/* $OpenBSD: if_sandrv.c,v 1.15 2013/11/11 03:08:20 dlg Exp $ */ /*- * Copyright (c) 2001-2004 Sangoma Technologies (SAN) * All rights reserved. www.sangoma.com * * This code is written by Alex Feldman for SAN. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above * copyright notice, this list of conditions and the following disclaimer * in the documentation and/or other materials provided with the * distribution. * 3. Neither the name of Sangoma Technologies nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY SANGOMA TECHNOLOGIES AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ #define __SDLA_HW_LEVEL #define __SDLADRV__ #include #include #include #include #include #include #include #include #include #include #define EXEC_DELAY 20 /* shared memory access delay, mks */ #define EXEC_TIMEOUT (hz*2) #define MAX_NLOOPS (EXEC_DELAY*2000) /* timeout used if jiffies are stopped ** EXEC_DELAY=20 ** EXEC_TIMEOUT=EXEC_DELAY*2000 = 40000 ** 40000 ~= 80 jiffies = EXEC_TIMEOUT */ #define EXEC_HZ_DIVISOR 8/10 /* We don't want to wait a full second on sdla_exec ** timeout, thus use HZ * EXEC_HZ_DIVISOR to get ** the number of jiffies we would like to wait */ #define IS_SUPPORTED_ADAPTER(hw) ((hw)->type == SDLA_AFT) #define SDLA_CTYPE_NAME(type) \ ((type) == SDLA_AFT) ? "AFT" : "Unknown" #define IS_AFT(hw) (hw->type == SDLA_AFT) /* Definitions for identifying and finding S514 PCI adapters */ #define V3_VENDOR_ID 0x11B0 /* V3 vendor ID number */ #define V3_DEVICE_ID 0x0002 /* V3 device ID number */ #define SANGOMA_SUBSYS_VENDOR 0x4753 /* ID for Sangoma */ /* Definition for identifying and finding XILINX PCI adapters */ #define SANGOMA_PCI_VENDOR 0x1923 /* Old value -> 0x11B0 */ #define SANGOMA_PCI_VENDOR_OLD 0x10EE /* Old value -> 0x11B0 */ #define SANGOMA_PCI_DEVICE 0x0300 /* Old value -> 0x0200 */ #define A101_1TE1_SUBSYS_VENDOR 0xA010 /* A101 with T1/E1 1 line */ #define A101_2TE1_SUBSYS_VENDOR 0xA011 /* A101 with T1/E1 2 lines */ #define A105_T3_SUBSYS_VENDOR 0xA020 /* A102 with T3 */ /* Read PCI SUBVENDOR ID */ #define PCI_SUBVENDOR_MASK 0xFFFF #define PCI_SUBVENDOR(pa) (pci_conf_read(pa->pa_pc, pa->pa_tag, \ PCI_SUBSYS_ID_REG) & PCI_SUBVENDOR_MASK) #define PCI_DEVICE_MASK 0xFFFF0000 #define PCI_DEVICE(id) ((id & PCI_DEVICE_MASK ) >> 16) /* Status values */ #define SDLA_MEM_RESERVED 0x0001 #define SDLA_MEM_MAPPED 0x0002 #define SDLA_IO_MAPPED 0x0004 #define SDLA_PCI_ENABLE 0x0008 struct san_softc { struct device dev; struct pci_attach_args pa; }; typedef struct sdla_hw_probe { int used; unsigned char hw_info[100]; LIST_ENTRY(sdla_hw_probe) next; } sdla_hw_probe_t; /* * This structure keeps common parameters per physical card. */ typedef struct sdlahw_card { int used; unsigned int type; /* S50x/S514/ADSL/XILINX */ unsigned int atype; /* SubVendor ID */ unsigned char core_id; /* SubSystem ID [0..7] */ unsigned char core_rev; /* SubSystem ID [8..15] */ unsigned char pci_extra_ver; unsigned int slot_no; unsigned int bus_no; bus_space_tag_t memt; struct pci_attach_args pa; /* PCI config header info */ pci_intr_handle_t ih; LIST_ENTRY(sdlahw_card) next; } sdlahw_card_t; /* * Adapter hardware configuration. Pointer to this structure is passed to all * APIs. */ typedef struct sdlahw { int used; unsigned magic; char devname[20]; u_int16_t status; int irq; /* interrupt request level */ unsigned int cpu_no; /* PCI CPU Number */ char auto_pci_cfg; /* Auto PCI configuration */ bus_addr_t mem_base_addr; bus_space_handle_t dpmbase; /* dual-port memory base */ unsigned dpmsize; /* dual-port memory size */ unsigned long memory; /* memory size */ unsigned reserved[5]; unsigned char hw_info[100]; u_int16_t configured; void *arg; /* card structure */ sdla_hw_probe_t *hwprobe; sdlahw_card_t *hwcard; LIST_ENTRY(sdlahw) next; } sdlahw_t; /* Entry Point for Low-Level function */ int sdladrv_init(void); int sdladrv_exit(void); static int sdla_pci_probe(int, struct pci_attach_args *); /* PCI bus interface function */ static int sdla_pci_write_config_word(void *, int, u_int16_t); static int sdla_pci_write_config_dword(void *, int, u_int32_t); static int sdla_pci_read_config_byte(void *, int, u_int8_t *); static int sdla_pci_read_config_word(void *, int, u_int16_t *); static int sdla_pci_read_config_dword(void *, int, u_int32_t *); static int sdla_detect (sdlahw_t *); static int sdla_detect_aft(sdlahw_t *); static int sdla_exec(sdlahw_t *, unsigned long); static void sdla_peek_by_4(sdlahw_t *, unsigned long, u_int8_t *, unsigned int); static void sdla_poke_by_4(sdlahw_t *, unsigned long, u_int8_t *, unsigned int); static sdlahw_card_t* sdla_card_register(u_int16_t, int, int); #if 0 static int sdla_card_unregister (unsigned char, int, int, int); #endif static sdlahw_card_t* sdla_card_search(u_int16_t, int, int); static sdlahw_t* sdla_hw_register(sdlahw_card_t *, int, int, void *); #if 0 static int sdla_hw_unregister(sdlahw_card_t*, int); #endif static sdlahw_t* sdla_hw_search(u_int16_t, int, int, int); static sdlahw_t* sdla_aft_hw_select (sdlahw_card_t *, int, int, struct pci_attach_args *); static void sdla_save_hw_probe (sdlahw_t*, int); /* SDLA PCI device relative entry point */ int san_match(struct device *, void *, void *); void san_attach(struct device *, struct device *, void *); struct cfdriver san_cd = { NULL, "san", DV_IFNET }; struct cfattach san_ca = { sizeof(struct san_softc), san_match, san_attach }; extern int ticks; /* SDLA ISA/PCI varibles */ static int Sangoma_cards_no = 0; static int Sangoma_devices_no = 0; static int Sangoma_PCI_cards_no = 0; /* private data */ char *san_drvname = "san"; /* Array of already initialized PCI slots */ static int pci_slot_ar[MAX_S514_CARDS]; LIST_HEAD(, sdlahw_card) sdlahw_card_head = LIST_HEAD_INITIALIZER(sdlahw_card_head); LIST_HEAD(, sdlahw) sdlahw_head = LIST_HEAD_INITIALIZER(sdlahw_head); LIST_HEAD(, sdla_hw_probe) sdlahw_probe_head = LIST_HEAD_INITIALIZER(sdlahw_probe_head); static sdla_hw_type_cnt_t sdla_adapter_cnt; /* * PCI Device Driver Entry Points */ int san_match(struct device *parent, void *match, void *aux) { struct pci_attach_args* pa = aux; u_int16_t vendor_id = PCI_VENDOR(pa->pa_id); u_int16_t device_id = PCI_DEVICE(pa->pa_id); if ((vendor_id == SANGOMA_PCI_VENDOR || vendor_id == SANGOMA_PCI_VENDOR_OLD) && device_id == SANGOMA_PCI_DEVICE) { return (1); } return (0); } #define PCI_CBIO 0x10 void san_attach(struct device *parent, struct device *self, void *aux) { struct pci_attach_args* pa = aux; u_int16_t vendor_id = PCI_VENDOR(pa->pa_id); u_int16_t subvendor_id = PCI_SUBVENDOR(pa); int atype = 0x00; atype = PCI_PRODUCT(pci_conf_read(pa->pa_pc, pa->pa_tag, PCI_SUBSYS_ID_REG)); switch (vendor_id) { case SANGOMA_PCI_VENDOR_OLD: case SANGOMA_PCI_VENDOR: switch (subvendor_id) { case A101_1TE1_SUBSYS_VENDOR: atype = A101_ADPTR_1TE1; break; case A101_2TE1_SUBSYS_VENDOR: atype = A101_ADPTR_2TE1; break; default: return; } break; default: return; } if (sdla_pci_probe(atype, pa)) { printf(": PCI probe FAILED!\n"); return; } #ifdef DEBUG switch (PCI_VENDOR(pa->pa_id)) { case V3_VENDOR_ID: switch (atype) { case S5141_ADPTR_1_CPU_SERIAL: log(LOG_INFO, "%s: Sangoma S5141/FT1 (Single CPU) " "adapter\n", self->dv_xname); break; case S5142_ADPTR_2_CPU_SERIAL: log(LOG_INFO, "%s: Sangoma S5142 (Dual CPU) adapter\n", self->dv_xname); break; case S5143_ADPTR_1_CPU_FT1: log(LOG_INFO, "%s: Sangoma S5143 (Single CPU) " "FT1 adapter\n", self->dv_xname); break; case S5144_ADPTR_1_CPU_T1E1: case S5148_ADPTR_1_CPU_T1E1: log(LOG_INFO, "%s: Sangoma S5144 (Single CPU) " "T1/E1 adapter\n", self->dv_xname); break; case S5145_ADPTR_1_CPU_56K: log(LOG_INFO, "%s: Sangoma S5145 (Single CPU) " "56K adapter\n", self->dv_xname); break; case S5147_ADPTR_2_CPU_T1E1: log(LOG_INFO, "%s: Sangoma S5147 (Dual CPU) " "T1/E1 adapter\n", self->dv_xname); break; } break; case SANGOMA_PCI_VENDOR_OLD: switch (atype) { case A101_ADPTR_1TE1: log(LOG_INFO, "%s: Sangoma AFT (1 channel) " "T1/E1 adapter\n", self->dv_xname); break; case A101_ADPTR_2TE1: log(LOG_INFO, "%s: Sangoma AFT (2 channels) " "T1/E1 adapter\n", self->dv_xname); break; } break; } #endif return; } /* * Module init point. */ int sdladrv_init(void) { int volatile i = 0; /* Initialize the PCI Card array, which * will store flags, used to mark * card initialization state */ for (i=0; ihwcard, tmp->cpu_no) == EBUSY) return EBUSY; } LIST_INIT(&sdlahw_head); elm_hw_card = LIST_FIRST(&sdlahw_card_head); while (elm_hw_card) { sdlahw_card_t *tmp = elm_hw_card; elm_hw_card = LIST_NEXT(elm_hw_card, next); if (sdla_card_unregister(tmp->hw_type, tmp->slot_no, tmp->bus_no, tmp->ioport) == EBUSY) return EBUSY; } LIST_INIT(&sdlahw_card_head); elm_hw_probe = LIST_FIRST(&sdlahw_probe_head); while (elm_hw_probe) { sdla_hw_probe_t *tmp = elm_hw_probe; elm_hw_probe = LIST_NEXT(elm_hw_probe, next); if (tmp->used){ log(LOG_INFO, "HW probe info is in used (%s)\n", elm_hw_probe->hw_info); return EBUSY; } LIST_REMOVE(tmp, next); free(tmp, M_DEVBUF); } #endif return (0); } static void sdla_save_hw_probe(sdlahw_t *hw, int port) { sdla_hw_probe_t *tmp_hw_probe; tmp_hw_probe = malloc(sizeof(*tmp_hw_probe), M_DEVBUF, M_NOWAIT|M_ZERO); if (tmp_hw_probe == NULL) return; snprintf(tmp_hw_probe->hw_info, sizeof(tmp_hw_probe->hw_info), "%s : SLOT=%d : BUS=%d : IRQ=%d : CPU=%c : PORT=%s", SDLA_ADPTR_DECODE(hw->hwcard->atype), hw->hwcard->slot_no, hw->hwcard->bus_no, hw->irq, SDLA_GET_CPU(hw->cpu_no), "PRI"); hw->hwprobe = tmp_hw_probe; tmp_hw_probe->used++; LIST_INSERT_HEAD(&sdlahw_probe_head, tmp_hw_probe, next); } static sdlahw_t* sdla_aft_hw_select(sdlahw_card_t *hwcard, int cpu_no, int irq, struct pci_attach_args *pa) { sdlahw_t* hw = NULL; int number_of_cards = 0; hwcard->type = SDLA_AFT; switch (hwcard->atype) { case A101_ADPTR_1TE1: hw = sdla_hw_register(hwcard, cpu_no, irq, pa); sdla_save_hw_probe(hw, 0); number_of_cards += 1; #ifdef DEBUG log(LOG_INFO, "%s: %s T1/E1 card found (%s rev.%d), " "cpu(s) 1, bus #%d, slot #%d, irq #%d\n", san_drvname, SDLA_ADPTR_DECODE(hwcard->atype), AFT_CORE_ID_DECODE(hwcard->core_id), hwcard->core_rev, hwcard->bus_no, hwcard->slot_no, irq); #endif /* DEBUG */ break; case A101_ADPTR_2TE1: hw = sdla_hw_register(hwcard, cpu_no, irq, pa); sdla_save_hw_probe(hw, 0); number_of_cards += 1; #ifdef DEBUG log(LOG_INFO, "%s: %s T1/E1 card found (%s rev.%d), " "cpu(s) 2, bus #%d, slot #%d, irq #%d\n", san_drvname, SDLA_ADPTR_DECODE(hwcard->atype), AFT_CORE_ID_DECODE(hwcard->core_id), hwcard->core_rev, hwcard->bus_no, hwcard->slot_no, irq); #endif /* DEBUG */ break; case A105_ADPTR_1_CHN_T3E3: hw = sdla_hw_register(hwcard, cpu_no, irq, pa); sdla_save_hw_probe(hw, 0); number_of_cards += 1; #ifdef DEBUG log(LOG_INFO, "%s: %s T3/E3 card found, cpu(s) 1," "bus #%d, slot #%d, irq #%d\n", san_drvname, SDLA_ADPTR_DECODE(hwcard->atype), hwcard->bus_no, hwcard->slot_no, irq); #endif /* DEBUG */ break; default: log(LOG_INFO, "%s: Unknown adapter %04X " "(bus #%d, slot #%d, irq #%d)!\n", san_drvname, hwcard->atype, hwcard->bus_no, hwcard->slot_no, irq); break; } return (hw); } static int sdla_pci_probe(int atype, struct pci_attach_args *pa) { sdlahw_card_t* hwcard; sdlahw_t* hw; /*sdladev_t* dev = NULL;*/ int dual_cpu = 0; int bus, slot, cpu = SDLA_CPU_A; u_int16_t vendor_id, subvendor_id, device_id; u_int8_t irq; pci_intr_handle_t ih; const char* intrstr = NULL; bus = pa->pa_bus; slot = pa->pa_device; vendor_id = PCI_VENDOR(pa->pa_id); subvendor_id = PCI_SUBVENDOR(pa); device_id = PCI_DEVICE(pa->pa_id); irq = (u_int8_t)pci_conf_read(pa->pa_pc, pa->pa_tag, PCI_INTLINE); /* Map and establish the interrupt */ if (pci_intr_map(pa, &ih)) { printf(": can't map interrupt\n"); return (EINVAL); } intrstr = pci_intr_string(pa->pa_pc, ih); if (intrstr != NULL) printf(" %s\n", intrstr); Sangoma_cards_no ++; reg_new_card: Sangoma_PCI_cards_no ++; hwcard = sdla_card_register(atype, slot, bus); if (hwcard == NULL) return (EINVAL); hwcard->memt = pa->pa_memt; hwcard->ih = ih; hwcard->pa = *pa; /* Increment number of available Sangoma devices */ Sangoma_devices_no ++; switch (atype) { case A101_ADPTR_1TE1: case A101_ADPTR_2TE1: hw = sdla_aft_hw_select(hwcard, cpu, irq, pa); sdla_adapter_cnt.AFT_adapters++; if (atype == A101_ADPTR_2TE1) dual_cpu = 1; break; } if (hw == NULL) return (EINVAL); if (san_dev_attach(hw, hw->devname, sizeof(hw->devname))) return (EINVAL); hw->used++; if (dual_cpu && cpu == SDLA_CPU_A) { cpu = SDLA_CPU_B; goto reg_new_card; } return (0); } int sdla_intr_establish(void *phw, int (*intr_func)(void*), void* intr_arg) { sdlahw_t *hw = (sdlahw_t*)phw; sdlahw_card_t *hwcard; WAN_ASSERT(hw == NULL); hwcard = hw->hwcard; if (pci_intr_establish(hwcard->pa.pa_pc, hwcard->ih, IPL_NET, intr_func, intr_arg, "san") == NULL) return (EINVAL); return 0; } int sdla_intr_disestablish(void *phw) { sdlahw_t *hw = (sdlahw_t*)phw; log(LOG_INFO, "%s: Disestablish interrupt is not defined!\n", hw->devname); return (EINVAL); } int sdla_get_hw_devices(void) { return (Sangoma_devices_no); } void* sdla_get_hw_adptr_cnt(void) { return (&sdla_adapter_cnt); } static sdlahw_card_t* sdla_card_register(u_int16_t atype, int slot_no, int bus_no) { sdlahw_card_t *new_hwcard, *last_hwcard; new_hwcard = sdla_card_search(atype, slot_no, bus_no); if (new_hwcard) return (new_hwcard); new_hwcard = malloc(sizeof(*new_hwcard), M_DEVBUF, M_NOWAIT | M_ZERO); if (!new_hwcard) return (NULL); new_hwcard->atype = atype; new_hwcard->slot_no = slot_no; new_hwcard->bus_no = bus_no; if (LIST_EMPTY(&sdlahw_card_head)) { /* Initialize SAN HW parameters */ sdladrv_init(); } LIST_FOREACH(last_hwcard, &sdlahw_card_head, next) { if (!LIST_NEXT(last_hwcard, next)) break; } if (last_hwcard) LIST_INSERT_AFTER(last_hwcard, new_hwcard, next); else LIST_INSERT_HEAD(&sdlahw_card_head, new_hwcard, next); return (new_hwcard); } #if 0 static int sdla_card_unregister(u_int16_t atype, int slot_no, int bus_no, int ioport) { sdlahw_card_t* tmp_card; LIST_FOREACH(tmp_card, &sdlahw_card_head, next){ if (tmp_card->atype != atype){ continue; } if (tmp_card->slot_no == slot_no && tmp_card->bus_no == bus_no){ break; } } if (tmp_card == NULL){ log(LOG_INFO, "Error: Card didn't find %04X card (slot=%d, bus=%d)\n" atype, slot_no, bus_no); return (EFAULT) } if (tmp_card->used){ log(LOG_INFO, "Error: Card is still in used (slot=%d,bus=%d,used=%d)\n", slot_no, bus_no, tmp_card->used); return (EBUSY); } LIST_REMOVE(tmp_card, next); free(tmp_card, M_DEVBUF); return 0; } #endif static sdlahw_card_t* sdla_card_search(u_int16_t atype, int slot_no, int bus_no) { sdlahw_card_t* tmp_card; LIST_FOREACH(tmp_card, &sdlahw_card_head, next) { if (tmp_card->atype != atype) continue; if (tmp_card->slot_no == slot_no && tmp_card->bus_no == bus_no) return (tmp_card); } return (NULL); } static sdlahw_t* sdla_hw_register(sdlahw_card_t *card, int cpu_no, int irq, void *dev) { sdlahw_t *new_hw, *last_hw; new_hw = sdla_hw_search(card->atype, card->slot_no, card->bus_no, cpu_no); if (new_hw) return (new_hw); new_hw = malloc(sizeof(*new_hw), M_DEVBUF, M_NOWAIT | M_ZERO); if (!new_hw) return (NULL); new_hw->cpu_no = cpu_no; new_hw->irq = irq; new_hw->hwcard = card; #if 0 new_hw->dev = dev; #endif new_hw->magic = SDLAHW_MAGIC; card->used++; LIST_FOREACH(last_hw, &sdlahw_head, next) { if (!LIST_NEXT(last_hw, next)) break; } if (last_hw) LIST_INSERT_AFTER(last_hw, new_hw, next); else LIST_INSERT_HEAD(&sdlahw_head, new_hw, next); return (new_hw); } #if 0 static int sdla_hw_unregister(sdlahw_card_t* hwcard, int cpu_no) { sdlahw_t* tmp_hw; int i; LIST_FOREACH(tmp_hw, &sdlahw_head, next) { if (tmp_hw->hwcard != hwcard) continue; if (tmp_hw->cpu_no == cpu_no) break; } if (tmp_hw == NULL) { log(LOG_INFO, "Error: Failed to find device (slot=%d,bus=%d,cpu=%c)\n", hwcard->slot_no, hwcard->bus_no, SDLA_GET_CPU(cpu_no)); return (EFAULT); } if (tmp_hw->used) { log(LOG_INFO, "Error: Device is still in used (slot=%d,bus=%d,cpu=%c,%d)\n", hwcard->slot_no, hwcard->bus_no, SDLA_GET_CPU(cpu_no), hwcard->used); return (EBUSY); } tmp_hw->hwprobe = NULL; tmp_hw->hwcard = NULL; hwcard->used--; /* Decrement card usage */ LIST_REMOVE(tmp_hw, next); free(tmp_hw, M_DEVBUF); return (0); } #endif static sdlahw_t* sdla_hw_search(u_int16_t atype, int slot_no, int bus_no, int cpu_no) { sdlahw_t* tmp_hw; LIST_FOREACH(tmp_hw, &sdlahw_head, next) { if (tmp_hw->hwcard == NULL) { log(LOG_INFO, "Critical Error: sdla_cpu_search: line %d\n", __LINE__); // XXX REMOVE in LIST_FOREACH LIST_REMOVE(tmp_hw, next); continue; } if (tmp_hw->hwcard->atype != atype) { // XXX why ??? LIST_REMOVE(tmp_hw, next); continue; } if (tmp_hw->hwcard->slot_no == slot_no && tmp_hw->hwcard->bus_no == bus_no && tmp_hw->cpu_no == cpu_no) return (tmp_hw); } return (NULL); } /* * Set up adapter. * o detect adapter type * o set up adapter shared memory * Return: 0 ok. * < 0 error */ int sdla_setup(void *phw) { sdlahw_card_t* hwcard = NULL; sdlahw_t* hw = (sdlahw_t*)phw; int err=0; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); hwcard = hw->hwcard; switch (hwcard->type) { case SDLA_AFT: break; default: log(LOG_INFO, "%s: Invalid card type %x\n", hw->devname, hw->hwcard->type); return (EINVAL); } hw->dpmsize = SDLA_WINDOWSIZE; err = sdla_detect(hw); return (err); } /* * Shut down SDLA: disable shared memory access and interrupts, stop CPU, etc. */ int sdla_down(void *phw) { sdlahw_card_t* card = NULL; sdlahw_t* hw = (sdlahw_t*)phw; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); card = hw->hwcard; switch (card->type) { case SDLA_AFT: /* free up the allocated virtual memory */ if (hw->status & SDLA_MEM_MAPPED) { bus_space_unmap(hw->hwcard->memt, hw->dpmbase, XILINX_PCI_MEM_SIZE); hw->status &= ~SDLA_MEM_MAPPED; } break; default: return (EINVAL); } return (0); } /* * Read the hardware interrupt status. */ int sdla_read_int_stat(void *phw, u_int32_t *int_status) { sdlahw_card_t* card = NULL; sdlahw_t* hw = (sdlahw_t*)phw; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); card = hw->hwcard; switch (card->type) { case SDLA_AFT: sdla_pci_read_config_dword(hw, PCI_INT_STATUS, int_status); } return (0); } /* * Generate an interrupt to adapter's CPU. */ int sdla_cmd(void *phw, unsigned long offset, wan_mbox_t *mbox) { sdlahw_t *hw = (sdlahw_t*)phw; int len = sizeof(wan_cmd_t); int err = 0; u_int8_t value; SDLA_MAGIC(hw); len += mbox->wan_data_len; sdla_peek(hw, offset, (void*)&value, 1); if (value != 0x00) { log(LOG_INFO, "%s: opp flag set on entry to sdla_exec!\n", hw->devname); return (0); } mbox->wan_opp_flag = 0x00; sdla_poke(hw, offset, (void*)mbox, len); err = sdla_exec(hw, offset); if (!err) { log(LOG_INFO, "%s: Command 0x%02X failed!\n", hw->devname, mbox->wan_command); return (WAN_CMD_TIMEOUT); } sdla_peek(hw, offset, (void*)mbox, sizeof(wan_cmd_t)); if (mbox->wan_data_len) { sdla_peek(hw, offset+offsetof(wan_mbox_t, wan_data), mbox->wan_data, mbox->wan_data_len); } return (mbox->wan_return_code); } /* * Execute Adapter Command. * o Set exec flag. * o Busy-wait until flag is reset. * o Return number of loops made, or 0 if command timed out. */ static int sdla_exec(sdlahw_t *hw, unsigned long offset) { volatile unsigned long tstop; volatile unsigned long nloops; u_int8_t value; value = 0x01; sdla_poke(hw, offset, (void*)&value, 1); tstop = ticks + EXEC_TIMEOUT; sdla_peek(hw, offset, (void*)&value, 1); for (nloops = 1; value == 0x01; ++ nloops) { DELAY(EXEC_DELAY); if (ticks - tstop > 0 || nloops > MAX_NLOOPS) { log(LOG_INFO, "%s: Timeout %lu ticks (max=%lu) " "loops %lu (max=%u)\n", hw->devname, (ticks-tstop+EXEC_TIMEOUT), (unsigned long)EXEC_TIMEOUT, nloops, MAX_NLOOPS); return (0); /* time is up! */ } sdla_peek(hw, offset, (void*)&value, 1); } return (nloops); } /* * Read absolute adapter memory. * Transfer data from adapter's memory to data buffer. * * Note: * Care should be taken when crossing dual-port memory window boundary. * This function is not atomic, so caller must disable interrupt if * interrupt routines are accessing adapter shared memory. */ int sdla_peek(void *phw, unsigned long addr, void *buf, unsigned len) { sdlahw_card_t* card = NULL; sdlahw_t* hw = (sdlahw_t*)phw; int err = 0; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); card = hw->hwcard; if (addr + len > hw->memory) /* verify arguments */ return (EINVAL); switch (card->type) { case SDLA_AFT: sdla_peek_by_4(hw, addr, buf, len); break; default: log(LOG_INFO, "%s: Invalid card type 0x%X\n", __FUNCTION__,card->type); err = (EINVAL); break; } return (err); } /* * Read data from adapter's memory to a data buffer in 4-byte chunks. * Note that we ensure that the SDLA memory address is on a 4-byte boundary * before we begin moving the data in 4-byte chunks. */ static void sdla_peek_by_4(sdlahw_t *hw, unsigned long offset, u_int8_t *buf, unsigned int len) { /* byte copy data until we get to a 4-byte boundary */ while (len && (offset & 0x03)) { sdla_bus_read_1(hw, offset++, buf); buf++; len--; } /* copy data in 4-byte chunks */ while (len >= 4) { sdla_bus_read_4(hw, offset, (u_int32_t*)buf); buf += 4; offset += 4; len -= 4; } /* byte copy any remaining data */ while (len) { sdla_bus_read_1(hw, offset++, buf); buf++; len--; } } /* * Write Absolute Adapter Memory. * Transfer data from data buffer to adapter's memory. * * Note: * Care should be taken when crossing dual-port memory window boundary. * This function is not atomic, so caller must disable interrupt if * interrupt routines are accessing adapter shared memory. */ int sdla_poke(void *phw, unsigned long addr, void *buf, unsigned len) { sdlahw_card_t* card = NULL; sdlahw_t* hw = (sdlahw_t*)phw; int err = 0; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); card = hw->hwcard; if (addr + len > hw->memory) { /* verify arguments */ return (EINVAL); } switch (card->type) { case SDLA_AFT: sdla_poke_by_4(hw, addr, buf, len); break; default: log(LOG_INFO, "%s: Invalid card type 0x%X\n", __FUNCTION__,card->type); err = (EINVAL); break; } return (err); } /* * Write from a data buffer to adapter's memory in 4-byte chunks. * Note that we ensure that the SDLA memory address is on a 4-byte boundary * before we begin moving the data in 4-byte chunks. */ static void sdla_poke_by_4(sdlahw_t *hw, unsigned long offset, u_int8_t *buf, unsigned int len) { /* byte copy data until we get to a 4-byte boundary */ while (len && (offset & 0x03)) { sdla_bus_write_1(hw, offset++, *buf); buf++; len --; } /* copy data in 4-byte chunks */ while (len >= 4) { sdla_bus_write_4(hw, offset, *(unsigned long *)buf); offset += 4; buf += 4; len -= 4; } /* byte copy any remaining data */ while (len) { sdla_bus_write_1(hw, offset++, *buf); buf++; len --; } } int sdla_poke_byte(void *phw, unsigned long offset, u_int8_t value) { sdlahw_t *hw = (sdlahw_t*)phw; SDLA_MAGIC(hw); /* Sangoma ISA card sdla_bus_write_1(hw, offset, value); */ sdla_poke(hw, offset, (void*)&value, 1); return (0); } int sdla_set_bit(void *phw, unsigned long offset, u_int8_t value) { sdlahw_t *hw = (sdlahw_t*)phw; u_int8_t tmp; SDLA_MAGIC(hw); /* Sangoma ISA card -> sdla_bus_read_1(hw, offset, &tmp); */ sdla_peek(hw, offset, (void*)&tmp, 1); tmp |= value; /* Sangoma ISA card -> sdla_bus_write_1(hw, offset, tmp); */ sdla_poke(hw, offset, (void*)&tmp, 1); return (0); } int sdla_clear_bit(void *phw, unsigned long offset, u_int8_t value) { sdlahw_t *hw = (sdlahw_t*)phw; u_int8_t tmp; SDLA_MAGIC(hw); /* Sangoma ISA card -> sdla_bus_read_1(hw, offset, &tmp); */ sdla_peek(hw, offset, (void*)&tmp, 1); tmp &= ~value; /* Sangoma ISA card -> sdla_bus_write_1(hw, offset, tmp); */ sdla_poke(hw, offset, (void*)&tmp, 1); return (0); } /* * Find the AFT HDLC PCI adapter in the PCI bus. * Return the number of AFT adapters found (0 if no adapter found). */ static int sdla_detect_aft(sdlahw_t *hw) { sdlahw_card_t *card; u_int16_t ut_u16; WAN_ASSERT(hw == NULL); WAN_ASSERT(hw->hwcard == NULL); card = hw->hwcard; sdla_pci_read_config_dword(hw, (hw->cpu_no == SDLA_CPU_A) ? PCI_IO_BASE_DWORD : PCI_MEM_BASE0_DWORD, (u_int32_t*)&hw->mem_base_addr); if (!hw->mem_base_addr) { if (hw->cpu_no == SDLA_CPU_B) { printf("%s: No PCI memory allocated for CPU #B\n", hw->devname); } else { printf("%s: No PCI memory allocated to card\n", hw->devname); } return (EINVAL); } #ifdef DEBUG log(LOG_INFO, "%s: AFT PCI memory at 0x%lX\n", hw->devname, (unsigned long)hw->mem_base_addr); #endif /* DEBUG */ sdla_pci_read_config_byte(hw, PCI_INTLINE, (u_int8_t*)&hw->irq); if (hw->irq == PCI_IRQ_NOT_ALLOCATED) { printf("%s: IRQ not allocated to AFT adapter\n", hw->devname); return (EINVAL); } #ifdef DEBUG log(LOG_INFO, "%s: IRQ %d allocated to the AFT PCI card\n", hw->devname, hw->irq); #endif /* DEBUG */ hw->memory=XILINX_PCI_MEM_SIZE; /* Map the physical PCI memory to virtual memory */ bus_space_map(hw->hwcard->memt, hw->mem_base_addr, XILINX_PCI_MEM_SIZE, 0, &hw->dpmbase); if (!hw->dpmbase) { printf("%s: can't map mem space\n", hw->devname); return (EINVAL); } hw->status |= SDLA_MEM_MAPPED; /* Enable master operation on PCI and enable bar0 memory */ sdla_pci_read_config_word(hw, XILINX_PCI_CMD_REG, &ut_u16); ut_u16 |=0x06; sdla_pci_write_config_word(hw, XILINX_PCI_CMD_REG, ut_u16); /* Set PCI Latency of 0xFF*/ sdla_pci_write_config_dword(hw, XILINX_PCI_LATENCY_REG, XILINX_PCI_LATENCY); return (0); } /* * Detect adapter type. */ static int sdla_detect(sdlahw_t *hw) { sdlahw_card_t *card = NULL; int err = 0; WAN_ASSERT(hw == NULL); WAN_ASSERT(hw->hwcard == NULL); card = hw->hwcard; switch (card->type) { case SDLA_AFT: err = sdla_detect_aft(hw); break; } if (err) sdla_down(hw); return (err); } int sdla_is_te1(void *phw) { sdlahw_card_t *hwcard = NULL; sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); hwcard = hw->hwcard; switch (hwcard->atype) { case S5144_ADPTR_1_CPU_T1E1: case S5147_ADPTR_2_CPU_T1E1: case S5148_ADPTR_1_CPU_T1E1: case A101_ADPTR_1TE1: case A101_ADPTR_2TE1: return (1); } return (0); } int sdla_check_mismatch(void *phw, unsigned char media) { sdlahw_card_t *hwcard = NULL; sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); hwcard = hw->hwcard; if (media == WAN_MEDIA_T1 || media == WAN_MEDIA_E1) { if (hwcard->atype != S5144_ADPTR_1_CPU_T1E1 && hwcard->atype != S5147_ADPTR_2_CPU_T1E1 && hwcard->atype != S5148_ADPTR_1_CPU_T1E1) { log(LOG_INFO, "%s: Error: Card type mismatch: " "User=T1/E1 Actual=%s\n", hw->devname, SDLA_ADPTR_DECODE(hwcard->atype)); return (EIO); } hwcard->atype = S5144_ADPTR_1_CPU_T1E1; } else if (media == WAN_MEDIA_56K) { if (hwcard->atype != S5145_ADPTR_1_CPU_56K) { log(LOG_INFO, "%s: Error: Card type mismatch: " "User=56K Actual=%s\n", hw->devname, SDLA_ADPTR_DECODE(hwcard->atype)); return (EIO); } } else { if (hwcard->atype == S5145_ADPTR_1_CPU_56K || hwcard->atype == S5144_ADPTR_1_CPU_T1E1 || hwcard->atype == S5147_ADPTR_2_CPU_T1E1 || hwcard->atype == S5148_ADPTR_1_CPU_T1E1) { log(LOG_INFO, "%s: Error: Card type mismatch: " "User=S514(1/2/3) Actual=%s\n", hw->devname, SDLA_ADPTR_DECODE(hwcard->atype)); return (EIO); } } return (0); } int sdla_getcfg(void *phw, int type, void *value) { sdlahw_t* hw = (sdlahw_t*)phw; sdlahw_card_t *hwcard; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); hwcard = hw->hwcard; switch (type) { case SDLA_CARDTYPE: *(u_int16_t*)value = hwcard->type; break; case SDLA_MEMBASE: *(bus_space_handle_t*)value = hw->dpmbase; break; case SDLA_MEMEND: *(u_int32_t*)value = ((unsigned long)hw->dpmbase + hw->dpmsize - 1); break; case SDLA_MEMSIZE: *(u_int16_t*)value = hw->dpmsize; break; case SDLA_MEMORY: *(u_int32_t*)value = hw->memory; break; case SDLA_IRQ: *(u_int16_t*)value = hw->irq; break; case SDLA_ADAPTERTYPE: *(u_int16_t*)value = hwcard->atype; break; case SDLA_CPU: *(u_int16_t*)value = hw->cpu_no; break; case SDLA_SLOT: *(u_int16_t*)value = hwcard->slot_no; break; case SDLA_BUS: *(u_int16_t*)value = hwcard->bus_no; break; case SDLA_DMATAG: *(bus_dma_tag_t*)value = hwcard->pa.pa_dmat; break; case SDLA_PCIEXTRAVER: *(u_int8_t*)value = hwcard->pci_extra_ver; break; case SDLA_BASEADDR: *(u_int32_t*)value = hw->mem_base_addr; break; } return (0); } int sdla_get_hwcard(void *phw, void **phwcard) { sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); *phwcard = hw->hwcard; return (0); } int sdla_get_hwprobe(void *phw, void **str) { sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); if (hw->hwprobe) *str = hw->hwprobe->hw_info; return (0); } int sdla_bus_write_1(void *phw, unsigned int offset, u_int8_t value) { sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); if (!(hw->status & SDLA_MEM_MAPPED)) return (0); bus_space_write_1(hw->hwcard->memt, hw->dpmbase, offset, value); return (0); } int sdla_bus_write_2(void *phw, unsigned int offset, u_int16_t value) { sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); if (!(hw->status & SDLA_MEM_MAPPED)) return (0); bus_space_write_2(hw->hwcard->memt, hw->dpmbase, offset, value); return (0); } int sdla_bus_write_4(void *phw, unsigned int offset, u_int32_t value) { sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); if (!(hw->status & SDLA_MEM_MAPPED)) return (0); bus_space_write_4(hw->hwcard->memt, hw->dpmbase, offset, value); return (0); } int sdla_bus_read_1(void *phw, unsigned int offset, u_int8_t *value) { sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT2(hw == NULL, 0); SDLA_MAGIC(hw); if (!(hw->status & SDLA_MEM_MAPPED)) return (0); *value = bus_space_read_1(hw->hwcard->memt, hw->dpmbase, offset); return (0); } int sdla_bus_read_2(void *phw, unsigned int offset, u_int16_t *value) { sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT2(hw == NULL, 0); SDLA_MAGIC(hw); if (!(hw->status & SDLA_MEM_MAPPED)) return (0); *value = bus_space_read_2(hw->hwcard->memt, hw->dpmbase, offset); return (0); } int sdla_bus_read_4(void *phw, unsigned int offset, u_int32_t *value) { sdlahw_t *hw = (sdlahw_t*)phw; WAN_ASSERT2(hw == NULL, 0); WAN_ASSERT2(hw->dpmbase == 0, 0); SDLA_MAGIC(hw); if (!(hw->status & SDLA_MEM_MAPPED)) return (0); *value = bus_space_read_4(hw->hwcard->memt, hw->dpmbase, offset); return (0); } static int sdla_pci_read_config_dword(void *phw, int reg, u_int32_t *value) { sdlahw_t *hw = (sdlahw_t*)phw; sdlahw_card_t *hwcard; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); hwcard = hw->hwcard; *value = pci_conf_read(hwcard->pa.pa_pc, hwcard->pa.pa_tag, reg); return (0); } static int sdla_pci_read_config_word(void *phw, int reg, u_int16_t *value) { sdlahw_t *hw = (sdlahw_t*)phw; sdlahw_card_t *hwcard; u_int32_t tmp = 0x00; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); hwcard = hw->hwcard; tmp = pci_conf_read(hwcard->pa.pa_pc, hwcard->pa.pa_tag, reg); *value = (u_int16_t)((tmp >> 16) & 0xFFFF); return (0); } static int sdla_pci_read_config_byte(void *phw, int reg, u_int8_t *value) { sdlahw_t *hw = (sdlahw_t*)phw; sdlahw_card_t *hwcard; u_int32_t tmp = 0x00; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); hwcard = hw->hwcard; tmp = pci_conf_read(hwcard->pa.pa_pc, hwcard->pa.pa_tag, reg); *value = (u_int8_t)(tmp & 0xFF); return (0); } static int sdla_pci_write_config_dword(void *phw, int reg, u_int32_t value) { sdlahw_t *hw = (sdlahw_t*)phw; sdlahw_card_t *card; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); card = hw->hwcard; pci_conf_write(card->pa.pa_pc, card->pa.pa_tag, reg, value); return (0); } static int sdla_pci_write_config_word(void *phw, int reg, u_int16_t value) { sdlahw_t *hw = (sdlahw_t*)phw; sdlahw_card_t *card; WAN_ASSERT(hw == NULL); SDLA_MAGIC(hw); WAN_ASSERT(hw->hwcard == NULL); card = hw->hwcard; pci_conf_write(card->pa.pa_pc, card->pa.pa_tag, reg, value); return (0); }