delay = 0; int err_halt = 0; int err_timeout = 0; int err_unrec = 0; grub_uint32_t intstatus; /* Pre-set target for ED - we need it to find proper ED */ /* Set the device address. */ target = transfer->devaddr; /* Set the endpoint. It should be masked, we need 4 bits only. */ target |= (transfer->endpoint & 15) << 7; /* Set the device speed. */ target |= (transfer->dev->speed == GRUB_USB_SPEED_LOW) << 13; /* Set the maximum packet size. */ target |= transfer->max << 16; /* Determine if transfer type is bulk - we need to select proper ED */ switch (transfer->type) { case GRUB_USB_TRANSACTION_TYPE_BULK: bulk = 1; break; case GRUB_USB_TRANSACTION_TYPE_CONTROL: break; default : return GRUB_USB_ERR_INTERNAL; } /* Find proper ED or add new ED */ ed_virt = grub_ohci_find_ed (o, bulk, target); if (!ed_virt) { grub_dprintf ("ohci","Fatal: No free ED !\n"); return GRUB_USB_ERR_INTERNAL; } /* Take pointer to first TD from ED */ td_head_phys = grub_le_to_cpu32 (ed_virt->td_head) & ~0xf; td_tail_phys = grub_le_to_cpu32 (ed_virt->td_tail) & ~0xf; /* Sanity check - td_head should be equal to td_tail */ if (td_head_phys != td_tail_phys) /* Should never happen ! */ { grub_dprintf ("ohci", "Fatal: HEAD is not equal to TAIL !\n"); grub_dprintf ("ohci", "HEAD = 0x%02x, TAIL = 0x%02x\n", td_head_phys, td_tail_phys); /* XXX: Fix: What to do ? */ return GRUB_USB_ERR_INTERNAL; } /* Now we should handle first TD. If ED is newly allocated, * we must allocate the first TD. */ if (!td_head_phys) { td_head_virt = grub_ohci_alloc_td (o); if (!td_head_virt) return GRUB_USB_ERR_INTERNAL; /* We don't need de-allocate ED */ /* We can set td_head only when ED is not active, i.e. * when it is newly allocated. */ ed_virt->td_head = grub_cpu_to_le32 ( GRUB_OHCI_TD_VIRT2PHYS (o, td_head_virt) ); ed_virt->td_tail = ed_virt->td_head; } else td_head_virt = GRUB_OHCI_TD_PHYS2VIRT ( o, td_head_phys ); /* Set TDs */ td_last_phys = td_head_phys; /* initial value to make compiler happy... */ for (i = 0, td_current_virt = td_head_virt; i < transfer->transcnt; i++) { grub_usb_transaction_t tr = &transfer->transactions[i]; grub_ohci_transaction (td_current_virt, tr->pid, tr->toggle, tr->size, tr->data); /* Set index of TD in transfer */ td_current_virt->tr_index = (grub_uint32_t) i; /* No IRQ request in TD if bad_OHCI set */ if (o->bad_OHCI) td_current_virt->token |= grub_cpu_to_le32 ( 7 << 21); /* Remember last used (processed) TD phys. addr. */ td_last_phys = GRUB_OHCI_TD_VIRT2PHYS (o, td_current_virt); /* Allocate next TD */ td_next_virt = grub_ohci_alloc_td (o); if (!td_next_virt) /* No free TD, cancel transfer and free TDs except head TD */ { if (i) /* if i==0 we have nothing to free... */ grub_ohci_free_tds (o, GRUB_OHCI_TD_PHYS2VIRT(o, grub_le_to_cpu32 (td_head_virt->next_td) ) ); /* Reset head TD */ grub_memset ( (void*)td_head_virt, 0, sizeof(struct grub_ohci_td) ); grub_dprintf ("ohci", "Fatal: No free TD !"); return GRUB_USB_ERR_INTERNAL; } /* Chain TDs */ td_current_virt->link_td = (grub_uint32_t) td_next_virt; td_current_virt->next_td = grub_cpu_to_le32 ( GRUB_OHCI_TD_VIRT2PHYS (o, td_next_virt) ); td_next_virt->prev_td_phys = GRUB_OHCI_TD_VIRT2PHYS (o, td_current_virt); td_current_virt = td_next_virt; } grub_dprintf ("ohci", "Tail TD (not processed) = %p\n", td_current_virt); /* Setup the Endpoint Descriptor for transfer. */ /* First set necessary fields in TARGET but keep (or set) skip bit */ /* Note: It could be simpler if speed, format and max. packet * size never change after first allocation of ED. * But unfortunately max. packet size may change during initial * setup sequence and we must handle it. */ ed_virt->target = grub_cpu_to_le32 (target | (1 << 14)); /* Set td_tail */ ed_virt->td_tail = grub_cpu_to_le32 ( GRUB_OHCI_TD_VIRT2PHYS (o, td_current_virt) ); /* Now reset skip bit */ ed_virt->target = grub_cpu_to_le32 (target); /* ed_virt->td_head = grub_cpu_to_le32 (td_head); Must not be changed, it is maintained by OHCI */ /* ed_virt->next_ed = grub_cpu_to_le32 (0); Handled by grub_ohci_find_ed, do not change ! */ grub_dprintf ("ohci", "program OHCI\n"); /* Program the OHCI to actually transfer. */ switch (transfer->type) { case GRUB_USB_TRANSACTION_TYPE_BULK: { grub_dprintf ("ohci", "BULK list filled\n"); /* Set BulkListFilled. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CMDSTATUS, 1 << 2); /* Read back of register should ensure it is really written */ grub_ohci_readreg32 (o, GRUB_OHCI_REG_CMDSTATUS); break; } case GRUB_USB_TRANSACTION_TYPE_CONTROL: { grub_dprintf ("ohci", "CONTROL list filled\n"); /* Set ControlListFilled. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CMDSTATUS, 1 << 1); /* Read back of register should ensure it is really written */ grub_ohci_readreg32 (o, GRUB_OHCI_REG_CMDSTATUS); break; } } /* Safety measure to avoid a hang. */ maxtime = grub_get_time_ms () + 1000; /* Wait until the transfer is completed or STALLs. */ do { /* Check transfer status */ intstatus = grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS); if (!o->bad_OHCI && (intstatus & 0x2) != 0) { /* Remember last successful TD */ tderr_phys = grub_le_to_cpu32 (o->hcca->donehead) & ~0xf; /* Reset DoneHead */ o->hcca->donehead = 0; grub_ohci_writereg32 (o, GRUB_OHCI_REG_INTSTATUS, (1 << 1)); /* Read back of register should ensure it is really written */ grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS); /* if TD is last, finish */ if (tderr_phys == td_last_phys) { if (grub_le_to_cpu32 (ed_virt->td_head) & 1) err_halt = 1; break; } continue; } if ((intstatus & 0x10) != 0) { /* Unrecoverable error - only reset can help...! */ err_unrec = 1; break; } /* Detected a HALT. */ if (err_halt || (grub_le_to_cpu32 (ed_virt->td_head) & 1)) { err_halt = 1; /* ED is halted, but donehead event can happened in the meantime */ intstatus = grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS); if (!o->bad_OHCI && (intstatus & 0x2) != 0) /* Don't break loop now, first do donehead action(s) */ continue; break; } /* bad OHCI handling */ if ( (grub_le_to_cpu32 (ed_virt->td_head) & ~0xf) == (grub_le_to_cpu32 (ed_virt->td_tail) & ~0xf) ) /* Empty ED */ { if (o->bad_OHCI) /* Bad OHCI detected previously */ { /* Try get last successful TD. */ tderr_phys = grub_le_to_cpu32 (o->hcca->donehead) & ~0xf; if (tderr_phys)/* Reset DoneHead if we were successful */ { o->hcca->donehead = 0; grub_ohci_writereg32 (o, GRUB_OHCI_REG_INTSTATUS, (1 << 1)); /* Read back of register should ensure it is really written */ grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS); } /* Check the HALT bit */ if (grub_le_to_cpu32 (ed_virt->td_head) & 1) err_halt = 1; break; } else /* Detection of bad OHCI */ /* We should wait short time (~2ms) before we say that * it is bad OHCI to prevent some hazard - * donehead can react in the meantime. This waiting is done * only once per OHCI driver "live cycle". */ if (!bad_OHCI_delay) /* Set delay time */ bad_OHCI_delay = grub_get_time_ms () + 2; else if (grub_get_time_ms () >= bad_OHCI_delay) o->bad_OHCI = 1; continue; } /* Timeout ? */ if (grub_get_time_ms () > maxtime) { err_timeout = 1; break; } grub_cpu_idle (); } while (1); /* There are many ways how the loop above can finish: * - normally without any error via INTSTATUS WDH bit * : tderr_phys == td_last_phys, td_head == td_tail * - normally with error via HALT bit in ED TD HEAD * : td_head = next TD after TD with error * : tderr_phys = last processed and retired TD with error, * i.e. should be != 0 * : if bad_OHCI == TRUE, tderr_phys will be probably invalid * - unrecoverable error - I never seen it but it could be * : err_unrec == TRUE, other values can contain anything... * - timeout, it can be caused by: * -- bad USB device - some devices have some bugs, see Linux source * and related links * -- bad OHCI controller - e.g. lost interrupts or does not set * proper bits in INTSTATUS when real IRQ not enabled etc., * see Linux source and related links * One known bug is handled - if transfer finished * successfully (i.e. HEAD==TAIL, last transfer TD is retired, * HALT bit is not set) and WDH bit is not set in INTSTATUS - in * this case we set o->bad_OHCI=TRUE and do alternate loop * and error handling - but there is problem how to find retired * TD with error code if HALT occurs and if DONEHEAD is not * working - we need to find TD previous to current ED HEAD * -- bad code of this driver or some unknown reasons - :-( * it can be e.g. bad handling of EDs/TDs/toggle bit... */ /* Remember target for debug and set skip flag in ED */ /* It should be normaly not necessary but we need it at least * in case of timeout */ target = grub_le_to_cpu32 ( ed_virt->target ); ed_virt->target = grub_cpu_to_le32 (target | (1 << 14)); /* Read registers for debug - they should be read now because * debug prints case unwanted delays, so something can happen * in the meantime... */ control = grub_ohci_readreg32 (o, GRUB_OHCI_REG_CONTROL); status = grub_ohci_readreg32 (o, GRUB_OHCI_REG_CMDSTATUS); intstatus = grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS); /* Now print debug values - to have full info what happened */ grub_dprintf ("ohci", "loop finished: control=0x%02x status=0x%02x\n", control, status); grub_dprintf ("ohci", "intstatus=0x%02x \n\t\t tderr_phys=0x%02x, td_last_phys=0x%02x\n", intstatus, tderr_phys, td_last_phys); grub_dprintf ("ohci", "err_unrec=%d, err_timeout=%d \n\t\t err_halt=%d, bad_OHCI=%d\n", err_unrec, err_timeout, err_halt, o->bad_OHCI); grub_dprintf ("ohci", "TARGET=0x%02x, HEAD=0x%02x, TAIL=0x%02x\n", target, grub_le_to_cpu32 (ed_virt->td_head), grub_le_to_cpu32 (ed_virt->td_tail) ); if (!err_halt && !err_unrec && !err_timeout) /* normal finish */ { /* Simple workaround if donehead is not working */ if (o->bad_OHCI && ( !tderr_phys || (tderr_phys != td_last_phys) ) ) { grub_dprintf ("ohci", "normal finish, but tderr_phys corrected\n"); tderr_phys = td_last_phys; /* I hope we can do it as transfer (most probably) finished OK */ } /* Prepare pointer to last processed TD */ tderr_virt = GRUB_OHCI_TD_PHYS2VIRT (o, tderr_phys); /* Set index of last processed TD */ if (tderr_virt) transfer->last_trans = tderr_virt->tr_index; else transfer->last_trans = -1; } else if (err_halt) /* error, ED is halted by OHCI, i.e. can be modified */ { /* First we must get proper tderr_phys value */ if (o->bad_OHCI) /* In case of bad_OHCI tderr_phys can be wrong */ { if ( tderr_phys ) /* check if tderr_phys points to TD with error */ errcode = grub_le_to_cpu32 ( GRUB_OHCI_TD_PHYS2VIRT (o, tderr_phys)->token ) >> 28; if ( !tderr_phys || !errcode ) /* tderr_phys not valid or points to wrong TD */ { /* Retired TD with error should be previous TD to ED->td_head */ tderr_phys = GRUB_OHCI_TD_PHYS2VIRT (o, grub_le_to_cpu32 ( ed_virt->td_head) & ~0xf ) ->prev_td_phys; } } /* Even if we have "good" OHCI, in some cases * tderr_phys can be zero, check it */ else if ( !tderr_phys ) { /* Retired TD with error should be previous TD to ED->td_head */ tderr_phys = GRUB_OHCI_TD_PHYS2VIRT (o, grub_le_to_cpu32 ( ed_virt->td_head) & ~0xf ) ->prev_td_phys; } /* Prepare pointer to last processed TD and get error code */ tderr_virt = GRUB_OHCI_TD_PHYS2VIRT (o, tderr_phys); /* Set index of last processed TD */ if (tderr_virt) { errcode = grub_le_to_cpu32 ( tderr_virt->token ) >> 28; transfer->last_trans = tderr_virt->tr_index; } else transfer->last_trans = -1; /* Evaluation of error code */ grub_dprintf ("ohci", "OHCI tderr_phys=0x%02x, errcode=0x%02x\n", tderr_phys, errcode); switch (errcode) { case 0: /* XXX: Should not happen! */ grub_error (GRUB_ERR_IO, "OHCI without reporting the reason"); err = GRUB_USB_ERR_INTERNAL; break; case 1: /* XXX: CRC error. */ err = GRUB_USB_ERR_TIMEOUT; break; case 2: err = GRUB_USB_ERR_BITSTUFF; break; case 3: /* XXX: Data Toggle error. */ err = GRUB_USB_ERR_DATA; break; case 4: err = GRUB_USB_ERR_STALL; break; case 5: /* XXX: Not responding. */ err = GRUB_USB_ERR_TIMEOUT; break; case 6: /* XXX: PID Check bits failed. */ err = GRUB_USB_ERR_BABBLE; break; case 7: /* XXX: PID unexpected failed. */ err = GRUB_USB_ERR_BABBLE; break; case 8: /* XXX: Data overrun error. */ err = GRUB_USB_ERR_DATA; grub_dprintf ("ohci", "Overrun, failed TD address: %p, index: %d\n", tderr_virt, tderr_virt->tr_index); break; case 9: /* XXX: Data underrun error. */ err = GRUB_USB_ERR_DATA; grub_dprintf ("ohci", "Underrun, failed TD address: %p, index: %d\n", tderr_virt, tderr_virt->tr_index); grub_dprintf ("ohci", "Underrun, number of not transferred bytes: %d\n", 1 + grub_le_to_cpu32 (tderr_virt->buffer_end) - grub_le_to_cpu32 (tderr_virt->buffer)); break; case 10: /* XXX: Reserved. */ err = GRUB_USB_ERR_NAK; break; case 11: /* XXX: Reserved. */ err = GRUB_USB_ERR_NAK; break; case 12: /* XXX: Buffer overrun. */ err = GRUB_USB_ERR_DATA; break; case 13: /* XXX: Buffer underrun. */ err = GRUB_USB_ERR_DATA; break; default: err = GRUB_USB_ERR_NAK; break; } } else if (err_unrec) { /* Don't try to get error code and last processed TD for proper * toggle bit value - anything can be invalid */ err = GRUB_USB_ERR_UNRECOVERABLE; grub_dprintf("ohci", "Unrecoverable error!"); /* Do OHCI reset in case of unrecoverable error - maybe we will need * do more - re-enumerate bus etc. (?) */ /* Suspend the OHCI by issuing a reset. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CMDSTATUS, 1); /* XXX: Magic. */ /* Read back of register should ensure it is really written */ grub_ohci_readreg32 (o, GRUB_OHCI_REG_CMDSTATUS); grub_millisleep (1); grub_dprintf ("ohci", "Unrecoverable error - OHCI reset\n"); /* Misc. resets. */ o->hcca->donehead = 0; grub_ohci_writereg32 (o, GRUB_OHCI_REG_INTSTATUS, 0x7f); /* Clears everything */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROLHEAD, o->ed_ctrl_addr); grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROLCURR, 0); grub_ohci_writereg32 (o, GRUB_OHCI_REG_BULKHEAD, o->ed_bulk_addr); grub_ohci_writereg32 (o, GRUB_OHCI_REG_BULKCURR, 0); /* Read back of register should ensure it is really written */ grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS); /* Enable the OHCI. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROL, (2 << 6) | GRUB_OHCI_REG_CONTROL_CONTROL_ENABLE | GRUB_OHCI_REG_CONTROL_BULK_ENABLE ); } else if (err_timeout) { /* In case of timeout do not detect error from TD */ err = GRUB_ERR_TIMEOUT; grub_dprintf("ohci", "Timeout !\n"); /* We should wait for next SOF to be sure that ED is unaccessed * by OHCI */ /* SF bit reset. (SF bit indicates Start Of Frame (SOF) packet) */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_INTSTATUS, (1<<2)); /* Wait for new SOF */ while ((grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS) & 0x4) == 0); /* Now we must find last processed TD if bad_OHCI == TRUE */ if (o->bad_OHCI) { /* Retired TD with error should be previous TD to ED->td_head */ tderr_phys = GRUB_OHCI_TD_PHYS2VIRT (o, grub_le_to_cpu32 ( ed_virt->td_head) & ~0xf) ->prev_td_phys; } tderr_virt = GRUB_OHCI_TD_PHYS2VIRT (o, tderr_phys); if (tderr_virt) transfer->last_trans = tderr_virt->tr_index; else transfer->last_trans = -1; } /* Set empty ED - set HEAD = TAIL = last (not processed) TD */ ed_virt->td_head = grub_cpu_to_le32 ( grub_le_to_cpu32 ( ed_virt->td_tail) & ~0xf); /* At this point always should be: * ED has skip bit set and halted or empty or after next SOF, * i.e. it is safe to free all TDs except last not processed * ED HEAD == TAIL == phys. addr. of td_current_virt */ /* Reset DoneHead - sanity cleanup */ o->hcca->donehead = 0; grub_ohci_writereg32 (o, GRUB_OHCI_REG_INTSTATUS, (1 << 1)); /* Read back of register should ensure it is really written */ grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS); /* Un-chainig of last TD */ if (td_current_virt->prev_td_phys) { grub_ohci_td_t td_prev_virt = GRUB_OHCI_TD_PHYS2VIRT (o, td_current_virt->prev_td_phys); td_next_virt = (grub_ohci_td_t) td_prev_virt->link_td; if (td_current_virt == td_next_virt) td_prev_virt->link_td = 0; } grub_dprintf ("ohci", "OHCI finished, freeing, err=0x%02x, errcode=0x%02x\n", err, errcode); grub_ohci_free_tds (o, td_head_virt); return err; } static grub_err_t grub_ohci_portstatus (grub_usb_controller_t dev, unsigned int port, unsigned int enable) { struct grub_ohci *o = (struct grub_ohci *) dev->data; grub_uint64_t endtime; grub_dprintf ("ohci", "begin of portstatus=0x%02x\n", grub_ohci_readreg32 (o, GRUB_OHCI_REG_RHUBPORT + port)); if (!enable) /* We don't need reset port */ { /* Disable the port and wait for it. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_RHUBPORT + port, GRUB_OHCI_CLEAR_PORT_ENABLE); endtime = grub_get_time_ms () + 1000; while ((grub_ohci_readreg32 (o, GRUB_OHCI_REG_RHUBPORT + port) & (1 << 1))) if (grub_get_time_ms () > endtime) return grub_error (GRUB_ERR_IO, "OHCI Timed out - disable"); grub_dprintf ("ohci", "end of portstatus=0x%02x\n", grub_ohci_readreg32 (o, GRUB_OHCI_REG_RHUBPORT + port)); return GRUB_ERR_NONE; } /* Reset the port */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_RHUBPORT + port, GRUB_OHCI_SET_PORT_RESET); grub_millisleep (50); /* For root hub should be nominaly 50ms */ /* End the reset signaling. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_RHUBPORT + port, GRUB_OHCI_SET_PORT_RESET_STATUS_CHANGE); grub_millisleep (10); /* Enable the port and wait for it. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_RHUBPORT + port, GRUB_OHCI_SET_PORT_ENABLE); endtime = grub_get_time_ms () + 1000; while (! (grub_ohci_readreg32 (o, GRUB_OHCI_REG_RHUBPORT + port) & (1 << 1))) if (grub_get_time_ms () > endtime) return grub_error (GRUB_ERR_IO, "OHCI Timed out - enable"); grub_millisleep (10); /* Reset bit Connect Status Change */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_RHUBPORT + port, GRUB_OHCI_RESET_CONNECT_CHANGE); grub_dprintf ("ohci", "end of portstatus=0x%02x\n", grub_ohci_readreg32 (o, GRUB_OHCI_REG_RHUBPORT + port)); return GRUB_ERR_NONE; } static grub_usb_speed_t grub_ohci_detect_dev (grub_usb_controller_t dev, int port, int *changed) { struct grub_ohci *o = (struct grub_ohci *) dev->data; grub_uint32_t status; status = grub_ohci_readreg32 (o, GRUB_OHCI_REG_RHUBPORT + port); grub_dprintf ("ohci", "detect_dev status=0x%02x\n", status); /* Connect Status Change bit - it detects change of connection */ *changed = ((status & GRUB_OHCI_RESET_CONNECT_CHANGE) != 0); if (! (status & 1)) return GRUB_USB_SPEED_NONE; else if (status & (1 << 9)) return GRUB_USB_SPEED_LOW; else return GRUB_USB_SPEED_FULL; } static int grub_ohci_hubports (grub_usb_controller_t dev) { struct grub_ohci *o = (struct grub_ohci *) dev->data; grub_uint32_t portinfo; portinfo = grub_ohci_readreg32 (o, GRUB_OHCI_REG_RHUBA); grub_dprintf ("ohci", "root hub ports=%d\n", portinfo & 0xFF); return portinfo & 0xFF; } static grub_err_t grub_ohci_fini_hw (int noreturn __attribute__ ((unused))) { struct grub_ohci *o; for (o = ohci; o; o = o->next) { int i, nports = grub_ohci_readreg32 (o, GRUB_OHCI_REG_RHUBA) & 0xff; grub_uint64_t maxtime; /* Set skip in all EDs */ if (o->ed_bulk) for (i=0; i < GRUB_OHCI_BULK_EDS; i++) o->ed_bulk[i].target |= grub_cpu_to_le32 (1 << 14); /* skip */ if (o->ed_ctrl) for (i=0; i < GRUB_OHCI_CTRL_EDS; i++) o->ed_ctrl[i].target |= grub_cpu_to_le32 (1 << 14); /* skip */ /* We should wait for next SOF to be sure that all EDs are * unaccessed by OHCI. But OHCI can be non-functional, so * more than 1ms timeout have to be applied. */ /* SF bit reset. (SF bit indicates Start Of Frame (SOF) packet) */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_INTSTATUS, (1<<2)); maxtime = grub_get_time_ms () + 2; /* Wait for new SOF or timeout */ while ( ((grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS) & 0x4) == 0) || (grub_get_time_ms () >= maxtime) ); for (i = 0; i < nports; i++) grub_ohci_writereg32 (o, GRUB_OHCI_REG_RHUBPORT + i, GRUB_OHCI_CLEAR_PORT_ENABLE); grub_ohci_writereg32 (o, GRUB_OHCI_REG_CMDSTATUS, 1); grub_millisleep (1); grub_ohci_writereg32 (o, GRUB_OHCI_REG_HCCA, 0); grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROLHEAD, 0); grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROLCURR, 0); grub_ohci_writereg32 (o, GRUB_OHCI_REG_BULKHEAD, 0); grub_ohci_writereg32 (o, GRUB_OHCI_REG_BULKCURR, 0); grub_ohci_writereg32 (o, GRUB_OHCI_REG_DONEHEAD, 0); grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROL, 0); /* Read back of register should ensure it is really written */ grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS); #if 0 /* Is this necessary before booting? Probably not .(?) * But it must be done if module is removed ! (Or not ?) * How to do it ? - Probably grub_ohci_restore_hw should be more * complicated. (?) * (If we do it, we need to reallocate EDs and TDs in function * grub_ohci_restore_hw ! */ /* Free allocated EDs and TDs */ grub_dma_free (o->td_chunk); grub_dma_free (o->ed_bulk_chunk); grub_dma_free (o->ed_ctrl_chunk); grub_dma_free (o->hcca_chunk); #endif } grub_millisleep (10); return GRUB_ERR_NONE; } static grub_err_t grub_ohci_restore_hw (void) { struct grub_ohci *o; for (o = ohci; o; o = o->next) { grub_ohci_writereg32 (o, GRUB_OHCI_REG_HCCA, o->hcca_addr); o->hcca->donehead = 0; grub_ohci_writereg32 (o, GRUB_OHCI_REG_INTSTATUS, 0x7f); /* Clears everything */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROLHEAD, o->ed_ctrl_addr); grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROLCURR, 0); grub_ohci_writereg32 (o, GRUB_OHCI_REG_BULKHEAD, o->ed_bulk_addr); grub_ohci_writereg32 (o, GRUB_OHCI_REG_BULKCURR, 0); /* Read back of register should ensure it is really written */ grub_ohci_readreg32 (o, GRUB_OHCI_REG_INTSTATUS); /* Enable the OHCI. */ grub_ohci_writereg32 (o, GRUB_OHCI_REG_CONTROL, (2 << 6) | GRUB_OHCI_REG_CONTROL_CONTROL_ENABLE | GRUB_OHCI_REG_CONTROL_BULK_ENABLE ); } return GRUB_ERR_NONE; } static struct grub_usb_controller_dev usb_controller = { .name = "ohci", .iterate = grub_ohci_iterate, .transfer = grub_ohci_transfer, .hubports = grub_ohci_hubports, .portstatus = grub_ohci_portstatus, .detect_dev = grub_ohci_detect_dev }; GRUB_MOD_INIT(ohci) { grub_ohci_inithw (); grub_usb_controller_dev_register (&usb_controller); grub_loader_register_preboot_hook (grub_ohci_fini_hw, grub_ohci_restore_hw, GRUB_LOADER_PREBOOT_HOOK_PRIO_DISK); } GRUB_MOD_FINI(ohci) { grub_ohci_fini_hw (0); grub_usb_controller_dev_unregister (&usb_controller); }