/* * QEMU USB OHCI Emulation * Copyright (c) 2004 Gianni Tedesco * Copyright (c) 2006 CodeSourcery * Copyright (c) 2006 Openedhand Ltd. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, see . * * TODO: * o Isochronous transfers * o Allocate bandwidth in frames properly * o Disable timers when nothing needs to be done, or remove timer usage * all together. * o BIOS work to boot from USB storage */ #include "qemu/osdep.h" #include "hw/irq.h" #include "qapi/error.h" #include "qemu/module.h" #include "qemu/timer.h" #include "hw/usb.h" #include "migration/vmstate.h" #include "hw/sysbus.h" #include "hw/qdev-dma.h" #include "hw/qdev-properties.h" #include "trace.h" #include "hcd-ohci.h" /* This causes frames to occur 1000x slower */ /*#define OHCI_TIME_WARP 1*/ #define ED_LINK_LIMIT 32 static int64_t usb_frame_time; static int64_t usb_bit_time; /* Host Controller Communications Area */ struct ohci_hcca { uint32_t intr[32]; uint16_t frame, pad; uint32_t done; }; #define HCCA_WRITEBACK_OFFSET offsetof(struct ohci_hcca, frame) #define HCCA_WRITEBACK_SIZE 8 /* frame, pad, done */ #define ED_WBACK_OFFSET offsetof(struct ohci_ed, head) #define ED_WBACK_SIZE 4 /* Bitfields for the first word of an Endpoint Desciptor. */ #define OHCI_ED_FA_SHIFT 0 #define OHCI_ED_FA_MASK (0x7f << OHCI_ED_FA_SHIFT) #define OHCI_ED_EN_SHIFT 7 #define OHCI_ED_EN_MASK (0xf << OHCI_ED_EN_SHIFT) #define OHCI_ED_D_SHIFT 11 #define OHCI_ED_D_MASK (3 << OHCI_ED_D_SHIFT) #define OHCI_ED_S (1 << 13) #define OHCI_ED_K (1 << 14) #define OHCI_ED_F (1 << 15) #define OHCI_ED_MPS_SHIFT 16 #define OHCI_ED_MPS_MASK (0x7ff << OHCI_ED_MPS_SHIFT) /* Flags in the head field of an Endpoint Desciptor. */ #define OHCI_ED_H 1 #define OHCI_ED_C 2 /* Bitfields for the first word of a Transfer Desciptor. */ #define OHCI_TD_R (1 << 18) #define OHCI_TD_DP_SHIFT 19 #define OHCI_TD_DP_MASK (3 << OHCI_TD_DP_SHIFT) #define OHCI_TD_DI_SHIFT 21 #define OHCI_TD_DI_MASK (7 << OHCI_TD_DI_SHIFT) #define OHCI_TD_T0 (1 << 24) #define OHCI_TD_T1 (1 << 25) #define OHCI_TD_EC_SHIFT 26 #define OHCI_TD_EC_MASK (3 << OHCI_TD_EC_SHIFT) #define OHCI_TD_CC_SHIFT 28 #define OHCI_TD_CC_MASK (0xf << OHCI_TD_CC_SHIFT) /* Bitfields for the first word of an Isochronous Transfer Desciptor. */ /* CC & DI - same as in the General Transfer Desciptor */ #define OHCI_TD_SF_SHIFT 0 #define OHCI_TD_SF_MASK (0xffff << OHCI_TD_SF_SHIFT) #define OHCI_TD_FC_SHIFT 24 #define OHCI_TD_FC_MASK (7 << OHCI_TD_FC_SHIFT) /* Isochronous Transfer Desciptor - Offset / PacketStatusWord */ #define OHCI_TD_PSW_CC_SHIFT 12 #define OHCI_TD_PSW_CC_MASK (0xf << OHCI_TD_PSW_CC_SHIFT) #define OHCI_TD_PSW_SIZE_SHIFT 0 #define OHCI_TD_PSW_SIZE_MASK (0xfff << OHCI_TD_PSW_SIZE_SHIFT) #define OHCI_PAGE_MASK 0xfffff000 #define OHCI_OFFSET_MASK 0xfff #define OHCI_DPTR_MASK 0xfffffff0 #define OHCI_BM(val, field) \ (((val) & OHCI_##field##_MASK) >> OHCI_##field##_SHIFT) #define OHCI_SET_BM(val, field, newval) do { \ val &= ~OHCI_##field##_MASK; \ val |= ((newval) << OHCI_##field##_SHIFT) & OHCI_##field##_MASK; \ } while (0) /* endpoint descriptor */ struct ohci_ed { uint32_t flags; uint32_t tail; uint32_t head; uint32_t next; }; /* General transfer descriptor */ struct ohci_td { uint32_t flags; uint32_t cbp; uint32_t next; uint32_t be; }; /* Isochronous transfer descriptor */ struct ohci_iso_td { uint32_t flags; uint32_t bp; uint32_t next; uint32_t be; uint16_t offset[8]; }; #define USB_HZ 12000000 /* OHCI Local stuff */ #define OHCI_CTL_CBSR ((1 << 0) | (1 << 1)) #define OHCI_CTL_PLE (1 << 2) #define OHCI_CTL_IE (1 << 3) #define OHCI_CTL_CLE (1 << 4) #define OHCI_CTL_BLE (1 << 5) #define OHCI_CTL_HCFS ((1 << 6) | (1 << 7)) #define OHCI_USB_RESET 0x00 #define OHCI_USB_RESUME 0x40 #define OHCI_USB_OPERATIONAL 0x80 #define OHCI_USB_SUSPEND 0xc0 #define OHCI_CTL_IR (1 << 8) #define OHCI_CTL_RWC (1 << 9) #define OHCI_CTL_RWE (1 << 10) #define OHCI_STATUS_HCR (1 << 0) #define OHCI_STATUS_CLF (1 << 1) #define OHCI_STATUS_BLF (1 << 2) #define OHCI_STATUS_OCR (1 << 3) #define OHCI_STATUS_SOC ((1 << 6) | (1 << 7)) #define OHCI_INTR_SO (1U << 0) /* Scheduling overrun */ #define OHCI_INTR_WD (1U << 1) /* HcDoneHead writeback */ #define OHCI_INTR_SF (1U << 2) /* Start of frame */ #define OHCI_INTR_RD (1U << 3) /* Resume detect */ #define OHCI_INTR_UE (1U << 4) /* Unrecoverable error */ #define OHCI_INTR_FNO (1U << 5) /* Frame number overflow */ #define OHCI_INTR_RHSC (1U << 6) /* Root hub status change */ #define OHCI_INTR_OC (1U << 30) /* Ownership change */ #define OHCI_INTR_MIE (1U << 31) /* Master Interrupt Enable */ #define OHCI_HCCA_SIZE 0x100 #define OHCI_HCCA_MASK 0xffffff00 #define OHCI_EDPTR_MASK 0xfffffff0 #define OHCI_FMI_FI 0x00003fff #define OHCI_FMI_FSMPS 0xffff0000 #define OHCI_FMI_FIT 0x80000000 #define OHCI_FR_RT (1U << 31) #define OHCI_LS_THRESH 0x628 #define OHCI_RHA_RW_MASK 0x00000000 /* Mask of supported features. */ #define OHCI_RHA_PSM (1 << 8) #define OHCI_RHA_NPS (1 << 9) #define OHCI_RHA_DT (1 << 10) #define OHCI_RHA_OCPM (1 << 11) #define OHCI_RHA_NOCP (1 << 12) #define OHCI_RHA_POTPGT_MASK 0xff000000 #define OHCI_RHS_LPS (1U << 0) #define OHCI_RHS_OCI (1U << 1) #define OHCI_RHS_DRWE (1U << 15) #define OHCI_RHS_LPSC (1U << 16) #define OHCI_RHS_OCIC (1U << 17) #define OHCI_RHS_CRWE (1U << 31) #define OHCI_PORT_CCS (1 << 0) #define OHCI_PORT_PES (1 << 1) #define OHCI_PORT_PSS (1 << 2) #define OHCI_PORT_POCI (1 << 3) #define OHCI_PORT_PRS (1 << 4) #define OHCI_PORT_PPS (1 << 8) #define OHCI_PORT_LSDA (1 << 9) #define OHCI_PORT_CSC (1 << 16) #define OHCI_PORT_PESC (1 << 17) #define OHCI_PORT_PSSC (1 << 18) #define OHCI_PORT_OCIC (1 << 19) #define OHCI_PORT_PRSC (1 << 20) #define OHCI_PORT_WTC (OHCI_PORT_CSC | OHCI_PORT_PESC | \ OHCI_PORT_PSSC | OHCI_PORT_OCIC | \ OHCI_PORT_PRSC) #define OHCI_TD_DIR_SETUP 0x0 #define OHCI_TD_DIR_OUT 0x1 #define OHCI_TD_DIR_IN 0x2 #define OHCI_TD_DIR_RESERVED 0x3 #define OHCI_CC_NOERROR 0x0 #define OHCI_CC_CRC 0x1 #define OHCI_CC_BITSTUFFING 0x2 #define OHCI_CC_DATATOGGLEMISMATCH 0x3 #define OHCI_CC_STALL 0x4 #define OHCI_CC_DEVICENOTRESPONDING 0x5 #define OHCI_CC_PIDCHECKFAILURE 0x6 #define OHCI_CC_UNDEXPETEDPID 0x7 #define OHCI_CC_DATAOVERRUN 0x8 #define OHCI_CC_DATAUNDERRUN 0x9 #define OHCI_CC_BUFFEROVERRUN 0xc #define OHCI_CC_BUFFERUNDERRUN 0xd #define OHCI_HRESET_FSBIR (1 << 0) static const char *ohci_reg_names[] = { "HcRevision", "HcControl", "HcCommandStatus", "HcInterruptStatus", "HcInterruptEnable", "HcInterruptDisable", "HcHCCA", "HcPeriodCurrentED", "HcControlHeadED", "HcControlCurrentED", "HcBulkHeadED", "HcBulkCurrentED", "HcDoneHead", "HcFmInterval", "HcFmRemaining", "HcFmNumber", "HcPeriodicStart", "HcLSThreshold", "HcRhDescriptorA", "HcRhDescriptorB", "HcRhStatus" }; static const char *ohci_reg_name(hwaddr addr) { if (addr >> 2 < ARRAY_SIZE(ohci_reg_names)) { return ohci_reg_names[addr >> 2]; } else { return ""; } } static void ohci_die(OHCIState *ohci) { ohci->ohci_die(ohci); } /* Update IRQ levels */ static inline void ohci_intr_update(OHCIState *ohci) { int level = 0; if ((ohci->intr & OHCI_INTR_MIE) && (ohci->intr_status & ohci->intr)) level = 1; qemu_set_irq(ohci->irq, level); } /* Set an interrupt */ static inline void ohci_set_interrupt(OHCIState *ohci, uint32_t intr) { ohci->intr_status |= intr; ohci_intr_update(ohci); } static USBDevice *ohci_find_device(OHCIState *ohci, uint8_t addr) { USBDevice *dev; int i; for (i = 0; i < ohci->num_ports; i++) { if ((ohci->rhport[i].ctrl & OHCI_PORT_PES) == 0) { continue; } dev = usb_find_device(&ohci->rhport[i].port, addr); if (dev != NULL) { return dev; } } return NULL; } void ohci_stop_endpoints(OHCIState *ohci) { USBDevice *dev; int i, j; if (ohci->async_td) { usb_cancel_packet(&ohci->usb_packet); ohci->async_td = 0; } for (i = 0; i < ohci->num_ports; i++) { dev = ohci->rhport[i].port.dev; if (dev && dev->attached) { usb_device_ep_stopped(dev, &dev->ep_ctl); for (j = 0; j < USB_MAX_ENDPOINTS; j++) { usb_device_ep_stopped(dev, &dev->ep_in[j]); usb_device_ep_stopped(dev, &dev->ep_out[j]); } } } } static void ohci_roothub_reset(OHCIState *ohci) { OHCIPort *port; int i; ohci_bus_stop(ohci); ohci->rhdesc_a = OHCI_RHA_NPS | ohci->num_ports; ohci->rhdesc_b = 0x0; /* Impl. specific */ ohci->rhstatus = 0; for (i = 0; i < ohci->num_ports; i++) { port = &ohci->rhport[i]; port->ctrl = 0; if (port->port.dev && port->port.dev->attached) { usb_port_reset(&port->port); } } ohci_stop_endpoints(ohci); } /* Reset the controller */ static void ohci_soft_reset(OHCIState *ohci) { trace_usb_ohci_reset(ohci->name); ohci_bus_stop(ohci); ohci->ctl = (ohci->ctl & OHCI_CTL_IR) | OHCI_USB_SUSPEND; ohci->old_ctl = 0; ohci->status = 0; ohci->intr_status = 0; ohci->intr = OHCI_INTR_MIE; ohci->hcca = 0; ohci->ctrl_head = ohci->ctrl_cur = 0; ohci->bulk_head = ohci->bulk_cur = 0; ohci->per_cur = 0; ohci->done = 0; ohci->done_count = 7; /* * FSMPS is marked TBD in OCHI 1.0, what gives ffs? * I took the value linux sets ... */ ohci->fsmps = 0x2778; ohci->fi = 0x2edf; ohci->fit = 0; ohci->frt = 0; ohci->frame_number = 0; ohci->pstart = 0; ohci->lst = OHCI_LS_THRESH; } void ohci_hard_reset(OHCIState *ohci) { ohci_soft_reset(ohci); ohci->ctl = 0; ohci_roothub_reset(ohci); } /* Get an array of dwords from main memory */ static inline int get_dwords(OHCIState *ohci, dma_addr_t addr, uint32_t *buf, int num) { int i; addr += ohci->localmem_base; for (i = 0; i < num; i++, buf++, addr += sizeof(*buf)) { if (dma_memory_read(ohci->as, addr, buf, sizeof(*buf), MEMTXATTRS_UNSPECIFIED)) { return -1; } *buf = le32_to_cpu(*buf); } return 0; } /* Put an array of dwords in to main memory */ static inline int put_dwords(OHCIState *ohci, dma_addr_t addr, uint32_t *buf, int num) { int i; addr += ohci->localmem_base; for (i = 0; i < num; i++, buf++, addr += sizeof(*buf)) { uint32_t tmp = cpu_to_le32(*buf); if (dma_memory_write(ohci->as, addr, &tmp, sizeof(tmp), MEMTXATTRS_UNSPECIFIED)) { return -1; } } return 0; } /* Get an array of words from main memory */ static inline int get_words(OHCIState *ohci, dma_addr_t addr, uint16_t *buf, int num) { int i; addr += ohci->localmem_base; for (i = 0; i < num; i++, buf++, addr += sizeof(*buf)) { if (dma_memory_read(ohci->as, addr, buf, sizeof(*buf), MEMTXATTRS_UNSPECIFIED)) { return -1; } *buf = le16_to_cpu(*buf); } return 0; } /* Put an array of words in to main memory */ static inline int put_words(OHCIState *ohci, dma_addr_t addr, uint16_t *buf, int num) { int i; addr += ohci->localmem_base; for (i = 0; i < num; i++, buf++, addr += sizeof(*buf)) { uint16_t tmp = cpu_to_le16(*buf); if (dma_memory_write(ohci->as, addr, &tmp, sizeof(tmp), MEMTXATTRS_UNSPECIFIED)) { return -1; } } return 0; } static inline int ohci_read_ed(OHCIState *ohci, dma_addr_t addr, struct ohci_ed *ed) { return get_dwords(ohci, addr, (uint32_t *)ed, sizeof(*ed) >> 2); } static inline int ohci_read_td(OHCIState *ohci, dma_addr_t addr, struct ohci_td *td) { return get_dwords(ohci, addr, (uint32_t *)td, sizeof(*td) >> 2); } static inline int ohci_read_iso_td(OHCIState *ohci, dma_addr_t addr, struct ohci_iso_td *td) { return get_dwords(ohci, addr, (uint32_t *)td, 4) || get_words(ohci, addr + 16, td->offset, 8); } static inline int ohci_read_hcca(OHCIState *ohci, dma_addr_t addr, struct ohci_hcca *hcca) { return dma_memory_read(ohci->as, addr + ohci->localmem_base, hcca, sizeof(*hcca), MEMTXATTRS_UNSPECIFIED); } static inline int ohci_put_ed(OHCIState *ohci, dma_addr_t addr, struct ohci_ed *ed) { /* * ed->tail is under control of the HCD. * Since just ed->head is changed by HC, just write back this */ return put_dwords(ohci, addr + ED_WBACK_OFFSET, (uint32_t *)((char *)ed + ED_WBACK_OFFSET), ED_WBACK_SIZE >> 2); } static inline int ohci_put_td(OHCIState *ohci, dma_addr_t addr, struct ohci_td *td) { return put_dwords(ohci, addr, (uint32_t *)td, sizeof(*td) >> 2); } static inline int ohci_put_iso_td(OHCIState *ohci, dma_addr_t addr, struct ohci_iso_td *td) { return put_dwords(ohci, addr, (uint32_t *)td, 4) || put_words(ohci, addr + 16, td->offset, 8); } static inline int ohci_put_hcca(OHCIState *ohci, dma_addr_t addr, struct ohci_hcca *hcca) { return dma_memory_write(ohci->as, addr + ohci->localmem_base + HCCA_WRITEBACK_OFFSET, (char *)hcca + HCCA_WRITEBACK_OFFSET, HCCA_WRITEBACK_SIZE, MEMTXATTRS_UNSPECIFIED); } /* Read/Write the contents of a TD from/to main memory. */ static int ohci_copy_td(OHCIState *ohci, struct ohci_td *td, uint8_t *buf, int len, DMADirection dir) { dma_addr_t ptr, n; ptr = td->cbp; n = 0x1000 - (ptr & 0xfff); if (n > len) { n = len; } if (dma_memory_rw(ohci->as, ptr + ohci->localmem_base, buf, n, dir, MEMTXATTRS_UNSPECIFIED)) { return -1; } if (n == len) { return 0; } ptr = td->be & ~0xfffu; buf += n; if (dma_memory_rw(ohci->as, ptr + ohci->localmem_base, buf, len - n, dir, MEMTXATTRS_UNSPECIFIED)) { return -1; } return 0; } /* Read/Write the contents of an ISO TD from/to main memory. */ static int ohci_copy_iso_td(OHCIState *ohci, uint32_t start_addr, uint32_t end_addr, uint8_t *buf, int len, DMADirection dir) { dma_addr_t ptr, n; ptr = start_addr; n = 0x1000 - (ptr & 0xfff); if (n > len) { n = len; } if (dma_memory_rw(ohci->as, ptr + ohci->localmem_base, buf, n, dir, MEMTXATTRS_UNSPECIFIED)) { return -1; } if (n == len) { return 0; } ptr = end_addr & ~0xfffu; buf += n; if (dma_memory_rw(ohci->as, ptr + ohci->localmem_base, buf, len - n, dir, MEMTXATTRS_UNSPECIFIED)) { return -1; } return 0; } #define USUB(a, b) ((int16_t)((uint16_t)(a) - (uint16_t)(b))) static int ohci_service_iso_td(OHCIState *ohci, struct ohci_ed *ed) { int dir; size_t len = 0; const char *str = NULL; int pid; int ret; int i; USBDevice *dev; USBEndpoint *ep; USBPacket *pkt; uint8_t buf[8192]; bool int_req; struct ohci_iso_td iso_td; uint32_t addr; uint16_t starting_frame; int16_t relative_frame_number; int frame_count; uint32_t start_offset, next_offset, end_offset = 0; uint32_t start_addr, end_addr; addr = ed->head & OHCI_DPTR_MASK; if (addr == 0) { ohci_die(ohci); return 1; } if (ohci_read_iso_td(ohci, addr, &iso_td)) { trace_usb_ohci_iso_td_read_failed(addr); ohci_die(ohci); return 1; } starting_frame = OHCI_BM(iso_td.flags, TD_SF); frame_count = OHCI_BM(iso_td.flags, TD_FC); relative_frame_number = USUB(ohci->frame_number, starting_frame); trace_usb_ohci_iso_td_head( ed->head & OHCI_DPTR_MASK, ed->tail & OHCI_DPTR_MASK, iso_td.flags, iso_td.bp, iso_td.next, iso_td.be, ohci->frame_number, starting_frame, frame_count, relative_frame_number); trace_usb_ohci_iso_td_head_offset( iso_td.offset[0], iso_td.offset[1], iso_td.offset[2], iso_td.offset[3], iso_td.offset[4], iso_td.offset[5], iso_td.offset[6], iso_td.offset[7]); if (relative_frame_number < 0) { trace_usb_ohci_iso_td_relative_frame_number_neg(relative_frame_number); return 1; } else if (relative_frame_number > frame_count) { /* * ISO TD expired - retire the TD to the Done Queue and continue with * the next ISO TD of the same ED */ trace_usb_ohci_iso_td_relative_frame_number_big(relative_frame_number, frame_count); if (OHCI_CC_DATAOVERRUN == OHCI_BM(iso_td.flags, TD_CC)) { /* avoid infinite loop */ return 1; } OHCI_SET_BM(iso_td.flags, TD_CC, OHCI_CC_DATAOVERRUN); ed->head &= ~OHCI_DPTR_MASK; ed->head |= (iso_td.next & OHCI_DPTR_MASK); iso_td.next = ohci->done; ohci->done = addr; i = OHCI_BM(iso_td.flags, TD_DI); if (i < ohci->done_count) { ohci->done_count = i; } if (ohci_put_iso_td(ohci, addr, &iso_td)) { ohci_die(ohci); return 1; } return 0; } dir = OHCI_BM(ed->flags, ED_D); switch (dir) { case OHCI_TD_DIR_IN: str = "in"; pid = USB_TOKEN_IN; break; case OHCI_TD_DIR_OUT: str = "out"; pid = USB_TOKEN_OUT; break; case OHCI_TD_DIR_SETUP: str = "setup"; pid = USB_TOKEN_SETUP; break; default: trace_usb_ohci_iso_td_bad_direction(dir); return 1; } if (!iso_td.bp || !iso_td.be) { trace_usb_ohci_iso_td_bad_bp_be(iso_td.bp, iso_td.be); return 1; } start_offset = iso_td.offset[relative_frame_number]; if (relative_frame_number < frame_count) { next_offset = iso_td.offset[relative_frame_number + 1]; } else { next_offset = iso_td.be; } if (!(OHCI_BM(start_offset, TD_PSW_CC) & 0xe) || ((relative_frame_number < frame_count) && !(OHCI_BM(next_offset, TD_PSW_CC) & 0xe))) { trace_usb_ohci_iso_td_bad_cc_not_accessed(start_offset, next_offset); return 1; } if ((relative_frame_number < frame_count) && (start_offset > next_offset)) { trace_usb_ohci_iso_td_bad_cc_overrun(start_offset, next_offset); return 1; } if ((start_offset & 0x1000) == 0) { start_addr = (iso_td.bp & OHCI_PAGE_MASK) | (start_offset & OHCI_OFFSET_MASK); } else { start_addr = (iso_td.be & OHCI_PAGE_MASK) | (start_offset & OHCI_OFFSET_MASK); } if (relative_frame_number < frame_count) { end_offset = next_offset - 1; if ((end_offset & 0x1000) == 0) { end_addr = (iso_td.bp & OHCI_PAGE_MASK) | (end_offset & OHCI_OFFSET_MASK); } else { end_addr = (iso_td.be & OHCI_PAGE_MASK) | (end_offset & OHCI_OFFSET_MASK); } } else { /* Last packet in the ISO TD */ end_addr = next_offset; } if (start_addr > end_addr) { trace_usb_ohci_iso_td_bad_cc_overrun(start_addr, end_addr); return 1; } if ((start_addr & OHCI_PAGE_MASK) != (end_addr & OHCI_PAGE_MASK)) { len = (end_addr & OHCI_OFFSET_MASK) + 0x1001 - (start_addr & OHCI_OFFSET_MASK); } else { len = end_addr - start_addr + 1; } if (len > sizeof(buf)) { len = sizeof(buf); } if (len && dir != OHCI_TD_DIR_IN) { if (ohci_copy_iso_td(ohci, start_addr, end_addr, buf, len, DMA_DIRECTION_TO_DEVICE)) { ohci_die(ohci); return 1; } } dev = ohci_find_device(ohci, OHCI_BM(ed->flags, ED_FA)); if (dev == NULL) { trace_usb_ohci_td_dev_error(); return 1; } ep = usb_ep_get(dev, pid, OHCI_BM(ed->flags, ED_EN)); pkt = g_new0(USBPacket, 1); usb_packet_init(pkt); int_req = relative_frame_number == frame_count && OHCI_BM(iso_td.flags, TD_DI) == 0; usb_packet_setup(pkt, pid, ep, 0, addr, false, int_req); usb_packet_addbuf(pkt, buf, len); usb_handle_packet(dev, pkt); if (pkt->status == USB_RET_ASYNC) { usb_device_flush_ep_queue(dev, ep); g_free(pkt); return 1; } if (pkt->status == USB_RET_SUCCESS) { ret = pkt->actual_length; } else { ret = pkt->status; } g_free(pkt); trace_usb_ohci_iso_td_so(start_offset, end_offset, start_addr, end_addr, str, len, ret); /* Writeback */ if (dir == OHCI_TD_DIR_IN && ret >= 0 && ret <= len) { /* IN transfer succeeded */ if (ohci_copy_iso_td(ohci, start_addr, end_addr, buf, ret, DMA_DIRECTION_FROM_DEVICE)) { ohci_die(ohci); return 1; } OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_CC, OHCI_CC_NOERROR); OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_SIZE, ret); } else if (dir == OHCI_TD_DIR_OUT && ret == len) { /* OUT transfer succeeded */ OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_CC, OHCI_CC_NOERROR); OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_SIZE, 0); } else { if (ret > (ssize_t) len) { trace_usb_ohci_iso_td_data_overrun(ret, len); OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_CC, OHCI_CC_DATAOVERRUN); OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_SIZE, len); } else if (ret >= 0) { trace_usb_ohci_iso_td_data_underrun(ret); OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_CC, OHCI_CC_DATAUNDERRUN); } else { switch (ret) { case USB_RET_IOERROR: case USB_RET_NODEV: OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_CC, OHCI_CC_DEVICENOTRESPONDING); OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_SIZE, 0); break; case USB_RET_NAK: case USB_RET_STALL: trace_usb_ohci_iso_td_nak(ret); OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_CC, OHCI_CC_STALL); OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_SIZE, 0); break; default: trace_usb_ohci_iso_td_bad_response(ret); OHCI_SET_BM(iso_td.offset[relative_frame_number], TD_PSW_CC, OHCI_CC_UNDEXPETEDPID); break; } } } if (relative_frame_number == frame_count) { /* Last data packet of ISO TD - retire the TD to the Done Queue */ OHCI_SET_BM(iso_td.flags, TD_CC, OHCI_CC_NOERROR); ed->head &= ~OHCI_DPTR_MASK; ed->head |= (iso_td.next & OHCI_DPTR_MASK); iso_td.next = ohci->done; ohci->done = addr; i = OHCI_BM(iso_td.flags, TD_DI); if (i < ohci->done_count) { ohci->done_count = i; } } if (ohci_put_iso_td(ohci, addr, &iso_td)) { ohci_die(ohci); } return 1; } #define HEX_CHAR_PER_LINE 16 static void ohci_td_pkt(const char *msg, const uint8_t *buf, size_t len) { bool print16; bool printall; int i; char tmp[3 * HEX_CHAR_PER_LINE + 1]; char *p = tmp; print16 = !!trace_event_get_state_backends(TRACE_USB_OHCI_TD_PKT_SHORT); printall = !!trace_event_get_state_backends(TRACE_USB_OHCI_TD_PKT_FULL); if (!printall && !print16) { return; } for (i = 0; ; i++) { if (i && (!(i % HEX_CHAR_PER_LINE) || (i == len))) { if (!printall) { trace_usb_ohci_td_pkt_short(msg, tmp); break; } trace_usb_ohci_td_pkt_full(msg, tmp); p = tmp; *p = 0; } if (i == len) { break; } p += sprintf(p, " %.2x", buf[i]); } } /* * Service a transport descriptor. * Returns nonzero to terminate processing of this endpoint. */ static int ohci_service_td(OHCIState *ohci, struct ohci_ed *ed) { int dir; size_t len = 0, pktlen = 0; const char *str = NULL; int pid; int ret; int i; USBDevice *dev; USBEndpoint *ep; struct ohci_td td; uint32_t addr; int flag_r; int completion; addr = ed->head & OHCI_DPTR_MASK; if (addr == 0) { ohci_die(ohci); return 1; } /* See if this TD has already been submitted to the device. */ completion = (addr == ohci->async_td); if (completion && !ohci->async_complete) { trace_usb_ohci_td_skip_async(); return 1; } if (ohci_read_td(ohci, addr, &td)) { trace_usb_ohci_td_read_error(addr); ohci_die(ohci); return 1; } dir = OHCI_BM(ed->flags, ED_D); switch (dir) { case OHCI_TD_DIR_OUT: case OHCI_TD_DIR_IN: /* Same value. */ break; default: dir = OHCI_BM(td.flags, TD_DP); break; } switch (dir) { case OHCI_TD_DIR_IN: str = "in"; pid = USB_TOKEN_IN; break; case OHCI_TD_DIR_OUT: str = "out"; pid = USB_TOKEN_OUT; break; case OHCI_TD_DIR_SETUP: str = "setup"; pid = USB_TOKEN_SETUP; break; default: trace_usb_ohci_td_bad_direction(dir); return 1; } if (td.cbp && td.be) { if ((td.cbp & 0xfffff000) != (td.be & 0xfffff000)) { len = (td.be & 0xfff) + 0x1001 - (td.cbp & 0xfff); } else { if (td.cbp > td.be) { trace_usb_ohci_iso_td_bad_cc_overrun(td.cbp, td.be); ohci_die(ohci); return 1; } len = (td.be - td.cbp) + 1; } if (len > sizeof(ohci->usb_buf)) { len = sizeof(ohci->usb_buf); } pktlen = len; if (len && dir != OHCI_TD_DIR_IN) { /* The endpoint may not allow us to transfer it all now */ pktlen = (ed->flags & OHCI_ED_MPS_MASK) >> OHCI_ED_MPS_SHIFT; if (pktlen > len) { pktlen = len; } if (!completion) { if (ohci_copy_td(ohci, &td, ohci->usb_buf, pktlen, DMA_DIRECTION_TO_DEVICE)) { ohci_die(ohci); } } } } flag_r = (td.flags & OHCI_TD_R) != 0; trace_usb_ohci_td_pkt_hdr(addr, (int64_t)pktlen, (int64_t)len, str, flag_r, td.cbp, td.be); ohci_td_pkt("OUT", ohci->usb_buf, pktlen); if (completion) { ohci->async_td = 0; ohci->async_complete = false; } else { dev = ohci_find_device(ohci, OHCI_BM(ed->flags, ED_FA)); if (dev == NULL) { trace_usb_ohci_td_dev_error(); return 1; } ep = usb_ep_get(dev, pid, OHCI_BM(ed->flags, ED_EN)); if (ohci->async_td) { /* * ??? The hardware should allow one active packet per * endpoint. We only allow one active packet per controller. * This should be sufficient as long as devices respond in a * timely manner. */ trace_usb_ohci_td_too_many_pending(ep->nr); return 1; } usb_packet_setup(&ohci->usb_packet, pid, ep, 0, addr, !flag_r, OHCI_BM(td.flags, TD_DI) == 0); usb_packet_addbuf(&ohci->usb_packet, ohci->usb_buf, pktlen); usb_handle_packet(dev, &ohci->usb_packet); trace_usb_ohci_td_packet_status(ohci->usb_packet.status); if (ohci->usb_packet.status == USB_RET_ASYNC) { usb_device_flush_ep_queue(dev, ep); ohci->async_td = addr; return 1; } } if (ohci->usb_packet.status == USB_RET_SUCCESS) { ret = ohci->usb_packet.actual_length; } else { ret = ohci->usb_packet.status; } if (ret >= 0) { if (dir == OHCI_TD_DIR_IN) { if (ohci_copy_td(ohci, &td, ohci->usb_buf, ret, DMA_DIRECTION_FROM_DEVICE)) { ohci_die(ohci); } ohci_td_pkt("IN", ohci->usb_buf, pktlen); } else { ret = pktlen; } } /* Writeback */ if (ret == pktlen || (dir == OHCI_TD_DIR_IN && ret >= 0 && flag_r)) { /* Transmission succeeded. */ if (ret == len) { td.cbp = 0; } else { if ((td.cbp & 0xfff) + ret > 0xfff) { td.cbp = (td.be & ~0xfff) + ((td.cbp + ret) & 0xfff); } else { td.cbp += ret; } } td.flags |= OHCI_TD_T1; td.flags ^= OHCI_TD_T0; OHCI_SET_BM(td.flags, TD_CC, OHCI_CC_NOERROR); OHCI_SET_BM(td.flags, TD_EC, 0); if ((dir != OHCI_TD_DIR_IN) && (ret != len)) { /* Partial packet transfer: TD not ready to retire yet */ goto exit_no_retire; } /* Setting ED_C is part of the TD retirement process */ ed->head &= ~OHCI_ED_C; if (td.flags & OHCI_TD_T0) { ed->head |= OHCI_ED_C; } } else { if (ret >= 0) { trace_usb_ohci_td_underrun(); OHCI_SET_BM(td.flags, TD_CC, OHCI_CC_DATAUNDERRUN); } else { switch (ret) { case USB_RET_IOERROR: case USB_RET_NODEV: trace_usb_ohci_td_dev_error(); OHCI_SET_BM(td.flags, TD_CC, OHCI_CC_DEVICENOTRESPONDING); break; case USB_RET_NAK: trace_usb_ohci_td_nak(); return 1; case USB_RET_STALL: trace_usb_ohci_td_stall(); OHCI_SET_BM(td.flags, TD_CC, OHCI_CC_STALL); break; case USB_RET_BABBLE: trace_usb_ohci_td_babble(); OHCI_SET_BM(td.flags, TD_CC, OHCI_CC_DATAOVERRUN); break; default: trace_usb_ohci_td_bad_device_response(ret); OHCI_SET_BM(td.flags, TD_CC, OHCI_CC_UNDEXPETEDPID); OHCI_SET_BM(td.flags, TD_EC, 3); break; } /* * An error occurred so we have to clear the interrupt counter. * See spec at 6.4.4 on page 104 */ ohci->done_count = 0; } ed->head |= OHCI_ED_H; } /* Retire this TD */ ed->head &= ~OHCI_DPTR_MASK; ed->head |= td.next & OHCI_DPTR_MASK; td.next = ohci->done; ohci->done = addr; i = OHCI_BM(td.flags, TD_DI); if (i < ohci->done_count) { ohci->done_count = i; } exit_no_retire: if (ohci_put_td(ohci, addr, &td)) { ohci_die(ohci); return 1; } return OHCI_BM(td.flags, TD_CC) != OHCI_CC_NOERROR; } /* Service an endpoint list. Returns nonzero if active TD were found. */ static int ohci_service_ed_list(OHCIState *ohci, uint32_t head) { struct ohci_ed ed; uint32_t next_ed; uint32_t cur; int active; uint32_t link_cnt = 0; active = 0; if (head == 0) { return 0; } for (cur = head; cur && link_cnt++ < ED_LINK_LIMIT; cur = next_ed) { if (ohci_read_ed(ohci, cur, &ed)) { trace_usb_ohci_ed_read_error(cur); ohci_die(ohci); return 0; } next_ed = ed.next & OHCI_DPTR_MASK; if ((ed.head & OHCI_ED_H) || (ed.flags & OHCI_ED_K)) { uint32_t addr; /* Cancel pending packets for ED that have been paused. */ addr = ed.head & OHCI_DPTR_MASK; if (ohci->async_td && addr == ohci->async_td) { usb_cancel_packet(&ohci->usb_packet); ohci->async_td = 0; usb_device_ep_stopped(ohci->usb_packet.ep->dev, ohci->usb_packet.ep); } continue; } while ((ed.head & OHCI_DPTR_MASK) != ed.tail) { trace_usb_ohci_ed_pkt(cur, (ed.head & OHCI_ED_H) != 0, (ed.head & OHCI_ED_C) != 0, ed.head & OHCI_DPTR_MASK, ed.tail & OHCI_DPTR_MASK, ed.next & OHCI_DPTR_MASK); trace_usb_ohci_ed_pkt_flags( OHCI_BM(ed.flags, ED_FA), OHCI_BM(ed.flags, ED_EN), OHCI_BM(ed.flags, ED_D), (ed.flags & OHCI_ED_S) != 0, (ed.flags & OHCI_ED_K) != 0, (ed.flags & OHCI_ED_F) != 0, OHCI_BM(ed.flags, ED_MPS)); active = 1; if ((ed.flags & OHCI_ED_F) == 0) { if (ohci_service_td(ohci, &ed)) { break; } } else { /* Handle isochronous endpoints */ if (ohci_service_iso_td(ohci, &ed)) { break; } } } if (ohci_put_ed(ohci, cur, &ed)) { ohci_die(ohci); return 0; } } return active; } /* set a timer for EOF */ static void ohci_eof_timer(OHCIState *ohci) { timer_mod(ohci->eof_timer, ohci->sof_time + usb_frame_time); } /* Set a timer for EOF and generate a SOF event */ static void ohci_sof(OHCIState *ohci) { ohci->sof_time += usb_frame_time; ohci_eof_timer(ohci); ohci_set_interrupt(ohci, OHCI_INTR_SF); } /* Process Control and Bulk lists. */ static void ohci_process_lists(OHCIState *ohci) { if ((ohci->ctl & OHCI_CTL_CLE) && (ohci->status & OHCI_STATUS_CLF)) { if (ohci->ctrl_cur && ohci->ctrl_cur != ohci->ctrl_head) { trace_usb_ohci_process_lists(ohci->ctrl_head, ohci->ctrl_cur); } if (!ohci_service_ed_list(ohci, ohci->ctrl_head)) { ohci->ctrl_cur = 0; ohci->status &= ~OHCI_STATUS_CLF; } } if ((ohci->ctl & OHCI_CTL_BLE) && (ohci->status & OHCI_STATUS_BLF)) { if (!ohci_service_ed_list(ohci, ohci->bulk_head)) { ohci->bulk_cur = 0; ohci->status &= ~OHCI_STATUS_BLF; } } } /* Do frame processing on frame boundary */ static void ohci_frame_boundary(void *opaque) { OHCIState *ohci = opaque; struct ohci_hcca hcca; if (ohci_read_hcca(ohci, ohci->hcca, &hcca)) { trace_usb_ohci_hcca_read_error(ohci->hcca); ohci_die(ohci); return; } /* Process all the lists at the end of the frame */ if (ohci->ctl & OHCI_CTL_PLE) { int n; n = ohci->frame_number & 0x1f; ohci_service_ed_list(ohci, le32_to_cpu(hcca.intr[n])); } /* Cancel all pending packets if either of the lists has been disabled. */ if (ohci->old_ctl & (~ohci->ctl) & (OHCI_CTL_BLE | OHCI_CTL_CLE)) { ohci_stop_endpoints(ohci); } ohci->old_ctl = ohci->ctl; ohci_process_lists(ohci); /* Stop if UnrecoverableError happened or ohci_sof will crash */ if (ohci->intr_status & OHCI_INTR_UE) { return; } /* Frame boundary, so do EOF stuf here */ ohci->frt = ohci->fit; /* Increment frame number and take care of endianness. */ ohci->frame_number = (ohci->frame_number + 1) & 0xffff; hcca.frame = cpu_to_le16(ohci->frame_number); if (ohci->done_count == 0 && !(ohci->intr_status & OHCI_INTR_WD)) { if (!ohci->done) { abort(); } if (ohci->intr & ohci->intr_status) { ohci->done |= 1; } hcca.done = cpu_to_le32(ohci->done); ohci->done = 0; ohci->done_count = 7; ohci_set_interrupt(ohci, OHCI_INTR_WD); } if (ohci->done_count != 7 && ohci->done_count != 0) { ohci->done_count--; } /* Do SOF stuff here */ ohci_sof(ohci); /* Writeback HCCA */ if (ohci_put_hcca(ohci, ohci->hcca, &hcca)) { ohci_die(ohci); } } /* * Start sending SOF tokens across the USB bus, lists are processed in * next frame */ static int ohci_bus_start(OHCIState *ohci) { trace_usb_ohci_start(ohci->name); /* * Delay the first SOF event by one frame time as linux driver is * not ready to receive it and can meet some race conditions */ ohci->sof_time = qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL); ohci_eof_timer(ohci); return 1; } /* Stop sending SOF tokens on the bus */ void ohci_bus_stop(OHCIState *ohci) { trace_usb_ohci_stop(ohci->name); timer_del(ohci->eof_timer); } /* Frame interval toggle is manipulated by the hcd only */ static void ohci_set_frame_interval(OHCIState *ohci, uint16_t val) { val &= OHCI_FMI_FI; if (val != ohci->fi) { trace_usb_ohci_set_frame_interval(ohci->name, ohci->fi, ohci->fi); } ohci->fi = val; } static void ohci_port_power(OHCIState *ohci, int i, int p) { if (p) { ohci->rhport[i].ctrl |= OHCI_PORT_PPS; } else { ohci->rhport[i].ctrl &= ~(OHCI_PORT_PPS | OHCI_PORT_CCS | OHCI_PORT_PSS | OHCI_PORT_PRS); } } /* Set HcControlRegister */ static void ohci_set_ctl(OHCIState *ohci, uint32_t val) { uint32_t old_state; uint32_t new_state; old_state = ohci->ctl & OHCI_CTL_HCFS; ohci->ctl = val; new_state = ohci->ctl & OHCI_CTL_HCFS; /* no state change */ if (old_state == new_state) { return; } trace_usb_ohci_set_ctl(ohci->name, new_state); switch (new_state) { case OHCI_USB_OPERATIONAL: ohci_bus_start(ohci); break; case OHCI_USB_SUSPEND: ohci_bus_stop(ohci); /* clear pending SF otherwise linux driver loops in ohci_irq() */ ohci->intr_status &= ~OHCI_INTR_SF; ohci_intr_update(ohci); break; case OHCI_USB_RESUME: trace_usb_ohci_resume(ohci->name); break; case OHCI_USB_RESET: ohci_roothub_reset(ohci); break; } } static uint32_t ohci_get_frame_remaining(OHCIState *ohci) { uint16_t fr; int64_t tks; if ((ohci->ctl & OHCI_CTL_HCFS) != OHCI_USB_OPERATIONAL) { return ohci->frt << 31; } /* Being in USB operational state guarnatees sof_time was set already. */ tks = qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL) - ohci->sof_time; if (tks < 0) { tks = 0; } /* avoid muldiv if possible */ if (tks >= usb_frame_time) { return ohci->frt << 31; } tks = tks / usb_bit_time; fr = (uint16_t)(ohci->fi - tks); return (ohci->frt << 31) | fr; } /* Set root hub status */ static void ohci_set_hub_status(OHCIState *ohci, uint32_t val) { uint32_t old_state; old_state = ohci->rhstatus; /* write 1 to clear OCIC */ if (val & OHCI_RHS_OCIC) { ohci->rhstatus &= ~OHCI_RHS_OCIC; } if (val & OHCI_RHS_LPS) { int i; for (i = 0; i < ohci->num_ports; i++) { ohci_port_power(ohci, i, 0); } trace_usb_ohci_hub_power_down(); } if (val & OHCI_RHS_LPSC) { int i; for (i = 0; i < ohci->num_ports; i++) { ohci_port_power(ohci, i, 1); } trace_usb_ohci_hub_power_up(); } if (val & OHCI_RHS_DRWE) { ohci->rhstatus |= OHCI_RHS_DRWE; } if (val & OHCI_RHS_CRWE) { ohci->rhstatus &= ~OHCI_RHS_DRWE; } if (old_state != ohci->rhstatus) { ohci_set_interrupt(ohci, OHCI_INTR_RHSC); } } /* * Sets a flag in a port status reg but only set it if the port is connected. * If not set ConnectStatusChange flag. If flag is enabled return 1. */ static int ohci_port_set_if_connected(OHCIState *ohci, int i, uint32_t val) { int ret = 1; /* writing a 0 has no effect */ if (val == 0) { return 0; } /* If CurrentConnectStatus is cleared we set ConnectStatusChange */ if (!(ohci->rhport[i].ctrl & OHCI_PORT_CCS)) { ohci->rhport[i].ctrl |= OHCI_PORT_CSC; if (ohci->rhstatus & OHCI_RHS_DRWE) { /* TODO: CSC is a wakeup event */ } return 0; } if (ohci->rhport[i].ctrl & val) { ret = 0; } /* set the bit */ ohci->rhport[i].ctrl |= val; return ret; } /* Set root hub port status */ static void ohci_port_set_status(OHCIState *ohci, int portnum, uint32_t val) { uint32_t old_state; OHCIPort *port; port = &ohci->rhport[portnum]; old_state = port->ctrl; /* Write to clear CSC, PESC, PSSC, OCIC, PRSC */ if (val & OHCI_PORT_WTC) { port->ctrl &= ~(val & OHCI_PORT_WTC); } if (val & OHCI_PORT_CCS) { port->ctrl &= ~OHCI_PORT_PES; } ohci_port_set_if_connected(ohci, portnum, val & OHCI_PORT_PES); if (ohci_port_set_if_connected(ohci, portnum, val & OHCI_PORT_PSS)) { trace_usb_ohci_port_suspend(portnum); } if (ohci_port_set_if_connected(ohci, portnum, val & OHCI_PORT_PRS)) { trace_usb_ohci_port_reset(portnum); usb_device_reset(port->port.dev); port->ctrl &= ~OHCI_PORT_PRS; /* ??? Should this also set OHCI_PORT_PESC. */ port->ctrl |= OHCI_PORT_PES | OHCI_PORT_PRSC; } /* Invert order here to ensure in ambiguous case, device is powered up. */ if (val & OHCI_PORT_LSDA) { ohci_port_power(ohci, portnum, 0); } if (val & OHCI_PORT_PPS) { ohci_port_power(ohci, portnum, 1); } if (old_state != port->ctrl) { ohci_set_interrupt(ohci, OHCI_INTR_RHSC); } } static uint64_t ohci_mem_read(void *opaque, hwaddr addr, unsigned size) { OHCIState *ohci = opaque; uint32_t retval; /* Only aligned reads are allowed on OHCI */ if (addr & 3) { trace_usb_ohci_mem_read_unaligned(addr); return 0xffffffff; } else if (addr >= 0x54 && addr < 0x54 + ohci->num_ports * 4) { /* HcRhPortStatus */ retval = ohci->rhport[(addr - 0x54) >> 2].ctrl | OHCI_PORT_PPS; trace_usb_ohci_mem_port_read(size, "HcRhPortStatus", (addr - 0x50) >> 2, addr, addr >> 2, retval); } else { switch (addr >> 2) { case 0: /* HcRevision */ retval = 0x10; break; case 1: /* HcControl */ retval = ohci->ctl; break; case 2: /* HcCommandStatus */ retval = ohci->status; break; case 3: /* HcInterruptStatus */ retval = ohci->intr_status; break; case 4: /* HcInterruptEnable */ case 5: /* HcInterruptDisable */ retval = ohci->intr; break; case 6: /* HcHCCA */ retval = ohci->hcca; break; case 7: /* HcPeriodCurrentED */ retval = ohci->per_cur; break; case 8: /* HcControlHeadED */ retval = ohci->ctrl_head; break; case 9: /* HcControlCurrentED */ retval = ohci->ctrl_cur; break; case 10: /* HcBulkHeadED */ retval = ohci->bulk_head; break; case 11: /* HcBulkCurrentED */ retval = ohci->bulk_cur; break; case 12: /* HcDoneHead */ retval = ohci->done; break; case 13: /* HcFmInterretval */ retval = (ohci->fit << 31) | (ohci->fsmps << 16) | (ohci->fi); break; case 14: /* HcFmRemaining */ retval = ohci_get_frame_remaining(ohci); break; case 15: /* HcFmNumber */ retval = ohci->frame_number; break; case 16: /* HcPeriodicStart */ retval = ohci->pstart; break; case 17: /* HcLSThreshold */ retval = ohci->lst; break; case 18: /* HcRhDescriptorA */ retval = ohci->rhdesc_a; break; case 19: /* HcRhDescriptorB */ retval = ohci->rhdesc_b; break; case 20: /* HcRhStatus */ retval = ohci->rhstatus; break; /* PXA27x specific registers */ case 24: /* HcStatus */ retval = ohci->hstatus & ohci->hmask; break; case 25: /* HcHReset */ retval = ohci->hreset; break; case 26: /* HcHInterruptEnable */ retval = ohci->hmask; break; case 27: /* HcHInterruptTest */ retval = ohci->htest; break; default: trace_usb_ohci_mem_read_bad_offset(addr); retval = 0xffffffff; } if (addr != 0xc || retval) { trace_usb_ohci_mem_read(size, ohci_reg_name(addr), addr, addr >> 2, retval); } } return retval; } static void ohci_mem_write(void *opaque, hwaddr addr, uint64_t val, unsigned size) { OHCIState *ohci = opaque; /* Only aligned reads are allowed on OHCI */ if (addr & 3) { trace_usb_ohci_mem_write_unaligned(addr); return; } if (addr >= 0x54 && addr < 0x54 + ohci->num_ports * 4) { /* HcRhPortStatus */ trace_usb_ohci_mem_port_write(size, "HcRhPortStatus", (addr - 0x50) >> 2, addr, addr >> 2, val); ohci_port_set_status(ohci, (addr - 0x54) >> 2, val); return; } trace_usb_ohci_mem_write(size, ohci_reg_name(addr), addr, addr >> 2, val); switch (addr >> 2) { case 1: /* HcControl */ ohci_set_ctl(ohci, val); break; case 2: /* HcCommandStatus */ /* SOC is read-only */ val = (val & ~OHCI_STATUS_SOC); /* Bits written as '0' remain unchanged in the register */ ohci->status |= val; if (ohci->status & OHCI_STATUS_HCR) { ohci_soft_reset(ohci); } break; case 3: /* HcInterruptStatus */ ohci->intr_status &= ~val; ohci_intr_update(ohci); break; case 4: /* HcInterruptEnable */ ohci->intr |= val; ohci_intr_update(ohci); break; case 5: /* HcInterruptDisable */ ohci->intr &= ~val; ohci_intr_update(ohci); break; case 6: /* HcHCCA */ ohci->hcca = val & OHCI_HCCA_MASK; break; case 7: /* HcPeriodCurrentED */ /* Ignore writes to this read-only register, Linux does them */ break; case 8: /* HcControlHeadED */ ohci->ctrl_head = val & OHCI_EDPTR_MASK; break; case 9: /* HcControlCurrentED */ ohci->ctrl_cur = val & OHCI_EDPTR_MASK; break; case 10: /* HcBulkHeadED */ ohci->bulk_head = val & OHCI_EDPTR_MASK; break; case 11: /* HcBulkCurrentED */ ohci->bulk_cur = val & OHCI_EDPTR_MASK; break; case 13: /* HcFmInterval */ ohci->fsmps = (val & OHCI_FMI_FSMPS) >> 16; ohci->fit = (val & OHCI_FMI_FIT) >> 31; ohci_set_frame_interval(ohci, val); break; case 15: /* HcFmNumber */ break; case 16: /* HcPeriodicStart */ ohci->pstart = val & 0xffff; break; case 17: /* HcLSThreshold */ ohci->lst = val & 0xffff; break; case 18: /* HcRhDescriptorA */ ohci->rhdesc_a &= ~OHCI_RHA_RW_MASK; ohci->rhdesc_a |= val & OHCI_RHA_RW_MASK; break; case 19: /* HcRhDescriptorB */ break; case 20: /* HcRhStatus */ ohci_set_hub_status(ohci, val); break; /* PXA27x specific registers */ case 24: /* HcStatus */ ohci->hstatus &= ~(val & ohci->hmask); break; case 25: /* HcHReset */ ohci->hreset = val & ~OHCI_HRESET_FSBIR; if (val & OHCI_HRESET_FSBIR) { ohci_hard_reset(ohci); } break; case 26: /* HcHInterruptEnable */ ohci->hmask = val; break; case 27: /* HcHInterruptTest */ ohci->htest = val; break; default: trace_usb_ohci_mem_write_bad_offset(addr); break; } } static const MemoryRegionOps ohci_mem_ops = { .read = ohci_mem_read, .write = ohci_mem_write, .endianness = DEVICE_LITTLE_ENDIAN, }; /* USBPortOps */ static void ohci_attach(USBPort *port1) { OHCIState *s = port1->opaque; OHCIPort *port = &s->rhport[port1->index]; uint32_t old_state = port->ctrl; /* set connect status */ port->ctrl |= OHCI_PORT_CCS | OHCI_PORT_CSC; /* update speed */ if (port->port.dev->speed == USB_SPEED_LOW) { port->ctrl |= OHCI_PORT_LSDA; } else { port->ctrl &= ~OHCI_PORT_LSDA; } /* notify of remote-wakeup */ if ((s->ctl & OHCI_CTL_HCFS) == OHCI_USB_SUSPEND) { ohci_set_interrupt(s, OHCI_INTR_RD); } trace_usb_ohci_port_attach(port1->index); if (old_state != port->ctrl) { ohci_set_interrupt(s, OHCI_INTR_RHSC); } } static void ohci_child_detach(USBPort *port1, USBDevice *dev) { OHCIState *ohci = port1->opaque; if (ohci->async_td && usb_packet_is_inflight(&ohci->usb_packet) && ohci->usb_packet.ep->dev == dev) { usb_cancel_packet(&ohci->usb_packet); ohci->async_td = 0; } } static void ohci_detach(USBPort *port1) { OHCIState *s = port1->opaque; OHCIPort *port = &s->rhport[port1->index]; uint32_t old_state = port->ctrl; ohci_child_detach(port1, port1->dev); /* set connect status */ if (port->ctrl & OHCI_PORT_CCS) { port->ctrl &= ~OHCI_PORT_CCS; port->ctrl |= OHCI_PORT_CSC; } /* disable port */ if (port->ctrl & OHCI_PORT_PES) { port->ctrl &= ~OHCI_PORT_PES; port->ctrl |= OHCI_PORT_PESC; } trace_usb_ohci_port_detach(port1->index); if (old_state != port->ctrl) { ohci_set_interrupt(s, OHCI_INTR_RHSC); } } static void ohci_wakeup(USBPort *port1) { OHCIState *s = port1->opaque; OHCIPort *port = &s->rhport[port1->index]; uint32_t intr = 0; if (port->ctrl & OHCI_PORT_PSS) { trace_usb_ohci_port_wakeup(port1->index); port->ctrl |= OHCI_PORT_PSSC; port->ctrl &= ~OHCI_PORT_PSS; intr = OHCI_INTR_RHSC; } /* Note that the controller can be suspended even if this port is not */ if ((s->ctl & OHCI_CTL_HCFS) == OHCI_USB_SUSPEND) { trace_usb_ohci_remote_wakeup(s->name); /* This is the one state transition the controller can do by itself */ s->ctl &= ~OHCI_CTL_HCFS; s->ctl |= OHCI_USB_RESUME; /* * In suspend mode only ResumeDetected is possible, not RHSC: * see the OHCI spec 5.1.2.3. */ intr = OHCI_INTR_RD; } ohci_set_interrupt(s, intr); } static void ohci_async_complete_packet(USBPort *port, USBPacket *packet) { OHCIState *ohci = container_of(packet, OHCIState, usb_packet); trace_usb_ohci_async_complete(); ohci->async_complete = true; ohci_process_lists(ohci); } static USBPortOps ohci_port_ops = { .attach = ohci_attach, .detach = ohci_detach, .child_detach = ohci_child_detach, .wakeup = ohci_wakeup, .complete = ohci_async_complete_packet, }; static USBBusOps ohci_bus_ops = { }; void usb_ohci_init(OHCIState *ohci, DeviceState *dev, uint32_t num_ports, dma_addr_t localmem_base, char *masterbus, uint32_t firstport, AddressSpace *as, void (*ohci_die_fn)(OHCIState *), Error **errp) { Error *err = NULL; int i; ohci->as = as; ohci->ohci_die = ohci_die_fn; if (num_ports > OHCI_MAX_PORTS) { error_setg(errp, "OHCI num-ports=%u is too big (limit is %u ports)", num_ports, OHCI_MAX_PORTS); return; } if (usb_frame_time == 0) { #ifdef OHCI_TIME_WARP usb_frame_time = NANOSECONDS_PER_SECOND; usb_bit_time = NANOSECONDS_PER_SECOND / (USB_HZ / 1000); #else usb_frame_time = NANOSECONDS_PER_SECOND / 1000; if (NANOSECONDS_PER_SECOND >= USB_HZ) { usb_bit_time = NANOSECONDS_PER_SECOND / USB_HZ; } else { usb_bit_time = 1; } #endif trace_usb_ohci_init_time(usb_frame_time, usb_bit_time); } ohci->num_ports = num_ports; if (masterbus) { USBPort *ports[OHCI_MAX_PORTS]; for (i = 0; i < num_ports; i++) { ports[i] = &ohci->rhport[i].port; } usb_register_companion(masterbus, ports, num_ports, firstport, ohci, &ohci_port_ops, USB_SPEED_MASK_LOW | USB_SPEED_MASK_FULL, &err); if (err) { error_propagate(errp, err); return; } } else { usb_bus_new(&ohci->bus, sizeof(ohci->bus), &ohci_bus_ops, dev); for (i = 0; i < num_ports; i++) { usb_register_port(&ohci->bus, &ohci->rhport[i].port, ohci, i, &ohci_port_ops, USB_SPEED_MASK_LOW | USB_SPEED_MASK_FULL); } } memory_region_init_io(&ohci->mem, OBJECT(dev), &ohci_mem_ops, ohci, "ohci", 256); ohci->localmem_base = localmem_base; ohci->name = object_get_typename(OBJECT(dev)); usb_packet_init(&ohci->usb_packet); ohci->async_td = 0; ohci->eof_timer = timer_new_ns(QEMU_CLOCK_VIRTUAL, ohci_frame_boundary, ohci); } /* * A typical OHCI will stop operating and set itself into error state * (which can be queried by MMIO) to signal that it got an error. */ void ohci_sysbus_die(struct OHCIState *ohci) { trace_usb_ohci_die(); ohci_set_interrupt(ohci, OHCI_INTR_UE); ohci_bus_stop(ohci); } static void ohci_realize_pxa(DeviceState *dev, Error **errp) { OHCISysBusState *s = SYSBUS_OHCI(dev); SysBusDevice *sbd = SYS_BUS_DEVICE(dev); Error *err = NULL; usb_ohci_init(&s->ohci, dev, s->num_ports, s->dma_offset, s->masterbus, s->firstport, &address_space_memory, ohci_sysbus_die, &err); if (err) { error_propagate(errp, err); return; } sysbus_init_irq(sbd, &s->ohci.irq); sysbus_init_mmio(sbd, &s->ohci.mem); } static void usb_ohci_reset_sysbus(DeviceState *dev) { OHCISysBusState *s = SYSBUS_OHCI(dev); OHCIState *ohci = &s->ohci; ohci_hard_reset(ohci); } static const VMStateDescription vmstate_ohci_state_port = { .name = "ohci-core/port", .version_id = 1, .minimum_version_id = 1, .fields = (VMStateField[]) { VMSTATE_UINT32(ctrl, OHCIPort), VMSTATE_END_OF_LIST() }, }; static bool ohci_eof_timer_needed(void *opaque) { OHCIState *ohci = opaque; return timer_pending(ohci->eof_timer); } static const VMStateDescription vmstate_ohci_eof_timer = { .name = "ohci-core/eof-timer", .version_id = 1, .minimum_version_id = 1, .needed = ohci_eof_timer_needed, .fields = (VMStateField[]) { VMSTATE_TIMER_PTR(eof_timer, OHCIState), VMSTATE_END_OF_LIST() }, }; const VMStateDescription vmstate_ohci_state = { .name = "ohci-core", .version_id = 1, .minimum_version_id = 1, .fields = (VMStateField[]) { VMSTATE_INT64(sof_time, OHCIState), VMSTATE_UINT32(ctl, OHCIState), VMSTATE_UINT32(status, OHCIState), VMSTATE_UINT32(intr_status, OHCIState), VMSTATE_UINT32(intr, OHCIState), VMSTATE_UINT32(hcca, OHCIState), VMSTATE_UINT32(ctrl_head, OHCIState), VMSTATE_UINT32(ctrl_cur, OHCIState), VMSTATE_UINT32(bulk_head, OHCIState), VMSTATE_UINT32(bulk_cur, OHCIState), VMSTATE_UINT32(per_cur, OHCIState), VMSTATE_UINT32(done, OHCIState), VMSTATE_INT32(done_count, OHCIState), VMSTATE_UINT16(fsmps, OHCIState), VMSTATE_UINT8(fit, OHCIState), VMSTATE_UINT16(fi, OHCIState), VMSTATE_UINT8(frt, OHCIState), VMSTATE_UINT16(frame_number, OHCIState), VMSTATE_UINT16(padding, OHCIState), VMSTATE_UINT32(pstart, OHCIState), VMSTATE_UINT32(lst, OHCIState), VMSTATE_UINT32(rhdesc_a, OHCIState), VMSTATE_UINT32(rhdesc_b, OHCIState), VMSTATE_UINT32(rhstatus, OHCIState), VMSTATE_STRUCT_ARRAY(rhport, OHCIState, OHCI_MAX_PORTS, 0, vmstate_ohci_state_port, OHCIPort), VMSTATE_UINT32(hstatus, OHCIState), VMSTATE_UINT32(hmask, OHCIState), VMSTATE_UINT32(hreset, OHCIState), VMSTATE_UINT32(htest, OHCIState), VMSTATE_UINT32(old_ctl, OHCIState), VMSTATE_UINT8_ARRAY(usb_buf, OHCIState, 8192), VMSTATE_UINT32(async_td, OHCIState), VMSTATE_BOOL(async_complete, OHCIState), VMSTATE_END_OF_LIST() }, .subsections = (const VMStateDescription*[]) { &vmstate_ohci_eof_timer, NULL } }; static Property ohci_sysbus_properties[] = { DEFINE_PROP_STRING("masterbus", OHCISysBusState, masterbus), DEFINE_PROP_UINT32("num-ports", OHCISysBusState, num_ports, 3), DEFINE_PROP_UINT32("firstport", OHCISysBusState, firstport, 0), DEFINE_PROP_DMAADDR("dma-offset", OHCISysBusState, dma_offset, 0), DEFINE_PROP_END_OF_LIST(), }; static void ohci_sysbus_class_init(ObjectClass *klass, void *data) { DeviceClass *dc = DEVICE_CLASS(klass); dc->realize = ohci_realize_pxa; set_bit(DEVICE_CATEGORY_USB, dc->categories); dc->desc = "OHCI USB Controller"; device_class_set_props(dc, ohci_sysbus_properties); dc->reset = usb_ohci_reset_sysbus; } static const TypeInfo ohci_sysbus_info = { .name = TYPE_SYSBUS_OHCI, .parent = TYPE_SYS_BUS_DEVICE, .instance_size = sizeof(OHCISysBusState), .class_init = ohci_sysbus_class_init, }; static void ohci_register_types(void) { type_register_static(&ohci_sysbus_info); } type_init(ohci_register_types)