/* hermes.c * * Driver core for the "Hermes" wireless MAC controller, as used in * the Lucent Orinoco and Cabletron RoamAbout cards. It should also * work on the hfa3841 and hfa3842 MAC controller chips used in the * Prism II chipsets. * * This is not a complete driver, just low-level access routines for * the MAC controller itself. * * Based on the prism2 driver from Absolute Value Systems' linux-wlan * project, the Linux wvlan_cs driver, Lucent's HCF-Light * (wvlan_hcf.c) library, and the NetBSD wireless driver (in no * particular order). * * Copyright (C) 2000, David Gibson, Linuxcare Australia. * (C) Copyright David Gibson, IBM Corp. 2001-2003. * * The contents of this file are subject to the Mozilla Public License * Version 1.1 (the "License"); you may not use this file except in * compliance with the License. You may obtain a copy of the License * at http://www.mozilla.org/MPL/ * * Software distributed under the License is distributed on an "AS IS" * basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See * the License for the specific language governing rights and * limitations under the License. * * Alternatively, the contents of this file may be used under the * terms of the GNU General Public License version 2 (the "GPL"), in * which case the provisions of the GPL are applicable instead of the * above. If you wish to allow the use of your version of this file * only under the terms of the GPL and not to allow others to use your * version of this file under the MPL, indicate your decision by * deleting the provisions above and replace them with the notice and * other provisions required by the GPL. If you do not delete the * provisions above, a recipient may use your version of this file * under either the MPL or the GPL. */ #include #include #include #include #include #include "hermes.h" MODULE_DESCRIPTION("Low-level driver helper for Lucent Hermes chipset and Prism II HFA384x wireless MAC controller"); MODULE_AUTHOR("Pavel Roskin " " & David Gibson "); MODULE_LICENSE("Dual MPL/GPL"); /* These are maximum timeouts. Most often, card wil react much faster */ #define CMD_BUSY_TIMEOUT (100) /* In iterations of ~1us */ #define CMD_INIT_TIMEOUT (50000) /* in iterations of ~10us */ #define CMD_COMPL_TIMEOUT (20000) /* in iterations of ~10us */ #define ALLOC_COMPL_TIMEOUT (1000) /* in iterations of ~10us */ /* * Debugging helpers */ #define DMSG(stuff...) do {printk(KERN_DEBUG "hermes @ %p: " , hw->iobase); \ printk(stuff);} while (0) #undef HERMES_DEBUG #ifdef HERMES_DEBUG #include #define DEBUG(lvl, stuff...) if ( (lvl) <= HERMES_DEBUG) DMSG(stuff) #else /* ! HERMES_DEBUG */ #define DEBUG(lvl, stuff...) do { } while (0) #endif /* ! HERMES_DEBUG */ /* * Internal functions */ /* Issue a command to the chip. Waiting for it to complete is the caller's problem. Returns -EBUSY if the command register is busy, 0 on success. Callable from any context. */ static int hermes_issue_cmd(hermes_t *hw, u16 cmd, u16 param0) { int k = CMD_BUSY_TIMEOUT; u16 reg; /* First wait for the command register to unbusy */ reg = hermes_read_regn(hw, CMD); while ( (reg & HERMES_CMD_BUSY) && k ) { k--; udelay(1); reg = hermes_read_regn(hw, CMD); } if (reg & HERMES_CMD_BUSY) { return -EBUSY; } hermes_write_regn(hw, PARAM2, 0); hermes_write_regn(hw, PARAM1, 0); hermes_write_regn(hw, PARAM0, param0); hermes_write_regn(hw, CMD, cmd); return 0; } /* * Function definitions */ void hermes_struct_init(hermes_t *hw, void __iomem *address, int reg_spacing) { hw->iobase = address; hw->reg_spacing = reg_spacing; hw->inten = 0x0; } int hermes_init(hermes_t *hw) { u16 status, reg; int err = 0; int k; /* We don't want to be interrupted while resetting the chipset */ hw->inten = 0x0; hermes_write_regn(hw, INTEN, 0); hermes_write_regn(hw, EVACK, 0xffff); /* Normally it's a "can't happen" for the command register to be busy when we go to issue a command because we are serializing all commands. However we want to have some chance of resetting the card even if it gets into a stupid state, so we actually wait to see if the command register will unbusy itself here. */ k = CMD_BUSY_TIMEOUT; reg = hermes_read_regn(hw, CMD); while (k && (reg & HERMES_CMD_BUSY)) { if (reg == 0xffff) /* Special case - the card has probably been removed, so don't wait for the timeout */ return -ENODEV; k--; udelay(1); reg = hermes_read_regn(hw, CMD); } /* No need to explicitly handle the timeout - if we've timed out hermes_issue_cmd() will probably return -EBUSY below */ /* According to the documentation, EVSTAT may contain obsolete event occurrence information. We have to acknowledge it by writing EVACK. */ reg = hermes_read_regn(hw, EVSTAT); hermes_write_regn(hw, EVACK, reg); /* We don't use hermes_docmd_wait here, because the reset wipes the magic constant in SWSUPPORT0 away, and it gets confused */ err = hermes_issue_cmd(hw, HERMES_CMD_INIT, 0); if (err) return err; reg = hermes_read_regn(hw, EVSTAT); k = CMD_INIT_TIMEOUT; while ( (! (reg & HERMES_EV_CMD)) && k) { k--; udelay(10); reg = hermes_read_regn(hw, EVSTAT); } hermes_write_regn(hw, SWSUPPORT0, HERMES_MAGIC); if (! hermes_present(hw)) { DEBUG(0, "hermes @ 0x%x: Card removed during reset.\n", hw->iobase); err = -ENODEV; goto out; } if (! (reg & HERMES_EV_CMD)) { printk(KERN_ERR "hermes @ %p: " "Timeout waiting for card to reset (reg=0x%04x)!\n", hw->iobase, reg); err = -ETIMEDOUT; goto out; } status = hermes_read_regn(hw, STATUS); hermes_write_regn(hw, EVACK, HERMES_EV_CMD); if (status & HERMES_STATUS_RESULT) err = -EIO; out: return err; } /* Issue a command to the chip, and (busy!) wait for it to * complete. * * Returns: < 0 on internal error, 0 on success, > 0 on error returned by the firmware * * Callable from any context, but locking is your problem. */ int hermes_docmd_wait(hermes_t *hw, u16 cmd, u16 parm0, struct hermes_response *resp) { int err; int k; u16 reg; u16 status; err = hermes_issue_cmd(hw, cmd, parm0); if (err) { if (! hermes_present(hw)) { if (net_ratelimit()) printk(KERN_WARNING "hermes @ %p: " "Card removed while issuing command " "0x%04x.\n", hw->iobase, cmd); err = -ENODEV; } else if (net_ratelimit()) printk(KERN_ERR "hermes @ %p: " "Error %d issuing command 0x%04x.\n", hw->iobase, err, cmd); goto out; } reg = hermes_read_regn(hw, EVSTAT); k = CMD_COMPL_TIMEOUT; while ( (! (reg & HERMES_EV_CMD)) && k) { k--; udelay(10); reg = hermes_read_regn(hw, EVSTAT); } if (! hermes_present(hw)) { printk(KERN_WARNING "hermes @ %p: Card removed " "while waiting for command 0x%04x completion.\n", hw->iobase, cmd); err = -ENODEV; goto out; } if (! (reg & HERMES_EV_CMD)) { printk(KERN_ERR "hermes @ %p: Timeout waiting for " "command 0x%04x completion.\n", hw->iobase, cmd); err = -ETIMEDOUT; goto out; } status = hermes_read_regn(hw, STATUS); if (resp) { resp->status = status; resp->resp0 = hermes_read_regn(hw, RESP0); resp->resp1 = hermes_read_regn(hw, RESP1); resp->resp2 = hermes_read_regn(hw, RESP2); } hermes_write_regn(hw, EVACK, HERMES_EV_CMD); if (status & HERMES_STATUS_RESULT) err = -EIO; out: return err; } int hermes_allocate(hermes_t *hw, u16 size, u16 *fid) { int err = 0; int k; u16 reg; if ( (size < HERMES_ALLOC_LEN_MIN) || (size > HERMES_ALLOC_LEN_MAX) ) return -EINVAL; err = hermes_docmd_wait(hw, HERMES_CMD_ALLOC, size, NULL); if (err) { return err; } reg = hermes_read_regn(hw, EVSTAT); k = ALLOC_COMPL_TIMEOUT; while ( (! (reg & HERMES_EV_ALLOC)) && k) { k--; udelay(10); reg = hermes_read_regn(hw, EVSTAT); } if (! hermes_present(hw)) { printk(KERN_WARNING "hermes @ %p: " "Card removed waiting for frame allocation.\n", hw->iobase); return -ENODEV; } if (! (reg & HERMES_EV_ALLOC)) { printk(KERN_ERR "hermes @ %p: " "Timeout waiting for frame allocation\n", hw->iobase); return -ETIMEDOUT; } *fid = hermes_read_regn(hw, ALLOCFID); hermes_write_regn(hw, EVACK, HERMES_EV_ALLOC); return 0; } /* Set up a BAP to read a particular chunk of data from card's internal buffer. * * Returns: < 0 on internal failure (errno), 0 on success, >0 on error * from firmware * * Callable from any context */ static int hermes_bap_seek(hermes_t *hw, int bap, u16 id, u16 offset) { int sreg = bap ? HERMES_SELECT1 : HERMES_SELECT0; int oreg = bap ? HERMES_OFFSET1 : HERMES_OFFSET0; int k; u16 reg; /* Paranoia.. */ if ( (offset > HERMES_BAP_OFFSET_MAX) || (offset % 2) ) return -EINVAL; k = HERMES_BAP_BUSY_TIMEOUT; reg = hermes_read_reg(hw, oreg); while ((reg & HERMES_OFFSET_BUSY) && k) { k--; udelay(1); reg = hermes_read_reg(hw, oreg); } if (reg & HERMES_OFFSET_BUSY) return -ETIMEDOUT; /* Now we actually set up the transfer */ hermes_write_reg(hw, sreg, id); hermes_write_reg(hw, oreg, offset); /* Wait for the BAP to be ready */ k = HERMES_BAP_BUSY_TIMEOUT; reg = hermes_read_reg(hw, oreg); while ( (reg & (HERMES_OFFSET_BUSY | HERMES_OFFSET_ERR)) && k) { k--; udelay(1); reg = hermes_read_reg(hw, oreg); } if (reg != offset) { printk(KERN_ERR "hermes @ %p: BAP%d offset %s: " "reg=0x%x id=0x%x offset=0x%x\n", hw->iobase, bap, (reg & HERMES_OFFSET_BUSY) ? "timeout" : "error", reg, id, offset); if (reg & HERMES_OFFSET_BUSY) { return -ETIMEDOUT; } return -EIO; /* error or wrong offset */ } return 0; } /* Read a block of data from the chip's buffer, via the * BAP. Synchronization/serialization is the caller's problem. len * must be even. * * Returns: < 0 on internal failure (errno), 0 on success, > 0 on error from firmware */ int hermes_bap_pread(hermes_t *hw, int bap, void *buf, int len, u16 id, u16 offset) { int dreg = bap ? HERMES_DATA1 : HERMES_DATA0; int err = 0; if ( (len < 0) || (len % 2) ) return -EINVAL; err = hermes_bap_seek(hw, bap, id, offset); if (err) goto out; /* Actually do the transfer */ hermes_read_words(hw, dreg, buf, len/2); out: return err; } /* Write a block of data to the chip's buffer, via the * BAP. Synchronization/serialization is the caller's problem. len * must be even. * * Returns: < 0 on internal failure (errno), 0 on success, > 0 on error from firmware */ int hermes_bap_pwrite(hermes_t *hw, int bap, const void *buf, int len, u16 id, u16 offset) { int dreg = bap ? HERMES_DATA1 : HERMES_DATA0; int err = 0; if ( (len < 0) || (len % 2) ) return -EINVAL; err = hermes_bap_seek(hw, bap, id, offset); if (err) goto out; /* Actually do the transfer */ hermes_write_words(hw, dreg, buf, len/2); out: return err; } /* Write a block of data to the chip's buffer with padding if * neccessary, via the BAP. Synchronization/serialization is the * caller's problem. len must be even. * * Returns: < 0 on internal failure (errno), 0 on success, > 0 on error from firmware */ int hermes_bap_pwrite_pad(hermes_t *hw, int bap, const void *buf, unsigned data_len, int len, u16 id, u16 offset) { int dreg = bap ? HERMES_DATA1 : HERMES_DATA0; int err = 0; if (len < 0 || len % 2 || data_len > len) return -EINVAL; err = hermes_bap_seek(hw, bap, id, offset); if (err) goto out; /* Transfer all the complete words of data */ hermes_write_words(hw, dreg, buf, data_len/2); /* If there is an odd byte left over pad and transfer it */ if (data_len & 1) { u8 end[2]; end[1] = 0; end[0] = ((unsigned char *)buf)[data_len - 1]; hermes_write_words(hw, dreg, end, 1); data_len ++; } /* Now send zeros for the padding */ if (data_len < len) hermes_clear_words(hw, dreg, (len - data_len) / 2); /* Complete */ out: return err; } /* Read a Length-Type-Value record from the card. * * If length is NULL, we ignore the length read from the card, and * read the entire buffer regardless. This is useful because some of * the configuration records appear to have incorrect lengths in * practice. * * Callable from user or bh context. */ int hermes_read_ltv(hermes_t *hw, int bap, u16 rid, unsigned bufsize, u16 *length, void *buf) { int err = 0; int dreg = bap ? HERMES_DATA1 : HERMES_DATA0; u16 rlength, rtype; unsigned nwords; if ( (bufsize < 0) || (bufsize % 2) ) return -EINVAL; err = hermes_docmd_wait(hw, HERMES_CMD_ACCESS, rid, NULL); if (err) return err; err = hermes_bap_seek(hw, bap, rid, 0); if (err) return err; rlength = hermes_read_reg(hw, dreg); if (! rlength) return -ENODATA; rtype = hermes_read_reg(hw, dreg); if (length) *length = rlength; if (rtype != rid) printk(KERN_WARNING "hermes @ %p: %s(): " "rid (0x%04x) does not match type (0x%04x)\n", hw->iobase, __FUNCTION__, rid, rtype); if (HERMES_RECLEN_TO_BYTES(rlength) > bufsize) printk(KERN_WARNING "hermes @ %p: " "Truncating LTV record from %d to %d bytes. " "(rid=0x%04x, len=0x%04x)\n", hw->iobase, HERMES_RECLEN_TO_BYTES(rlength), bufsize, rid, rlength); nwords = min((unsigned)rlength - 1, bufsize / 2); hermes_read_words(hw, dreg, buf, nwords); return 0; } int hermes_write_ltv(hermes_t *hw, int bap, u16 rid, u16 length, const void *value) { int dreg = bap ? HERMES_DATA1 : HERMES_DATA0; int err = 0; unsigned count; if (length == 0) return -EINVAL; err = hermes_bap_seek(hw, bap, rid, 0); if (err) return err; hermes_write_reg(hw, dreg, length); hermes_write_reg(hw, dreg, rid); count = length - 1; hermes_write_words(hw, dreg, value, count); err = hermes_docmd_wait(hw, HERMES_CMD_ACCESS | HERMES_CMD_WRITE, rid, NULL); return err; } EXPORT_SYMBOL(hermes_struct_init); EXPORT_SYMBOL(hermes_init); EXPORT_SYMBOL(hermes_docmd_wait); EXPORT_SYMBOL(hermes_allocate); EXPORT_SYMBOL(hermes_bap_pread); EXPORT_SYMBOL(hermes_bap_pwrite); EXPORT_SYMBOL(hermes_bap_pwrite_pad); EXPORT_SYMBOL(hermes_read_ltv); EXPORT_SYMBOL(hermes_write_ltv); static int __init init_hermes(void) { return 0; } static void __exit exit_hermes(void) { } module_init(init_hermes); module_exit(exit_hermes);